// This file was generated automatially by gencpp's singleheader.cpp(See: https://github.com/Ed94/gencpp) #pragma once #ifdef __clang__ # pragma clang diagnostic push # pragma clang diagnostic ignored "-Wunused-const-variable" # pragma clang diagnostic ignored "-Wunused-but-set-variable" # pragma clang diagnostic ignored "-Wswitch" # pragma clang diagnostic ignored "-Wunused-variable" # pragma clang diagnostic ignored "-Wunknown-pragmas" # pragma clang diagnostic ignored "-Wvarargs" # pragma clang diagnostic ignored "-Wunused-function" #endif #ifdef __GNUC__ # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wunknown-pragmas" # pragma GCC diagnostic ignored "-Wcomment" # pragma GCC diagnostic ignored "-Wswitch" # pragma GCC diagnostic ignored "-Wunused-variable" #endif /* gencpp: An attempt at "simple" staged metaprogramming for c/c++. See Readme.md for more information from the project repository. Public Address: https://github.com/Ed94/gencpp This is a single header variant of the library. Define GEN_IMPLEMENTATION before including this file in a single compilation unit. */ #if ! defined(GEN_DONT_ENFORCE_GEN_TIME_GUARD) && ! defined(GEN_TIME) # error Gen.hpp : GEN_TIME not defined #endif #ifdef GEN_DONT_USE_NAMESPACE # define GEN_NS_BEGIN # define GEN_NS_END #else # define GEN_NS_BEGIN namespace gen { # define GEN_NS_END } #endif //! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file. // Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl #ifndef GEN_ROLL_OWN_DEPENDENCIES #pragma region Platform Detection /* Platform architecture */ #if defined( _WIN64 ) || defined( __x86_64__ ) || defined( _M_X64 ) || defined( __64BIT__ ) || defined( __powerpc64__ ) || defined( __ppc64__ ) || defined( __aarch64__ ) # ifndef GEN_ARCH_64_BIT # define GEN_ARCH_64_BIT 1 # endif #else # ifndef GEN_ARCH_32_BItxt_StrCaT # define GEN_ARCH_32_BIT 1 # endif #endif /* Platform OS */ #if defined( _WIN32 ) || defined( _WIN64 ) # ifndef GEN_SYSTEM_WINDOWS # define GEN_SYSTEM_WINDOWS 1 # endif #elif defined( __APPLE__ ) && defined( __MACH__ ) # ifndef GEN_SYSTEM_OSX # define GEN_SYSTEM_OSX 1 # endif # ifndef GEN_SYSTEM_MACOS # define GEN_SYSTEM_MACOS 1 # endif # include # if TARGET_IPHONE_SIMULATOR == 1 || TARGET_OS_IPHONE == 1 # ifndef GEN_SYSTEM_IOS # define GEN_SYSTEM_IOS 1 # endif # endif #elif defined( __unix__ ) # ifndef GEN_SYSTEM_UNIX # define GEN_SYSTEM_UNIX 1 # endif # if defined( ANDROID ) || defined( __ANDROID__ ) # ifndef GEN_SYSTEM_ANDROID # define GEN_SYSTEM_ANDROID 1 # endif # ifndef GEN_SYSTEM_LINUX # define GEN_SYSTEM_LINUX 1 # endif # elif defined( __linux__ ) # ifndef GEN_SYSTEM_LINUX # define GEN_SYSTEM_LINUX 1 # endif # elif defined( __FreeBSD__ ) || defined( __FreeBSD_kernel__ ) # ifndef GEN_SYSTEM_FREEBSD # define GEN_SYSTEM_FREEBSD 1 # endif # elif defined( __OpenBSD__ ) # ifndef GEN_SYSTEM_OPENBSD # define GEN_SYSTEM_OPENBSD 1 # endif # elif defined( __EMSCRIPTEN__ ) # ifndef GEN_SYSTEM_EMSCRIPTEN # define GEN_SYSTEM_EMSCRIPTEN 1 # endif # elif defined( __CYGWIN__ ) # ifndef GEN_SYSTEM_CYGWIN # define GEN_SYSTEM_CYGWIN 1 # endif # else # error This UNIX operating system is not supported # endif #else # error This operating system is not supported #endif /* Platform compiler */ #if defined( _MSC_VER ) # define GEN_COMPILER_MSVC 1 #elif defined( __GNUC__ ) # define GEN_COMPILER_GCC 1 #elif defined( __clang__ ) # define GEN_COMPILER_CLANG 1 #elif defined( __MINGW32__ ) # define GEN_COMPILER_MINGW 1 # error Unknown compiler #endif #if defined( __has_attribute ) # define GEN_HAS_ATTRIBUTE( attribute ) __has_attribute( attribute ) #else # define GEN_HAS_ATTRIBUTE( attribute ) ( 0 ) #endif #if defined(GEN_GCC_VERSION_CHECK) # undef GEN_GCC_VERSION_CHECK #endif #if defined(GEN_GCC_VERSION) # define GEN_GCC_VERSION_CHECK(major,minor,patch) (GEN_GCC_VERSION >= GEN_VERSION_ENCODE(major, minor, patch)) #else # define GEN_GCC_VERSION_CHECK(major,minor,patch) (0) #endif #pragma endregion Platform Detection #pragma region Mandatory Includes # include # include # if defined( GEN_SYSTEM_WINDOWS ) # include # endif #pragma endregion Mandatory Includes #ifdef GEN_DONT_USE_NAMESPACE # define GEN_NS # define GEN_NS_BEGIN # define GEN_NS_END #else # define GEN_NS gen:: # define GEN_NS_BEGIN namespace gen { # define GEN_NS_END } #endif GEN_NS_BEGIN #pragma region Macros #ifndef global #define global static // Global variables #endif #ifndef internal #define internal static // Internal linkage #endif #ifndef local_persist #define local_persist static // Local Persisting variables #endif #ifndef api_c #define api_c extern "C" #endif #ifndef bit #define bit( Value ) ( 1 << Value ) #define bitfield_is_equal( Type, Field, Mask ) ( (Type(Mask) & Type(Field)) == Type(Mask) ) #endif #ifndef ccast #define ccast( type, value ) ( const_cast< type >( (value) ) ) #endif #ifndef pcast #define pcast( type, value ) ( * reinterpret_cast< type* >( & ( value ) ) ) #endif #ifndef rcast #define rcast( type, value ) reinterpret_cast< type >( value ) #endif #ifndef scast #define scast( type, value ) static_cast< type >( value ) #endif #ifndef stringize #define stringize_va( ... ) #__VA_ARGS__ #define stringize( ... ) stringize_va( __VA_ARGS__ ) #endif #ifndef do_once #define do_once( statement ) for ( local_persist b32 once = true; once; once = false, (statement) ) #define do_once_start \ do \ { \ local_persist \ bool done = false; \ if ( done ) \ break; \ done = true; #define do_once_end \ } \ while(0); #endif #ifndef labeled_scope_start #define labeled_scope_start if ( false ) { #define labeled_scope_end } #endif #ifndef compiler_decorated_func_name # ifdef COMPILER_CLANG # define compiler_decorated_func_name __PRETTY_NAME__ # elif defined(COMPILER_MSVC) # define compiler_decorated_func_name __FUNCDNAME__ # endif #endif #ifndef num_args_impl #define num_args_impl( _0, \ _1, _2, _3, _4, _5, _6, _7, _8, _9, _10, \ _11, _12, _13, _14, _15, _16, _17, _18, _19, _20, \ _21, _22, _23, _24, _25, _26, _27, _28, _29, _30, \ _31, _32, _33, _34, _35, _36, _37, _38, _39, _40, \ _41, _42, _43, _44, _45, _46, _47, _48, _49, _50, \ _51, _52, _53, _54, _55, _56, _57, _58, _59, _60, \ _61, _62, _63, _64, _65, _66, _67, _68, _69, _70, \ _71, _72, _73, _74, _75, _76, _77, _78, _79, _80, \ _81, _82, _83, _84, _85, _86, _87, _88, _89, _90, \ _91, _92, _93, _94, _95, _96, _97, _98, _99, _100, \ N, ... \ ) N // ## deletes preceding comma if _VA_ARGS__ is empty (GCC, Clang) #define num_args(...) \ num_args_impl(_, ## __VA_ARGS__, \ 100, 99, 98, 97, 96, 95, 94, 93, 92, 91, \ 90, 89, 88, 87, 86, 85, 84, 83, 82, 81, \ 80, 79, 78, 77, 76, 75, 74, 73, 72, 71, \ 70, 69, 68, 67, 66, 65, 64, 63, 62, 61, \ 60, 59, 58, 57, 56, 55, 54, 53, 52, 51, \ 50, 49, 48, 47, 46, 45, 44, 43, 42, 41, \ 40, 39, 38, 37, 36, 35, 34, 33, 32, 31, \ 30, 29, 28, 27, 26, 25, 24, 23, 22, 21, \ 20, 19, 18, 17, 16, 15, 14, 13, 12, 11, \ 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, \ 0 \ ) #endif #ifndef clamp #define clamp( x, lower, upper ) min( max( ( x ), ( lower ) ), ( upper ) ) #endif #ifndef count_of #define count_of( x ) ( ( size_of( x ) / size_of( 0 [ x ] ) ) / ( ( ssize )( ! ( size_of( x ) % size_of( 0 [ x ] ) ) ) ) ) #endif #ifndef is_between #define is_between( x, lower, upper ) ( ( ( lower ) <= ( x ) ) && ( ( x ) <= ( upper ) ) ) #endif #ifndef size_of #define size_of( x ) ( ssize )( sizeof( x ) ) #endif #ifndef max #define max( a, b ) ( (a > b) ? (a) : (b) ) #endif #ifndef min #define min( a, b ) ( (a < b) ? (a) : (b) ) #endif #if defined( _MSC_VER ) || defined( GEN_COMPILER_TINYC ) # define offset_of( Type, element ) ( ( GEN_NS( ssize ) ) & ( ( ( Type* )0 )->element ) ) #else # define offset_of( Type, element ) __builtin_offsetof( Type, element ) #endif #ifndef forceinline # ifdef GEN_COMPILER_MSVC # define forceinline __forceinline # define neverinline __declspec( noinline ) # elif defined(GEN_COMPILER_GCC) # define forceinline inline __attribute__((__always_inline__)) # define neverinline __attribute__( ( __noinline__ ) ) # elif defined(GEN_COMPILER_CLANG) # if __has_attribute(__always_inline__) # define forceinline inline __attribute__((__always_inline__)) # define neverinline __attribute__( ( __noinline__ ) ) # else # define forceinline # define neverinline # endif # else # define forceinline # define neverinline # endif #endif #ifndef neverinline # ifdef GEN_COMPILER_MSVC # define neverinline __declspec( noinline ) # elif defined(GEN_COMPILER_GCC) # define neverinline __attribute__( ( __noinline__ ) ) # elif defined(GEN_COMPILER_CLANG) # if __has_attribute(__always_inline__) # define neverinline __attribute__( ( __noinline__ ) ) # else # define neverinline # endif # else # define neverinline # endif #endif #pragma endregion Macros #pragma region Basic Types #define GEN_U8_MIN 0u #define GEN_U8_MAX 0xffu #define GEN_I8_MIN ( -0x7f - 1 ) #define GEN_I8_MAX 0x7f #define GEN_U16_MIN 0u #define GEN_U16_MAX 0xffffu #define GEN_I16_MIN ( -0x7fff - 1 ) #define GEN_I16_MAX 0x7fff #define GEN_U32_MIN 0u #define GEN_U32_MAX 0xffffffffu #define GEN_I32_MIN ( -0x7fffffff - 1 ) #define GEN_I32_MAX 0x7fffffff #define GEN_U64_MIN 0ull #define GEN_U64_MAX 0xffffffffffffffffull #define GEN_I64_MIN ( -0x7fffffffffffffffll - 1 ) #define GEN_I64_MAX 0x7fffffffffffffffll #if defined( GEN_ARCH_32_BIT ) # define GEN_USIZE_MIN GEN_U32_MIN # define GEN_USIZE_MAX GEN_U32_MAX # define GEN_ISIZE_MIN GEN_S32_MIN # define GEN_ISIZE_MAX GEN_S32_MAX #elif defined( GEN_ARCH_64_BIT ) # define GEN_USIZE_MIN GEN_U64_MIN # define GEN_USIZE_MAX GEN_U64_MAX # define GEN_ISIZE_MIN GEN_I64_MIN # define GEN_ISIZE_MAX GEN_I64_MAX #else # error Unknown architecture size. This library only supports 32 bit and 64 bit architectures. #endif #define GEN_F32_MIN 1.17549435e-38f #define GEN_F32_MAX 3.40282347e+38f #define GEN_F64_MIN 2.2250738585072014e-308 #define GEN_F64_MAX 1.7976931348623157e+308 #if defined( GEN_COMPILER_MSVC ) # if _MSC_VER < 1300 typedef unsigned char u8; typedef signed char s8; typedef unsigned short u16; typedef signed short s16; typedef unsigned int u32; typedef signed int s32; # else typedef unsigned __int8 u8; typedef signed __int8 s8; typedef unsigned __int16 u16; typedef signed __int16 s16; typedef unsigned __int32 u32; typedef signed __int32 s32; # endif typedef unsigned __int64 u64; typedef signed __int64 s64; #else # include typedef uint8_t u8; typedef int8_t s8; typedef uint16_t u16; typedef int16_t s16; typedef uint32_t u32; typedef int32_t s32; typedef uint64_t u64; typedef int64_t s64; #endif static_assert( sizeof( u8 ) == sizeof( s8 ), "sizeof(u8) != sizeof(s8)" ); static_assert( sizeof( u16 ) == sizeof( s16 ), "sizeof(u16) != sizeof(s16)" ); static_assert( sizeof( u32 ) == sizeof( s32 ), "sizeof(u32) != sizeof(s32)" ); static_assert( sizeof( u64 ) == sizeof( s64 ), "sizeof(u64) != sizeof(s64)" ); static_assert( sizeof( u8 ) == 1, "sizeof(u8) != 1" ); static_assert( sizeof( u16 ) == 2, "sizeof(u16) != 2" ); static_assert( sizeof( u32 ) == 4, "sizeof(u32) != 4" ); static_assert( sizeof( u64 ) == 8, "sizeof(u64) != 8" ); typedef size_t usize; typedef ptrdiff_t ssize; static_assert( sizeof( usize ) == sizeof( ssize ), "sizeof(usize) != sizeof(ssize)" ); // NOTE: (u)zpl_intptr is only here for semantic reasons really as this library will only support 32/64 bit OSes. #if defined( _WIN64 ) typedef signed __int64 sptr; typedef unsigned __int64 uptr; #elif defined( _WIN32 ) // NOTE; To mark types changing their size, e.g. zpl_intptr # ifndef _W64 # if ! defined( __midl ) && ( defined( _X86_ ) || defined( _M_IX86 ) ) && _MSC_VER >= 1300 # define _W64 __w64 # else # define _W64 # endif # endif typedef _W64 signed int sptr; typedef _W64 unsigned int uptr; #else typedef uintptr_t uptr; typedef intptr_t sptr; #endif static_assert( sizeof( uptr ) == sizeof( sptr ), "sizeof(uptr) != sizeof(sptr)" ); typedef float f32; typedef double f64; static_assert( sizeof( f32 ) == 4, "sizeof(f32) != 4" ); static_assert( sizeof( f64 ) == 8, "sizeof(f64) != 8" ); typedef s8 b8; typedef s16 b16; typedef s32 b32; using mem_ptr = void*; using mem_ptr_const = void const*; template uptr to_uptr( Type* ptr ) { return (uptr)ptr; } template sptr to_sptr( Type* ptr ) { return (sptr)ptr; } template mem_ptr to_mem_ptr ( Type ptr ) { return (mem_ptr) ptr; } template mem_ptr_const to_mem_ptr_const( Type ptr ) { return (mem_ptr_const)ptr; } #pragma endregion Basic Types #pragma region Debug #if defined( _MSC_VER ) # if _MSC_VER < 1300 # define GEN_DEBUG_TRAP() __asm int 3 /* Trap to debugger! */ # else # define GEN_DEBUG_TRAP() __debugbreak() # endif #elif defined( GEN_COMPILER_TINYC ) # define GEN_DEBUG_TRAP() process_exit( 1 ) #else # define GEN_DEBUG_TRAP() __builtin_trap() #endif #define GEN_ASSERT( cond ) GEN_ASSERT_MSG( cond, NULL ) #define GEN_ASSERT_MSG( cond, msg, ... ) \ do \ { \ if ( ! ( cond ) ) \ { \ assert_handler( #cond, __FILE__, scast( s64, __LINE__ ), msg, ##__VA_ARGS__ ); \ GEN_DEBUG_TRAP(); \ } \ } while ( 0 ) #define GEN_ASSERT_NOT_NULL( ptr ) GEN_ASSERT_MSG( ( ptr ) != NULL, #ptr " must not be NULL" ) // NOTE: Things that shouldn't happen with a message! #define GEN_PANIC( msg, ... ) GEN_ASSERT_MSG( 0, msg, ##__VA_ARGS__ ) #if Build_Debug #define GEN_FATAL( ... ) \ do \ { \ local_persist thread_local \ char buf[GEN_PRINTF_MAXLEN] = { 0 }; \ \ str_fmt(buf, GEN_PRINTF_MAXLEN, __VA_ARGS__); \ GEN_PANIC(buf); \ } \ while (0) #else # define GEN_FATAL( ... ) \ do \ { \ str_fmt_out_err( __VA_ARGS__ ); \ process_exit(1); \ } \ while (0) #endif void assert_handler( char const* condition, char const* file, s32 line, char const* msg, ... ); s32 assert_crash( char const* condition ); void process_exit( u32 code ); #pragma endregion Debug #pragma region Memory #define kilobytes( x ) ( ( x ) * ( s64 )( 1024 ) ) #define megabytes( x ) ( kilobytes( x ) * ( s64 )( 1024 ) ) #define gigabytes( x ) ( megabytes( x ) * ( s64 )( 1024 ) ) #define terabytes( x ) ( gigabytes( x ) * ( s64 )( 1024 ) ) #define GEN__ONES ( scast( GEN_NS usize, - 1) / GEN_U8_MAX ) #define GEN__HIGHS ( GEN__ONES * ( GEN_U8_MAX / 2 + 1 ) ) #define GEN__HAS_ZERO( x ) ( ( ( x ) - GEN__ONES ) & ~( x ) & GEN__HIGHS ) template< class Type > void swap( Type& a, Type& b ) { Type tmp = a; a = b; b = tmp; } //! Checks if value is power of 2. b32 is_power_of_two( ssize x ); //! Aligns address to specified alignment. void* align_forward( void* ptr, ssize alignment ); //! Aligns value to a specified alignment. s64 align_forward_i64( s64 value, ssize alignment ); //! Moves pointer forward by bytes. void* pointer_add( void* ptr, ssize bytes ); //! Moves pointer forward by bytes. void const* pointer_add_const( void const* ptr, ssize bytes ); //! Calculates difference between two addresses. ssize pointer_diff( void const* begin, void const* end ); //! Copy non-overlapping memory from source to destination. void* mem_copy( void* dest, void const* source, ssize size ); //! Search for a constant value within the size limit at memory location. void const* mem_find( void const* data, u8 byte_value, ssize size ); //! Copy memory from source to destination. void* mem_move( void* dest, void const* source, ssize size ); //! Set constant value at memory location with specified size. void* mem_set( void* data, u8 byte_value, ssize size ); //! @param ptr Memory location to clear up. //! @param size The size to clear up with. void zero_size( void* ptr, ssize size ); //! Clears up an item. #define zero_item( t ) zero_size( ( t ), size_of( *( t ) ) ) // NOTE: Pass pointer of struct //! Clears up an array. #define zero_array( a, count ) zero_size( ( a ), size_of( *( a ) ) * count ) enum AllocType : u8 { EAllocation_ALLOC, EAllocation_FREE, EAllocation_FREE_ALL, EAllocation_RESIZE, }; using AllocatorProc = void* ( void* allocator_data, AllocType type , ssize size, ssize alignment , void* old_memory, ssize old_size , u64 flags ); struct AllocatorInfo { AllocatorProc* Proc; void* Data; }; enum AllocFlag { ALLOCATOR_FLAG_CLEAR_TO_ZERO = bit( 0 ), }; #ifndef GEN_DEFAULT_MEMORY_ALIGNMENT # define GEN_DEFAULT_MEMORY_ALIGNMENT ( 2 * size_of( void* ) ) #endif #ifndef GEN_DEFAULT_ALLOCATOR_FLAGS # define GEN_DEFAULT_ALLOCATOR_FLAGS ( ALLOCATOR_FLAG_CLEAR_TO_ZERO ) #endif //! Allocate memory with default alignment. void* alloc( AllocatorInfo a, ssize size ); //! Allocate memory with specified alignment. void* alloc_align( AllocatorInfo a, ssize size, ssize alignment ); //! Free allocated memory. void free( AllocatorInfo a, void* ptr ); //! Free all memory allocated by an allocator. void free_all( AllocatorInfo a ); //! Resize an allocated memory. void* resize( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size ); //! Resize an allocated memory with specified alignment. void* resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment ); //! Allocate memory for an item. #define alloc_item( allocator_, Type ) ( Type* )alloc( allocator_, size_of( Type ) ) //! Allocate memory for an array of items. #define alloc_array( allocator_, Type, count ) ( Type* )alloc( allocator_, size_of( Type ) * ( count ) ) /* heap memory analysis tools */ /* define GEN_HEAP_ANALYSIS to enable this feature */ /* call zpl_heap_stats_init at the beginning of the entry point */ /* you can call zpl_heap_stats_check near the end of the execution to validate any possible leaks */ void heap_stats_init( void ); ssize heap_stats_used_memory( void ); ssize heap_stats_alloc_count( void ); void heap_stats_check( void ); //! Allocate/Resize memory using default options. //! Use this if you don't need a "fancy" resize allocation void* default_resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment ); void* heap_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ); //! The heap allocator backed by operating system's memory manager. constexpr AllocatorInfo heap( void ) { return { heap_allocator_proc, nullptr }; } //! Helper to allocate memory using heap allocator. #define malloc( sz ) alloc( heap(), sz ) //! Helper to free memory allocated by heap allocator. #define mfree( ptr ) free( heap(), ptr ) struct VirtualMemory { void* data; ssize size; }; //! Initialize virtual memory from existing data. VirtualMemory vm_from_memory( void* data, ssize size ); //! Allocate virtual memory at address with size. //! @param addr The starting address of the region to reserve. If NULL, it lets operating system to decide where to allocate it. //! @param size The size to serve. VirtualMemory vm_alloc( void* addr, ssize size ); //! Release the virtual memory. b32 vm_free( VirtualMemory vm ); //! Trim virtual memory. VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size ); //! Purge virtual memory. b32 gen_vm_purge( VirtualMemory vm ); //! Retrieve VM's page size and alignment. ssize gen_virtual_memory_page_size( ssize* alignment_out ); struct Arena { static void* allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ); static Arena init_from_memory( void* start, ssize size ) { return { { nullptr, nullptr }, start, size, 0, 0 }; } static Arena init_from_allocator( AllocatorInfo backing, ssize size ) { Arena result = { backing, alloc( backing, size), size, 0, 0 }; return result; } static Arena init_sub( Arena& parent, ssize size ) { return init_from_allocator( parent.Backing, size ); } ssize alignment_of( ssize alignment ) { ssize alignment_offset, result_pointer, mask; GEN_ASSERT( is_power_of_two( alignment ) ); alignment_offset = 0; result_pointer = (ssize) PhysicalStart + TotalUsed; mask = alignment - 1; if ( result_pointer & mask ) alignment_offset = alignment - ( result_pointer & mask ); return alignment_offset; } // This id is defined by Unreal for asserts #pragma push_macro("check") #undef check void check() { GEN_ASSERT( TempCount == 0 ); } #pragma pop_macro("check") void free() { if ( Backing.Proc ) { gen::free( Backing, PhysicalStart ); PhysicalStart = nullptr; } } ssize size_remaining( ssize alignment ) { ssize result = TotalSize - ( TotalUsed + alignment_of( alignment ) ); return result; } AllocatorInfo Backing; void* PhysicalStart; ssize TotalSize; ssize TotalUsed; ssize TempCount; operator AllocatorInfo() { return { allocator_proc, this }; } }; // Just a wrapper around using an arena with memory associated with its scope instead of from an allocator. // Used for static segment or stack allocations. template< s32 Size > struct FixedArena { static FixedArena init() { FixedArena result = { Arena::init_from_memory( result.memory, Size ), {0} }; return result; } ssize size_remaining( ssize alignment ) { return arena.size_remaining( alignment ); } operator AllocatorInfo() { return { Arena::allocator_proc, &arena }; } Arena arena; char memory[ Size ]; }; using Arena_1KB = FixedArena< kilobytes( 1 ) >; using Arena_4KB = FixedArena< kilobytes( 4 ) >; using Arena_8KB = FixedArena< kilobytes( 8 ) >; using Arena_16KB = FixedArena< kilobytes( 16 ) >; using Arena_32KB = FixedArena< kilobytes( 32 ) >; using Arena_64KB = FixedArena< kilobytes( 64 ) >; using Arena_128KB = FixedArena< kilobytes( 128 ) >; using Arena_256KB = FixedArena< kilobytes( 256 ) >; using Arena_512KB = FixedArena< kilobytes( 512 ) >; using Arena_1MB = FixedArena< megabytes( 1 ) >; using Arena_2MB = FixedArena< megabytes( 2 ) >; using Arena_4MB = FixedArena< megabytes( 4 ) >; struct Pool { static void* allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ); static Pool init( AllocatorInfo backing, ssize num_blocks, ssize block_size ) { return init_align( backing, num_blocks, block_size, GEN_DEFAULT_MEMORY_ALIGNMENT ); } static Pool init_align( AllocatorInfo backing, ssize num_blocks, ssize block_size, ssize block_align ); void clear(); void free() { if ( Backing.Proc ) { gen::free( Backing, PhysicalStart ); } } AllocatorInfo Backing; void* PhysicalStart; void* FreeList; ssize BlockSize; ssize BlockAlign; ssize TotalSize; ssize NumBlocks; operator AllocatorInfo() { return { allocator_proc, this }; } }; inline b32 is_power_of_two( ssize x ) { if ( x <= 0 ) return false; return ! ( x & ( x - 1 ) ); } inline mem_ptr align_forward( void* ptr, ssize alignment ) { GEN_ASSERT( is_power_of_two( alignment ) ); uptr p = to_uptr(ptr); uptr forward = (p + ( alignment - 1 ) ) & ~( alignment - 1 ); return to_mem_ptr(forward); } inline s64 align_forward_i64( s64 value, ssize alignment ) { return value + ( alignment - value % alignment ) % alignment; } inline void* pointer_add ( void* ptr, ssize bytes ) { return rcast(void*, rcast( u8*, ptr) + bytes ); } inline void const* pointer_add_const( void const* ptr, ssize bytes ) { return rcast(void const*, rcast( u8 const*, ptr) + bytes ); } inline sptr pointer_diff( mem_ptr_const begin, mem_ptr_const end ) { return scast( ssize, rcast( u8 const*, end) - rcast(u8 const*, begin) ); } inline void* mem_move( void* destination, void const* source, ssize byte_count ) { if ( destination == NULL ) { return NULL; } u8* dest_ptr = rcast( u8*, destination); u8 const* src_ptr = rcast( u8 const*, source); if ( dest_ptr == src_ptr ) return dest_ptr; if ( src_ptr + byte_count <= dest_ptr || dest_ptr + byte_count <= src_ptr ) // NOTE: Non-overlapping return mem_copy( dest_ptr, src_ptr, byte_count ); if ( dest_ptr < src_ptr ) { if ( to_uptr(src_ptr) % size_of( ssize ) == to_uptr(dest_ptr) % size_of( ssize ) ) { while ( pcast( uptr, dest_ptr) % size_of( ssize ) ) { if ( ! byte_count-- ) return destination; *dest_ptr++ = *src_ptr++; } while ( byte_count >= size_of( ssize ) ) { * rcast(ssize*, dest_ptr) = * rcast(ssize const*, src_ptr); byte_count -= size_of( ssize ); dest_ptr += size_of( ssize ); src_ptr += size_of( ssize ); } } for ( ; byte_count; byte_count-- ) *dest_ptr++ = *src_ptr++; } else { if ( ( to_uptr(src_ptr) % size_of( ssize ) ) == ( to_uptr(dest_ptr) % size_of( ssize ) ) ) { while ( to_uptr( dest_ptr + byte_count ) % size_of( ssize ) ) { if ( ! byte_count-- ) return destination; dest_ptr[ byte_count ] = src_ptr[ byte_count ]; } while ( byte_count >= size_of( ssize ) ) { byte_count -= size_of( ssize ); * rcast(ssize*, dest_ptr + byte_count ) = * rcast( ssize const*, src_ptr + byte_count ); } } while ( byte_count ) byte_count--, dest_ptr[ byte_count ] = src_ptr[ byte_count ]; } return destination; } inline void* mem_set( void* destination, u8 fill_byte, ssize byte_count ) { if ( destination == NULL ) { return NULL; } ssize align_offset; u8* dest_ptr = rcast( u8*, destination); u32 fill_word = ( ( u32 )-1 ) / 255 * fill_byte; if ( byte_count == 0 ) return destination; dest_ptr[ 0 ] = dest_ptr[ byte_count - 1 ] = fill_byte; if ( byte_count < 3 ) return destination; dest_ptr[ 1 ] = dest_ptr[ byte_count - 2 ] = fill_byte; dest_ptr[ 2 ] = dest_ptr[ byte_count - 3 ] = fill_byte; if ( byte_count < 7 ) return destination; dest_ptr[ 3 ] = dest_ptr[ byte_count - 4 ] = fill_byte; if ( byte_count < 9 ) return destination; align_offset = -to_sptr( dest_ptr ) & 3; dest_ptr += align_offset; byte_count -= align_offset; byte_count &= -4; * rcast( u32*, ( dest_ptr + 0 ) ) = fill_word; * rcast( u32*, ( dest_ptr + byte_count - 4 ) ) = fill_word; if ( byte_count < 9 ) return destination; * rcast( u32*, dest_ptr + 4 ) = fill_word; * rcast( u32*, dest_ptr + 8 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 12 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 8 ) = fill_word; if ( byte_count < 25 ) return destination; * rcast( u32*, dest_ptr + 12 ) = fill_word; * rcast( u32*, dest_ptr + 16 ) = fill_word; * rcast( u32*, dest_ptr + 20 ) = fill_word; * rcast( u32*, dest_ptr + 24 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 28 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 24 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 20 ) = fill_word; * rcast( u32*, dest_ptr + byte_count - 16 ) = fill_word; align_offset = 24 + to_uptr( dest_ptr ) & 4; dest_ptr += align_offset; byte_count -= align_offset; { u64 fill_doubleword = ( scast( u64, fill_word) << 32 ) | fill_word; while ( byte_count > 31 ) { * rcast( u64*, dest_ptr + 0 ) = fill_doubleword; * rcast( u64*, dest_ptr + 8 ) = fill_doubleword; * rcast( u64*, dest_ptr + 16 ) = fill_doubleword; * rcast( u64*, dest_ptr + 24 ) = fill_doubleword; byte_count -= 32; dest_ptr += 32; } } return destination; } inline void* alloc_align( AllocatorInfo a, ssize size, ssize alignment ) { return a.Proc( a.Data, EAllocation_ALLOC, size, alignment, nullptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS ); } inline void* alloc( AllocatorInfo a, ssize size ) { return alloc_align( a, size, GEN_DEFAULT_MEMORY_ALIGNMENT ); } inline void free( AllocatorInfo a, void* ptr ) { if ( ptr != nullptr ) a.Proc( a.Data, EAllocation_FREE, 0, 0, ptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS ); } inline void free_all( AllocatorInfo a ) { a.Proc( a.Data, EAllocation_FREE_ALL, 0, 0, nullptr, 0, GEN_DEFAULT_ALLOCATOR_FLAGS ); } inline void* resize( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size ) { return resize_align( a, ptr, old_size, new_size, GEN_DEFAULT_MEMORY_ALIGNMENT ); } inline void* resize_align( AllocatorInfo a, void* ptr, ssize old_size, ssize new_size, ssize alignment ) { return a.Proc( a.Data, EAllocation_RESIZE, new_size, alignment, ptr, old_size, GEN_DEFAULT_ALLOCATOR_FLAGS ); } inline void* default_resize_align( AllocatorInfo a, void* old_memory, ssize old_size, ssize new_size, ssize alignment ) { if ( ! old_memory ) return alloc_align( a, new_size, alignment ); if ( new_size == 0 ) { free( a, old_memory ); return nullptr; } if ( new_size < old_size ) new_size = old_size; if ( old_size == new_size ) { return old_memory; } else { void* new_memory = alloc_align( a, new_size, alignment ); if ( ! new_memory ) return nullptr; mem_move( new_memory, old_memory, min( new_size, old_size ) ); free( a, old_memory ); return new_memory; } } inline void zero_size( void* ptr, ssize size ) { mem_set( ptr, 0, size ); } #pragma endregion Memory #pragma region String Ops const char* char_first_occurence( const char* str, char c ); constexpr auto str_find = &char_first_occurence; b32 char_is_alpha( char c ); b32 char_is_alphanumeric( char c ); b32 char_is_digit( char c ); b32 char_is_hex_digit( char c ); b32 char_is_space( char c ); char char_to_lower( char c ); char char_to_upper( char c ); s32 digit_to_int( char c ); s32 hex_digit_to_int( char c ); s32 str_compare( const char* s1, const char* s2 ); s32 str_compare( const char* s1, const char* s2, ssize len ); char* str_copy( char* dest, const char* source, ssize len ); ssize str_copy_nulpad( char* dest, const char* source, ssize len ); ssize str_len( const char* str ); ssize str_len( const char* str, ssize max_len ); char* str_reverse( char* str ); // NOTE: ASCII only char const* str_skip( char const* str, char c ); char const* str_skip_any( char const* str, char const* char_list ); char const* str_trim( char const* str, b32 catch_newline ); // NOTE: ASCII only void str_to_lower( char* str ); void str_to_upper( char* str ); s64 str_to_i64( const char* str, char** end_ptr, s32 base ); void i64_to_str( s64 value, char* string, s32 base ); void u64_to_str( u64 value, char* string, s32 base ); f64 str_to_f64( const char* str, char** end_ptr ); inline const char* char_first_occurence( const char* s, char c ) { char ch = c; for ( ; *s != ch; s++ ) { if ( *s == '\0' ) return NULL; } return s; } inline b32 char_is_alpha( char c ) { if ( ( c >= 'A' && c <= 'Z' ) || ( c >= 'a' && c <= 'z' ) ) return true; return false; } inline b32 char_is_alphanumeric( char c ) { return char_is_alpha( c ) || char_is_digit( c ); } inline b32 char_is_digit( char c ) { if ( c >= '0' && c <= '9' ) return true; return false; } inline b32 char_is_hex_digit( char c ) { if ( char_is_digit( c ) || ( c >= 'a' && c <= 'f' ) || ( c >= 'A' && c <= 'F' ) ) return true; return false; } inline b32 char_is_space( char c ) { if ( c == ' ' || c == '\t' || c == '\n' || c == '\r' || c == '\f' || c == '\v' ) return true; return false; } inline char char_to_lower( char c ) { if ( c >= 'A' && c <= 'Z' ) return 'a' + ( c - 'A' ); return c; } inline char char_to_upper( char c ) { if ( c >= 'a' && c <= 'z' ) return 'A' + ( c - 'a' ); return c; } inline s32 digit_to_int( char c ) { return char_is_digit( c ) ? c - '0' : c - 'W'; } inline s32 hex_digit_to_int( char c ) { if ( char_is_digit( c ) ) return digit_to_int( c ); else if ( is_between( c, 'a', 'f' ) ) return c - 'a' + 10; else if ( is_between( c, 'A', 'F' ) ) return c - 'A' + 10; return -1; } inline s32 str_compare( const char* s1, const char* s2 ) { while ( *s1 && ( *s1 == *s2 ) ) { s1++, s2++; } return *( u8* )s1 - *( u8* )s2; } inline s32 str_compare( const char* s1, const char* s2, ssize len ) { for ( ; len > 0; s1++, s2++, len-- ) { if ( *s1 != *s2 ) return ( ( s1 < s2 ) ? -1 : +1 ); else if ( *s1 == '\0' ) return 0; } return 0; } inline char* str_copy( char* dest, const char* source, ssize len ) { GEN_ASSERT_NOT_NULL( dest ); if ( source ) { char* str = dest; while ( len > 0 && *source ) { *str++ = *source++; len--; } while ( len > 0 ) { *str++ = '\0'; len--; } } return dest; } inline ssize str_copy_nulpad( char* dest, const char* source, ssize len ) { ssize result = 0; GEN_ASSERT_NOT_NULL( dest ); if ( source ) { const char* source_start = source; char* str = dest; while ( len > 0 && *source ) { *str++ = *source++; len--; } while ( len > 0 ) { *str++ = '\0'; len--; } result = source - source_start; } return result; } inline ssize str_len( const char* str ) { if ( str == NULL ) { return 0; } const char* p = str; while ( *str ) str++; return str - p; } inline ssize str_len( const char* str, ssize max_len ) { const char* end = rcast(const char*, mem_find( str, 0, max_len )); if ( end ) return end - str; return max_len; } inline char* str_reverse( char* str ) { ssize len = str_len( str ); char* a = str + 0; char* b = str + len - 1; len /= 2; while ( len-- ) { swap( *a, *b ); a++, b--; } return str; } inline char const* str_skip( char const* str, char c ) { while ( *str && *str != c ) { ++str; } return str; } inline char const* str_skip_any( char const* str, char const* char_list ) { char const* closest_ptr = rcast( char const*, pointer_add_const( rcast(void const*, str), str_len( str ) )); ssize char_list_count = str_len( char_list ); for ( ssize i = 0; i < char_list_count; i++ ) { char const* p = str_skip( str, char_list[ i ] ); closest_ptr = min( closest_ptr, p ); } return closest_ptr; } inline char const* str_trim( char const* str, b32 catch_newline ) { while ( *str && char_is_space( *str ) && ( ! catch_newline || ( catch_newline && *str != '\n' ) ) ) { ++str; } return str; } inline void str_to_lower( char* str ) { if ( ! str ) return; while ( *str ) { *str = char_to_lower( *str ); str++; } } inline void str_to_upper( char* str ) { if ( ! str ) return; while ( *str ) { *str = char_to_upper( *str ); str++; } } #pragma endregion String Ops #pragma region Printing struct FileInfo; #ifndef GEN_PRINTF_MAXLEN # define GEN_PRINTF_MAXLEN kilobytes(128) #endif // NOTE: A locally persisting buffer is used internally char* str_fmt_buf ( char const* fmt, ... ); char* str_fmt_buf_va ( char const* fmt, va_list va ); ssize str_fmt ( char* str, ssize n, char const* fmt, ... ); ssize str_fmt_va ( char* str, ssize n, char const* fmt, va_list va ); ssize str_fmt_out_va ( char const* fmt, va_list va ); ssize str_fmt_out_err ( char const* fmt, ... ); ssize str_fmt_out_err_va( char const* fmt, va_list va ); ssize str_fmt_file ( FileInfo* f, char const* fmt, ... ); ssize str_fmt_file_va ( FileInfo* f, char const* fmt, va_list va ); constexpr char const* Msg_Invalid_Value = "INVALID VALUE PROVIDED"; inline ssize log_fmt(char const* fmt, ...) { ssize res; va_list va; va_start(va, fmt); res = str_fmt_out_va(fmt, va); va_end(va); return res; } #pragma endregion Printing #pragma region Containers template struct RemoveConst { typedef TType Type; }; template struct RemoveConst { typedef TType Type; }; template struct RemoveConst { typedef TType Type[]; }; template struct RemoveConst { typedef TType Type[Size]; }; template using TRemoveConst = typename RemoveConst::Type; template struct Array { struct Header { AllocatorInfo Allocator; usize Capacity; usize Num; }; static Array init( AllocatorInfo allocator ) { return init_reserve( allocator, grow_formula(0) ); } static Array init_reserve( AllocatorInfo allocator, ssize capacity ) { Header* header = rcast( Header*, alloc( allocator, sizeof(Header) + sizeof(Type) * capacity )); if ( header == nullptr ) return { nullptr }; header->Allocator = allocator; header->Capacity = capacity; header->Num = 0; return { rcast( Type*, header + 1) }; } static usize grow_formula( usize value ) { return 2 * value + 8; } bool append( Array other ) { return append( other, other.num() ); } bool append( Type value ) { Header* header = get_header(); if ( header->Num == header->Capacity ) { if ( ! grow( header->Capacity )) return false; header = get_header(); } Data[ header->Num ] = value; header->Num++; return true; } bool append( Type* items, usize item_num ) { Header* header = get_header(); if ( header->Num + item_num > header->Capacity ) { if ( ! grow( header->Capacity + item_num )) return false; header = get_header(); } mem_copy( Data + header->Num, items, item_num * sizeof(Type) ); header->Num += item_num; return true; } bool append_at( Type item, usize idx ) { Header* header = get_header(); if ( idx >= header->Num ) idx = header->Num - 1; if ( idx < 0 ) idx = 0; if ( header->Capacity < header->Num + 1 ) { if ( ! grow( header->Capacity + 1 )) return false; header = get_header(); } Type* target = Data + idx; mem_move( target + 1, target, (header->Num - idx) * sizeof(Type) ); header->Num++; return true; } bool append_at( Type* items, usize item_num, usize idx ) { Header* header = get_header(); if ( idx >= header->Num ) { return append( items, item_num ); } if ( item_num > header->Capacity ) { if ( ! grow( header->Capacity + item_num ) ) return false; header = get_header(); } Type* target = Data + idx + item_num; Type* src = Data + idx; mem_move( target, src, (header->Num - idx) * sizeof(Type) ); mem_copy( src, items, item_num * sizeof(Type) ); header->Num += item_num; return true; } Type& back( void ) { Header& header = * get_header(); return Data[ header.Num - 1 ]; } void clear( void ) { Header& header = * get_header(); header.Num = 0; } bool fill( usize begin, usize end, Type value ) { Header& header = * get_header(); if ( begin < 0 || end > header.Num ) return false; for ( ssize idx = ssize(begin); idx < ssize(end); idx++ ) { Data[ idx ] = value; } return true; } void free( void ) { Header& header = * get_header(); gen::free( header.Allocator, &header ); Data = nullptr; } Header* get_header( void ) { using NonConstType = TRemoveConst< Type >; return rcast( Header*, const_cast(Data) ) - 1 ; } bool grow( usize min_capacity ) { Header& header = * get_header(); usize new_capacity = grow_formula( header.Capacity ); if ( new_capacity < min_capacity ) new_capacity = min_capacity; return set_capacity( new_capacity ); } usize num( void ) { return get_header()->Num; } void pop( void ) { Header& header = * get_header(); GEN_ASSERT( header.Num > 0 ); header.Num--; } void remove_at( usize idx ) { Header* header = get_header(); GEN_ASSERT( idx < header->Num ); mem_move( header + idx, header + idx + 1, sizeof( Type ) * ( header->Num - idx - 1 ) ); header->Num--; } bool reserve( usize new_capacity ) { Header& header = * get_header(); if ( header.Capacity < new_capacity ) return set_capacity( new_capacity ); return true; } bool resize( usize num ) { Header* header = get_header(); if ( header->Capacity < num ) { if ( ! grow( num ) ) return false; header = get_header(); } header->Num = num; return true; } bool set_capacity( usize new_capacity ) { Header& header = * get_header(); if ( new_capacity == header.Capacity ) return true; if ( new_capacity < header.Num ) { // Already have the memory, mine as well keep it. header.Num = new_capacity; return true; } ssize size = sizeof( Header ) + sizeof( Type ) * new_capacity; Header* new_header = rcast( Header*, alloc( header.Allocator, size ) ); if ( new_header == nullptr ) return false; mem_move( new_header, &header, sizeof( Header ) + sizeof( Type ) * header.Num ); new_header->Capacity = new_capacity; gen::free( header.Allocator, &header ); Data = rcast( Type*, new_header + 1); return true; } Type* Data; operator Type*() { return Data; } operator Type const*() const { return Data; } // For-range based support Type* begin() { return Data; } Type* end() { return Data + get_header()->Num; } }; // TODO(Ed) : This thing needs ALOT of work. template struct HashTable { struct FindResult { ssize HashIndex; ssize PrevIndex; ssize EntryIndex; }; struct Entry { u64 Key; ssize Next; Type Value; }; static constexpr f32 CriticalLoadScale = 0.7f; static HashTable init( AllocatorInfo allocator ) { HashTable result = init_reserve(allocator, 8); return result; } static HashTable init_reserve( AllocatorInfo allocator, usize num ) { HashTable result = { { nullptr }, { nullptr } }; result.Hashes = Array::init_reserve( allocator, num ); result.Hashes.get_header()->Num = num; result.Hashes.resize( num ); result.Hashes.fill( 0, num, -1); result.Entries = Array::init_reserve( allocator, num ); return result; } void clear( void ) { Entries.clear(); Hashes.fill( 0, Hashes.num(), -1); } void destroy( void ) { if ( Hashes && Hashes.get_header()->Capacity ) { Hashes.free(); Entries.free(); } } Type* get( u64 key ) { ssize idx = find( key ).EntryIndex; if ( idx >= 0 ) return & Entries[ idx ].Value; return nullptr; } using MapProc = void (*)( u64 key, Type value ); void map( MapProc map_proc ) { GEN_ASSERT_NOT_NULL( map_proc ); for ( ssize idx = 0; idx < ssize(Entries.num()); ++idx ) { map_proc( Entries[ idx ].Key, Entries[ idx ].Value ); } } using MapMutProc = void (*)( u64 key, Type* value ); void map_mut( MapMutProc map_proc ) { GEN_ASSERT_NOT_NULL( map_proc ); for ( ssize idx = 0; idx < ssize(Entries.num()); ++idx ) { map_proc( Entries[ idx ].Key, & Entries[ idx ].Value ); } } void grow() { ssize new_num = Array::grow_formula( Entries.num() ); rehash( new_num ); } void rehash( ssize new_num ) { ssize last_added_index; HashTable new_ht = init_reserve( Hashes.get_header()->Allocator, new_num ); for ( ssize idx = 0; idx < ssize(Entries.num()); ++idx ) { FindResult find_result; Entry& entry = Entries[ idx ]; find_result = new_ht.find( entry.Key ); last_added_index = new_ht.add_entry( entry.Key ); if ( find_result.PrevIndex < 0 ) new_ht.Hashes[ find_result.HashIndex ] = last_added_index; else new_ht.Entries[ find_result.PrevIndex ].Next = last_added_index; new_ht.Entries[ last_added_index ].Next = find_result.EntryIndex; new_ht.Entries[ last_added_index ].Value = entry.Value; } destroy(); *this = new_ht; } void rehash_fast() { ssize idx; for ( idx = 0; idx < ssize(Entries.num()); idx++ ) Entries[ idx ].Next = -1; for ( idx = 0; idx < ssize(Hashes.num()); idx++ ) Hashes[ idx ] = -1; for ( idx = 0; idx < ssize(Entries.num()); idx++ ) { Entry* entry; FindResult find_result; entry = & Entries[ idx ]; find_result = find( entry->Key ); if ( find_result.PrevIndex < 0 ) Hashes[ find_result.HashIndex ] = idx; else Entries[ find_result.PrevIndex ].Next = idx; } } void remove( u64 key ) { FindResult find_result = find( key); if ( find_result.EntryIndex >= 0 ) { Entries.remove_at( find_result.EntryIndex ); rehash_fast(); } } void remove_entry( ssize idx ) { Entries.remove_at( idx ); } void set( u64 key, Type value ) { ssize idx; FindResult find_result; if ( full() ) grow(); find_result = find( key ); if ( find_result.EntryIndex >= 0 ) { idx = find_result.EntryIndex; } else { idx = add_entry( key ); if ( find_result.PrevIndex >= 0 ) { Entries[ find_result.PrevIndex ].Next = idx; } else { Hashes[ find_result.HashIndex ] = idx; } } Entries[ idx ].Value = value; if ( full() ) grow(); } ssize slot( u64 key ) { for ( ssize idx = 0; idx < ssize(Hashes.num()); ++idx ) if ( Hashes[ idx ] == key ) return idx; return -1; } Array< ssize> Hashes; Array< Entry> Entries; protected: ssize add_entry( u64 key ) { ssize idx; Entry entry = { key, -1 }; idx = Entries.num(); Entries.append( entry ); return idx; } FindResult find( u64 key ) { FindResult result = { -1, -1, -1 }; if ( Hashes.num() > 0 ) { result.HashIndex = key % Hashes.num(); result.EntryIndex = Hashes[ result.HashIndex ]; while ( result.EntryIndex >= 0 ) { if ( Entries[ result.EntryIndex ].Key == key ) break; result.PrevIndex = result.EntryIndex; result.EntryIndex = Entries[ result.EntryIndex ].Next; } } return result; } b32 full() { usize critical_load = usize( CriticalLoadScale * f32(Hashes.num()) ); b32 result = Entries.num() > critical_load; return result; } }; #pragma endregion Containers #pragma region Hashing u32 crc32( void const* data, ssize len ); u64 crc64( void const* data, ssize len ); #pragma endregion Hashing #pragma region Strings // Constant string with length. struct StrC { ssize Len; char const* Ptr; operator char const* () const { return Ptr; } char const& operator[]( ssize index ) const { return Ptr[index]; } }; #define cast_to_strc( str ) * rcast( StrC*, (str) - sizeof(ssize) ) #define txt( text ) StrC { sizeof( text ) - 1, ( text ) } inline StrC to_str( char const* str ) { return { str_len( str ), str }; } // Dynamic String // This is directly based off the ZPL string api. // They used a header pattern // I kept it for simplicty of porting but its not necessary to keep it that way. struct String { struct Header { AllocatorInfo Allocator; ssize Capacity; ssize Length; }; static usize grow_formula( usize value ) { // Using a very aggressive growth formula to reduce time mem_copying with recursive calls to append in this library. return 4 * value + 8; } static String make( AllocatorInfo allocator, char const* str ) { ssize length = str ? str_len( str ) : 0; return make_length( allocator, str, length ); } static String make( AllocatorInfo allocator, StrC str ) { return make_length( allocator, str.Ptr, str.Len ); } static String make_reserve( AllocatorInfo allocator, ssize capacity ); static String make_length( AllocatorInfo allocator, char const* str, ssize length ); static String fmt( AllocatorInfo allocator, char* buf, ssize buf_size, char const* fmt, ... ); static String fmt_buf( AllocatorInfo allocator, char const* fmt, ... ); static String join( AllocatorInfo allocator, char const** parts, ssize num_parts, char const* glue ) { String result = make( allocator, "" ); for ( ssize idx = 0; idx < num_parts; ++idx ) { result.append( parts[ idx ] ); if ( idx < num_parts - 1 ) result.append( glue ); } return result; } static bool are_equal( String lhs, String rhs ) { if ( lhs.length() != rhs.length() ) return false; for ( ssize idx = 0; idx < lhs.length(); ++idx ) if ( lhs[ idx ] != rhs[ idx ] ) return false; return true; } static bool are_equal( String lhs, StrC rhs ) { if ( lhs.length() != (rhs.Len) ) return false; for ( ssize idx = 0; idx < lhs.length(); ++idx ) if ( lhs[idx] != rhs[idx] ) return false; return true; } bool make_space_for( char const* str, ssize add_len ); bool append( char c ) { return append( & c, 1 ); } bool append( char const* str ) { return append( str, str_len( str ) ); } bool append( char const* str, ssize length ) { if ( sptr(str) > 0 ) { ssize curr_len = this->length(); if ( ! make_space_for( str, length ) ) return false; Header& header = get_header(); mem_copy( Data + curr_len, str, length ); Data[ curr_len + length ] = '\0'; header.Length = curr_len + length; } return str != nullptr; } bool append( StrC str) { return append( str.Ptr, str.Len ); } bool append( const String other ) { return append( other.Data, other.length() ); } bool append_fmt( char const* fmt, ... ); ssize avail_space() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Capacity - header.Length; } char& back() { return Data[ length() - 1 ]; } bool contains(StrC substring) const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); if (substring.Len > header.Length) return false; ssize main_len = header.Length; ssize sub_len = substring.Len; for (ssize i = 0; i <= main_len - sub_len; ++i) { if (str_compare(Data + i, substring.Ptr, sub_len) == 0) return true; } return false; } bool contains(String const& substring) const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); if (substring.length() > header.Length) return false; ssize main_len = header.Length; ssize sub_len = substring.length(); for (ssize i = 0; i <= main_len - sub_len; ++i) { if (str_compare(Data + i, substring.Data, sub_len) == 0) return true; } return false; } ssize capacity() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Capacity; } void clear() { get_header().Length = 0; } String duplicate( AllocatorInfo allocator ) const { return make_length( allocator, Data, length() ); } void free() { if ( ! Data ) return; Header& header = get_header(); gen::free( header.Allocator, & header ); } Header& get_header() { return *(Header*)(Data - sizeof(Header)); } ssize length() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return header.Length; } b32 starts_with( StrC substring ) const { if (substring.Len > length()) return false; b32 result = str_compare(Data, substring.Ptr, substring.Len ) == 0; return result; } b32 starts_with( String substring ) const { if (substring.length() > length()) return false; b32 result = str_compare(Data, substring, substring.length() - 1 ) == 0; return result; } void skip_line() { #define current (*scanner) char* scanner = Data; while ( current != '\r' && current != '\n' ) { ++ scanner; } s32 new_length = scanner - Data; if ( current == '\r' ) { new_length += 1; } mem_move( Data, scanner, new_length ); Header* header = & get_header(); header->Length = new_length; #undef current } void strip_space() { char* write_pos = Data; char* read_pos = Data; while ( * read_pos) { if ( ! char_is_space( *read_pos )) { *write_pos = *read_pos; write_pos++; } read_pos++; } write_pos[0] = '\0'; // Null-terminate the modified string // Update the length if needed get_header().Length = write_pos - Data; } void trim( char const* cut_set ) { ssize len = 0; char* start_pos = Data; char* end_pos = Data + length() - 1; while ( start_pos <= end_pos && char_first_occurence( cut_set, *start_pos ) ) start_pos++; while ( end_pos > start_pos && char_first_occurence( cut_set, *end_pos ) ) end_pos--; len = scast( ssize, ( start_pos > end_pos ) ? 0 : ( ( end_pos - start_pos ) + 1 ) ); if ( Data != start_pos ) mem_move( Data, start_pos, len ); Data[ len ] = '\0'; get_header().Length = len; } void trim_space() { return trim( " \t\r\n\v\f" ); } // Debug function that provides a copy of the string with whitespace characters visualized. String visualize_whitespace() const { Header* header = (Header*)(Data - sizeof(Header)); String result = make_reserve(header->Allocator, length() * 2); // Assume worst case for space requirements. for ( char c : *this ) { switch ( c ) { case ' ': result.append( txt("·") ); break; case '\t': result.append( txt("→") ); break; case '\n': result.append( txt("↵") ); break; case '\r': result.append( txt("⏎") ); break; case '\v': result.append( txt("⇕") ); break; case '\f': result.append( txt("⌂") ); break; default: result.append(c); break; } } return result; } // For-range support char* begin() const { return Data; } char* end() const { Header const& header = * rcast( Header const*, Data - sizeof( Header )); return Data + header.Length; } operator bool() { return Data != nullptr; } operator char* () { return Data; } operator char const* () const { return Data; } operator StrC() const { return { length(), Data }; } // Used with cached strings // Essentially makes the string a string view. String const& operator = ( String const& other ) const { if ( this == & other ) return *this; String* this_ = ccast(String*, this); this_->Data = other.Data; return *this; } char& operator [] ( ssize index ) { return Data[ index ]; } char const& operator [] ( ssize index ) const { return Data[ index ]; } char* Data; }; struct String_POD { char* Data; }; static_assert( sizeof( String_POD ) == sizeof( String ), "String is not a POD" ); // Implements basic string interning. Data structure is based off the ZPL Hashtable. using StringTable = HashTable; // Represents strings cached with the string table. // Should never be modified, if changed string is desired, cache_string( str ) another. using StringCached = String const; #pragma endregion Strings #pragma region File Handling typedef u32 FileMode; enum FileModeFlag { EFileMode_READ = bit( 0 ), EFileMode_WRITE = bit( 1 ), EFileMode_APPEND = bit( 2 ), EFileMode_RW = bit( 3 ), GEN_FILE_MODES = EFileMode_READ | EFileMode_WRITE | EFileMode_APPEND | EFileMode_RW, }; // NOTE: Only used internally and for the file operations enum SeekWhenceType { ESeekWhence_BEGIN = 0, ESeekWhence_CURRENT = 1, ESeekWhence_END = 2, }; enum FileError { EFileError_NONE, EFileError_INVALID, EFileError_INVALID_FILENAME, EFileError_EXISTS, EFileError_NOT_EXISTS, EFileError_PERMISSION, EFileError_TRUNCATION_FAILURE, EFileError_NOT_EMPTY, EFileError_NAME_TOO_LONG, EFileError_UNKNOWN, }; union FileDescriptor { void* p; sptr i; uptr u; }; typedef struct FileOperations FileOperations; #define GEN_FILE_OPEN_PROC( name ) FileError name( FileDescriptor* fd, FileOperations* ops, FileMode mode, char const* filename ) #define GEN_FILE_READ_AT_PROC( name ) b32 name( FileDescriptor fd, void* buffer, ssize size, s64 offset, ssize* bytes_read, b32 stop_at_newline ) #define GEN_FILE_WRITE_AT_PROC( name ) b32 name( FileDescriptor fd, void const* buffer, ssize size, s64 offset, ssize* bytes_written ) #define GEN_FILE_SEEK_PROC( name ) b32 name( FileDescriptor fd, s64 offset, SeekWhenceType whence, s64* new_offset ) #define GEN_FILE_CLOSE_PROC( name ) void name( FileDescriptor fd ) typedef GEN_FILE_OPEN_PROC( file_open_proc ); typedef GEN_FILE_READ_AT_PROC( FileReadProc ); typedef GEN_FILE_WRITE_AT_PROC( FileWriteProc ); typedef GEN_FILE_SEEK_PROC( FileSeekProc ); typedef GEN_FILE_CLOSE_PROC( FileCloseProc ); struct FileOperations { FileReadProc* read_at; FileWriteProc* write_at; FileSeekProc* seek; FileCloseProc* close; }; extern FileOperations const default_file_operations; typedef u64 FileTime; enum DirType { GEN_DIR_TYPE_FILE, GEN_DIR_TYPE_FOLDER, GEN_DIR_TYPE_UNKNOWN, }; struct DirInfo; struct DirEntry { char const* filename; struct DirInfo* dir_info; u8 type; }; struct DirInfo { char const* fullpath; DirEntry* entries; // zpl_array // Internals char** filenames; // zpl_array String buf; }; struct FileInfo { FileOperations ops; FileDescriptor fd; b32 is_temp; char const* filename; FileTime last_write_time; DirEntry* dir; }; enum FileStandardType { EFileStandard_INPUT, EFileStandard_OUTPUT, EFileStandard_ERROR, EFileStandard_COUNT, }; /** * Get standard file I/O. * @param std Check zpl_file_standard_type * @return File handle to standard I/O */ FileInfo* file_get_standard( FileStandardType std ); /** * Closes the file * @param file */ FileError file_close( FileInfo* file ); /** * Returns the currently opened file's name * @param file */ inline char const* file_name( FileInfo* file ) { return file->filename ? file->filename : ""; } /** * Opens a file * @param file * @param filename */ FileError file_open( FileInfo* file, char const* filename ); /** * Opens a file using a specified mode * @param file * @param mode Access mode to use * @param filename */ FileError file_open_mode( FileInfo* file, FileMode mode, char const* filename ); /** * Reads from a file * @param file * @param buffer Buffer to read to * @param size Size to read */ b32 file_read( FileInfo* file, void* buffer, ssize size ); /** * Reads file at a specific offset * @param file * @param buffer Buffer to read to * @param size Size to read * @param offset Offset to read from * @param bytes_read How much data we've actually read */ b32 file_read_at( FileInfo* file, void* buffer, ssize size, s64 offset ); /** * Reads file safely * @param file * @param buffer Buffer to read to * @param size Size to read * @param offset Offset to read from * @param bytes_read How much data we've actually read */ b32 file_read_at_check( FileInfo* file, void* buffer, ssize size, s64 offset, ssize* bytes_read ); struct FileContents { AllocatorInfo allocator; void* data; ssize size; }; constexpr b32 zero_terminate = true; constexpr b32 no_zero_terminate = false; /** * Reads the whole file contents * @param a Allocator to use * @param zero_terminate End the read data with null terminator * @param filepath Path to the file * @return File contents data */ FileContents file_read_contents( AllocatorInfo a, b32 zero_terminate, char const* filepath ); /** * Returns a size of the file * @param file * @return File size */ s64 file_size( FileInfo* file ); /** * Seeks the file cursor from the beginning of file to a specific position * @param file * @param offset Offset to seek to */ s64 file_seek( FileInfo* file, s64 offset ); /** * Seeks the file cursor to the end of the file * @param file */ s64 file_seek_to_end( FileInfo* file ); /** * Returns the length from the beginning of the file we've read so far * @param file * @return Our current position in file */ s64 file_tell( FileInfo* file ); /** * Writes to a file * @param file * @param buffer Buffer to read from * @param size Size to read */ b32 file_write( FileInfo* file, void const* buffer, ssize size ); /** * Writes to file at a specific offset * @param file * @param buffer Buffer to read from * @param size Size to write * @param offset Offset to write to * @param bytes_written How much data we've actually written */ b32 file_write_at( FileInfo* file, void const* buffer, ssize size, s64 offset ); /** * Writes to file safely * @param file * @param buffer Buffer to read from * @param size Size to write * @param offset Offset to write to * @param bytes_written How much data we've actually written */ b32 file_write_at_check( FileInfo* file, void const* buffer, ssize size, s64 offset, ssize* bytes_written ); enum FileStreamFlags : u32 { /* Allows us to write to the buffer directly. Beware: you can not append a new data! */ EFileStream_WRITABLE = bit( 0 ), /* Clones the input buffer so you can write (zpl_file_write*) data into it. */ /* Since we work with a clone, the buffer size can dynamically grow as well. */ EFileStream_CLONE_WRITABLE = bit( 1 ), }; /** * Opens a new memory stream * @param file * @param allocator */ b8 file_stream_new( FileInfo* file, AllocatorInfo allocator ); /** * Opens a memory stream over an existing buffer * @param file * @param allocator * @param buffer Memory to create stream from * @param size Buffer's size * @param flags */ b8 file_stream_open( FileInfo* file, AllocatorInfo allocator, u8* buffer, ssize size, FileStreamFlags flags ); /** * Retrieves the stream's underlying buffer and buffer size. * @param file memory stream * @param size (Optional) buffer size */ u8* file_stream_buf( FileInfo* file, ssize* size ); extern FileOperations const memory_file_operations; inline s64 file_seek( FileInfo* f, s64 offset ) { s64 new_offset = 0; if ( ! f->ops.read_at ) f->ops = default_file_operations; f->ops.seek( f->fd, offset, ESeekWhence_BEGIN, &new_offset ); return new_offset; } inline s64 file_seek_to_end( FileInfo* f ) { s64 new_offset = 0; if ( ! f->ops.read_at ) f->ops = default_file_operations; f->ops.seek( f->fd, 0, ESeekWhence_END, &new_offset ); return new_offset; } inline s64 file_tell( FileInfo* f ) { s64 new_offset = 0; if ( ! f->ops.read_at ) f->ops = default_file_operations; f->ops.seek( f->fd, 0, ESeekWhence_CURRENT, &new_offset ); return new_offset; } inline b32 file_read( FileInfo* f, void* buffer, ssize size ) { s64 cur_offset = file_tell( f ); b32 result = file_read_at( f, buffer, size, file_tell( f ) ); file_seek( f, cur_offset + size ); return result; } inline b32 file_read_at( FileInfo* f, void* buffer, ssize size, s64 offset ) { return file_read_at_check( f, buffer, size, offset, NULL ); } inline b32 file_read_at_check( FileInfo* f, void* buffer, ssize size, s64 offset, ssize* bytes_read ) { if ( ! f->ops.read_at ) f->ops = default_file_operations; return f->ops.read_at( f->fd, buffer, size, offset, bytes_read, false ); } inline b32 file_write( FileInfo* f, void const* buffer, ssize size ) { s64 cur_offset = file_tell( f ); b32 result = file_write_at( f, buffer, size, file_tell( f ) ); file_seek( f, cur_offset + size ); return result; } inline b32 file_write_at( FileInfo* f, void const* buffer, ssize size, s64 offset ) { return file_write_at_check( f, buffer, size, offset, NULL ); } inline b32 file_write_at_check( FileInfo* f, void const* buffer, ssize size, s64 offset, ssize* bytes_written ) { if ( ! f->ops.read_at ) f->ops = default_file_operations; return f->ops.write_at( f->fd, buffer, size, offset, bytes_written ); } #pragma endregion File Handling #pragma region Timing #ifdef GEN_BENCHMARK //! Return CPU timestamp. u64 read_cpu_time_stamp_counter( void ); //! Return relative time (in seconds) since the application start. f64 time_rel( void ); //! Return relative time since the application start. u64 time_rel_ms( void ); #endif #pragma endregion Timing #pragma region Parsing #pragma region ADT enum ADT_Type : u32 { EADT_TYPE_UNINITIALISED, /* node was not initialised, this is a programming error! */ EADT_TYPE_ARRAY, EADT_TYPE_OBJECT, EADT_TYPE_STRING, EADT_TYPE_MULTISTRING, EADT_TYPE_INTEGER, EADT_TYPE_REAL, }; enum ADT_Props : u32 { EADT_PROPS_NONE, EADT_PROPS_NAN, EADT_PROPS_NAN_NEG, EADT_PROPS_INFINITY, EADT_PROPS_INFINITY_NEG, EADT_PROPS_FALSE, EADT_PROPS_TRUE, EADT_PROPS_NULL, EADT_PROPS_IS_EXP, EADT_PROPS_IS_HEX, // Used internally so that people can fill in real numbers they plan to write. EADT_PROPS_IS_PARSED_REAL, }; enum ADT_NamingStyle : u32 { EADT_NAME_STYLE_DOUBLE_QUOTE, EADT_NAME_STYLE_SINGLE_QUOTE, EADT_NAME_STYLE_NO_QUOTES, }; enum ADT_AssignStyle : u32 { EADT_ASSIGN_STYLE_COLON, EADT_ASSIGN_STYLE_EQUALS, EADT_ASSIGN_STYLE_LINE, }; enum ADT_DelimStyle : u32 { EADT_DELIM_STYLE_COMMA, EADT_DELIM_STYLE_LINE, EADT_DELIM_STYLE_NEWLINE, }; enum ADT_Error : u32 { EADT_ERROR_NONE, EADT_ERROR_INTERNAL, EADT_ERROR_ALREADY_CONVERTED, EADT_ERROR_INVALID_TYPE, EADT_ERROR_OUT_OF_MEMORY, }; struct ADT_Node { char const* name; struct ADT_Node* parent; /* properties */ ADT_Type type : 4; u8 props : 4; #ifndef GEN_PARSER_DISABLE_ANALYSIS u8 cfg_mode : 1; u8 name_style : 2; u8 assign_style : 2; u8 delim_style : 2; u8 delim_line_width : 4; u8 assign_line_width : 4; #endif /* adt data */ union { char const* string; Array nodes; ///< zpl_array struct { union { f64 real; s64 integer; }; #ifndef GEN_PARSER_DISABLE_ANALYSIS /* number analysis */ s32 base; s32 base2; u8 base2_offset : 4; s8 exp : 4; u8 neg_zero : 1; u8 lead_digit : 1; #endif }; }; }; /* ADT NODE LIMITS * delimiter and assignment segment width is limited to 128 whitespace symbols each. * real number limits decimal position to 128 places. * real number exponent is limited to 64 digits. */ /** * @brief Initialise an ADT object or array * * @param node * @param backing Memory allocator used for descendants * @param name Node's name * @param is_array * @return error code */ u8 adt_make_branch( ADT_Node* node, AllocatorInfo backing, char const* name, b32 is_array ); /** * @brief Destroy an ADT branch and its descendants * * @param node * @return error code */ u8 adt_destroy_branch( ADT_Node* node ); /** * @brief Initialise an ADT leaf * * @param node * @param name Node's name * @param type Node's type (use zpl_adt_make_branch for container nodes) * @return error code */ u8 adt_make_leaf( ADT_Node* node, char const* name, ADT_Type type ); /** * @brief Fetch a node using provided URI string. * * This method uses a basic syntax to fetch a node from the ADT. The following features are available * to retrieve the data: * * - "a/b/c" navigates through objects "a" and "b" to get to "c" * - "arr/[foo=123]/bar" iterates over "arr" to find any object with param "foo" that matches the value "123", then gets its field called "bar" * - "arr/3" retrieves the 4th element in "arr" * - "arr/[apple]" retrieves the first element of value "apple" in "arr" * * @param node ADT node * @param uri Locator string as described above * @return zpl_adt_node* * * @see code/apps/examples/json_get.c */ ADT_Node* adt_query( ADT_Node* node, char const* uri ); /** * @brief Find a field node within an object by the given name. * * @param node * @param name * @param deep_search Perform search recursively * @return zpl_adt_node * node */ ADT_Node* adt_find( ADT_Node* node, char const* name, b32 deep_search ); /** * @brief Allocate an unitialised node within a container at a specified index. * * @param parent * @param index * @return zpl_adt_node * node */ ADT_Node* adt_alloc_at( ADT_Node* parent, ssize index ); /** * @brief Allocate an unitialised node within a container. * * @param parent * @return zpl_adt_node * node */ ADT_Node* adt_alloc( ADT_Node* parent ); /** * @brief Move an existing node to a new container at a specified index. * * @param node * @param new_parent * @param index * @return zpl_adt_node * node */ ADT_Node* adt_move_node_at( ADT_Node* node, ADT_Node* new_parent, ssize index ); /** * @brief Move an existing node to a new container. * * @param node * @param new_parent * @return zpl_adt_node * node */ ADT_Node* adt_move_node( ADT_Node* node, ADT_Node* new_parent ); /** * @brief Swap two nodes. * * @param node * @param other_node * @return */ void adt_swap_nodes( ADT_Node* node, ADT_Node* other_node ); /** * @brief Remove node from container. * * @param node * @return */ void adt_remove_node( ADT_Node* node ); /** * @brief Initialise a node as an object * * @param obj * @param name * @param backing * @return */ b8 adt_set_obj( ADT_Node* obj, char const* name, AllocatorInfo backing ); /** * @brief Initialise a node as an array * * @param obj * @param name * @param backing * @return */ b8 adt_set_arr( ADT_Node* obj, char const* name, AllocatorInfo backing ); /** * @brief Initialise a node as a string * * @param obj * @param name * @param value * @return */ b8 adt_set_str( ADT_Node* obj, char const* name, char const* value ); /** * @brief Initialise a node as a float * * @param obj * @param name * @param value * @return */ b8 adt_set_flt( ADT_Node* obj, char const* name, f64 value ); /** * @brief Initialise a node as a signed integer * * @param obj * @param name * @param value * @return */ b8 adt_set_int( ADT_Node* obj, char const* name, s64 value ); /** * @brief Append a new node to a container as an object * * @param parent * @param name * @return* */ ADT_Node* adt_append_obj( ADT_Node* parent, char const* name ); /** * @brief Append a new node to a container as an array * * @param parent * @param name * @return* */ ADT_Node* adt_append_arr( ADT_Node* parent, char const* name ); /** * @brief Append a new node to a container as a string * * @param parent * @param name * @param value * @return* */ ADT_Node* adt_append_str( ADT_Node* parent, char const* name, char const* value ); /** * @brief Append a new node to a container as a float * * @param parent * @param name * @param value * @return* */ ADT_Node* adt_append_flt( ADT_Node* parent, char const* name, f64 value ); /** * @brief Append a new node to a container as a signed integer * * @param parent * @param name * @param value * @return* */ ADT_Node* adt_append_int( ADT_Node* parent, char const* name, s64 value ); /* parser helpers */ /** * @brief Parses a text and stores the result into an unitialised node. * * @param node * @param base * @return* */ char* adt_parse_number( ADT_Node* node, char* base ); /** * @brief Parses a text and stores the result into an unitialised node. * This function expects the entire input to be a number. * * @param node * @param base * @return* */ char* adt_parse_number_strict( ADT_Node* node, char* base_str ); /** * @brief Parses and converts an existing string node into a number. * * @param node * @return */ ADT_Error adt_str_to_number( ADT_Node* node ); /** * @brief Parses and converts an existing string node into a number. * This function expects the entire input to be a number. * * @param node * @return */ ADT_Error adt_str_to_number_strict( ADT_Node* node ); /** * @brief Prints a number into a file stream. * * The provided file handle can also be a memory mapped stream. * * @see zpl_file_stream_new * @param file * @param node * @return */ ADT_Error adt_print_number( FileInfo* file, ADT_Node* node ); /** * @brief Prints a string into a file stream. * * The provided file handle can also be a memory mapped stream. * * @see zpl_file_stream_new * @param file * @param node * @param escaped_chars * @param escape_symbol * @return */ ADT_Error adt_print_string( FileInfo* file, ADT_Node* node, char const* escaped_chars, char const* escape_symbol ); #pragma endregion ADT #pragma region CSV enum CSV_Error : u32 { ECSV_Error__NONE, ECSV_Error__INTERNAL, ECSV_Error__UNEXPECTED_END_OF_INPUT, ECSV_Error__MISMATCHED_ROWS, }; typedef ADT_Node CSV_Object; u8 csv_parse( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header ); u8 csv_parse_delimiter( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header, char delim ); void csv_free( CSV_Object* obj ); void csv_write( FileInfo* file, CSV_Object* obj ); String csv_write_string( AllocatorInfo a, CSV_Object* obj ); void csv_write_delimiter( FileInfo* file, CSV_Object* obj, char delim ); String csv_write_string_delimiter( AllocatorInfo a, CSV_Object* obj, char delim ); /* inline */ inline u8 csv_parse( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header ) { return csv_parse_delimiter( root, text, allocator, has_header, ',' ); } inline void csv_write( FileInfo* file, CSV_Object* obj ) { csv_write_delimiter( file, obj, ',' ); } inline String csv_write_string( AllocatorInfo a, CSV_Object* obj ) { return csv_write_string_delimiter( a, obj, ',' ); } #pragma endregion CSV #pragma endregion Parsing GEN_NS_END // GEN_ROLL_OWN_DEPENDENCIES #endif GEN_NS_BEGIN #pragma region Types using LogFailType = ssize(*)(char const*, ...); // By default this library will either crash or exit if an error is detected while generating codes. // Even if set to not use GEN_FATAL, GEN_FATAL will still be used for memory failures as the library is unusable when they occur. #ifdef GEN_DONT_USE_FATAL #define log_failure log_fmt #else #define log_failure GEN_FATAL #endif enum class AccessSpec : u32 { Default, Private, Protected, Public, Num_AccessSpec, Invalid, }; inline char const* to_str( AccessSpec type ) { local_persist char const* lookup[ (u32)AccessSpec::Num_AccessSpec ] = { "", "private", "protected", "public", }; if ( type > AccessSpec::Public ) return "Invalid"; return lookup[ (u32)type ]; } enum CodeFlag : u32 { None = 0, FunctionType = bit(0), ParamPack = bit(1), Module_Export = bit(2), Module_Import = bit(3), }; // Used to indicate if enum definitoin is an enum class or regular enum. enum class EnumT : u8 { Regular, Class }; constexpr EnumT EnumClass = EnumT::Class; constexpr EnumT EnumRegular = EnumT::Regular; enum class ModuleFlag : u32 { None = 0, Export = bit(0), Import = bit(1), Num_ModuleFlags, Invalid, }; inline StrC to_str( ModuleFlag flag ) { local_persist StrC lookup[ (u32)ModuleFlag::Num_ModuleFlags ] = { { sizeof("__none__"), "__none__" }, { sizeof("export"), "export" }, { sizeof("import"), "import" }, }; if ( flag > ModuleFlag::Import ) return { sizeof("invalid"), "invalid" }; return lookup[ (u32)flag ]; } inline ModuleFlag operator|( ModuleFlag A, ModuleFlag B) { return (ModuleFlag)( (u32)A | (u32)B ); } enum class EPreprocessCond : u32 { If, IfDef, IfNotDef, ElIf }; constexpr EPreprocessCond PreprocessCond_If = EPreprocessCond::If; constexpr EPreprocessCond PreprocessCond_IfDef = EPreprocessCond::IfDef; constexpr EPreprocessCond PreprocessCond_IfNotDef = EPreprocessCond::IfNotDef; constexpr EPreprocessCond PreprocessCond_ElIf = EPreprocessCond::ElIf; namespace ECode { enum Type : u32 { Invalid, Untyped, NewLine, Comment, Access_Private, Access_Protected, Access_Public, PlatformAttributes, Class, Class_Fwd, Class_Body, Constructor, Constructor_Fwd, Destructor, Destructor_Fwd, Enum, Enum_Fwd, Enum_Body, Enum_Class, Enum_Class_Fwd, Execution, Export_Body, Extern_Linkage, Extern_Linkage_Body, Friend, Function, Function_Fwd, Function_Body, Global_Body, Module, Namespace, Namespace_Body, Operator, Operator_Fwd, Operator_Member, Operator_Member_Fwd, Operator_Cast, Operator_Cast_Fwd, Parameters, Preprocess_Define, Preprocess_Include, Preprocess_If, Preprocess_IfDef, Preprocess_IfNotDef, Preprocess_ElIf, Preprocess_Else, Preprocess_EndIf, Preprocess_Pragma, Specifiers, Struct, Struct_Fwd, Struct_Body, Template, Typedef, Typename, Union, Union_Body, Using, Using_Namespace, Variable, NumTypes }; inline StrC to_str( Type type ) { local_persist StrC lookup[] { { sizeof( "Invalid" ), "Invalid" }, { sizeof( "Untyped" ), "Untyped" }, { sizeof( "NewLine" ), "NewLine" }, { sizeof( "Comment" ), "Comment" }, { sizeof( "Access_Private" ), "Access_Private" }, { sizeof( "Access_Protected" ), "Access_Protected" }, { sizeof( "Access_Public" ), "Access_Public" }, { sizeof( "PlatformAttributes" ), "PlatformAttributes" }, { sizeof( "Class" ), "Class" }, { sizeof( "Class_Fwd" ), "Class_Fwd" }, { sizeof( "Class_Body" ), "Class_Body" }, { sizeof( "Constructor" ), "Constructor" }, { sizeof( "Constructor_Fwd" ), "Constructor_Fwd" }, { sizeof( "Destructor" ), "Destructor" }, { sizeof( "Destructor_Fwd" ), "Destructor_Fwd" }, { sizeof( "Enum" ), "Enum" }, { sizeof( "Enum_Fwd" ), "Enum_Fwd" }, { sizeof( "Enum_Body" ), "Enum_Body" }, { sizeof( "Enum_Class" ), "Enum_Class" }, { sizeof( "Enum_Class_Fwd" ), "Enum_Class_Fwd" }, { sizeof( "Execution" ), "Execution" }, { sizeof( "Export_Body" ), "Export_Body" }, { sizeof( "Extern_Linkage" ), "Extern_Linkage" }, { sizeof( "Extern_Linkage_Body" ), "Extern_Linkage_Body" }, { sizeof( "Friend" ), "Friend" }, { sizeof( "Function" ), "Function" }, { sizeof( "Function_Fwd" ), "Function_Fwd" }, { sizeof( "Function_Body" ), "Function_Body" }, { sizeof( "Global_Body" ), "Global_Body" }, { sizeof( "Module" ), "Module" }, { sizeof( "Namespace" ), "Namespace" }, { sizeof( "Namespace_Body" ), "Namespace_Body" }, { sizeof( "Operator" ), "Operator" }, { sizeof( "Operator_Fwd" ), "Operator_Fwd" }, { sizeof( "Operator_Member" ), "Operator_Member" }, { sizeof( "Operator_Member_Fwd" ), "Operator_Member_Fwd" }, { sizeof( "Operator_Cast" ), "Operator_Cast" }, { sizeof( "Operator_Cast_Fwd" ), "Operator_Cast_Fwd" }, { sizeof( "Parameters" ), "Parameters" }, { sizeof( "Preprocess_Define" ), "Preprocess_Define" }, { sizeof( "Preprocess_Include" ), "Preprocess_Include" }, { sizeof( "Preprocess_If" ), "Preprocess_If" }, { sizeof( "Preprocess_IfDef" ), "Preprocess_IfDef" }, { sizeof( "Preprocess_IfNotDef" ), "Preprocess_IfNotDef" }, { sizeof( "Preprocess_ElIf" ), "Preprocess_ElIf" }, { sizeof( "Preprocess_Else" ), "Preprocess_Else" }, { sizeof( "Preprocess_EndIf" ), "Preprocess_EndIf" }, { sizeof( "Preprocess_Pragma" ), "Preprocess_Pragma" }, { sizeof( "Specifiers" ), "Specifiers" }, { sizeof( "Struct" ), "Struct" }, { sizeof( "Struct_Fwd" ), "Struct_Fwd" }, { sizeof( "Struct_Body" ), "Struct_Body" }, { sizeof( "Template" ), "Template" }, { sizeof( "Typedef" ), "Typedef" }, { sizeof( "Typename" ), "Typename" }, { sizeof( "Union" ), "Union" }, { sizeof( "Union_Body" ), "Union_Body" }, { sizeof( "Using" ), "Using" }, { sizeof( "Using_Namespace" ), "Using_Namespace" }, { sizeof( "Variable" ), "Variable" }, }; return lookup[type]; } } // namespace ECode using CodeT = ECode::Type; namespace EOperator { enum Type : u32 { Invalid, Assign, Assign_Add, Assign_Subtract, Assign_Multiply, Assign_Divide, Assign_Modulo, Assign_BAnd, Assign_BOr, Assign_BXOr, Assign_LShift, Assign_RShift, Increment, Decrement, Unary_Plus, Unary_Minus, UnaryNot, Add, Subtract, Multiply, Divide, Modulo, BNot, BAnd, BOr, BXOr, LShift, RShift, LAnd, LOr, LEqual, LNot, Lesser, Greater, LesserEqual, GreaterEqual, Subscript, Indirection, AddressOf, MemberOfPointer, PtrToMemOfPtr, FunctionCall, Comma, New, NewArray, Delete, DeleteArray, NumOps }; inline StrC to_str( Type op ) { local_persist StrC lookup[] { { sizeof( "INVALID" ), "INVALID" }, { sizeof( "=" ), "=" }, { sizeof( "+=" ), "+=" }, { sizeof( "-=" ), "-=" }, { sizeof( "*=" ), "*=" }, { sizeof( "/=" ), "/=" }, { sizeof( "%=" ), "%=" }, { sizeof( "&=" ), "&=" }, { sizeof( "|=" ), "|=" }, { sizeof( "^=" ), "^=" }, { sizeof( "<<=" ), "<<=" }, { sizeof( ">>=" ), ">>=" }, { sizeof( "++" ), "++" }, { sizeof( "--" ), "--" }, { sizeof( "+" ), "+" }, { sizeof( "-" ), "-" }, { sizeof( "!" ), "!" }, { sizeof( "+" ), "+" }, { sizeof( "-" ), "-" }, { sizeof( "*" ), "*" }, { sizeof( "/" ), "/" }, { sizeof( "%" ), "%" }, { sizeof( "~" ), "~" }, { sizeof( "&" ), "&" }, { sizeof( "|" ), "|" }, { sizeof( "^" ), "^" }, { sizeof( "<<" ), "<<" }, { sizeof( ">>" ), ">>" }, { sizeof( "&&" ), "&&" }, { sizeof( "||" ), "||" }, { sizeof( "==" ), "==" }, { sizeof( "!=" ), "!=" }, { sizeof( "<" ), "<" }, { sizeof( ">" ), ">" }, { sizeof( "<=" ), "<=" }, { sizeof( ">=" ), ">=" }, { sizeof( "[]" ), "[]" }, { sizeof( "*" ), "*" }, { sizeof( "&" ), "&" }, { sizeof( "->" ), "->" }, { sizeof( "->*" ), "->*" }, { sizeof( "()" ), "()" }, { sizeof( "," ), "," }, { sizeof( "new" ), "new" }, { sizeof( "new[]" ), "new[]" }, { sizeof( "delete" ), "delete" }, { sizeof( "delete[]" ), "delete[]" }, }; return lookup[op]; } } // namespace EOperator using OperatorT = EOperator::Type; namespace ESpecifier { enum Type : u32 { Invalid, Consteval, Constexpr, Constinit, Explicit, External_Linkage, ForceInline, Global, Inline, Internal_Linkage, Local_Persist, Mutable, NeverInline, Ptr, Ref, Register, RValue, Static, Thread_Local, Virtual, Const, Final, NoExceptions, Override, Pure, Volatile, NumSpecifiers }; inline bool is_trailing( Type specifier ) { return specifier > Virtual; } inline StrC to_str( Type type ) { local_persist StrC lookup[] { { sizeof( "INVALID" ), "INVALID" }, { sizeof( "consteval" ), "consteval" }, { sizeof( "constexpr" ), "constexpr" }, { sizeof( "constinit" ), "constinit" }, { sizeof( "explicit" ), "explicit" }, { sizeof( "extern" ), "extern" }, { sizeof( "forceinline" ), "forceinline" }, { sizeof( "global" ), "global" }, { sizeof( "inline" ), "inline" }, { sizeof( "internal" ), "internal" }, { sizeof( "local_persist" ), "local_persist" }, { sizeof( "mutable" ), "mutable" }, { sizeof( "neverinline" ), "neverinline" }, { sizeof( "*" ), "*" }, { sizeof( "&" ), "&" }, { sizeof( "register" ), "register" }, { sizeof( "&&" ), "&&" }, { sizeof( "static" ), "static" }, { sizeof( "thread_local" ), "thread_local" }, { sizeof( "virtual" ), "virtual" }, { sizeof( "const" ), "const" }, { sizeof( "final" ), "final" }, { sizeof( "noexcept" ), "noexcept" }, { sizeof( "override" ), "override" }, { sizeof( "= 0" ), "= 0" }, { sizeof( "volatile" ), "volatile" }, }; return lookup[type]; } inline Type to_type( StrC str ) { local_persist u32 keymap[NumSpecifiers]; do_once_start for ( u32 index = 0; index < NumSpecifiers; index++ ) { StrC enum_str = to_str( (Type)index ); keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1 ); } do_once_end u32 hash = crc32( str.Ptr, str.Len ); for ( u32 index = 0; index < NumSpecifiers; index++ ) { if ( keymap[index] == hash ) return (Type)index; } return Invalid; } } // namespace ESpecifier using SpecifierT = ESpecifier::Type; #pragma endregion Types #pragma region AST struct AST; struct AST_Body; struct AST_Attributes; struct AST_Comment; struct AST_Constructor; // struct AST_BaseClass; struct AST_Class; struct AST_Define; struct AST_Destructor; struct AST_Enum; struct AST_Exec; struct AST_Extern; struct AST_Include; struct AST_Friend; struct AST_Fn; struct AST_Module; struct AST_NS; struct AST_Operator; struct AST_OpCast; struct AST_Param; struct AST_Pragma; struct AST_PreprocessCond; struct AST_Specifiers; #if GEN_EXECUTION_EXPRESSION_SUPPORT struct AST_Expr; struct AST_Expr_Assign; struct AST_Expr_Alignof; struct AST_Expr_Binary; struct AST_Expr_CStyleCast; struct AST_Expr_FunctionalCast; struct AST_Expr_CppCast; struct AST_Expr_ProcCall; struct AST_Expr_Decltype; struct AST_Expr_Comma; // TODO(Ed) : This is a binary op not sure if it needs its own AST... struct AST_Expr_AMS; // Access Member Symbol struct AST_Expr_Sizeof; struct AST_Expr_Subscript; struct AST_Expr_Ternary; struct AST_Expr_UnaryPrefix; struct AST_Expr_UnaryPostfix; struct AST_Expr_Element; struct AST_Stmt; struct AST_Stmt_Break; struct AST_Stmt_Case; struct AST_Stmt_Continue; struct AST_Stmt_Decl; struct AST_Stmt_Do; struct AST_Stmt_Expr; // TODO(Ed) : Is this distinction needed? (Should it be a flag instead?) struct AST_Stmt_Else; struct AST_Stmt_If; struct AST_Stmt_For; struct AST_Stmt_Goto; struct AST_Stmt_Label; struct AST_Stmt_Switch; struct AST_Stmt_While; #endif struct AST_Struct; struct AST_Template; struct AST_Type; struct AST_Typedef; struct AST_Union; struct AST_Using; struct AST_Var; struct Code; struct CodeBody; // These are to offer ease of use and optionally strong type safety for the AST. struct CodeAttributes; // struct CodeBaseClass; struct CodeComment; struct CodeClass; struct CodeConstructor; struct CodeDefine; struct CodeDestructor; struct CodeEnum; struct CodeExec; struct CodeExtern; struct CodeInclude; struct CodeFriend; struct CodeFn; struct CodeModule; struct CodeNS; struct CodeOperator; struct CodeOpCast; struct CodeParam; struct CodePreprocessCond; struct CodePragma; struct CodeSpecifiers; #if GEN_EXECUTION_EXPRESSION_SUPPORT struct CodeExpr; struct CodeExpr_Assign; struct CodeExpr_Alignof; struct CodeExpr_Binary; struct CodeExpr_CStyleCast; struct CodeExpr_FunctionalCast; struct CodeExpr_CppCast; struct CodeExpr_Element; struct CodeExpr_ProcCall; struct CodeExpr_Decltype; struct CodeExpr_Comma; struct CodeExpr_AMS; // Access Member Symbol struct CodeExpr_Sizeof; struct CodeExpr_Subscript; struct CodeExpr_Ternary; struct CodeExpr_UnaryPrefix; struct CodeExpr_UnaryPostfix; struct CodeStmt; struct CodeStmt_Break; struct CodeStmt_Case; struct CodeStmt_Continue; struct CodeStmt_Decl; struct CodeStmt_Do; struct CodeStmt_Expr; struct CodeStmt_Else; struct CodeStmt_If; struct CodeStmt_For; struct CodeStmt_Goto; struct CodeStmt_Label; struct CodeStmt_Switch; struct CodeStmt_While; #endif struct CodeStruct; struct CodeTemplate; struct CodeType; struct CodeTypedef; struct CodeUnion; struct CodeUsing; struct CodeVar; namespace parser { struct Token; } /* AST* wrapper - Not constantly have to append the '*' as this is written often.. - Allows for implicit conversion to any of the ASTs (raw or filtered). */ struct Code { # pragma region Statics // Used to identify ASTs that should always be duplicated. (Global constant ASTs) static Code Global; // Used to identify invalid generated code. static Code Invalid; # pragma endregion Statics # define Using_Code( Typename ) \ char const* debug_str(); \ Code duplicate(); \ bool is_equal( Code other ); \ bool is_valid(); \ void set_global(); \ String to_string(); \ Typename& operator = ( AST* other ); \ Typename& operator = ( Code other ); \ bool operator ==( Code other ); \ bool operator !=( Code other ); \ operator bool(); Using_Code( Code ); template< class Type > forceinline Type cast() { return * rcast( Type*, this ); } AST* operator ->() { return ast; } Code& operator ++(); // TODO(Ed) : Remove this overload. auto& operator*() { local_persist thread_local Code NullRef = { nullptr }; if ( ast == nullptr ) return NullRef; return *this; } AST* ast; #ifdef GEN_ENFORCE_STRONG_CODE_TYPES # define operator explicit operator #endif operator CodeBody() const; operator CodeAttributes() const; // operator CodeBaseClass() const; operator CodeComment() const; operator CodeClass() const; operator CodeConstructor() const; operator CodeDefine() const; operator CodeDestructor() const; operator CodeExec() const; operator CodeEnum() const; operator CodeExtern() const; operator CodeInclude() const; operator CodeFriend() const; operator CodeFn() const; operator CodeModule() const; operator CodeNS() const; operator CodeOperator() const; operator CodeOpCast() const; operator CodeParam() const; operator CodePragma() const; operator CodePreprocessCond() const; operator CodeSpecifiers() const; operator CodeStruct() const; operator CodeTemplate() const; operator CodeType() const; operator CodeTypedef() const; operator CodeUnion() const; operator CodeUsing() const; operator CodeVar() const; #undef operator }; struct Code_POD { AST* ast; }; static_assert( sizeof(Code) == sizeof(Code_POD), "ERROR: Code is not POD" ); // Desired width of the AST data structure. constexpr int const AST_POD_Size = 128; /* Simple AST POD with functionality to seralize into C++ syntax. */ struct AST { # pragma region Member Functions void append ( AST* other ); char const* debug_str (); AST* duplicate (); Code& entry ( u32 idx ); bool has_entries(); bool is_equal ( AST* other ); char const* type_str(); bool validate_body(); String to_string(); neverinline void to_string( String& result ); template< class Type > forceinline Type cast() { return * this; } operator Code(); operator CodeBody(); operator CodeAttributes(); // operator CodeBaseClass(); operator CodeComment(); operator CodeConstructor(); operator CodeDestructor(); operator CodeClass(); operator CodeDefine(); operator CodeEnum(); operator CodeExec(); operator CodeExtern(); operator CodeInclude(); operator CodeFriend(); operator CodeFn(); operator CodeModule(); operator CodeNS(); operator CodeOperator(); operator CodeOpCast(); operator CodeParam(); operator CodePragma(); operator CodePreprocessCond(); operator CodeSpecifiers(); operator CodeStruct(); operator CodeTemplate(); operator CodeType(); operator CodeTypedef(); operator CodeUnion(); operator CodeUsing(); operator CodeVar(); # pragma endregion Member Functions constexpr static int ArrSpecs_Cap = ( AST_POD_Size - sizeof(AST*) * 3 - sizeof(parser::Token*) - sizeof(AST*) - sizeof(StringCached) - sizeof(CodeT) - sizeof(ModuleFlag) - sizeof(int) ) / sizeof(int) - 1; // -1 for 4 extra bytes union { struct { AST* InlineCmt; // Class, Constructor, Destructor, Enum, Friend, Functon, Operator, OpCast, Struct, Typedef, Using, Variable AST* Attributes; // Class, Enum, Function, Struct, Typedef, Union, Using, Variable AST* Specs; // Destructor, Function, Operator, Typename, Variable union { AST* InitializerList; // Constructor AST* ParentType; // Class, Struct, ParentType->Next has a possible list of interfaces. AST* ReturnType; // Function, Operator, Typename AST* UnderlyingType; // Enum, Typedef AST* ValueType; // Parameter, Variable }; union { AST* Macro; // Parameter AST* BitfieldSize; // Variable (Class/Struct Data Member) AST* Params; // Constructor, Function, Operator, Template, Typename }; union { AST* ArrExpr; // Typename AST* Body; // Class, Constructor, Destructor, Enum, Friend, Function, Namespace, Struct, Union AST* Declaration; // Friend, Template AST* Value; // Parameter, Variable }; union { AST* NextVar; // Variable; Possible way to handle comma separated variables declarations. ( , NextVar->Specs NextVar->Name NextVar->ArrExpr = NextVar->Value ) AST* SuffixSpecs; // Only used with typenames, to store the function suffix if typename is function signature. ( May not be needed ) AST* PostNameMacro; // Only used with parameters for specifically UE_REQUIRES (Thanks Unreal) }; }; StringCached Content; // Attributes, Comment, Execution, Include struct { SpecifierT ArrSpecs[ArrSpecs_Cap]; // Specifiers AST* NextSpecs; // Specifiers; If ArrSpecs is full, then NextSpecs is used. }; }; union { AST* Prev; AST* Front; AST* Last; }; union { AST* Next; AST* Back; }; parser::Token* Token; // Reference to starting token, only avaialble if it was derived from parsing. AST* Parent; StringCached Name; CodeT Type; // CodeFlag CodeFlags; ModuleFlag ModuleFlags; union { b32 IsFunction; // Used by typedef to not serialize the name field. b32 IsParamPack; // Used by typename to know if type should be considered a parameter pack. OperatorT Op; AccessSpec ParentAccess; s32 NumEntries; s32 VarConstructorInit; // Used by variables to know that initialization is using a constructor expression instead of an assignment expression. }; }; struct AST_POD { union { struct { AST* InlineCmt; // Class, Constructor, Destructor, Enum, Friend, Functon, Operator, OpCast, Struct, Typedef, Using, Variable AST* Attributes; // Class, Enum, Function, Struct, Typedef, Union, Using, Variable AST* Specs; // Destructor, Function, Operator, Typename, Variable union { AST* InitializerList; // Constructor AST* ParentType; // Class, Struct, ParentType->Next has a possible list of interfaces. AST* ReturnType; // Function, Operator, Typename AST* UnderlyingType; // Enum, Typedef AST* ValueType; // Parameter, Variable }; union { AST* Macro; // Parameter AST* BitfieldSize; // Variable (Class/Struct Data Member) AST* Params; // Constructor, Function, Operator, Template, Typename }; union { AST* ArrExpr; // Typename AST* Body; // Class, Constructr, Destructor, Enum, Friend, Function, Namespace, Struct, Union AST* Declaration; // Friend, Template AST* Value; // Parameter, Variable }; union { AST* NextVar; // Variable; Possible way to handle comma separated variables declarations. ( , NextVar->Specs NextVar->Name NextVar->ArrExpr = NextVar->Value ) AST* SuffixSpecs; // Only used with typenames, to store the function suffix if typename is function signature. ( May not be needed ) AST* PostNameMacro; // Only used with parameters for specifically UE_REQUIRES (Thanks Unreal) }; }; StringCached Content; // Attributes, Comment, Execution, Include struct { SpecifierT ArrSpecs[AST::ArrSpecs_Cap]; // Specifiers AST* NextSpecs; // Specifiers; If ArrSpecs is full, then NextSpecs is used. }; }; union { AST* Prev; AST* Front; AST* Last; }; union { AST* Next; AST* Back; }; parser::Token* Token; // Reference to starting token, only avaialble if it was derived from parsing. AST* Parent; StringCached Name; CodeT Type; CodeFlag CodeFlags; ModuleFlag ModuleFlags; union { b32 IsFunction; // Used by typedef to not serialize the name field. b32 IsParamPack; // Used by typename to know if type should be considered a parameter pack. OperatorT Op; AccessSpec ParentAccess; s32 NumEntries; s32 VarConstructorInit; // Used by variables to know that initialization is using a constructor expression instead of an assignment expression. }; }; struct test { SpecifierT ArrSpecs[AST::ArrSpecs_Cap]; // Specifiers AST* NextSpecs; // Specifiers; If ArrSpecs is full, then NextSpecs is used. }; constexpr int pls = sizeof(test); // Its intended for the AST to have equivalent size to its POD. // All extra functionality within the AST namespace should just be syntatic sugar. static_assert( sizeof(AST) == sizeof(AST_POD), "ERROR: AST IS NOT POD" ); static_assert( sizeof(AST_POD) == AST_POD_Size, "ERROR: AST POD is not size of AST_POD_Size" ); // Used when the its desired when omission is allowed in a definition. #define NoCode { nullptr } #define CodeInvalid (* Code::Invalid.ast) // Uses an implicitly overloaded cast from the AST to the desired code type. #pragma region Code Types struct CodeBody { Using_Code( CodeBody ); void append( Code other ) { raw()->append( other.ast ); } void append( CodeBody body ) { for ( Code entry : body ) { append( entry ); } } bool has_entries() { return rcast( AST*, ast )->has_entries(); } void to_string( String& result ); void to_string_export( String& result ); AST* raw() { return rcast( AST*, ast ); } AST_Body* operator->() { return ast; } operator Code() { return * rcast( Code*, this ); } #pragma region Iterator Code begin() { if ( ast ) return { rcast( AST*, ast)->Front }; return { nullptr }; } Code end() { return { rcast(AST*, ast)->Back->Next }; } #pragma endregion Iterator AST_Body* ast; }; struct CodeClass { Using_Code( CodeClass ); void add_interface( CodeType interface ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw() { return rcast( AST*, ast ); } operator Code() { return * rcast( Code*, this ); } AST_Class* operator->() { if ( ast == nullptr ) { log_failure("Attempt to dereference a nullptr"); return nullptr; } return ast; } AST_Class* ast; }; struct CodeParam { Using_Code( CodeParam ); void append( CodeParam other ); CodeParam get( s32 idx ); bool has_entries(); void to_string( String& result ); AST* raw() { return rcast( AST*, ast ); } AST_Param* operator->() { if ( ast == nullptr ) { log_failure("Attempt to dereference a nullptr!"); return nullptr; } return ast; } operator Code() { return { (AST*)ast }; } #pragma region Iterator CodeParam begin() { if ( ast ) return { ast }; return { nullptr }; } CodeParam end() { // return { (AST_Param*) rcast( AST*, ast)->Last }; return { nullptr }; } CodeParam& operator++(); CodeParam operator*() { return * this; } #pragma endregion Iterator AST_Param* ast; }; struct CodeSpecifiers { Using_Code( CodeSpecifiers ); bool append( SpecifierT spec ) { if ( ast == nullptr ) { log_failure("CodeSpecifiers: Attempted to append to a null specifiers AST!"); return false; } if ( raw()->NumEntries == AST::ArrSpecs_Cap ) { log_failure("CodeSpecifiers: Attempted to append over %d specifiers to a specifiers AST!", AST::ArrSpecs_Cap ); return false; } raw()->ArrSpecs[ raw()->NumEntries ] = spec; raw()->NumEntries++; return true; } s32 has( SpecifierT spec ) { for ( s32 idx = 0; idx < raw()->NumEntries; idx++ ) { if ( raw()->ArrSpecs[ idx ] == spec ) return idx; } return -1; } void to_string( String& result ); AST* raw() { return rcast( AST*, ast ); } AST_Specifiers* operator->() { if ( ast == nullptr ) { log_failure("Attempt to dereference a nullptr!"); return nullptr; } return ast; } operator Code() { return { (AST*) ast }; } #pragma region Iterator SpecifierT* begin() { if ( ast ) return & raw()->ArrSpecs[0]; return nullptr; } SpecifierT* end() { return raw()->ArrSpecs + raw()->NumEntries; } #pragma endregion Iterator AST_Specifiers* ast; }; struct CodeStruct { Using_Code( CodeStruct ); void add_interface( CodeType interface ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw() { return rcast( AST*, ast ); } operator Code() { return * rcast( Code*, this ); } AST_Struct* operator->() { if ( ast == nullptr ) { log_failure("Attempt to dereference a nullptr"); return nullptr; } return ast; } AST_Struct* ast; }; #define Define_CodeType( Typename ) \ struct Code##Typename \ { \ Using_Code( Code ## Typename ); \ AST* raw(); \ operator Code(); \ AST_##Typename* operator->(); \ AST_##Typename* ast; \ } Define_CodeType( Attributes ); // Define_CodeType( BaseClass ); Define_CodeType( Comment ); struct CodeConstructor { Using_Code( CodeConstructor ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw(); operator Code(); AST_Constructor* operator->(); AST_Constructor* ast; }; struct CodeDefine { Using_Code( CodeDefine ); void to_string( String& result ); AST* raw(); operator Code(); AST_Define* operator->(); AST_Define* ast; }; struct CodeDestructor { Using_Code( CodeDestructor ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw(); operator Code(); AST_Destructor* operator->(); AST_Destructor* ast; }; struct CodeEnum { Using_Code( CodeEnum ); void to_string_def( String& result ); void to_string_fwd( String& result ); void to_string_class_def( String& result ); void to_string_class_fwd( String& result ); AST* raw(); operator Code(); AST_Enum* operator->(); AST_Enum* ast; }; Define_CodeType( Exec ); #if GEN_EXECUTION_EXPRESSION_SUPPORT struct CodeExpr { Using_Code( CodeExpr ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr* operator->(); AST_Expr* ast; }; struct CodeExpr_Assign { Using_Code( CodeExpr_Assign ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Assign* operator->(); AST_Expr_Assign* ast; }; struct CodeExpr_Alignof { Using_Code( CodeExpr_Alignof ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Alignof* operator->(); AST_Expr_Alignof* ast; }; struct CodeExpr_Binary { Using_Code( CodeExpr_Binary ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Binary* operator->(); AST_Expr_Binary* ast; }; struct CodeExpr_CStyleCast { Using_Code( CodeExpr_CStyleCast ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_CStyleCast* operator->(); AST_Expr_CStyleCast* ast; }; struct CodeExpr_FunctionalCast { Using_Code( CodeExpr_FunctionalCast ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_FunctionalCast* operator->(); AST_Expr_FunctionalCast* ast; }; struct CodeExpr_CppCast { Using_Code( CodeExpr_CppCast ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_CppCast* operator->(); AST_Expr_CppCast* ast; }; struct CodeExpr_Element { Using_Code( CodeExpr_Element ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Element* operator->(); AST_Expr_Element* ast; }; struct CodeExpr_ProcCall { Using_Code( CodeExpr_ProcCall ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_ProcCall* operator->(); AST_Expr_ProcCall* ast; }; struct CodeExpr_Decltype { Using_Code( CodeExpr_Decltype ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Decltype* operator->(); AST_Expr_Decltype* ast; }; struct CodeExpr_Comma { Using_Code( CodeExpr_Comma ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Comma* operator->(); AST_Expr_Comma* ast; }; struct CodeExpr_AMS { Using_Code( CodeExpr_AMS ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_AMS* operator->(); AST_Expr_AMS* ast; }; struct CodeExpr_Sizeof { Using_Code( CodeExpr_Sizeof ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Sizeof* operator->(); AST_Expr_Sizeof* ast; }; struct CodeExpr_Subscript { Using_Code( CodeExpr_Subscript ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Subscript* operator->(); AST_Expr_Subscript* ast; }; struct CodeExpr_Ternary { Using_Code( CodeExpr_Ternary ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_Ternary* operator->(); AST_Expr_Ternary* ast; }; struct CodeExpr_UnaryPrefix { Using_Code( CodeExpr_UnaryPrefix ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_UnaryPrefix* operator->(); AST_Expr_UnaryPrefix* ast; }; struct CodeExpr_UnaryPostfix { Using_Code( CodeExpr_UnaryPostfix ); void to_string( String& result ); AST* raw(); operator Code(); AST_Expr_UnaryPostfix* operator->(); AST_Expr_UnaryPostfix* ast; }; #endif struct CodeExtern { Using_Code( CodeExtern ); void to_string( String& result ); AST* raw(); operator Code(); AST_Extern* operator->(); AST_Extern* ast; }; struct CodeInclude { Using_Code( CodeInclude ); void to_string( String& result ); AST* raw(); operator Code(); AST_Include* operator->(); AST_Include* ast; }; struct CodeFriend { Using_Code( CodeFriend ); void to_string( String& result ); AST* raw(); operator Code(); AST_Friend* operator->(); AST_Friend* ast; }; struct CodeFn { Using_Code( CodeFn ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw(); operator Code(); AST_Fn* operator->(); AST_Fn* ast; }; struct CodeModule { Using_Code( CodeModule ); void to_string( String& result ); AST* raw(); operator Code(); AST_Module* operator->(); AST_Module* ast; }; struct CodeNS { Using_Code( CodeNS ); void to_string( String& result ); AST* raw(); operator Code(); AST_NS* operator->(); AST_NS* ast; }; struct CodeOperator { Using_Code( CodeOperator ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw(); operator Code(); AST_Operator* operator->(); AST_Operator* ast; }; struct CodeOpCast { Using_Code( CodeOpCast ); void to_string_def( String& result ); void to_string_fwd( String& result ); AST* raw(); operator Code(); AST_OpCast* operator->(); AST_OpCast* ast; }; struct CodePragma { Using_Code( CodePragma ); void to_string( String& result ); AST* raw(); operator Code(); AST_Pragma* operator->(); AST_Pragma* ast; }; struct CodePreprocessCond { Using_Code( CodePreprocessCond ); void to_string_if( String& result ); void to_string_ifdef( String& result ); void to_string_ifndef( String& result ); void to_string_elif( String& result ); void to_string_else( String& result ); void to_string_endif( String& result ); AST* raw(); operator Code(); AST_PreprocessCond* operator->(); AST_PreprocessCond* ast; }; #if GEN_EXECUTION_EXPRESSION_SUPPORT struct CodeStmt { Using_Code( CodeStmt ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt* operator->(); AST_Stmt* ast; }; struct CodeStmt_Break { Using_Code( CodeStmt_Break ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Break* operator->(); AST_Stmt_Break* ast; }; struct CodeStmt_Case { Using_Code( CodeStmt_Case ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Case* operator->(); AST_Stmt_Case* ast; }; struct CodeStmt_Continue { Using_Code( CodeStmt_Continue ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Continue* operator->(); AST_Stmt_Continue* ast; }; struct CodeStmt_Decl { Using_Code( CodeStmt_Decl ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Decl* operator->(); AST_Stmt_Decl* ast; }; struct CodeStmt_Do { Using_Code( CodeStmt_Do ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Do* operator->(); AST_Stmt_Do* ast; }; struct CodeStmt_Expr { Using_Code( CodeStmt_Expr ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Expr* operator->(); AST_Stmt_Expr* ast; }; struct CodeStmt_Else { Using_Code( CodeStmt_Else ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Else* operator->(); AST_Stmt_Else* ast; }; struct CodeStmt_If { Using_Code( CodeStmt_If ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_If* operator->(); AST_Stmt_If* ast; }; struct CodeStmt_For { Using_Code( CodeStmt_For ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_For* operator->(); AST_Stmt_For* ast; }; struct CodeStmt_Goto { Using_Code( CodeStmt_Goto ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Goto* operator->(); AST_Stmt_Goto* ast; }; struct CodeStmt_Label { Using_Code( CodeStmt_Label ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Label* operator->(); AST_Stmt_Label* ast; }; struct CodeStmt_Switch { Using_Code( CodeStmt_Switch ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_Switch* operator->(); AST_Stmt_Switch* ast; }; struct CodeStmt_While { Using_Code( CodeStmt_While ); void to_string( String& result ); AST* raw(); operator Code(); AST_Stmt_While* operator->(); AST_Stmt_While* ast; }; #endif struct CodeTemplate { Using_Code( CodeTemplate ); void to_string( String& result ); AST* raw(); operator Code(); AST_Template* operator->(); AST_Template* ast; }; struct CodeType { Using_Code( CodeType ); void to_string( String& result ); AST* raw(); operator Code(); AST_Type* operator->(); AST_Type* ast; }; struct CodeTypedef { Using_Code( CodeTypedef ); void to_string( String& result ); AST* raw(); operator Code(); AST_Typedef* operator->(); AST_Typedef* ast; }; struct CodeUnion { Using_Code( CodeUnion ); void to_string( String& result ); AST* raw(); operator Code(); AST_Union* operator->(); AST_Union* ast; }; struct CodeUsing { Using_Code( CodeUsing ); void to_string( String& result ); void to_string_ns( String& result ); AST* raw(); operator Code(); AST_Using* operator->(); AST_Using* ast; }; struct CodeVar { Using_Code( CodeVar ); void to_string( String& result ); AST* raw(); operator Code(); AST_Var* operator->(); AST_Var* ast; }; #undef Define_CodeType #undef Using_Code #pragma endregion Code Types #pragma region AST Types /* Show only relevant members of the AST for its type. AST* fields are replaced with Code types. - Guards assignemnts to AST* fields to ensure the AST is duplicated if assigned to another parent. */ struct AST_Body { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; Code Front; Code Back; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) ]; s32 NumEntries; }; static_assert( sizeof(AST_Body) == sizeof(AST), "ERROR: AST_Body is not the same size as AST"); struct AST_Attributes { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Attributes) == sizeof(AST), "ERROR: AST_Attributes is not the same size as AST"); #if 0 struct AST_BaseClass { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_BaseClass) == sizeof(AST), "ERROR: AST_BaseClass is not the same size as AST"); #endif struct AST_Comment { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Comment) == sizeof(AST), "ERROR: AST_Comment is not the same size as AST"); struct AST_Class { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; // Only supported by forward declarations CodeAttributes Attributes; char _PAD_SPECS_ [ sizeof(AST*) ]; CodeType ParentType; char _PAD_PARAMS_[ sizeof(AST*) ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; CodeType Prev; CodeType Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; AccessSpec ParentAccess; }; static_assert( sizeof(AST_Class) == sizeof(AST), "ERROR: AST_Class is not the same size as AST"); struct AST_Constructor { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; // Only supported by forward declarations char _PAD_PROPERTIES_ [ sizeof(AST*) * 1 ]; CodeSpecifiers Specs; Code InitializerList; CodeParam Params; Code Body; char _PAD_PROPERTIES_2_ [ sizeof(AST*) * 2 ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Constructor) == sizeof(AST), "ERROR: AST_Constructor is not the same size as AST"); struct AST_Define { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Define) == sizeof(AST), "ERROR: AST_Define is not the same size as AST"); struct AST_Destructor { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; char _PAD_PROPERTIES_ [ sizeof(AST*) * 1 ]; CodeSpecifiers Specs; char _PAD_PROPERTIES_2_ [ sizeof(AST*) * 2 ]; Code Body; char _PAD_PROPERTIES_3_ [ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Destructor) == sizeof(AST), "ERROR: AST_Destructor is not the same size as AST"); struct AST_Enum { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; char _PAD_SPEC_ [ sizeof(AST*) ]; CodeType UnderlyingType; char _PAD_PARAMS_[ sizeof(AST*) ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Enum) == sizeof(AST), "ERROR: AST_Enum is not the same size as AST"); struct AST_Exec { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Exec) == sizeof(AST), "ERROR: AST_Exec is not the same size as AST"); #if GEN_EXECUTION_EXPRESSION_SUPPORT struct AST_Expr { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr) == sizeof(AST), "ERROR: AST_Expr is not the same size as AST"); struct AST_Expr_Assign { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Assign) == sizeof(AST), "ERROR: AST_Expr_Assign is not the same size as AST"); struct AST_Expr_Alignof { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Alignof) == sizeof(AST), "ERROR: AST_Expr_Alignof is not the same size as AST"); struct AST_Expr_Binary { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Binary) == sizeof(AST), "ERROR: AST_Expr_Binary is not the same size as AST"); struct AST_Expr_CStyleCast { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_CStyleCast) == sizeof(AST), "ERROR: AST_Expr_CStyleCast is not the same size as AST"); struct AST_Expr_FunctionalCast { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_FunctionalCast) == sizeof(AST), "ERROR: AST_Expr_FunctionalCast is not the same size as AST"); struct AST_Expr_CppCast { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_CppCast) == sizeof(AST), "ERROR: AST_Expr_CppCast is not the same size as AST"); struct AST_Expr_ProcCall { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_ProcCall) == sizeof(AST), "ERROR: AST_Expr_Identifier is not the same size as AST"); struct AST_Expr_Decltype { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Decltype) == sizeof(AST), "ERROR: AST_Expr_Decltype is not the same size as AST"); struct AST_Expr_Comma { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Comma) == sizeof(AST), "ERROR: AST_Expr_Comma is not the same size as AST"); struct AST_Expr_AMS { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_AMS) == sizeof(AST), "ERROR: AST_Expr_AMS is not the same size as AST"); struct AST_Expr_Sizeof { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Sizeof) == sizeof(AST), "ERROR: AST_Expr_Sizeof is not the same size as AST"); struct AST_Expr_Subscript { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Subscript) == sizeof(AST), "ERROR: AST_Expr_Subscript is not the same size as AST"); struct AST_Expr_Ternary { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Ternary) == sizeof(AST), "ERROR: AST_Expr_Ternary is not the same size as AST"); struct AST_Expr_UnaryPrefix { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_UnaryPrefix) == sizeof(AST), "ERROR: AST_Expr_UnaryPrefix is not the same size as AST"); struct AST_Expr_UnaryPostfix { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_UnaryPostfix) == sizeof(AST), "ERROR: AST_Expr_UnaryPostfix is not the same size as AST"); struct AST_Expr_Element { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Expr_Element) == sizeof(AST), "ERROR: AST_Expr_Element is not the same size as AST"); #endif struct AST_Extern { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_PROPERTIES_[ sizeof(AST*) * 5 ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Extern) == sizeof(AST), "ERROR: AST_Extern is not the same size as AST"); struct AST_Include { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Include) == sizeof(AST), "ERROR: AST_Include is not the same size as AST"); struct AST_Friend { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; char _PAD_PROPERTIES_[ sizeof(AST*) * 4 ]; Code Declaration; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Friend) == sizeof(AST), "ERROR: AST_Friend is not the same size as AST"); struct AST_Fn { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; CodeSpecifiers Specs; CodeType ReturnType; CodeParam Params; CodeBody Body; char _PAD_PROPERTIES_ [ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Fn) == sizeof(AST), "ERROR: AST_Fn is not the same size as AST"); struct AST_Module { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Module) == sizeof(AST), "ERROR: AST_Module is not the same size as AST"); struct AST_NS { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_PROPERTIES_[ sizeof(AST*) * 5 ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_NS) == sizeof(AST), "ERROR: AST_NS is not the same size as AST"); struct AST_Operator { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; CodeSpecifiers Specs; CodeType ReturnType; CodeParam Params; CodeBody Body; char _PAD_PROPERTIES_ [ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; OperatorT Op; }; static_assert( sizeof(AST_Operator) == sizeof(AST), "ERROR: AST_Operator is not the same size as AST"); struct AST_OpCast { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; char _PAD_PROPERTIES_[ sizeof(AST*) ]; CodeSpecifiers Specs; CodeType ValueType; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; CodeBody Body; char _PAD_PROPERTIES_3_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_OpCast) == sizeof(AST), "ERROR: AST_OpCast is not the same size as AST"); struct AST_Param { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_PROPERTIES_2_[ sizeof(AST*) * 3 ]; CodeType ValueType; Code Macro; Code Value; Code PostNameMacro; // Thanks Unreal // char _PAD_PROPERTIES_3_[sizeof( AST* )]; }; }; CodeParam Last; CodeParam Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) ]; s32 NumEntries; }; static_assert( sizeof(AST_Param) == sizeof(AST), "ERROR: AST_Param is not the same size as AST"); struct AST_Pragma { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Pragma) == sizeof(AST), "ERROR: AST_Pragma is not the same size as AST"); struct AST_PreprocessCond { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; StringCached Content; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_PreprocessCond) == sizeof(AST), "ERROR: AST_PreprocessCond is not the same size as AST"); struct AST_Specifiers { SpecifierT ArrSpecs[ AST::ArrSpecs_Cap ]; CodeSpecifiers NextSpecs; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) ]; s32 NumEntries; }; static_assert( sizeof(AST_Specifiers) == sizeof(AST), "ERROR: AST_Specifier is not the same size as AST"); #if GEN_EXECUTION_EXPRESSION_SUPPORT struct AST_Stmt { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt) == sizeof(AST), "ERROR: AST_Stmt is not the same size as AST"); struct AST_Stmt_Break { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Break) == sizeof(AST), "ERROR: AST_Stmt_Break is not the same size as AST"); struct AST_Stmt_Case { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Case) == sizeof(AST), "ERROR: AST_Stmt_Case is not the same size as AST"); struct AST_Stmt_Continue { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Continue) == sizeof(AST), "ERROR: AST_Stmt_Continue is not the same size as AST"); struct AST_Stmt_Decl { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Decl) == sizeof(AST), "ERROR: AST_Stmt_Decl is not the same size as AST"); struct AST_Stmt_Do { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Do) == sizeof(AST), "ERROR: AST_Stmt_Do is not the same size as AST"); struct AST_Stmt_Expr { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Expr) == sizeof(AST), "ERROR: AST_Stmt_Expr is not the same size as AST"); struct AST_Stmt_Else { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Else) == sizeof(AST), "ERROR: AST_Stmt_Else is not the same size as AST"); struct AST_Stmt_If { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_If) == sizeof(AST), "ERROR: AST_Stmt_If is not the same size as AST"); struct AST_Stmt_For { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_For) == sizeof(AST), "ERROR: AST_Stmt_For is not the same size as AST"); struct AST_Stmt_Goto { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Goto) == sizeof(AST), "ERROR: AST_Stmt_Goto is not the same size as AST"); struct AST_Stmt_Label { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Label) == sizeof(AST), "ERROR: AST_Stmt_Label is not the same size as AST"); struct AST_Stmt_Switch { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_Switch) == sizeof(AST), "ERROR: AST_Stmt_Switch is not the same size as AST"); struct AST_Stmt_While { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; }; CodeExpr Prev; CodeExpr Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) + sizeof(u32) ]; }; static_assert( sizeof(AST_Stmt_While) == sizeof(AST), "ERROR: AST_Stmt_While is not the same size as AST"); #endif struct AST_Struct { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; char _PAD_SPECS_ [ sizeof(AST*) ]; CodeType ParentType; char _PAD_PARAMS_[ sizeof(AST*) ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; CodeType Prev; CodeType Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; AccessSpec ParentAccess; }; static_assert( sizeof(AST_Struct) == sizeof(AST), "ERROR: AST_Struct is not the same size as AST"); struct AST_Template { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_PROPERTIES_[ sizeof(AST*) * 4 ]; CodeParam Params; Code Declaration; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Template) == sizeof(AST), "ERROR: AST_Template is not the same size as AST"); #if 0 // WIP... The type ast is going to become more advanced and lead to a major change to AST design. struct AST_Type { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_INLINE_CMT_[ sizeof(AST*) ]; CodeAttributes Attributes; CodeSpecifiers Specs; Code QualifierID; // CodeType ReturnType; // Only used for function signatures // CodeParam Params; // Only used for function signatures Code ArrExpr; // CodeSpecifiers SpecsFuncSuffix; // Only used for function signatures }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) ]; b32 IsParamPack; }; static_assert( sizeof(AST_Type) == sizeof(AST), "ERROR: AST_Type is not the same size as AST"); #endif struct AST_Type { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_INLINE_CMT_[ sizeof(AST*) ]; CodeAttributes Attributes; CodeSpecifiers Specs; CodeType ReturnType; // Only used for function signatures CodeParam Params; // Only used for function signatures Code ArrExpr; CodeSpecifiers SpecsFuncSuffix; // Only used for function signatures }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; char _PAD_UNUSED_[ sizeof(ModuleFlag) ]; b32 IsParamPack; }; static_assert( sizeof(AST_Type) == sizeof(AST), "ERROR: AST_Type is not the same size as AST"); struct AST_Typedef { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; char _PAD_PROPERTIES_[ sizeof(AST*) * 2 ]; Code UnderlyingType; char _PAD_PROPERTIES_2_[ sizeof(AST*) * 3 ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; b32 IsFunction; }; static_assert( sizeof(AST_Typedef) == sizeof(AST), "ERROR: AST_Typedef is not the same size as AST"); struct AST_Union { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { char _PAD_INLINE_CMT_[ sizeof(AST*) ]; CodeAttributes Attributes; char _PAD_PROPERTIES_[ sizeof(AST*) * 3 ]; CodeBody Body; char _PAD_PROPERTIES_2_[ sizeof(AST*) ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Union) == sizeof(AST), "ERROR: AST_Union is not the same size as AST"); struct AST_Using { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; char _PAD_SPECS_ [ sizeof(AST*) ]; CodeType UnderlyingType; char _PAD_PROPERTIES_[ sizeof(AST*) * 3 ]; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; char _PAD_UNUSED_[ sizeof(u32) ]; }; static_assert( sizeof(AST_Using) == sizeof(AST), "ERROR: AST_Using is not the same size as AST"); struct AST_Var { union { char _PAD_[ sizeof(SpecifierT) * AST::ArrSpecs_Cap + sizeof(AST*) ]; struct { CodeComment InlineCmt; CodeAttributes Attributes; CodeSpecifiers Specs; CodeType ValueType; Code BitfieldSize; Code Value; CodeVar NextVar; }; }; Code Prev; Code Next; parser::Token* Tok; Code Parent; StringCached Name; CodeT Type; ModuleFlag ModuleFlags; s32 VarConstructorInit; }; static_assert( sizeof(AST_Var) == sizeof(AST), "ERROR: AST_Var is not the same size as AST"); #pragma endregion AST Types #pragma endregion AST #pragma region Gen Interface // Initialize the library. // This currently just initializes the CodePool. void init(); // Currently manually free's the arenas, code for checking for leaks. // However on Windows at least, it doesn't need to occur as the OS will clean up after the process. void deinit(); // Clears the allocations, but doesn't return to the heap, the calls init() again. // Ease of use. void reset(); // Used internally to retrive or make string allocations. // Strings are stored in a series of string arenas of fixed size (SizePer_StringArena) StringCached get_cached_string( StrC str ); /* This provides a fresh Code AST. The gen interface use this as their method from getting a new AST object from the CodePool. Use this if you want to make your own API for formatting the supported Code Types. */ Code make_code(); // Set these before calling gen's init() procedure. void set_allocator_data_arrays ( AllocatorInfo data_array_allocator ); void set_allocator_code_pool ( AllocatorInfo pool_allocator ); void set_allocator_lexer ( AllocatorInfo lex_allocator ); void set_allocator_string_arena( AllocatorInfo string_allocator ); void set_allocator_string_table( AllocatorInfo string_allocator ); void set_allocator_type_table ( AllocatorInfo type_reg_allocator ); #pragma region Upfront CodeAttributes def_attributes( StrC content ); CodeComment def_comment ( StrC content ); CodeClass def_class( StrC name , Code body = NoCode , CodeType parent = NoCode, AccessSpec access = AccessSpec::Default , CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None , CodeType* interfaces = nullptr, s32 num_interfaces = 0 ); CodeConstructor def_constructor( CodeParam params = NoCode, Code initializer_list = NoCode, Code body = NoCode ); CodeDefine def_define( StrC name, StrC content ); CodeDestructor def_destructor( Code body = NoCode, CodeSpecifiers specifiers = NoCode ); CodeEnum def_enum( StrC name , Code body = NoCode, CodeType type = NoCode , EnumT specifier = EnumRegular, CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None ); CodeExec def_execution ( StrC content ); CodeExtern def_extern_link( StrC name, Code body ); CodeFriend def_friend ( Code symbol ); CodeFn def_function( StrC name , CodeParam params = NoCode, CodeType ret_type = NoCode, Code body = NoCode , CodeSpecifiers specifiers = NoCode, CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None ); CodeInclude def_include ( StrC content, bool foreign = false ); CodeModule def_module ( StrC name, ModuleFlag mflags = ModuleFlag::None ); CodeNS def_namespace( StrC name, Code body, ModuleFlag mflags = ModuleFlag::None ); CodeOperator def_operator( OperatorT op, StrC nspace , CodeParam params = NoCode, CodeType ret_type = NoCode, Code body = NoCode , CodeSpecifiers specifiers = NoCode, CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None ); CodeOpCast def_operator_cast( CodeType type, Code body = NoCode, CodeSpecifiers specs = NoCode ); CodeParam def_param ( CodeType type, StrC name, Code value = NoCode ); CodePragma def_pragma( StrC directive ); CodePreprocessCond def_preprocess_cond( EPreprocessCond type, StrC content ); CodeSpecifiers def_specifier( SpecifierT specifier ); CodeStruct def_struct( StrC name , Code body = NoCode , CodeType parent = NoCode, AccessSpec access = AccessSpec::Default , CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None , CodeType* interfaces = nullptr, s32 num_interfaces = 0 ); CodeTemplate def_template( CodeParam params, Code definition, ModuleFlag mflags = ModuleFlag::None ); CodeType def_type ( StrC name, Code arrayexpr = NoCode, CodeSpecifiers specifiers = NoCode, CodeAttributes attributes = NoCode ); CodeTypedef def_typedef( StrC name, Code type, CodeAttributes attributes = NoCode, ModuleFlag mflags = ModuleFlag::None ); CodeUnion def_union( StrC name, Code body, CodeAttributes attributes = NoCode, ModuleFlag mflags = ModuleFlag::None ); CodeUsing def_using( StrC name, CodeType type = NoCode , CodeAttributes attributess = NoCode , ModuleFlag mflags = ModuleFlag::None ); CodeUsing def_using_namespace( StrC name ); CodeVar def_variable( CodeType type, StrC name, Code value = NoCode , CodeSpecifiers specifiers = NoCode, CodeAttributes attributes = NoCode , ModuleFlag mflags = ModuleFlag::None ); // Constructs an empty body. Use AST::validate_body() to check if the body is was has valid entries. CodeBody def_body( CodeT type ); // There are two options for defining a struct body, either varadically provided with the args macro to auto-deduce the arg num, /// or provide as an array of Code objects. CodeBody def_class_body ( s32 num, ... ); CodeBody def_class_body ( s32 num, Code* codes ); CodeBody def_enum_body ( s32 num, ... ); CodeBody def_enum_body ( s32 num, Code* codes ); CodeBody def_export_body ( s32 num, ... ); CodeBody def_export_body ( s32 num, Code* codes); CodeBody def_extern_link_body( s32 num, ... ); CodeBody def_extern_link_body( s32 num, Code* codes ); CodeBody def_function_body ( s32 num, ... ); CodeBody def_function_body ( s32 num, Code* codes ); CodeBody def_global_body ( s32 num, ... ); CodeBody def_global_body ( s32 num, Code* codes ); CodeBody def_namespace_body ( s32 num, ... ); CodeBody def_namespace_body ( s32 num, Code* codes ); CodeParam def_params ( s32 num, ... ); CodeParam def_params ( s32 num, CodeParam* params ); CodeSpecifiers def_specifiers ( s32 num, ... ); CodeSpecifiers def_specifiers ( s32 num, SpecifierT* specs ); CodeBody def_struct_body ( s32 num, ... ); CodeBody def_struct_body ( s32 num, Code* codes ); CodeBody def_union_body ( s32 num, ... ); CodeBody def_union_body ( s32 num, Code* codes ); #pragma endregion Upfront #pragma region Parsing // TODO(Ed) : Implmeent the new parser API design. #if 0 namespace parser { struct StackNode { StackNode* Prev; Token Start; Token Name; // The name of the AST node (if parsed) StrC FailedProc; // The name of the procedure that failed }; // Stack nodes are allocated the error's allocator struct Error { String message; StackNode* context_stack; }; } struct ParseInfo { Arena FileMem; Arena TokMem; Arena CodeMem; FileContents FileContent; Array Tokens; Array Errors; // Errors are allocated to a dedicated general arena. }; CodeBody parse_file( StrC path ); #endif CodeClass parse_class ( StrC class_def ); CodeConstructor parse_constructor ( StrC constructor_def ); CodeDestructor parse_destructor ( StrC destructor_def ); CodeEnum parse_enum ( StrC enum_def ); CodeBody parse_export_body ( StrC export_def ); CodeExtern parse_extern_link ( StrC exten_link_def ); CodeFriend parse_friend ( StrC friend_def ); CodeFn parse_function ( StrC fn_def ); CodeBody parse_global_body ( StrC body_def ); CodeNS parse_namespace ( StrC namespace_def ); CodeOperator parse_operator ( StrC operator_def ); CodeOpCast parse_operator_cast( StrC operator_def ); CodeStruct parse_struct ( StrC struct_def ); CodeTemplate parse_template ( StrC template_def ); CodeType parse_type ( StrC type_def ); CodeTypedef parse_typedef ( StrC typedef_def ); CodeUnion parse_union ( StrC union_def ); CodeUsing parse_using ( StrC using_def ); CodeVar parse_variable ( StrC var_def ); #pragma endregion Parsing #pragma region Untyped text ssize token_fmt_va( char* buf, usize buf_size, s32 num_tokens, va_list va ); //! Do not use directly. Use the token_fmt macro instead. StrC token_fmt_impl( ssize, ... ); Code untyped_str ( StrC content); Code untyped_fmt ( char const* fmt, ... ); Code untyped_token_fmt( char const* fmt, s32 num_tokens, ... ); #pragma endregion Untyped text #pragma endregion Gen Interface #pragma region Inlines inline void AST::append( AST* other ) { if ( other->Parent ) other = other->duplicate(); other->Parent = this; if ( Front == nullptr ) { Front = other; Back = other; NumEntries++; return; } AST* Current = Back; Current->Next = other; other->Prev = Current; Back = other; NumEntries++; } inline Code& AST::entry( u32 idx ) { AST** current = & Front; while ( idx >= 0 && current != nullptr ) { if ( idx == 0 ) return * rcast( Code*, current); current = & ( * current )->Next; idx--; } return * rcast( Code*, current); } inline bool AST::has_entries() { return NumEntries > 0; } inline char const* AST::type_str() { return ECode::to_str( Type ); } inline AST::operator Code() { return { this }; } inline Code& Code::operator ++() { if ( ast ) ast = ast->Next; return *this; } inline void CodeClass::add_interface( CodeType type ) { CodeType possible_slot = ast->ParentType; if ( possible_slot.ast ) { // Were adding an interface to parent type, so we need to make sure the parent type is public. ast->ParentAccess = AccessSpec::Public; // If your planning on adding a proper parent, // then you'll need to move this over to ParentType->next and update ParentAccess accordingly. } while ( possible_slot.ast != nullptr ) { possible_slot.ast = (AST_Type*) possible_slot->Next.ast; } possible_slot.ast = type.ast; } inline void CodeParam::append( CodeParam other ) { AST* self = (AST*) ast; AST* entry = (AST*) other.ast; if ( entry->Parent ) entry = entry->duplicate(); entry->Parent = self; if ( self->Last == nullptr ) { self->Last = entry; self->Next = entry; self->NumEntries++; return; } self->Last->Next = entry; self->Last = entry; self->NumEntries++; } inline CodeParam CodeParam::get( s32 idx ) { CodeParam param = *this; do { if ( ! ++ param ) return { nullptr }; param = { (AST_Param*) param.raw()->Next }; } while ( --idx ); return param; } inline bool CodeParam::has_entries() { return ast->NumEntries > 0; } inline CodeParam& CodeParam::operator ++() { ast = ast->Next.ast; return * this; } inline void CodeStruct::add_interface( CodeType type ) { CodeType possible_slot = ast->ParentType; if ( possible_slot.ast ) { // Were adding an interface to parent type, so we need to make sure the parent type is public. ast->ParentAccess = AccessSpec::Public; // If your planning on adding a proper parent, // then you'll need to move this over to ParentType->next and update ParentAccess accordingly. } while ( possible_slot.ast != nullptr ) { possible_slot.ast = (AST_Type*) possible_slot->Next.ast; } possible_slot.ast = type.ast; } inline CodeBody def_body( CodeT type ) { switch ( type ) { using namespace ECode; case Class_Body: case Enum_Body: case Export_Body: case Extern_Linkage: case Function_Body: case Global_Body: case Namespace_Body: case Struct_Body: case Union_Body: break; default: log_failure( "def_body: Invalid type %s", (char const*)ECode::to_str(type) ); return (CodeBody)Code::Invalid; } Code result = make_code(); result->Type = type; return (CodeBody)result; } inline StrC token_fmt_impl( ssize num, ... ) { local_persist thread_local char buf[GEN_PRINTF_MAXLEN] = { 0 }; mem_set( buf, 0, GEN_PRINTF_MAXLEN ); va_list va; va_start(va, num ); ssize result = token_fmt_va(buf, GEN_PRINTF_MAXLEN, num, va); va_end(va); return { result, buf }; } #pragma region generated code inline implementation inline char const* Code::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code Code::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool Code::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool Code::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void Code::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline Code& Code::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool Code::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool Code::operator!=( Code other ) { return (AST*)ast != other.ast; } inline Code::operator bool() { return ast != nullptr; } inline char const* CodeBody::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeBody::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeBody::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeBody::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeBody::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeBody& CodeBody::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeBody::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeBody::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeBody::operator bool() { return ast != nullptr; } inline char const* CodeAttributes::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeAttributes::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeAttributes::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeAttributes::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeAttributes::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeAttributes& CodeAttributes::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeAttributes::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeAttributes::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeAttributes::operator bool() { return ast != nullptr; } inline AST* CodeAttributes::raw() { return rcast( AST*, ast ); } inline CodeAttributes::operator Code() { return *rcast( Code*, this ); } inline AST_Attributes* CodeAttributes::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeComment::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeComment::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeComment::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeComment::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeComment::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeComment& CodeComment::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeComment::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeComment::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeComment::operator bool() { return ast != nullptr; } inline AST* CodeComment::raw() { return rcast( AST*, ast ); } inline CodeComment::operator Code() { return *rcast( Code*, this ); } inline AST_Comment* CodeComment::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeConstructor::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeConstructor::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeConstructor::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeConstructor::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeConstructor::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeConstructor& CodeConstructor::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeConstructor::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeConstructor::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeConstructor::operator bool() { return ast != nullptr; } inline AST* CodeConstructor::raw() { return rcast( AST*, ast ); } inline CodeConstructor::operator Code() { return *rcast( Code*, this ); } inline AST_Constructor* CodeConstructor::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeClass::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeClass::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeClass::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeClass::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeClass::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeClass& CodeClass::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeClass::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeClass::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeClass::operator bool() { return ast != nullptr; } inline char const* CodeDefine::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeDefine::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeDefine::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeDefine::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeDefine::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeDefine& CodeDefine::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeDefine::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeDefine::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeDefine::operator bool() { return ast != nullptr; } inline AST* CodeDefine::raw() { return rcast( AST*, ast ); } inline CodeDefine::operator Code() { return *rcast( Code*, this ); } inline AST_Define* CodeDefine::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeDestructor::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeDestructor::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeDestructor::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeDestructor::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeDestructor::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeDestructor& CodeDestructor::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeDestructor::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeDestructor::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeDestructor::operator bool() { return ast != nullptr; } inline AST* CodeDestructor::raw() { return rcast( AST*, ast ); } inline CodeDestructor::operator Code() { return *rcast( Code*, this ); } inline AST_Destructor* CodeDestructor::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeEnum::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeEnum::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeEnum::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeEnum::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeEnum::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeEnum& CodeEnum::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeEnum::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeEnum::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeEnum::operator bool() { return ast != nullptr; } inline AST* CodeEnum::raw() { return rcast( AST*, ast ); } inline CodeEnum::operator Code() { return *rcast( Code*, this ); } inline AST_Enum* CodeEnum::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeExec::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeExec::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeExec::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeExec::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeExec::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeExec& CodeExec::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeExec::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeExec::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeExec::operator bool() { return ast != nullptr; } inline AST* CodeExec::raw() { return rcast( AST*, ast ); } inline CodeExec::operator Code() { return *rcast( Code*, this ); } inline AST_Exec* CodeExec::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeExtern::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeExtern::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeExtern::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeExtern::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeExtern::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeExtern& CodeExtern::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeExtern::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeExtern::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeExtern::operator bool() { return ast != nullptr; } inline AST* CodeExtern::raw() { return rcast( AST*, ast ); } inline CodeExtern::operator Code() { return *rcast( Code*, this ); } inline AST_Extern* CodeExtern::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeFriend::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeFriend::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeFriend::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeFriend::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeFriend::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeFriend& CodeFriend::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeFriend::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeFriend::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeFriend::operator bool() { return ast != nullptr; } inline AST* CodeFriend::raw() { return rcast( AST*, ast ); } inline CodeFriend::operator Code() { return *rcast( Code*, this ); } inline AST_Friend* CodeFriend::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeFn::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeFn::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeFn::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeFn::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeFn::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeFn& CodeFn::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeFn::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeFn::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeFn::operator bool() { return ast != nullptr; } inline AST* CodeFn::raw() { return rcast( AST*, ast ); } inline CodeFn::operator Code() { return *rcast( Code*, this ); } inline AST_Fn* CodeFn::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeInclude::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeInclude::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeInclude::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeInclude::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeInclude::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeInclude& CodeInclude::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeInclude::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeInclude::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeInclude::operator bool() { return ast != nullptr; } inline AST* CodeInclude::raw() { return rcast( AST*, ast ); } inline CodeInclude::operator Code() { return *rcast( Code*, this ); } inline AST_Include* CodeInclude::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeModule::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeModule::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeModule::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeModule::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeModule::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeModule& CodeModule::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeModule::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeModule::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeModule::operator bool() { return ast != nullptr; } inline AST* CodeModule::raw() { return rcast( AST*, ast ); } inline CodeModule::operator Code() { return *rcast( Code*, this ); } inline AST_Module* CodeModule::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeNS::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeNS::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeNS::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeNS::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeNS::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeNS& CodeNS::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeNS::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeNS::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeNS::operator bool() { return ast != nullptr; } inline AST* CodeNS::raw() { return rcast( AST*, ast ); } inline CodeNS::operator Code() { return *rcast( Code*, this ); } inline AST_NS* CodeNS::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeOperator::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeOperator::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeOperator::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeOperator::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeOperator::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeOperator& CodeOperator::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeOperator::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeOperator::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeOperator::operator bool() { return ast != nullptr; } inline AST* CodeOperator::raw() { return rcast( AST*, ast ); } inline CodeOperator::operator Code() { return *rcast( Code*, this ); } inline AST_Operator* CodeOperator::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeOpCast::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeOpCast::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeOpCast::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeOpCast::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeOpCast::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeOpCast& CodeOpCast::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeOpCast::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeOpCast::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeOpCast::operator bool() { return ast != nullptr; } inline AST* CodeOpCast::raw() { return rcast( AST*, ast ); } inline CodeOpCast::operator Code() { return *rcast( Code*, this ); } inline AST_OpCast* CodeOpCast::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeParam::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeParam::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeParam::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeParam::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeParam::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeParam& CodeParam::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeParam::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeParam::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeParam::operator bool() { return ast != nullptr; } inline char const* CodePragma::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodePragma::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodePragma::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodePragma::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodePragma::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodePragma& CodePragma::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodePragma::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodePragma::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodePragma::operator bool() { return ast != nullptr; } inline AST* CodePragma::raw() { return rcast( AST*, ast ); } inline CodePragma::operator Code() { return *rcast( Code*, this ); } inline AST_Pragma* CodePragma::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodePreprocessCond::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodePreprocessCond::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodePreprocessCond::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodePreprocessCond::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodePreprocessCond::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodePreprocessCond& CodePreprocessCond::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodePreprocessCond::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodePreprocessCond::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodePreprocessCond::operator bool() { return ast != nullptr; } inline AST* CodePreprocessCond::raw() { return rcast( AST*, ast ); } inline CodePreprocessCond::operator Code() { return *rcast( Code*, this ); } inline AST_PreprocessCond* CodePreprocessCond::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeSpecifiers::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeSpecifiers::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeSpecifiers::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeSpecifiers::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeSpecifiers::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeSpecifiers& CodeSpecifiers::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeSpecifiers::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeSpecifiers::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeSpecifiers::operator bool() { return ast != nullptr; } inline char const* CodeStruct::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeStruct::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeStruct::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeStruct::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeStruct::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeStruct& CodeStruct::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeStruct::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeStruct::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeStruct::operator bool() { return ast != nullptr; } inline char const* CodeTemplate::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeTemplate::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeTemplate::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeTemplate::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeTemplate::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeTemplate& CodeTemplate::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeTemplate::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeTemplate::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeTemplate::operator bool() { return ast != nullptr; } inline AST* CodeTemplate::raw() { return rcast( AST*, ast ); } inline CodeTemplate::operator Code() { return *rcast( Code*, this ); } inline AST_Template* CodeTemplate::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeType::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeType::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeType::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeType::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeType::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeType& CodeType::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeType::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeType::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeType::operator bool() { return ast != nullptr; } inline AST* CodeType::raw() { return rcast( AST*, ast ); } inline CodeType::operator Code() { return *rcast( Code*, this ); } inline AST_Type* CodeType::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeTypedef::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeTypedef::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeTypedef::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeTypedef::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeTypedef::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeTypedef& CodeTypedef::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeTypedef::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeTypedef::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeTypedef::operator bool() { return ast != nullptr; } inline AST* CodeTypedef::raw() { return rcast( AST*, ast ); } inline CodeTypedef::operator Code() { return *rcast( Code*, this ); } inline AST_Typedef* CodeTypedef::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeUnion::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeUnion::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeUnion::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeUnion::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeUnion::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeUnion& CodeUnion::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeUnion::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeUnion::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeUnion::operator bool() { return ast != nullptr; } inline AST* CodeUnion::raw() { return rcast( AST*, ast ); } inline CodeUnion::operator Code() { return *rcast( Code*, this ); } inline AST_Union* CodeUnion::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeUsing::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeUsing::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeUsing::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeUsing::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeUsing::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeUsing& CodeUsing::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeUsing::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeUsing::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeUsing::operator bool() { return ast != nullptr; } inline AST* CodeUsing::raw() { return rcast( AST*, ast ); } inline CodeUsing::operator Code() { return *rcast( Code*, this ); } inline AST_Using* CodeUsing::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } inline char const* CodeVar::debug_str() { if ( ast == nullptr ) return "Code::debug_str: AST is null!"; return rcast( AST*, ast )->debug_str(); } inline Code CodeVar::duplicate() { if ( ast == nullptr ) { log_failure( "Code::duplicate: Cannot duplicate code, AST is null!" ); return Code::Invalid; } return { rcast( AST*, ast )->duplicate() }; } inline bool CodeVar::is_equal( Code other ) { if ( ast == nullptr || other.ast == nullptr ) { return ast == nullptr && other.ast == nullptr; } return rcast( AST*, ast )->is_equal( other.ast ); } inline bool CodeVar::is_valid() { return (AST*)ast != nullptr && rcast( AST*, ast )->Type != CodeT::Invalid; } inline void CodeVar::set_global() { if ( ast == nullptr ) { log_failure( "Code::set_global: Cannot set code as global, AST is null!" ); return; } rcast( AST*, ast )->Parent = Code::Global.ast; } inline CodeVar& CodeVar::operator=( Code other ) { if ( other.ast && other->Parent ) { ast = rcast( decltype( ast ), other.ast->duplicate() ); rcast( AST*, ast )->Parent = nullptr; } ast = rcast( decltype( ast ), other.ast ); return *this; } inline bool CodeVar::operator==( Code other ) { return (AST*)ast == other.ast; } inline bool CodeVar::operator!=( Code other ) { return (AST*)ast != other.ast; } inline CodeVar::operator bool() { return ast != nullptr; } inline AST* CodeVar::raw() { return rcast( AST*, ast ); } inline CodeVar::operator Code() { return *rcast( Code*, this ); } inline AST_Var* CodeVar::operator->() { if ( ast == nullptr ) { log_failure( "Attempt to dereference a nullptr!" ); return nullptr; } return ast; } #pragma endregion generated code inline implementation #pragma region generated AST/Code cast implementation inline AST::operator CodeBody() { return { rcast( AST_Body*, this ) }; } inline Code::operator CodeBody() const { return { (AST_Body*)ast }; } inline AST::operator CodeAttributes() { return { rcast( AST_Attributes*, this ) }; } inline Code::operator CodeAttributes() const { return { (AST_Attributes*)ast }; } inline AST::operator CodeComment() { return { rcast( AST_Comment*, this ) }; } inline Code::operator CodeComment() const { return { (AST_Comment*)ast }; } inline AST::operator CodeConstructor() { return { rcast( AST_Constructor*, this ) }; } inline Code::operator CodeConstructor() const { return { (AST_Constructor*)ast }; } inline AST::operator CodeClass() { return { rcast( AST_Class*, this ) }; } inline Code::operator CodeClass() const { return { (AST_Class*)ast }; } inline AST::operator CodeDefine() { return { rcast( AST_Define*, this ) }; } inline Code::operator CodeDefine() const { return { (AST_Define*)ast }; } inline AST::operator CodeDestructor() { return { rcast( AST_Destructor*, this ) }; } inline Code::operator CodeDestructor() const { return { (AST_Destructor*)ast }; } inline AST::operator CodeEnum() { return { rcast( AST_Enum*, this ) }; } inline Code::operator CodeEnum() const { return { (AST_Enum*)ast }; } inline AST::operator CodeExec() { return { rcast( AST_Exec*, this ) }; } inline Code::operator CodeExec() const { return { (AST_Exec*)ast }; } inline AST::operator CodeExtern() { return { rcast( AST_Extern*, this ) }; } inline Code::operator CodeExtern() const { return { (AST_Extern*)ast }; } inline AST::operator CodeFriend() { return { rcast( AST_Friend*, this ) }; } inline Code::operator CodeFriend() const { return { (AST_Friend*)ast }; } inline AST::operator CodeFn() { return { rcast( AST_Fn*, this ) }; } inline Code::operator CodeFn() const { return { (AST_Fn*)ast }; } inline AST::operator CodeInclude() { return { rcast( AST_Include*, this ) }; } inline Code::operator CodeInclude() const { return { (AST_Include*)ast }; } inline AST::operator CodeModule() { return { rcast( AST_Module*, this ) }; } inline Code::operator CodeModule() const { return { (AST_Module*)ast }; } inline AST::operator CodeNS() { return { rcast( AST_NS*, this ) }; } inline Code::operator CodeNS() const { return { (AST_NS*)ast }; } inline AST::operator CodeOperator() { return { rcast( AST_Operator*, this ) }; } inline Code::operator CodeOperator() const { return { (AST_Operator*)ast }; } inline AST::operator CodeOpCast() { return { rcast( AST_OpCast*, this ) }; } inline Code::operator CodeOpCast() const { return { (AST_OpCast*)ast }; } inline AST::operator CodeParam() { return { rcast( AST_Param*, this ) }; } inline Code::operator CodeParam() const { return { (AST_Param*)ast }; } inline AST::operator CodePragma() { return { rcast( AST_Pragma*, this ) }; } inline Code::operator CodePragma() const { return { (AST_Pragma*)ast }; } inline AST::operator CodePreprocessCond() { return { rcast( AST_PreprocessCond*, this ) }; } inline Code::operator CodePreprocessCond() const { return { (AST_PreprocessCond*)ast }; } inline AST::operator CodeSpecifiers() { return { rcast( AST_Specifiers*, this ) }; } inline Code::operator CodeSpecifiers() const { return { (AST_Specifiers*)ast }; } inline AST::operator CodeStruct() { return { rcast( AST_Struct*, this ) }; } inline Code::operator CodeStruct() const { return { (AST_Struct*)ast }; } inline AST::operator CodeTemplate() { return { rcast( AST_Template*, this ) }; } inline Code::operator CodeTemplate() const { return { (AST_Template*)ast }; } inline AST::operator CodeType() { return { rcast( AST_Type*, this ) }; } inline Code::operator CodeType() const { return { (AST_Type*)ast }; } inline AST::operator CodeTypedef() { return { rcast( AST_Typedef*, this ) }; } inline Code::operator CodeTypedef() const { return { (AST_Typedef*)ast }; } inline AST::operator CodeUnion() { return { rcast( AST_Union*, this ) }; } inline Code::operator CodeUnion() const { return { (AST_Union*)ast }; } inline AST::operator CodeUsing() { return { rcast( AST_Using*, this ) }; } inline Code::operator CodeUsing() const { return { (AST_Using*)ast }; } inline AST::operator CodeVar() { return { rcast( AST_Var*, this ) }; } inline Code::operator CodeVar() const { return { (AST_Var*)ast }; } #pragma endregion generated AST / Code cast implementation #pragma endregion Inlines #pragma region Constants #ifndef GEN_GLOBAL_BUCKET_SIZE # define GEN_GLOBAL_BUCKET_SIZE megabytes(8) #endif #ifndef GEN_CODEPOOL_NUM_BLOCKS # define GEN_CODEPOOL_NUM_BLOCKS kilobytes(16) #endif #ifndef GEN_SIZE_PER_STRING_ARENA # define GEN_SIZE_PER_STRING_ARENA megabytes(1) #endif #ifndef GEN_MAX_COMMENT_LINE_LENGTH # define GEN_MAX_COMMENT_LINE_LENGTH 1024 #endif #ifndef GEN_MAX_NAME_LENGTH # define GEN_MAX_NAME_LENGTH 128 #endif #ifndef GEN_MAX_UNTYPED_STR_LENGTH # define GEN_MAX_UNTYPED_STR_LENGTH megabytes(1) #endif #ifndef GEN_TOKEN_FMT_TOKEN_MAP_MEM_SIZE # define GEN_TOKEN_FMT_TOKEN_MAP_MEM_SIZE kilobytes(4) #endif #ifndef GEN_LEX_ALLOCATOR_SIZE # define GEN_LEX_ALLOCATOR_SIZE megabytes(4) #endif #ifndef GEN_BUILDER_STR_BUFFER_RESERVE # define GEN_BUILDER_STR_BUFFER_RESERVE megabytes(2) #endif // These constexprs are used for allocation behavior of data structures // or string handling while constructing or serializing. // Change them to suit your needs. constexpr s32 InitSize_DataArrays = 16; // NOTE: This limits the maximum size of an allocation // If you are generating a string larger than this, increase the size of the bucket here. constexpr usize Global_BucketSize = GEN_GLOBAL_BUCKET_SIZE; constexpr s32 CodePool_NumBlocks = GEN_CODEPOOL_NUM_BLOCKS; constexpr s32 SizePer_StringArena = GEN_SIZE_PER_STRING_ARENA; constexpr s32 MaxCommentLineLength = GEN_MAX_COMMENT_LINE_LENGTH; constexpr s32 MaxNameLength = GEN_MAX_NAME_LENGTH; constexpr s32 MaxUntypedStrLength = GEN_MAX_UNTYPED_STR_LENGTH; constexpr s32 TokenFmt_TokenMap_MemSize = GEN_TOKEN_FMT_TOKEN_MAP_MEM_SIZE; constexpr s32 LexAllocator_Size = GEN_LEX_ALLOCATOR_SIZE; constexpr s32 Builder_StrBufferReserve = GEN_BUILDER_STR_BUFFER_RESERVE; extern Code access_public; extern Code access_protected; extern Code access_private; extern CodeAttributes attrib_api_export; extern CodeAttributes attrib_api_import; extern Code module_global_fragment; extern Code module_private_fragment; extern Code fmt_newline; extern CodePragma pragma_once; extern CodeParam param_varadic; extern CodePreprocessCond preprocess_else; extern CodePreprocessCond preprocess_endif; extern CodeSpecifiers spec_const; extern CodeSpecifiers spec_consteval; extern CodeSpecifiers spec_constexpr; extern CodeSpecifiers spec_constinit; extern CodeSpecifiers spec_extern_linkage; extern CodeSpecifiers spec_final; extern CodeSpecifiers spec_forceinline; extern CodeSpecifiers spec_global; extern CodeSpecifiers spec_inline; extern CodeSpecifiers spec_internal_linkage; extern CodeSpecifiers spec_local_persist; extern CodeSpecifiers spec_mutable; extern CodeSpecifiers spec_neverinline; extern CodeSpecifiers spec_noexcept; extern CodeSpecifiers spec_override; extern CodeSpecifiers spec_ptr; extern CodeSpecifiers spec_pure; extern CodeSpecifiers spec_ref; extern CodeSpecifiers spec_register; extern CodeSpecifiers spec_rvalue; extern CodeSpecifiers spec_static_member; extern CodeSpecifiers spec_thread_local; extern CodeSpecifiers spec_virtual; extern CodeSpecifiers spec_volatile; extern CodeType t_empty; // Used with varaidc parameters. (Exposing just in case its useful for another circumstance) extern CodeType t_auto; extern CodeType t_void; extern CodeType t_int; extern CodeType t_bool; extern CodeType t_char; extern CodeType t_wchar_t; extern CodeType t_class; extern CodeType t_typename; #ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS // Predefined typename codes. Are set to readonly and are setup during gen::init() extern CodeType t_b32; extern CodeType t_s8; extern CodeType t_s16; extern CodeType t_s32; extern CodeType t_s64; extern CodeType t_u8; extern CodeType t_u16; extern CodeType t_u32; extern CodeType t_u64; extern CodeType t_ssize; extern CodeType t_usize; extern CodeType t_f32; extern CodeType t_f64; #endif #pragma endregion Constants #pragma region Macros # define gen_main main # define __ NoCode // Convienence for defining any name used with the gen api. // Lets you provide the length and string literal to the functions without the need for the DSL. # define name( Id_ ) { sizeof(stringize( Id_ )) - 1, stringize(Id_) } // Same as name just used to indicate intention of literal for code instead of names. # define code( ... ) { sizeof(stringize(__VA_ARGS__)) - 1, stringize( __VA_ARGS__ ) } # define args( ... ) num_args( __VA_ARGS__ ), __VA_ARGS__ # define code_str( ... ) GEN_NS untyped_str( code( __VA_ARGS__ ) ) # define code_fmt( ... ) GEN_NS untyped_str( token_fmt( __VA_ARGS__ ) ) // Takes a format string (char const*) and a list of tokens (StrC) and returns a StrC of the formatted string. # define token_fmt( ... ) GEN_NS token_fmt_impl( (num_args( __VA_ARGS__ ) + 1) / 2, __VA_ARGS__ ) #pragma endregion Macros // Used by the lexer to persistently treat all these identifiers as preprocessor defines. // Populate with strings via gen::get_cached_string. // Functional defines must have format: id( ;at minimum to indicate that the define is only valid with arguments. extern Array< StringCached > PreprocessorDefines; #ifdef GEN_EXPOSE_BACKEND // Global allocator used for data with process lifetime. extern AllocatorInfo GlobalAllocator; extern Array< Arena > Global_AllocatorBuckets; extern Array< Pool > CodePools; extern Array< Arena > StringArenas; extern StringTable StringCache; extern Arena LexArena; extern AllocatorInfo Allocator_DataArrays; extern AllocatorInfo Allocator_CodePool; extern AllocatorInfo Allocator_Lexer; extern AllocatorInfo Allocator_StringArena; extern AllocatorInfo Allocator_StringTable; extern AllocatorInfo Allocator_TypeTable; #endif #pragma region Builder struct Builder { FileInfo File; String Buffer; static Builder open( char const* path ); void pad_lines( s32 num ); void print( Code ); void print_fmt( char const* fmt, ... ); void write(); }; #pragma endregion Builder GEN_NS_END #pragma region GENCPP IMPLEMENTATION GUARD #if defined(GEN_IMPLEMENTATION) && ! defined(GEN_IMPLEMENTED) # define GEN_IMPLEMENTED //! If its desired to roll your own dependencies, define GEN_ROLL_OWN_DEPENDENCIES before including this file. // Dependencies are derived from the c-zpl library: https://github.com/zpl-c/zpl #ifndef GEN_ROLL_OWN_DEPENDENCIES GEN_NS_BEGIN #pragma region Macros and Includes # include // NOTE: Ensure we use standard methods for these calls if we use GEN_PICO # if ! defined( GEN_PICO_CUSTOM_ROUTINES ) # if ! defined( GEN_MODULE_CORE ) # define _strlen strlen # define _printf_err( fmt, ... ) fprintf( stderr, fmt, __VA_ARGS__ ) # define _printf_err_va( fmt, va ) vfprintf( stderr, fmt, va ) # else # define _strlen str_len # define _printf_err( fmt, ... ) str_fmt_out_err( fmt, __VA_ARGS__ ) # define _printf_err_va( fmt, va ) str_fmt_out_err_va( fmt, va ) # endif # endif # # include # # if defined( GEN_SYSTEM_UNIX ) || defined( GEN_SYSTEM_MACOS ) # include # elif defined( GEN_SYSTEM_WINDOWS ) # if ! defined( GEN_NO_WINDOWS_H ) # ifndef WIN32_LEAN_AND_MEAN # ifndef NOMINMAX # define NOMINMAX # endif # # define WIN32_LEAN_AND_MEAN # define WIN32_MEAN_AND_LEAN # define VC_EXTRALEAN # endif # include # undef NOMINMAX # undef WIN32_LEAN_AND_MEAN # undef WIN32_MEAN_AND_LEAN # undef VC_EXTRALEAN # endif # endif #include #ifdef GEN_SYSTEM_MACOS # include #endif #ifdef GEN_SYSTEM_CYGWIN # include #endif #if defined( GEN_SYSTEM_WINDOWS ) && ! defined( GEN_COMPILER_GCC ) # include #endif #if defined( GEN_SYSTEM_LINUX ) # include #endif #ifdef GEN_BENCHMARK // Timing includes #if defined( GEN_SYSTEM_MACOS ) || GEN_SYSTEM_UNIX # include # include #endif #if defined( GEN_SYSTEM_MACOS ) # include # include # include #endif #if defined( GEN_SYSTEM_EMSCRIPTEN ) # include #endif #if defined( GEN_SYSTEM_WINDOWS ) # include #endif #endif #pragma endregion Macros and Includes #pragma region Debug void assert_handler( char const* condition, char const* file, s32 line, char const* msg, ... ) { _printf_err( "%s:(%d): Assert Failure: ", file, line ); if ( condition ) _printf_err( "`%s` \n", condition ); if ( msg ) { va_list va; va_start( va, msg ); _printf_err_va( msg, va ); va_end( va ); } _printf_err( "%s", "\n" ); } s32 assert_crash( char const* condition ) { GEN_PANIC( condition ); return 0; } #if defined( GEN_SYSTEM_WINDOWS ) void process_exit( u32 code ) { ExitProcess( code ); } #else # include void process_exit( u32 code ) { exit( code ); } #endif #pragma endregion Debug #pragma region String Ops internal ssize _scan_zpl_i64( const char* text, s32 base, s64* value ) { const char* text_begin = text; s64 result = 0; b32 negative = false; if ( *text == '-' ) { negative = true; text++; } if ( base == 16 && str_compare( text, "0x", 2 ) == 0 ) text += 2; for ( ;; ) { s64 v; if ( char_is_digit( *text ) ) v = *text - '0'; else if ( base == 16 && char_is_hex_digit( *text ) ) v = hex_digit_to_int( *text ); else break; result *= base; result += v; text++; } if ( value ) { if ( negative ) result = -result; *value = result; } return ( text - text_begin ); } // TODO : Are these good enough for characters? global const char _num_to_char_table[] = "0123456789" "ABCDEFGHIJKLMNOPQRSTUVWXYZ" "abcdefghijklmnopqrstuvwxyz" "@$"; s64 str_to_i64( const char* str, char** end_ptr, s32 base ) { ssize len; s64 value; if ( ! base ) { if ( ( str_len( str ) > 2 ) && ( str_compare( str, "0x", 2 ) == 0 ) ) base = 16; else base = 10; } len = _scan_zpl_i64( str, base, &value ); if ( end_ptr ) *end_ptr = ( char* )str + len; return value; } void i64_to_str( s64 value, char* string, s32 base ) { char* buf = string; b32 negative = false; u64 v; if ( value < 0 ) { negative = true; value = -value; } v = scast( u64, value); if ( v != 0 ) { while ( v > 0 ) { *buf++ = _num_to_char_table[ v % base ]; v /= base; } } else { *buf++ = '0'; } if ( negative ) *buf++ = '-'; *buf = '\0'; str_reverse( string ); } void u64_to_str( u64 value, char* string, s32 base ) { char* buf = string; if ( value ) { while ( value > 0 ) { *buf++ = _num_to_char_table[ value % base ]; value /= base; } } else { *buf++ = '0'; } *buf = '\0'; str_reverse( string ); } f64 str_to_f64( const char* str, char** end_ptr ) { f64 result, value, sign, scale; s32 frac; while ( char_is_space( *str ) ) { str++; } sign = 1.0; if ( *str == '-' ) { sign = -1.0; str++; } else if ( *str == '+' ) { str++; } for ( value = 0.0; char_is_digit( *str ); str++ ) { value = value * 10.0 + ( *str - '0' ); } if ( *str == '.' ) { f64 pow10 = 10.0; str++; while ( char_is_digit( *str ) ) { value += ( *str - '0' ) / pow10; pow10 *= 10.0; str++; } } frac = 0; scale = 1.0; if ( ( *str == 'e' ) || ( *str == 'E' ) ) { u32 exp; str++; if ( *str == '-' ) { frac = 1; str++; } else if ( *str == '+' ) { str++; } for ( exp = 0; char_is_digit( *str ); str++ ) { exp = exp * 10 + ( *str - '0' ); } if ( exp > 308 ) exp = 308; while ( exp >= 50 ) { scale *= 1e50; exp -= 50; } while ( exp >= 8 ) { scale *= 1e8; exp -= 8; } while ( exp > 0 ) { scale *= 10.0; exp -= 1; } } result = sign * ( frac ? ( value / scale ) : ( value * scale ) ); if ( end_ptr ) * end_ptr = rcast( char*, ccast(char*, str) ); return result; } #pragma endregion String Ops #pragma region Printing enum { GEN_FMT_MINUS = bit( 0 ), GEN_FMT_PLUS = bit( 1 ), GEN_FMT_ALT = bit( 2 ), GEN_FMT_SPACE = bit( 3 ), GEN_FMT_ZERO = bit( 4 ), GEN_FMT_CHAR = bit( 5 ), GEN_FMT_SHORT = bit( 6 ), GEN_FMT_INT = bit( 7 ), GEN_FMT_LONG = bit( 8 ), GEN_FMT_LLONG = bit( 9 ), GEN_FMT_SIZE = bit( 10 ), GEN_FMT_INTPTR = bit( 11 ), GEN_FMT_UNSIGNED = bit( 12 ), GEN_FMT_LOWER = bit( 13 ), GEN_FMT_UPPER = bit( 14 ), GEN_FMT_WIDTH = bit( 15 ), GEN_FMT_DONE = bit( 30 ), GEN_FMT_INTS = GEN_FMT_CHAR | GEN_FMT_SHORT | GEN_FMT_INT | GEN_FMT_LONG | GEN_FMT_LLONG | GEN_FMT_SIZE | GEN_FMT_INTPTR }; struct _format_info { s32 base; s32 flags; s32 width; s32 precision; }; internal ssize _print_string( char* text, ssize max_len, _format_info* info, char const* str ) { ssize res = 0, len = 0; ssize remaining = max_len; char* begin = text; if ( str == NULL && max_len >= 6 ) { res += str_copy_nulpad( text, "(null)", 6 ); return res; } if ( info && info->precision >= 0 ) // Made the design decision for this library that precision is the length of the string. len = info->precision; else len = str_len( str ); if ( info && ( info->width == 0 && info->flags & GEN_FMT_WIDTH ) ) { return res; } if ( info && ( info->width == 0 || info->flags & GEN_FMT_MINUS ) ) { if ( info->precision > 0 ) len = info->precision < len ? info->precision : len; if ( res + len > max_len ) return res; res += str_copy_nulpad( text, str, len ); text += res; if ( info->width > res ) { ssize padding = info->width - len; char pad = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' '; while ( padding-- > 0 && remaining-- > 0 ) *text++ = pad, res++; } } else { if ( info && ( info->width > res ) ) { ssize padding = info->width - len; char pad = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' '; while ( padding-- > 0 && remaining-- > 0 ) *text++ = pad, res++; } if ( res + len > max_len ) return res; res += str_copy_nulpad( text, str, len ); } if ( info ) { if ( info->flags & GEN_FMT_UPPER ) str_to_upper( begin ); else if ( info->flags & GEN_FMT_LOWER ) str_to_lower( begin ); } return res; } internal ssize _print_char( char* text, ssize max_len, _format_info* info, char arg ) { char str[ 2 ] = ""; str[ 0 ] = arg; return _print_string( text, max_len, info, str ); } internal ssize _print_repeated_char( char* text, ssize max_len, _format_info* info, char arg ) { ssize res = 0; s32 rem = ( info ) ? ( info->width > 0 ) ? info->width : 1 : 1; res = rem; while ( rem-- > 0 ) *text++ = arg; return res; } internal ssize _print_i64( char* text, ssize max_len, _format_info* info, s64 value ) { char num[ 130 ]; i64_to_str( value, num, info ? info->base : 10 ); return _print_string( text, max_len, info, num ); } internal ssize _print_u64( char* text, ssize max_len, _format_info* info, u64 value ) { char num[ 130 ]; u64_to_str( value, num, info ? info->base : 10 ); return _print_string( text, max_len, info, num ); } internal ssize _print_f64( char* text, ssize max_len, _format_info* info, b32 is_hexadecimal, f64 arg ) { // TODO: Handle exponent notation ssize width, len, remaining = max_len; char* text_begin = text; if ( arg ) { u64 value; if ( arg < 0 ) { if ( remaining > 1 ) *text = '-', remaining--; text++; arg = -arg; } else if ( info->flags & GEN_FMT_MINUS ) { if ( remaining > 1 ) *text = '+', remaining--; text++; } value = scast( u64, arg); len = _print_u64( text, remaining, NULL, value ); text += len; if ( len >= remaining ) remaining = min( remaining, 1 ); else remaining -= len; arg -= value; if ( info->precision < 0 ) info->precision = 6; if ( ( info->flags & GEN_FMT_ALT ) || info->precision > 0 ) { s64 mult = 10; if ( remaining > 1 ) *text = '.', remaining--; text++; while ( info->precision-- > 0 ) { value = scast( u64, arg * mult ); len = _print_u64( text, remaining, NULL, value ); text += len; if ( len >= remaining ) remaining = min( remaining, 1 ); else remaining -= len; arg -= scast( f64, value / mult); mult *= 10; } } } else { if ( remaining > 1 ) *text = '0', remaining--; text++; if ( info->flags & GEN_FMT_ALT ) { if ( remaining > 1 ) *text = '.', remaining--; text++; } } width = info->width - ( text - text_begin ); if ( width > 0 ) { char fill = ( info->flags & GEN_FMT_ZERO ) ? '0' : ' '; char* end = text + remaining - 1; len = ( text - text_begin ); for ( len = ( text - text_begin ); len--; ) { if ( ( text_begin + len + width ) < end ) *( text_begin + len + width ) = *( text_begin + len ); } len = width; text += len; if ( len >= remaining ) remaining = min( remaining, 1 ); else remaining -= len; while ( len-- ) { if ( text_begin + len < end ) text_begin[ len ] = fill; } } return ( text - text_begin ); } neverinline ssize str_fmt_va( char* text, ssize max_len, char const* fmt, va_list va ) { char const* text_begin = text; ssize remaining = max_len, res; while ( *fmt ) { _format_info info = { 0 }; ssize len = 0; info.precision = -1; while ( *fmt && *fmt != '%' && remaining ) *text++ = *fmt++; if ( *fmt == '%' ) { do { switch ( *++fmt ) { case '-' : { info.flags |= GEN_FMT_MINUS; break; } case '+' : { info.flags |= GEN_FMT_PLUS; break; } case '#' : { info.flags |= GEN_FMT_ALT; break; } case ' ' : { info.flags |= GEN_FMT_SPACE; break; } case '0' : { info.flags |= ( GEN_FMT_ZERO | GEN_FMT_WIDTH ); break; } default : { info.flags |= GEN_FMT_DONE; break; } } } while ( ! ( info.flags & GEN_FMT_DONE ) ); } // NOTE: Optional Width if ( *fmt == '*' ) { int width = va_arg( va, int ); if ( width < 0 ) { info.flags |= GEN_FMT_MINUS; info.width = -width; } else { info.width = width; } info.flags |= GEN_FMT_WIDTH; fmt++; } else { info.width = scast( s32, str_to_i64( fmt, ccast( char**, & fmt), 10 )); if ( info.width != 0 ) { info.flags |= GEN_FMT_WIDTH; } } // NOTE: Optional Precision if ( *fmt == '.' ) { fmt++; if ( *fmt == '*' ) { info.precision = va_arg( va, int ); fmt++; } else { info.precision = scast( s32, str_to_i64( fmt, ccast( char**, & fmt), 10 )); } info.flags &= ~GEN_FMT_ZERO; } switch ( *fmt++ ) { case 'h' : if ( *fmt == 'h' ) { // hh => char info.flags |= GEN_FMT_CHAR; fmt++; } else { // h => short info.flags |= GEN_FMT_SHORT; } break; case 'l' : if ( *fmt == 'l' ) { // ll => long long info.flags |= GEN_FMT_LLONG; fmt++; } else { // l => long info.flags |= GEN_FMT_LONG; } break; break; case 'z' : // NOTE: zpl_usize info.flags |= GEN_FMT_UNSIGNED; // fallthrough case 't' : // NOTE: zpl_isize info.flags |= GEN_FMT_SIZE; break; default : fmt--; break; } switch ( *fmt ) { case 'u' : info.flags |= GEN_FMT_UNSIGNED; // fallthrough case 'd' : case 'i' : info.base = 10; break; case 'o' : info.base = 8; break; case 'x' : info.base = 16; info.flags |= ( GEN_FMT_UNSIGNED | GEN_FMT_LOWER ); break; case 'X' : info.base = 16; info.flags |= ( GEN_FMT_UNSIGNED | GEN_FMT_UPPER ); break; case 'f' : case 'F' : case 'g' : case 'G' : len = _print_f64( text, remaining, &info, 0, va_arg( va, f64 ) ); break; case 'a' : case 'A' : len = _print_f64( text, remaining, &info, 1, va_arg( va, f64 ) ); break; case 'c' : len = _print_char( text, remaining, &info, scast( char, va_arg( va, int ) )); break; case 's' : len = _print_string( text, remaining, &info, va_arg( va, char* ) ); break; case 'S': { String gen_str = String { va_arg( va, char*) }; info.precision = gen_str.length(); len = _print_string( text, remaining, &info, gen_str ); } break; case 'r' : len = _print_repeated_char( text, remaining, &info, va_arg( va, int ) ); break; case 'p' : info.base = 16; info.flags |= ( GEN_FMT_LOWER | GEN_FMT_UNSIGNED | GEN_FMT_ALT | GEN_FMT_INTPTR ); break; case '%' : len = _print_char( text, remaining, &info, '%' ); break; default : fmt--; break; } fmt++; if ( info.base != 0 ) { if ( info.flags & GEN_FMT_UNSIGNED ) { u64 value = 0; switch ( info.flags & GEN_FMT_INTS ) { case GEN_FMT_CHAR : value = scast( u64, scast( u8, va_arg( va, int ))); break; case GEN_FMT_SHORT : value = scast( u64, scast( u16, va_arg( va, int ))); break; case GEN_FMT_LONG: value = scast( u64, va_arg( va, unsigned long )); break; case GEN_FMT_LLONG : value = scast( u64, va_arg( va, unsigned long long )); break; case GEN_FMT_SIZE : value = scast( u64, va_arg( va, usize )); break; case GEN_FMT_INTPTR : value = scast( u64, va_arg( va, uptr )); break; default : value = scast( u64, va_arg( va, unsigned int )); break; } len = _print_u64( text, remaining, &info, value ); } else { s64 value = 0; switch ( info.flags & GEN_FMT_INTS ) { case GEN_FMT_CHAR : value = scast( s64, scast( s8, va_arg( va, int ))); break; case GEN_FMT_SHORT : value = scast( s64, scast( s16, va_arg( va, int ))); break; case GEN_FMT_LONG : value = scast( s64, va_arg( va, long )); break; case GEN_FMT_LLONG : value = scast( s64, va_arg( va, long long )); break; case GEN_FMT_SIZE : value = scast( s64, va_arg( va, usize )); break; case GEN_FMT_INTPTR : value = scast( s64, va_arg( va, uptr )); break; default : value = scast( s64, va_arg( va, int )); break; } len = _print_i64( text, remaining, &info, value ); } } text += len; if ( len >= remaining ) remaining = min( remaining, 1 ); else remaining -= len; } *text++ = '\0'; res = ( text - text_begin ); return ( res >= max_len || res < 0 ) ? -1 : res; } char* str_fmt_buf_va( char const* fmt, va_list va ) { local_persist thread_local char buffer[ GEN_PRINTF_MAXLEN ]; str_fmt_va( buffer, size_of( buffer ), fmt, va ); return buffer; } char* str_fmt_buf( char const* fmt, ... ) { va_list va; char* str; va_start( va, fmt ); str = str_fmt_buf_va( fmt, va ); va_end( va ); return str; } ssize str_fmt_file_va( struct FileInfo* f, char const* fmt, va_list va ) { local_persist thread_local char buf[ GEN_PRINTF_MAXLEN ]; ssize len = str_fmt_va( buf, size_of( buf ), fmt, va ); b32 res = file_write( f, buf, len - 1 ); // NOTE: prevent extra whitespace return res ? len : -1; } ssize str_fmt_file( struct FileInfo* f, char const* fmt, ... ) { ssize res; va_list va; va_start( va, fmt ); res = str_fmt_file_va( f, fmt, va ); va_end( va ); return res; } ssize str_fmt( char* str, ssize n, char const* fmt, ... ) { ssize res; va_list va; va_start( va, fmt ); res = str_fmt_va( str, n, fmt, va ); va_end( va ); return res; } ssize str_fmt_out_va( char const* fmt, va_list va ) { return str_fmt_file_va( file_get_standard( EFileStandard_OUTPUT ), fmt, va ); } ssize str_fmt_out_err_va( char const* fmt, va_list va ) { return str_fmt_file_va( file_get_standard( EFileStandard_ERROR ), fmt, va ); } ssize str_fmt_out_err( char const* fmt, ... ) { ssize res; va_list va; va_start( va, fmt ); res = str_fmt_out_err_va( fmt, va ); va_end( va ); return res; } #pragma endregion Printing #pragma region Memory void* mem_copy( void* dest, void const* source, ssize n ) { if ( dest == NULL ) { return NULL; } return memcpy( dest, source, n ); } void const* mem_find( void const* data, u8 c, ssize n ) { u8 const* s = rcast( u8 const*, data); while ( ( rcast( uptr, s) & ( sizeof( usize ) - 1 ) ) && n && *s != c ) { s++; n--; } if ( n && *s != c ) { ssize const* w; ssize k = GEN__ONES * c; w = rcast( ssize const*, s); while ( n >= size_of( ssize ) && ! GEN__HAS_ZERO( *w ^ k ) ) { w++; n -= size_of( ssize ); } s = rcast( u8 const*, w); while ( n && *s != c ) { s++; n--; } } return n ? rcast( void const*, s ) : NULL; } #define GEN_HEAP_STATS_MAGIC 0xDEADC0DE struct _heap_stats { u32 magic; ssize used_memory; ssize alloc_count; }; global _heap_stats _heap_stats_info; void heap_stats_init( void ) { zero_item( &_heap_stats_info ); _heap_stats_info.magic = GEN_HEAP_STATS_MAGIC; } ssize heap_stats_used_memory( void ) { GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" ); return _heap_stats_info.used_memory; } ssize heap_stats_alloc_count( void ) { GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" ); return _heap_stats_info.alloc_count; } void heap_stats_check( void ) { GEN_ASSERT_MSG( _heap_stats_info.magic == GEN_HEAP_STATS_MAGIC, "heap_stats is not initialised yet, call heap_stats_init first!" ); GEN_ASSERT( _heap_stats_info.used_memory == 0 ); GEN_ASSERT( _heap_stats_info.alloc_count == 0 ); } struct _heap_alloc_info { ssize size; void* physical_start; }; void* heap_allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ) { void* ptr = NULL; // unused( allocator_data ); // unused( old_size ); if ( ! alignment ) alignment = GEN_DEFAULT_MEMORY_ALIGNMENT; #ifdef GEN_HEAP_ANALYSIS ssize alloc_info_size = size_of( _heap_alloc_info ); ssize alloc_info_remainder = ( alloc_info_size % alignment ); ssize track_size = max( alloc_info_size, alignment ) + alloc_info_remainder; switch ( type ) { case EAllocation_FREE : { if ( ! old_memory ) break; _heap_alloc_info* alloc_info = rcast( _heap_alloc_info*, old_memory) - 1; _heap_stats_info.used_memory -= alloc_info->size; _heap_stats_info.alloc_count--; old_memory = alloc_info->physical_start; } break; case EAllocation_ALLOC : { size += track_size; } break; default : break; } #endif switch ( type ) { #if defined( GEN_COMPILER_MSVC ) || ( defined( GEN_COMPILER_GCC ) && defined( GEN_SYSTEM_WINDOWS ) ) || ( defined( GEN_COMPILER_TINYC ) && defined( GEN_SYSTEM_WINDOWS ) ) case EAllocation_ALLOC : ptr = _aligned_malloc( size, alignment ); if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO ) zero_size( ptr, size ); break; case EAllocation_FREE : _aligned_free( old_memory ); break; case EAllocation_RESIZE : { AllocatorInfo a = heap(); ptr = default_resize_align( a, old_memory, old_size, size, alignment ); } break; #elif defined( GEN_SYSTEM_LINUX ) && ! defined( GEN_CPU_ARM ) && ! defined( GEN_COMPILER_TINYC ) case EAllocation_ALLOC : { ptr = aligned_alloc( alignment, ( size + alignment - 1 ) & ~( alignment - 1 ) ); if ( flags & GEN_ALLOCATOR_FLAG_CLEAR_TO_ZERO ) { zero_size( ptr, size ); } } break; case EAllocation_FREE : { free( old_memory ); } break; case EAllocation_RESIZE : { AllocatorInfo a = heap(); ptr = default_resize_align( a, old_memory, old_size, size, alignment ); } break; #else case EAllocation_ALLOC : { posix_memalign( &ptr, alignment, size ); if ( flags & GEN_ALLOCATOR_FLAG_CLEAR_TO_ZERO ) { zero_size( ptr, size ); } } break; case EAllocation_FREE : { free( old_memory ); } break; case EAllocation_RESIZE : { AllocatorInfo a = heap(); ptr = default_resize_align( a, old_memory, old_size, size, alignment ); } break; #endif case EAllocation_FREE_ALL : break; } #ifdef GEN_HEAP_ANALYSIS if ( type == EAllocation_ALLOC ) { _heap_alloc_info* alloc_info = rcast( _heap_alloc_info*, rcast( char*, ptr) + alloc_info_remainder ); zero_item( alloc_info ); alloc_info->size = size - track_size; alloc_info->physical_start = ptr; ptr = rcast( void*, alloc_info + 1 ); _heap_stats_info.used_memory += alloc_info->size; _heap_stats_info.alloc_count++; } #endif return ptr; } #pragma region VirtualMemory VirtualMemory vm_from_memory( void* data, ssize size ) { VirtualMemory vm; vm.data = data; vm.size = size; return vm; } #if defined( GEN_SYSTEM_WINDOWS ) VirtualMemory vm_alloc( void* addr, ssize size ) { VirtualMemory vm; GEN_ASSERT( size > 0 ); vm.data = VirtualAlloc( addr, size, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE ); vm.size = size; return vm; } b32 vm_free( VirtualMemory vm ) { MEMORY_BASIC_INFORMATION info; while ( vm.size > 0 ) { if ( VirtualQuery( vm.data, &info, size_of( info ) ) == 0 ) return false; if ( info.BaseAddress != vm.data || info.AllocationBase != vm.data || info.State != MEM_COMMIT || info.RegionSize > scast( usize, vm.size) ) { return false; } if ( VirtualFree( vm.data, 0, MEM_RELEASE ) == 0 ) return false; vm.data = pointer_add( vm.data, info.RegionSize ); vm.size -= info.RegionSize; } return true; } VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size ) { VirtualMemory new_vm = { 0 }; void* ptr; GEN_ASSERT( vm.size >= lead_size + size ); ptr = pointer_add( vm.data, lead_size ); vm_free( vm ); new_vm = vm_alloc( ptr, size ); if ( new_vm.data == ptr ) return new_vm; if ( new_vm.data ) vm_free( new_vm ); return new_vm; } b32 vm_purge( VirtualMemory vm ) { VirtualAlloc( vm.data, vm.size, MEM_RESET, PAGE_READWRITE ); // NOTE: Can this really fail? return true; } ssize virtual_memory_page_size( ssize* alignment_out ) { SYSTEM_INFO info; GetSystemInfo( &info ); if ( alignment_out ) *alignment_out = info.dwAllocationGranularity; return info.dwPageSize; } #else # include # ifndef MAP_ANONYMOUS # define MAP_ANONYMOUS MAP_ANON # endif VirtualMemory vm_alloc( void* addr, ssize size ) { VirtualMemory vm; GEN_ASSERT( size > 0 ); vm.data = mmap( addr, size, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_PRIVATE, -1, 0 ); vm.size = size; return vm; } b32 vm_free( VirtualMemory vm ) { munmap( vm.data, vm.size ); return true; } VirtualMemory vm_trim( VirtualMemory vm, ssize lead_size, ssize size ) { void* ptr; ssize trail_size; GEN_ASSERT( vm.size >= lead_size + size ); ptr = pointer_add( vm.data, lead_size ); trail_size = vm.size - lead_size - size; if ( lead_size != 0 ) vm_free( vm_from_memory(( vm.data, lead_size ) ); if ( trail_size != 0 ) vm_free( vm_from_memory( ptr, trail_size ) ); return vm_from_memory( ptr, size ); } b32 vm_purge( VirtualMemory vm ) { int err = madvise( vm.data, vm.size, MADV_DONTNEED ); return err != 0; } ssize virtual_memory_page_size( ssize* alignment_out ) { // TODO: Is this always true? ssize result = scast( ssize, sysconf( _SC_PAGE_SIZE )); if ( alignment_out ) *alignment_out = result; return result; } #endif #pragma endregion VirtualMemory void* Arena::allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ) { Arena* arena = rcast(Arena*, allocator_data); void* ptr = NULL; // unused( old_size ); switch ( type ) { case EAllocation_ALLOC : { void* end = pointer_add( arena->PhysicalStart, arena->TotalUsed ); ssize total_size = align_forward_i64( size, alignment ); // NOTE: Out of memory if ( arena->TotalUsed + total_size > (ssize) arena->TotalSize ) { // zpl__printf_err("%s", "Arena out of memory\n"); GEN_FATAL("Arena out of memory! (Possibly could not fit for the largest size Arena!!)"); return nullptr; } ptr = align_forward( end, alignment ); arena->TotalUsed += total_size; if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO ) zero_size( ptr, size ); } break; case EAllocation_FREE : // NOTE: Free all at once // Use Temp_Arena_Memory if you want to free a block break; case EAllocation_FREE_ALL : arena->TotalUsed = 0; break; case EAllocation_RESIZE : { // TODO : Check if ptr is on top of stack and just extend AllocatorInfo a = arena->Backing; ptr = default_resize_align( a, old_memory, old_size, size, alignment ); } break; } return ptr; } void* Pool::allocator_proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ) { Pool* pool = rcast( Pool*, allocator_data); void* ptr = NULL; // unused( old_size ); switch ( type ) { case EAllocation_ALLOC : { uptr next_free; GEN_ASSERT( size == pool->BlockSize ); GEN_ASSERT( alignment == pool->BlockAlign ); GEN_ASSERT( pool->FreeList != NULL ); next_free = * rcast( uptr*, pool->FreeList); ptr = pool->FreeList; pool->FreeList = rcast( void*, next_free); pool->TotalSize += pool->BlockSize; if ( flags & ALLOCATOR_FLAG_CLEAR_TO_ZERO ) zero_size( ptr, size ); } break; case EAllocation_FREE : { uptr* next; if ( old_memory == NULL ) return NULL; next = rcast( uptr*, old_memory); *next = rcast( uptr, pool->FreeList); pool->FreeList = old_memory; pool->TotalSize -= pool->BlockSize; } break; case EAllocation_FREE_ALL : { ssize actual_block_size, block_index; void* curr; uptr* end; actual_block_size = pool->BlockSize + pool->BlockAlign; pool->TotalSize = 0; // NOTE: Init intrusive freelist curr = pool->PhysicalStart; for ( block_index = 0; block_index < pool->NumBlocks - 1; block_index++ ) { uptr* next = rcast( uptr*, curr); * next = rcast( uptr, curr) + actual_block_size; curr = pointer_add( curr, actual_block_size ); } end = rcast( uptr*, curr); * end = scast( uptr, NULL); pool->FreeList = pool->PhysicalStart; } break; case EAllocation_RESIZE : // NOTE: Cannot resize GEN_PANIC( "You cannot resize something allocated by with a pool." ); break; } return ptr; } Pool Pool::init_align( AllocatorInfo backing, ssize num_blocks, ssize block_size, ssize block_align ) { Pool pool = {}; ssize actual_block_size, pool_size, block_index; void *data, *curr; uptr* end; zero_item( &pool ); pool.Backing = backing; pool.BlockSize = block_size; pool.BlockAlign = block_align; pool.NumBlocks = num_blocks; actual_block_size = block_size + block_align; pool_size = num_blocks * actual_block_size; data = alloc_align( backing, pool_size, block_align ); // NOTE: Init intrusive freelist curr = data; for ( block_index = 0; block_index < num_blocks - 1; block_index++ ) { uptr* next = ( uptr* ) curr; *next = ( uptr ) curr + actual_block_size; curr = pointer_add( curr, actual_block_size ); } end = ( uptr* ) curr; *end = ( uptr ) NULL; pool.PhysicalStart = data; pool.FreeList = data; return pool; } void Pool::clear() { ssize actual_block_size, block_index; void* curr; uptr* end; actual_block_size = BlockSize + BlockAlign; curr = PhysicalStart; for ( block_index = 0; block_index < NumBlocks - 1; block_index++ ) { uptr* next = ( uptr* ) curr; *next = ( uptr ) curr + actual_block_size; curr = pointer_add( curr, actual_block_size ); } end = ( uptr* ) curr; *end = ( uptr ) NULL; FreeList = PhysicalStart; } #pragma endregion Memory #pragma region Hashing global u32 const _crc32_table[ 256 ] = { 0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, 0x076dc419, 0x706af48f, 0xe963a535, 0x9e6495a3, 0x0edb8832, 0x79dcb8a4, 0xe0d5e91e, 0x97d2d988, 0x09b64c2b, 0x7eb17cbd, 0xe7b82d07, 0x90bf1d91, 0x1db71064, 0x6ab020f2, 0xf3b97148, 0x84be41de, 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7, 0x136c9856, 0x646ba8c0, 0xfd62f97a, 0x8a65c9ec, 0x14015c4f, 0x63066cd9, 0xfa0f3d63, 0x8d080df5, 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172, 0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, 0x35b5a8fa, 0x42b2986c, 0xdbbbc9d6, 0xacbcf940, 0x32d86ce3, 0x45df5c75, 0xdcd60dcf, 0xabd13d59, 0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, 0x21b4f4b5, 0x56b3c423, 0xcfba9599, 0xb8bda50f, 0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924, 0x2f6f7c87, 0x58684c11, 0xc1611dab, 0xb6662d3d, 0x76dc4190, 0x01db7106, 0x98d220bc, 0xefd5102a, 0x71b18589, 0x06b6b51f, 0x9fbfe4a5, 0xe8b8d433, 0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, 0x7f6a0dbb, 0x086d3d2d, 0x91646c97, 0xe6635c01, 0x6b6b51f4, 0x1c6c6162, 0x856530d8, 0xf262004e, 0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, 0x65b0d9c6, 0x12b7e950, 0x8bbeb8ea, 0xfcb9887c, 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65, 0x4db26158, 0x3ab551ce, 0xa3bc0074, 0xd4bb30e2, 0x4adfa541, 0x3dd895d7, 0xa4d1c46d, 0xd3d6f4fb, 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0, 0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9, 0x5005713c, 0x270241aa, 0xbe0b1010, 0xc90c2086, 0x5768b525, 0x206f85b3, 0xb966d409, 0xce61e49f, 0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, 0x59b33d17, 0x2eb40d81, 0xb7bd5c3b, 0xc0ba6cad, 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a, 0xead54739, 0x9dd277af, 0x04db2615, 0x73dc1683, 0xe3630b12, 0x94643b84, 0x0d6d6a3e, 0x7a6a5aa8, 0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1, 0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, 0xf762575d, 0x806567cb, 0x196c3671, 0x6e6b06e7, 0xfed41b76, 0x89d32be0, 0x10da7a5a, 0x67dd4acc, 0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, 0xd6d6a3e8, 0xa1d1937e, 0x38d8c2c4, 0x4fdff252, 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b, 0xd80d2bda, 0xaf0a1b4c, 0x36034af6, 0x41047a60, 0xdf60efc3, 0xa867df55, 0x316e8eef, 0x4669be79, 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236, 0xcc0c7795, 0xbb0b4703, 0x220216b9, 0x5505262f, 0xc5ba3bbe, 0xb2bd0b28, 0x2bb45a92, 0x5cb36a04, 0xc2d7ffa7, 0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d, 0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a, 0x9c0906a9, 0xeb0e363f, 0x72076785, 0x05005713, 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38, 0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7, 0x0bdbdf21, 0x86d3d2d4, 0xf1d4e242, 0x68ddb3f8, 0x1fda836e, 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777, 0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, 0x8f659eff, 0xf862ae69, 0x616bffd3, 0x166ccf45, 0xa00ae278, 0xd70dd2ee, 0x4e048354, 0x3903b3c2, 0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, 0xaed16a4a, 0xd9d65adc, 0x40df0b66, 0x37d83bf0, 0xa9bcae53, 0xdebb9ec5, 0x47b2cf7f, 0x30b5ffe9, 0xbdbdf21c, 0xcabac28a, 0x53b39330, 0x24b4a3a6, 0xbad03605, 0xcdd70693, 0x54de5729, 0x23d967bf, 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94, 0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d, }; u32 crc32( void const* data, ssize len ) { ssize remaining; u32 result = ~( scast( u32, 0) ); u8 const* c = rcast( u8 const*, data); for ( remaining = len; remaining--; c++ ) result = ( result >> 8 ) ^ ( _crc32_table[ ( result ^ *c ) & 0xff ] ); return ~result; } global u64 const _crc64_table[ 256 ] = { 0x0000000000000000ull, 0x7ad870c830358979ull, 0xf5b0e190606b12f2ull, 0x8f689158505e9b8bull, 0xc038e5739841b68full, 0xbae095bba8743ff6ull, 0x358804e3f82aa47dull, 0x4f50742bc81f2d04ull, 0xab28ecb46814fe75ull, 0xd1f09c7c5821770cull, 0x5e980d24087fec87ull, 0x24407dec384a65feull, 0x6b1009c7f05548faull, 0x11c8790fc060c183ull, 0x9ea0e857903e5a08ull, 0xe478989fa00bd371ull, 0x7d08ff3b88be6f81ull, 0x07d08ff3b88be6f8ull, 0x88b81eabe8d57d73ull, 0xf2606e63d8e0f40aull, 0xbd301a4810ffd90eull, 0xc7e86a8020ca5077ull, 0x4880fbd87094cbfcull, 0x32588b1040a14285ull, 0xd620138fe0aa91f4ull, 0xacf86347d09f188dull, 0x2390f21f80c18306ull, 0x594882d7b0f40a7full, 0x1618f6fc78eb277bull, 0x6cc0863448deae02ull, 0xe3a8176c18803589ull, 0x997067a428b5bcf0ull, 0xfa11fe77117cdf02ull, 0x80c98ebf2149567bull, 0x0fa11fe77117cdf0ull, 0x75796f2f41224489ull, 0x3a291b04893d698dull, 0x40f16bccb908e0f4ull, 0xcf99fa94e9567b7full, 0xb5418a5cd963f206ull, 0x513912c379682177ull, 0x2be1620b495da80eull, 0xa489f35319033385ull, 0xde51839b2936bafcull, 0x9101f7b0e12997f8ull, 0xebd98778d11c1e81ull, 0x64b116208142850aull, 0x1e6966e8b1770c73ull, 0x8719014c99c2b083ull, 0xfdc17184a9f739faull, 0x72a9e0dcf9a9a271ull, 0x08719014c99c2b08ull, 0x4721e43f0183060cull, 0x3df994f731b68f75ull, 0xb29105af61e814feull, 0xc849756751dd9d87ull, 0x2c31edf8f1d64ef6ull, 0x56e99d30c1e3c78full, 0xd9810c6891bd5c04ull, 0xa3597ca0a188d57dull, 0xec09088b6997f879ull, 0x96d1784359a27100ull, 0x19b9e91b09fcea8bull, 0x636199d339c963f2ull, 0xdf7adabd7a6e2d6full, 0xa5a2aa754a5ba416ull, 0x2aca3b2d1a053f9dull, 0x50124be52a30b6e4ull, 0x1f423fcee22f9be0ull, 0x659a4f06d21a1299ull, 0xeaf2de5e82448912ull, 0x902aae96b271006bull, 0x74523609127ad31aull, 0x0e8a46c1224f5a63ull, 0x81e2d7997211c1e8ull, 0xfb3aa75142244891ull, 0xb46ad37a8a3b6595ull, 0xceb2a3b2ba0eececull, 0x41da32eaea507767ull, 0x3b024222da65fe1eull, 0xa2722586f2d042eeull, 0xd8aa554ec2e5cb97ull, 0x57c2c41692bb501cull, 0x2d1ab4dea28ed965ull, 0x624ac0f56a91f461ull, 0x1892b03d5aa47d18ull, 0x97fa21650afae693ull, 0xed2251ad3acf6feaull, 0x095ac9329ac4bc9bull, 0x7382b9faaaf135e2ull, 0xfcea28a2faafae69ull, 0x8632586aca9a2710ull, 0xc9622c4102850a14ull, 0xb3ba5c8932b0836dull, 0x3cd2cdd162ee18e6ull, 0x460abd1952db919full, 0x256b24ca6b12f26dull, 0x5fb354025b277b14ull, 0xd0dbc55a0b79e09full, 0xaa03b5923b4c69e6ull, 0xe553c1b9f35344e2ull, 0x9f8bb171c366cd9bull, 0x10e3202993385610ull, 0x6a3b50e1a30ddf69ull, 0x8e43c87e03060c18ull, 0xf49bb8b633338561ull, 0x7bf329ee636d1eeaull, 0x012b592653589793ull, 0x4e7b2d0d9b47ba97ull, 0x34a35dc5ab7233eeull, 0xbbcbcc9dfb2ca865ull, 0xc113bc55cb19211cull, 0x5863dbf1e3ac9decull, 0x22bbab39d3991495ull, 0xadd33a6183c78f1eull, 0xd70b4aa9b3f20667ull, 0x985b3e827bed2b63ull, 0xe2834e4a4bd8a21aull, 0x6debdf121b863991ull, 0x1733afda2bb3b0e8ull, 0xf34b37458bb86399ull, 0x8993478dbb8deae0ull, 0x06fbd6d5ebd3716bull, 0x7c23a61ddbe6f812ull, 0x3373d23613f9d516ull, 0x49aba2fe23cc5c6full, 0xc6c333a67392c7e4ull, 0xbc1b436e43a74e9dull, 0x95ac9329ac4bc9b5ull, 0xef74e3e19c7e40ccull, 0x601c72b9cc20db47ull, 0x1ac40271fc15523eull, 0x5594765a340a7f3aull, 0x2f4c0692043ff643ull, 0xa02497ca54616dc8ull, 0xdafce7026454e4b1ull, 0x3e847f9dc45f37c0ull, 0x445c0f55f46abeb9ull, 0xcb349e0da4342532ull, 0xb1eceec59401ac4bull, 0xfebc9aee5c1e814full, 0x8464ea266c2b0836ull, 0x0b0c7b7e3c7593bdull, 0x71d40bb60c401ac4ull, 0xe8a46c1224f5a634ull, 0x927c1cda14c02f4dull, 0x1d148d82449eb4c6ull, 0x67ccfd4a74ab3dbfull, 0x289c8961bcb410bbull, 0x5244f9a98c8199c2ull, 0xdd2c68f1dcdf0249ull, 0xa7f41839ecea8b30ull, 0x438c80a64ce15841ull, 0x3954f06e7cd4d138ull, 0xb63c61362c8a4ab3ull, 0xcce411fe1cbfc3caull, 0x83b465d5d4a0eeceull, 0xf96c151de49567b7ull, 0x76048445b4cbfc3cull, 0x0cdcf48d84fe7545ull, 0x6fbd6d5ebd3716b7ull, 0x15651d968d029fceull, 0x9a0d8ccedd5c0445ull, 0xe0d5fc06ed698d3cull, 0xaf85882d2576a038ull, 0xd55df8e515432941ull, 0x5a3569bd451db2caull, 0x20ed197575283bb3ull, 0xc49581ead523e8c2ull, 0xbe4df122e51661bbull, 0x3125607ab548fa30ull, 0x4bfd10b2857d7349ull, 0x04ad64994d625e4dull, 0x7e7514517d57d734ull, 0xf11d85092d094cbfull, 0x8bc5f5c11d3cc5c6ull, 0x12b5926535897936ull, 0x686de2ad05bcf04full, 0xe70573f555e26bc4ull, 0x9ddd033d65d7e2bdull, 0xd28d7716adc8cfb9ull, 0xa85507de9dfd46c0ull, 0x273d9686cda3dd4bull, 0x5de5e64efd965432ull, 0xb99d7ed15d9d8743ull, 0xc3450e196da80e3aull, 0x4c2d9f413df695b1ull, 0x36f5ef890dc31cc8ull, 0x79a59ba2c5dc31ccull, 0x037deb6af5e9b8b5ull, 0x8c157a32a5b7233eull, 0xf6cd0afa9582aa47ull, 0x4ad64994d625e4daull, 0x300e395ce6106da3ull, 0xbf66a804b64ef628ull, 0xc5bed8cc867b7f51ull, 0x8aeeace74e645255ull, 0xf036dc2f7e51db2cull, 0x7f5e4d772e0f40a7ull, 0x05863dbf1e3ac9deull, 0xe1fea520be311aafull, 0x9b26d5e88e0493d6ull, 0x144e44b0de5a085dull, 0x6e963478ee6f8124ull, 0x21c640532670ac20ull, 0x5b1e309b16452559ull, 0xd476a1c3461bbed2ull, 0xaeaed10b762e37abull, 0x37deb6af5e9b8b5bull, 0x4d06c6676eae0222ull, 0xc26e573f3ef099a9ull, 0xb8b627f70ec510d0ull, 0xf7e653dcc6da3dd4ull, 0x8d3e2314f6efb4adull, 0x0256b24ca6b12f26ull, 0x788ec2849684a65full, 0x9cf65a1b368f752eull, 0xe62e2ad306bafc57ull, 0x6946bb8b56e467dcull, 0x139ecb4366d1eea5ull, 0x5ccebf68aecec3a1ull, 0x2616cfa09efb4ad8ull, 0xa97e5ef8cea5d153ull, 0xd3a62e30fe90582aull, 0xb0c7b7e3c7593bd8ull, 0xca1fc72bf76cb2a1ull, 0x45775673a732292aull, 0x3faf26bb9707a053ull, 0x70ff52905f188d57ull, 0x0a2722586f2d042eull, 0x854fb3003f739fa5ull, 0xff97c3c80f4616dcull, 0x1bef5b57af4dc5adull, 0x61372b9f9f784cd4ull, 0xee5fbac7cf26d75full, 0x9487ca0fff135e26ull, 0xdbd7be24370c7322ull, 0xa10fceec0739fa5bull, 0x2e675fb4576761d0ull, 0x54bf2f7c6752e8a9ull, 0xcdcf48d84fe75459ull, 0xb71738107fd2dd20ull, 0x387fa9482f8c46abull, 0x42a7d9801fb9cfd2ull, 0x0df7adabd7a6e2d6ull, 0x772fdd63e7936bafull, 0xf8474c3bb7cdf024ull, 0x829f3cf387f8795dull, 0x66e7a46c27f3aa2cull, 0x1c3fd4a417c62355ull, 0x935745fc4798b8deull, 0xe98f353477ad31a7ull, 0xa6df411fbfb21ca3ull, 0xdc0731d78f8795daull, 0x536fa08fdfd90e51ull, 0x29b7d047efec8728ull, }; u64 crc64( void const* data, ssize len ) { ssize remaining; u64 result = ( scast( u64, 0) ); u8 const* c = rcast( u8 const*, data); for ( remaining = len; remaining--; c++ ) result = ( result >> 8 ) ^ ( _crc64_table[ ( result ^ *c ) & 0xff ] ); return result; } #pragma endregion Hashing #pragma region String String String::fmt( AllocatorInfo allocator, char* buf, ssize buf_size, char const* fmt, ... ) { va_list va; va_start( va, fmt ); str_fmt_va( buf, buf_size, fmt, va ); va_end( va ); return make( allocator, buf ); } String String::make_length( AllocatorInfo allocator, char const* str, ssize length ) { constexpr ssize header_size = sizeof( Header ); s32 alloc_size = header_size + length + 1; void* allocation = alloc( allocator, alloc_size ); if ( allocation == nullptr ) return { nullptr }; Header& header = * rcast(Header*, allocation); header = { allocator, length, length }; String result = { rcast( char*, allocation) + header_size }; if ( length && str ) mem_copy( result, str, length ); else mem_set( result, 0, alloc_size - header_size ); result[ length ] = '\0'; return result; } String String::make_reserve( AllocatorInfo allocator, ssize capacity ) { constexpr ssize header_size = sizeof( Header ); s32 alloc_size = header_size + capacity + 1; void* allocation = alloc( allocator, alloc_size ); if ( allocation == nullptr ) return { nullptr }; mem_set( allocation, 0, alloc_size ); Header* header = rcast(Header*, allocation); header->Allocator = allocator; header->Capacity = capacity; header->Length = 0; String result = { rcast(char*, allocation) + header_size }; return result; } String String::fmt_buf( AllocatorInfo allocator, char const* fmt, ... ) { local_persist thread_local char buf[ GEN_PRINTF_MAXLEN ] = { 0 }; va_list va; va_start( va, fmt ); str_fmt_va( buf, GEN_PRINTF_MAXLEN, fmt, va ); va_end( va ); return make( allocator, buf ); } bool String::append_fmt( char const* fmt, ... ) { ssize res; char buf[ GEN_PRINTF_MAXLEN ] = { 0 }; va_list va; va_start( va, fmt ); res = str_fmt_va( buf, count_of( buf ) - 1, fmt, va ) - 1; va_end( va ); return append( buf, res ); } bool String::make_space_for( char const* str, ssize add_len ) { ssize available = avail_space(); // NOTE: Return if there is enough space left if ( available >= add_len ) { return true; } else { ssize new_len, old_size, new_size; void* ptr; void* new_ptr; AllocatorInfo allocator = get_header().Allocator; Header* header = nullptr; new_len = grow_formula( length() + add_len ); ptr = & get_header(); old_size = size_of( Header ) + length() + 1; new_size = size_of( Header ) + new_len + 1; new_ptr = resize( allocator, ptr, old_size, new_size ); if ( new_ptr == nullptr ) return false; header = rcast( Header*, new_ptr); header->Allocator = allocator; header->Capacity = new_len; Data = rcast( char*, header + 1 ); return true; } } #pragma endregion String #pragma region File Handling #if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN ) internal wchar_t* _alloc_utf8_to_ucs2( AllocatorInfo a, char const* text, ssize* w_len_ ) { wchar_t* w_text = NULL; ssize len = 0, w_len = 0, w_len1 = 0; if ( text == NULL ) { if ( w_len_ ) *w_len_ = w_len; return NULL; } len = str_len( text ); if ( len == 0 ) { if ( w_len_ ) *w_len_ = w_len; return NULL; } w_len = MultiByteToWideChar( CP_UTF8, MB_ERR_INVALID_CHARS, text, scast( int, len), NULL, 0 ); if ( w_len == 0 ) { if ( w_len_ ) *w_len_ = w_len; return NULL; } w_text = alloc_array( a, wchar_t, w_len + 1 ); w_len1 = MultiByteToWideChar( CP_UTF8, MB_ERR_INVALID_CHARS, text, scast( int, len), w_text, scast( int, w_len) ); if ( w_len1 == 0 ) { free( a, w_text ); if ( w_len_ ) *w_len_ = 0; return NULL; } w_text[ w_len ] = 0; if ( w_len_ ) *w_len_ = w_len; return w_text; } internal GEN_FILE_SEEK_PROC( _win32_file_seek ) { LARGE_INTEGER li_offset; li_offset.QuadPart = offset; if ( ! SetFilePointerEx( fd.p, li_offset, &li_offset, whence ) ) { return false; } if ( new_offset ) *new_offset = li_offset.QuadPart; return true; } internal GEN_FILE_READ_AT_PROC( _win32_file_read ) { // unused( stop_at_newline ); b32 result = false; _win32_file_seek( fd, offset, ESeekWhence_BEGIN, NULL ); DWORD size_ = scast( DWORD, ( size > GEN_I32_MAX ? GEN_I32_MAX : size )); DWORD bytes_read_; if ( ReadFile( fd.p, buffer, size_, &bytes_read_, NULL ) ) { if ( bytes_read ) *bytes_read = bytes_read_; result = true; } return result; } internal GEN_FILE_WRITE_AT_PROC( _win32_file_write ) { DWORD size_ = scast( DWORD, ( size > GEN_I32_MAX ? GEN_I32_MAX : size )); DWORD bytes_written_; _win32_file_seek( fd, offset, ESeekWhence_BEGIN, NULL ); if ( WriteFile( fd.p, buffer, size_, &bytes_written_, NULL ) ) { if ( bytes_written ) *bytes_written = bytes_written_; return true; } return false; } internal GEN_FILE_CLOSE_PROC( _win32_file_close ) { CloseHandle( fd.p ); } FileOperations const default_file_operations = { _win32_file_read, _win32_file_write, _win32_file_seek, _win32_file_close }; neverinline GEN_FILE_OPEN_PROC( _win32_file_open ) { DWORD desired_access; DWORD creation_disposition; void* handle; wchar_t* w_text; switch ( mode & GEN_FILE_MODES ) { case EFileMode_READ : desired_access = GENERIC_READ; creation_disposition = OPEN_EXISTING; break; case EFileMode_WRITE : desired_access = GENERIC_WRITE; creation_disposition = CREATE_ALWAYS; break; case EFileMode_APPEND : desired_access = GENERIC_WRITE; creation_disposition = OPEN_ALWAYS; break; case EFileMode_READ | EFileMode_RW : desired_access = GENERIC_READ | GENERIC_WRITE; creation_disposition = OPEN_EXISTING; break; case EFileMode_WRITE | EFileMode_RW : desired_access = GENERIC_READ | GENERIC_WRITE; creation_disposition = CREATE_ALWAYS; break; case EFileMode_APPEND | EFileMode_RW : desired_access = GENERIC_READ | GENERIC_WRITE; creation_disposition = OPEN_ALWAYS; break; default : GEN_PANIC( "Invalid file mode" ); return EFileError_INVALID; } w_text = _alloc_utf8_to_ucs2( heap(), filename, NULL ); handle = CreateFileW( w_text, desired_access, FILE_SHARE_READ | FILE_SHARE_DELETE, NULL, creation_disposition, FILE_ATTRIBUTE_NORMAL, NULL ); free( heap(), w_text ); if ( handle == INVALID_HANDLE_VALUE ) { DWORD err = GetLastError(); switch ( err ) { case ERROR_FILE_NOT_FOUND : return EFileError_NOT_EXISTS; case ERROR_FILE_EXISTS : return EFileError_EXISTS; case ERROR_ALREADY_EXISTS : return EFileError_EXISTS; case ERROR_ACCESS_DENIED : return EFileError_PERMISSION; } return EFileError_INVALID; } if ( mode & EFileMode_APPEND ) { LARGE_INTEGER offset = { { 0 } }; if ( ! SetFilePointerEx( handle, offset, NULL, ESeekWhence_END ) ) { CloseHandle( handle ); return EFileError_INVALID; } } fd->p = handle; *ops = default_file_operations; return EFileError_NONE; } #else // POSIX # include internal GEN_FILE_SEEK_PROC( _posix_file_seek ) { # if defined( GEN_SYSTEM_OSX ) s64 res = lseek( fd.i, offset, whence ); # else // TODO(ZaKlaus): @fixme lseek64 s64 res = lseek( fd.i, offset, whence ); # endif if ( res < 0 ) return false; if ( new_offset ) *new_offset = res; return true; } internal GEN_FILE_READ_AT_PROC( _posix_file_read ) { unused( stop_at_newline ); ssize res = pread( fd.i, buffer, size, offset ); if ( res < 0 ) return false; if ( bytes_read ) *bytes_read = res; return true; } internal GEN_FILE_WRITE_AT_PROC( _posix_file_write ) { ssize res; s64 curr_offset = 0; _posix_file_seek( fd, 0, ESeekWhence_CURRENT, &curr_offset ); if ( curr_offset == offset ) { // NOTE: Writing to stdout et al. doesn't like pwrite for numerous reasons res = write( scast( int, fd.i), buffer, size ); } else { res = pwrite( scast( int, fd.i), buffer, size, offset ); } if ( res < 0 ) return false; if ( bytes_written ) *bytes_written = res; return true; } internal GEN_FILE_CLOSE_PROC( _posix_file_close ) { close( fd.i ); } FileOperations const default_file_operations = { _posix_file_read, _posix_file_write, _posix_file_seek, _posix_file_close }; neverinline GEN_FILE_OPEN_PROC( _posix_file_open ) { s32 os_mode; switch ( mode & GEN_FILE_MODES ) { case EFileMode_READ : os_mode = O_RDONLY; break; case EFileMode_WRITE : os_mode = O_WRONLY | O_CREAT | O_TRUNC; break; case EFileMode_APPEND : os_mode = O_WRONLY | O_APPEND | O_CREAT; break; case EFileMode_READ | EFileMode_RW : os_mode = O_RDWR; break; case EFileMode_WRITE | EFileMode_RW : os_mode = O_RDWR | O_CREAT | O_TRUNC; break; case EFileMode_APPEND | EFileMode_RW : os_mode = O_RDWR | O_APPEND | O_CREAT; break; default : GEN_PANIC( "Invalid file mode" ); return EFileError_INVALID; } fd->i = open( filename, os_mode, S_IRUSR | S_IWUSR | S_IRGRP | S_IWGRP | S_IROTH | S_IWOTH ); if ( fd->i < 0 ) { // TODO : More file errors return EFileError_INVALID; } *ops = default_file_operations; return EFileError_NONE; } // POSIX #endif internal void _dirinfo_free_entry( DirEntry* entry ); // TODO : Is this a bad idea? global b32 _std_file_set = false; global FileInfo _std_files[ EFileStandard_COUNT ] = { { { nullptr, nullptr, nullptr, nullptr }, { nullptr }, 0, nullptr, 0, nullptr } }; #if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN ) FileInfo* file_get_standard( FileStandardType std ) { if ( ! _std_file_set ) { # define GEN__SET_STD_FILE( type, v ) \ _std_files[ type ].fd.p = v; \ _std_files[ type ].ops = default_file_operations GEN__SET_STD_FILE( EFileStandard_INPUT, GetStdHandle( STD_INPUT_HANDLE ) ); GEN__SET_STD_FILE( EFileStandard_OUTPUT, GetStdHandle( STD_OUTPUT_HANDLE ) ); GEN__SET_STD_FILE( EFileStandard_ERROR, GetStdHandle( STD_ERROR_HANDLE ) ); # undef GEN__SET_STD_FILE _std_file_set = true; } return &_std_files[ std ]; } #else // POSIX FileInfo* file_get_standard( FileStandardType std ) { if ( ! _std_file_set ) { # define GEN__SET_STD_FILE( type, v ) \ _std_files[ type ].fd.i = v; \ _std_files[ type ].ops = default_file_operations GEN__SET_STD_FILE( EFileStandard_INPUT, 0 ); GEN__SET_STD_FILE( EFileStandard_OUTPUT, 1 ); GEN__SET_STD_FILE( EFileStandard_ERROR, 2 ); # undef GEN__SET_STD_FILE _std_file_set = true; } return &_std_files[ std ]; } #endif FileError file_close( FileInfo* f ) { if ( ! f ) return EFileError_INVALID; if ( f->filename ) free( heap(), ccast( char*, f->filename )); #if defined( GEN_SYSTEM_WINDOWS ) if ( f->fd.p == INVALID_HANDLE_VALUE ) return EFileError_INVALID; #else if ( f->fd.i < 0 ) return EFileError_INVALID; #endif if ( f->is_temp ) { f->ops.close( f->fd ); return EFileError_NONE; } if ( ! f->ops.read_at ) f->ops = default_file_operations; f->ops.close( f->fd ); #if 0 if ( f->Dir ) { _dirinfo_free_entry( f->Dir ); mfree( f->Dir ); f->Dir = NULL; } #endif return EFileError_NONE; } FileError file_new( FileInfo* f, FileDescriptor fd, FileOperations ops, char const* filename ) { FileError err = EFileError_NONE; ssize len = str_len( filename ); f->ops = ops; f->fd = fd; f->dir = nullptr; f->last_write_time = 0; f->filename = alloc_array( heap(), char, len + 1 ); mem_copy( ccast( char*, f->filename), ccast( char*, filename), len + 1 ); return err; } FileError file_open( FileInfo* f, char const* filename ) { return file_open_mode( f, EFileMode_READ, filename ); } FileError file_open_mode( FileInfo* f, FileMode mode, char const* filename ) { FileInfo file_ = { { nullptr, nullptr, nullptr, nullptr }, { nullptr }, 0, nullptr, 0, nullptr }; *f = file_; FileError err; #if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN ) err = _win32_file_open( &f->fd, &f->ops, mode, filename ); #else err = _posix_file_open( &f->fd, &f->ops, mode, filename ); #endif if ( err == EFileError_NONE ) return file_new( f, f->fd, f->ops, filename ); return err; } s64 file_size( FileInfo* f ) { s64 size = 0; s64 prev_offset = file_tell( f ); file_seek_to_end( f ); size = file_tell( f ); file_seek( f, prev_offset ); return size; } FileContents file_read_contents( AllocatorInfo a, b32 zero_terminate, char const* filepath ) { FileContents result; FileInfo file ; result.allocator = a; if ( file_open( &file, filepath ) == EFileError_NONE ) { ssize fsize = scast( ssize , file_size( &file )); if ( fsize > 0 ) { result.data = alloc( a, zero_terminate ? fsize + 1 : fsize ); result.size = fsize; file_read_at( &file, result.data, result.size, 0 ); if ( zero_terminate ) { u8* str = rcast( u8*, result.data); str[ fsize ] = '\0'; } } file_close( &file ); } return result; } struct _memory_fd { u8 magic; u8* buf; //< zpl_array OR plain buffer if we can't write ssize cursor; AllocatorInfo allocator; FileStreamFlags flags; ssize cap; }; #define GEN__FILE_STREAM_FD_MAGIC 37 FileDescriptor _file_stream_fd_make( _memory_fd* d ); _memory_fd* _file_stream_from_fd( FileDescriptor fd ); inline FileDescriptor _file_stream_fd_make( _memory_fd* d ) { FileDescriptor fd = { 0 }; fd.p = ( void* )d; return fd; } inline _memory_fd* _file_stream_from_fd( FileDescriptor fd ) { _memory_fd* d = ( _memory_fd* )fd.p; GEN_ASSERT( d->magic == GEN__FILE_STREAM_FD_MAGIC ); return d; } b8 file_stream_new( FileInfo* file, AllocatorInfo allocator ) { GEN_ASSERT_NOT_NULL( file ); _memory_fd* d = ( _memory_fd* )alloc( allocator, size_of( _memory_fd ) ); if ( ! d ) return false; zero_item( file ); d->magic = GEN__FILE_STREAM_FD_MAGIC; d->allocator = allocator; d->flags = EFileStream_CLONE_WRITABLE; d->cap = 0; d->buf = Array::init( allocator ); if ( ! d->buf ) return false; file->ops = memory_file_operations; file->fd = _file_stream_fd_make( d ); file->dir = NULL; file->last_write_time = 0; file->filename = NULL; file->is_temp = true; return true; } b8 file_stream_open( FileInfo* file, AllocatorInfo allocator, u8* buffer, ssize size, FileStreamFlags flags ) { GEN_ASSERT_NOT_NULL( file ); _memory_fd* d = ( _memory_fd* )alloc( allocator, size_of( _memory_fd ) ); if ( ! d ) return false; zero_item( file ); d->magic = GEN__FILE_STREAM_FD_MAGIC; d->allocator = allocator; d->flags = flags; if ( d->flags & EFileStream_CLONE_WRITABLE ) { Array arr = Array::init_reserve( allocator, size ); d->buf = arr; if ( ! d->buf ) return false; mem_copy( d->buf, buffer, size ); d->cap = size; arr.get_header()->Num = size; } else { d->buf = buffer; d->cap = size; } file->ops = memory_file_operations; file->fd = _file_stream_fd_make( d ); file->dir = NULL; file->last_write_time = 0; file->filename = NULL; file->is_temp = true; return true; } u8* file_stream_buf( FileInfo* file, ssize* size ) { GEN_ASSERT_NOT_NULL( file ); _memory_fd* d = _file_stream_from_fd( file->fd ); if ( size ) *size = d->cap; return d->buf; } internal GEN_FILE_SEEK_PROC( _memory_file_seek ) { _memory_fd* d = _file_stream_from_fd( fd ); ssize buflen = d->cap; if ( whence == ESeekWhence_BEGIN ) d->cursor = 0; else if ( whence == ESeekWhence_END ) d->cursor = buflen; d->cursor = max( 0, clamp( d->cursor + offset, 0, buflen ) ); if ( new_offset ) *new_offset = d->cursor; return true; } internal GEN_FILE_READ_AT_PROC( _memory_file_read ) { // unused( stop_at_newline ); _memory_fd* d = _file_stream_from_fd( fd ); mem_copy( buffer, d->buf + offset, size ); if ( bytes_read ) *bytes_read = size; return true; } internal GEN_FILE_WRITE_AT_PROC( _memory_file_write ) { _memory_fd* d = _file_stream_from_fd( fd ); if ( ! ( d->flags & ( EFileStream_CLONE_WRITABLE | EFileStream_WRITABLE ) ) ) return false; ssize buflen = d->cap; ssize extralen = max( 0, size - ( buflen - offset ) ); ssize rwlen = size - extralen; ssize new_cap = buflen + extralen; if ( d->flags & EFileStream_CLONE_WRITABLE ) { Array arr = { d->buf }; if ( arr.get_header()->Capacity < usize(new_cap) ) { if ( ! arr.grow( ( s64 )( new_cap ) ) ) return false; d->buf = arr; } } mem_copy( d->buf + offset, buffer, rwlen ); if ( ( d->flags & EFileStream_CLONE_WRITABLE ) && extralen > 0 ) { Array arr = { d->buf }; mem_copy( d->buf + offset + rwlen, pointer_add_const( buffer, rwlen ), extralen ); d->cap = new_cap; arr.get_header()->Capacity = new_cap; } else { extralen = 0; } if ( bytes_written ) *bytes_written = ( rwlen + extralen ); return true; } internal GEN_FILE_CLOSE_PROC( _memory_file_close ) { _memory_fd* d = _file_stream_from_fd( fd ); AllocatorInfo allocator = d->allocator; if ( d->flags & EFileStream_CLONE_WRITABLE ) { Array arr = { d->buf }; arr.free(); } free( allocator, d ); } FileOperations const memory_file_operations = { _memory_file_read, _memory_file_write, _memory_file_seek, _memory_file_close }; #pragma endregion File Handling #pragma region Timing #ifdef GEN_BENCHMARK #if defined( GEN_COMPILER_MSVC ) && ! defined( __clang__ ) u64 read_cpu_time_stamp_counter( void ) { return __rdtsc(); } #elif defined( __i386__ ) u64 read_cpu_time_stamp_counter( void ) { u64 x; __asm__ volatile( ".byte 0x0f, 0x31" : "=A"( x ) ); return x; } #elif defined( __x86_64__ ) u64 read_cpu_time_stamp_counter( void ) { u32 hi, lo; __asm__ __volatile__( "rdtsc" : "=a"( lo ), "=d"( hi ) ); return scast( u64, lo ) | ( scast( u64, hi ) << 32 ); } #elif defined( __powerpc__ ) u64 read_cpu_time_stamp_counter( void ) { u64 result = 0; u32 upper, lower, tmp; __asm__ volatile( "0: \n" "\tmftbu %0 \n" "\tmftb %1 \n" "\tmftbu %2 \n" "\tcmpw %2,%0 \n" "\tbne 0b \n" : "=r"( upper ), "=r"( lower ), "=r"( tmp ) ); result = upper; result = result << 32; result = result | lower; return result; } #elif defined( GEN_SYSTEM_EMSCRIPTEN ) u64 read_cpu_time_stamp_counter( void ) { return ( u64 )( emscripten_get_now() * 1e+6 ); } #elif defined( GEN_CPU_ARM ) && ! defined( GEN_COMPILER_TINYC ) u64 read_cpu_time_stamp_counter( void ) { # if defined( __aarch64__ ) int64_t r = 0; asm volatile( "mrs %0, cntvct_el0" : "=r"( r ) ); # elif ( __ARM_ARCH >= 6 ) uint32_t r = 0; uint32_t pmccntr; uint32_t pmuseren; uint32_t pmcntenset; // Read the user mode perf monitor counter access permissions. asm volatile( "mrc p15, 0, %0, c9, c14, 0" : "=r"( pmuseren ) ); if ( pmuseren & 1 ) { // Allows reading perfmon counters for user mode code. asm volatile( "mrc p15, 0, %0, c9, c12, 1" : "=r"( pmcntenset ) ); if ( pmcntenset & 0x80000000ul ) { // Is it counting? asm volatile( "mrc p15, 0, %0, c9, c13, 0" : "=r"( pmccntr ) ); // The counter is set up to count every 64th cycle return ( ( int64_t )pmccntr ) * 64; // Should optimize to << 6 } } # else # error "No suitable method for read_cpu_time_stamp_counter for this cpu type" # endif return r; } #else u64 read_cpu_time_stamp_counter( void ) { GEN_PANIC( "read_cpu_time_stamp_counter is not supported on this particular setup" ); return -0; } #endif #if defined( GEN_SYSTEM_WINDOWS ) || defined( GEN_SYSTEM_CYGWIN ) u64 time_rel_ms( void ) { local_persist LARGE_INTEGER win32_perf_count_freq = {}; u64 result; LARGE_INTEGER counter; local_persist LARGE_INTEGER win32_perf_counter = {}; if ( ! win32_perf_count_freq.QuadPart ) { QueryPerformanceFrequency( &win32_perf_count_freq ); GEN_ASSERT( win32_perf_count_freq.QuadPart != 0 ); QueryPerformanceCounter( &win32_perf_counter ); } QueryPerformanceCounter( &counter ); result = ( counter.QuadPart - win32_perf_counter.QuadPart ) * 1000 / ( win32_perf_count_freq.QuadPart ); return result; } #else # if defined( GEN_SYSTEM_LINUX ) || defined( GEN_SYSTEM_FREEBSD ) || defined( GEN_SYSTEM_OPENBSD ) || defined( GEN_SYSTEM_EMSCRIPTEN ) u64 _unix_gettime( void ) { struct timespec t; u64 result; clock_gettime( 1 /*CLOCK_MONOTONIC*/, &t ); result = 1000 * t.tv_sec + 1.0e-6 * t.tv_nsec; return result; } # endif u64 time_rel_ms( void ) { # if defined( GEN_SYSTEM_OSX ) u64 result; local_persist u64 timebase = 0; local_persist u64 timestart = 0; if ( ! timestart ) { mach_timebase_info_data_t tb = { 0 }; mach_timebase_info( &tb ); timebase = tb.numer; timebase /= tb.denom; timestart = mach_absolute_time(); } // NOTE: mach_absolute_time() returns things in nanoseconds result = 1.0e-6 * ( mach_absolute_time() - timestart ) * timebase; return result; # else local_persist u64 unix_timestart = 0.0; if ( ! unix_timestart ) { unix_timestart = _unix_gettime(); } u64 now = _unix_gettime(); return ( now - unix_timestart ); # endif } #endif f64 time_rel( void ) { return ( f64 )( time_rel_ms() * 1e-3 ); } #endif #pragma endregion Timing #pragma region Parsing #pragma region ADT #define _adt_fprintf( s_, fmt_, ... ) \ do \ { \ if ( str_fmt_file( s_, fmt_, ##__VA_ARGS__ ) < 0 ) \ return EADT_ERROR_OUT_OF_MEMORY; \ } while ( 0 ) u8 adt_make_branch( ADT_Node* node, AllocatorInfo backing, char const* name, b32 is_array ) { ADT_Type type = EADT_TYPE_OBJECT; if ( is_array ) type = EADT_TYPE_ARRAY; ADT_Node* parent = node->parent; zero_item( node ); node->type = type; node->name = name; node->parent = parent; node->nodes = Array::init( backing ); if ( ! node->nodes ) return EADT_ERROR_OUT_OF_MEMORY; return 0; } u8 adt_destroy_branch( ADT_Node* node ) { GEN_ASSERT_NOT_NULL( node ); if ( ( node->type == EADT_TYPE_OBJECT || node->type == EADT_TYPE_ARRAY ) && node->nodes ) { for ( ssize i = 0; i < scast(ssize, node->nodes.num()); ++i ) { adt_destroy_branch( node->nodes + i ); } node->nodes.free(); } return 0; } u8 adt_make_leaf( ADT_Node* node, char const* name, ADT_Type type ) { GEN_ASSERT( type != EADT_TYPE_OBJECT && type != EADT_TYPE_ARRAY ); ADT_Node* parent = node->parent; zero_item( node ); node->type = type; node->name = name; node->parent = parent; return 0; } ADT_Node* adt_find( ADT_Node* node, char const* name, b32 deep_search ) { if ( node->type != EADT_TYPE_OBJECT ) { return NULL; } for ( ssize i = 0; i < scast(ssize, node->nodes.num()); i++ ) { if ( ! str_compare( node->nodes[ i ].name, name ) ) { return ( node->nodes + i ); } } if ( deep_search ) { for ( ssize i = 0; i < scast(ssize, node->nodes.num()); i++ ) { ADT_Node* res = adt_find( node->nodes + i, name, deep_search ); if ( res != NULL ) return res; } } return NULL; } internal ADT_Node* _adt_get_value( ADT_Node* node, char const* value ) { switch ( node->type ) { case EADT_TYPE_MULTISTRING : case EADT_TYPE_STRING : { if ( node->string && ! str_compare( node->string, value ) ) { return node; } } break; case EADT_TYPE_INTEGER : case EADT_TYPE_REAL : { char back[ 4096 ] = { 0 }; FileInfo tmp; /* allocate a file descriptor for a memory-mapped number to string conversion, input source buffer is not cloned, however. */ file_stream_open( &tmp, heap(), ( u8* )back, size_of( back ), EFileStream_WRITABLE ); adt_print_number( &tmp, node ); ssize fsize = 0; u8* buf = file_stream_buf( &tmp, &fsize ); if ( ! str_compare( ( char const* )buf, value ) ) { file_close( &tmp ); return node; } file_close( &tmp ); } break; default : break; /* node doesn't support value based lookup */ } return NULL; } internal ADT_Node* _adt_get_field( ADT_Node* node, char* name, char* value ) { for ( ssize i = 0; i < scast(ssize, node->nodes.num()); i++ ) { if ( ! str_compare( node->nodes[ i ].name, name ) ) { ADT_Node* child = &node->nodes[ i ]; if ( _adt_get_value( child, value ) ) { return node; /* this object does contain a field of a specified value! */ } } } return NULL; } ADT_Node* adt_query( ADT_Node* node, char const* uri ) { GEN_ASSERT_NOT_NULL( uri ); if ( *uri == '/' ) { uri++; } if ( *uri == 0 ) { return node; } if ( ! node || ( node->type != EADT_TYPE_OBJECT && node->type != EADT_TYPE_ARRAY ) ) { return NULL; } #if defined EADT_URI_DEBUG || 0 str_fmt_out( "uri: %s\n", uri ); #endif char * p = ( char* )uri, *b = p, *e = p; ADT_Node* found_node = NULL; b = p; p = e = ( char* )str_skip( p, '/' ); char* buf = str_fmt_buf( "%.*s", ( int )( e - b ), b ); /* handle field value lookup */ if ( *b == '[' ) { char *l_p = buf + 1, *l_b = l_p, *l_e = l_p, *l_b2 = l_p, *l_e2 = l_p; l_e = ( char* )str_skip( l_p, '=' ); l_e2 = ( char* )str_skip( l_p, ']' ); if ( ( ! *l_e && node->type != EADT_TYPE_ARRAY ) || ! *l_e2 ) { GEN_ASSERT_MSG( 0, "Invalid field value lookup" ); return NULL; } *l_e2 = 0; /* [field=value] */ if ( *l_e ) { *l_e = 0; l_b2 = l_e + 1; /* run a value comparison against our own fields */ if ( node->type == EADT_TYPE_OBJECT ) { found_node = _adt_get_field( node, l_b, l_b2 ); } /* run a value comparison against any child that is an object node */ else if ( node->type == EADT_TYPE_ARRAY ) { for ( ssize i = 0; i < scast(ssize, node->nodes.num()); i++ ) { ADT_Node* child = &node->nodes[ i ]; if ( child->type != EADT_TYPE_OBJECT ) { continue; } found_node = _adt_get_field( child, l_b, l_b2 ); if ( found_node ) break; } } } /* [value] */ else { for ( ssize i = 0; i < scast(ssize, node->nodes.num()); i++ ) { ADT_Node* child = &node->nodes[ i ]; if ( _adt_get_value( child, l_b2 ) ) { found_node = child; break; /* we found a matching value in array, ignore the rest of it */ } } } /* go deeper if uri continues */ if ( *e ) { return adt_query( found_node, e + 1 ); } } /* handle field name lookup */ else if ( node->type == EADT_TYPE_OBJECT ) { found_node = adt_find( node, buf, false ); /* go deeper if uri continues */ if ( *e ) { return adt_query( found_node, e + 1 ); } } /* handle array index lookup */ else { ssize idx = ( ssize )str_to_i64( buf, NULL, 10 ); if ( idx >= 0 && idx < scast(ssize, node->nodes.num()) ) { found_node = &node->nodes[ idx ]; /* go deeper if uri continues */ if ( *e ) { return adt_query( found_node, e + 1 ); } } } return found_node; } ADT_Node* adt_alloc_at( ADT_Node* parent, ssize index ) { if ( ! parent || ( parent->type != EADT_TYPE_OBJECT && parent->type != EADT_TYPE_ARRAY ) ) { return NULL; } if ( ! parent->nodes ) return NULL; if ( index < 0 || index > scast(ssize, parent->nodes.num()) ) return NULL; ADT_Node o = { 0 }; o.parent = parent; if ( ! parent->nodes.append_at( o, index ) ) return NULL; return parent->nodes + index; } ADT_Node* adt_alloc( ADT_Node* parent ) { if ( ! parent || ( parent->type != EADT_TYPE_OBJECT && parent->type != EADT_TYPE_ARRAY ) ) { return NULL; } if ( ! parent->nodes ) return NULL; return adt_alloc_at( parent, parent->nodes.num() ); } b8 adt_set_obj( ADT_Node* obj, char const* name, AllocatorInfo backing ) { return adt_make_branch( obj, backing, name, 0 ); } b8 adt_set_arr( ADT_Node* obj, char const* name, AllocatorInfo backing ) { return adt_make_branch( obj, backing, name, 1 ); } b8 adt_set_str( ADT_Node* obj, char const* name, char const* value ) { adt_make_leaf( obj, name, EADT_TYPE_STRING ); obj->string = value; return true; } b8 adt_set_flt( ADT_Node* obj, char const* name, f64 value ) { adt_make_leaf( obj, name, EADT_TYPE_REAL ); obj->real = value; return true; } b8 adt_set_int( ADT_Node* obj, char const* name, s64 value ) { adt_make_leaf( obj, name, EADT_TYPE_INTEGER ); obj->integer = value; return true; } ADT_Node* adt_move_node_at( ADT_Node* node, ADT_Node* new_parent, ssize index ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( new_parent ); ADT_Node* old_parent = node->parent; ADT_Node* new_node = adt_alloc_at( new_parent, index ); *new_node = *node; new_node->parent = new_parent; if ( old_parent ) { adt_remove_node( node ); } return new_node; } ADT_Node* adt_move_node( ADT_Node* node, ADT_Node* new_parent ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( new_parent ); GEN_ASSERT( new_parent->type == EADT_TYPE_ARRAY || new_parent->type == EADT_TYPE_OBJECT ); return adt_move_node_at( node, new_parent, new_parent->nodes.num() ); } void adt_swap_nodes( ADT_Node* node, ADT_Node* other_node ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( other_node ); ADT_Node* parent = node->parent; ADT_Node* other_parent = other_node->parent; ssize index = ( pointer_diff( parent->nodes, node ) / size_of( ADT_Node ) ); ssize index2 = ( pointer_diff( other_parent->nodes, other_node ) / size_of( ADT_Node ) ); ADT_Node temp = parent->nodes[ index ]; temp.parent = other_parent; other_parent->nodes[ index2 ].parent = parent; parent->nodes[ index ] = other_parent->nodes[ index2 ]; other_parent->nodes[ index2 ] = temp; } void adt_remove_node( ADT_Node* node ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( node->parent ); ADT_Node* parent = node->parent; ssize index = ( pointer_diff( parent->nodes, node ) / size_of( ADT_Node ) ); parent->nodes.remove_at( index ); } ADT_Node* adt_append_obj( ADT_Node* parent, char const* name ) { ADT_Node* o = adt_alloc( parent ); if ( ! o ) return NULL; if ( adt_set_obj( o, name, parent->nodes.get_header()->Allocator ) ) { adt_remove_node( o ); return NULL; } return o; } ADT_Node* adt_append_arr( ADT_Node* parent, char const* name ) { ADT_Node* o = adt_alloc( parent ); if ( ! o ) return NULL; if ( adt_set_arr( o, name, parent->nodes.get_header()->Allocator ) ) { adt_remove_node( o ); return NULL; } return o; } ADT_Node* adt_append_str( ADT_Node* parent, char const* name, char const* value ) { ADT_Node* o = adt_alloc( parent ); if ( ! o ) return NULL; adt_set_str( o, name, value ); return o; } ADT_Node* adt_append_flt( ADT_Node* parent, char const* name, f64 value ) { ADT_Node* o = adt_alloc( parent ); if ( ! o ) return NULL; adt_set_flt( o, name, value ); return o; } ADT_Node* adt_append_int( ADT_Node* parent, char const* name, s64 value ) { ADT_Node* o = adt_alloc( parent ); if ( ! o ) return NULL; adt_set_int( o, name, value ); return o; } /* parser helpers */ char* adt_parse_number_strict( ADT_Node* node, char* base_str ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( base_str ); char *p = base_str, *e = p; while ( *e ) ++e; while ( *p && ( str_find( "eE.+-", *p ) || char_is_hex_digit( *p ) ) ) { ++p; } if ( p >= e ) { return adt_parse_number( node, base_str ); } return base_str; } char* adt_parse_number( ADT_Node* node, char* base_str ) { GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( base_str ); char *p = base_str, *e = p; s32 base = 0; s32 base2 = 0; u8 base2_offset = 0; s8 exp = 0, orig_exp = 0; u8 neg_zero = 0; u8 lead_digit = 0; ADT_Type node_type = EADT_TYPE_UNINITIALISED; u8 node_props = 0; /* skip false positives and special cases */ if ( ! ! str_find( "eE", *p ) || ( ! ! str_find( ".+-", *p ) && ! char_is_hex_digit( *( p + 1 ) ) && *( p + 1 ) != '.' ) ) { return ++base_str; } node_type = EADT_TYPE_INTEGER; neg_zero = false; ssize ib = 0; char buf[ 48 ] = { 0 }; if ( *e == '+' ) ++e; else if ( *e == '-' ) { buf[ ib++ ] = *e++; } if ( *e == '.' ) { node_type = EADT_TYPE_REAL; node_props = EADT_PROPS_IS_PARSED_REAL; lead_digit = false; buf[ ib++ ] = '0'; do { buf[ ib++ ] = *e; } while ( char_is_digit( *++e ) ); } else { if ( ! str_compare( e, "0x", 2 ) || ! str_compare( e, "0X", 2 ) ) { node_props = EADT_PROPS_IS_HEX; } /* bail if ZPL_ADT_PROPS_IS_HEX is unset but we get 'x' on input */ if ( char_to_lower( *e ) == 'x' && ( node_props != EADT_PROPS_IS_HEX ) ) { return ++base_str; } while ( char_is_hex_digit( *e ) || char_to_lower( *e ) == 'x' ) { buf[ ib++ ] = *e++; } if ( *e == '.' ) { node_type = EADT_TYPE_REAL; lead_digit = true; u32 step = 0; do { buf[ ib++ ] = *e; ++step; } while ( char_is_digit( *++e ) ); if ( step < 2 ) { buf[ ib++ ] = '0'; } } } /* check if we have a dot here, this is a false positive (IP address, ...) */ if ( *e == '.' ) { return ++base_str; } f32 eb = 10; char expbuf[ 6 ] = { 0 }; ssize expi = 0; if ( *e && ! ! str_find( "eE", *e ) ) { ++e; if ( *e == '+' || *e == '-' || char_is_digit( *e ) ) { if ( *e == '-' ) { eb = 0.1f; } if ( ! char_is_digit( *e ) ) { ++e; } while ( char_is_digit( *e ) ) { expbuf[ expi++ ] = *e++; } } orig_exp = exp = ( u8 )str_to_i64( expbuf, NULL, 10 ); } if ( node_type == EADT_TYPE_INTEGER ) { node->integer = str_to_i64( buf, 0, 0 ); #ifndef GEN_PARSER_DISABLE_ANALYSIS /* special case: negative zero */ if ( node->integer == 0 && buf[ 0 ] == '-' ) { neg_zero = true; } #endif while ( orig_exp-- > 0 ) { node->integer *= ( s64 )eb; } } else { node->real = str_to_f64( buf, 0 ); #ifndef GEN_PARSER_DISABLE_ANALYSIS char *q = buf, *base_string = q, *base_string2 = q; base_string = ccast( char*, str_skip( base_string, '.' )); *base_string = '\0'; base_string2 = base_string + 1; char* base_string_off = base_string2; while ( *base_string_off++ == '0' ) base2_offset++; base = ( s32 )str_to_i64( q, 0, 0 ); base2 = ( s32 )str_to_i64( base_string2, 0, 0 ); if ( exp ) { exp = exp * ( ! ( eb == 10.0f ) ? -1 : 1 ); node_props = EADT_PROPS_IS_EXP; } /* special case: negative zero */ if ( base == 0 && buf[ 0 ] == '-' ) { neg_zero = true; } #endif while ( orig_exp-- > 0 ) { node->real *= eb; } } node->type = node_type; node->props = node_props; #ifndef GEN_PARSER_DISABLE_ANALYSIS node->base = base; node->base2 = base2; node->base2_offset = base2_offset; node->exp = exp; node->neg_zero = neg_zero; node->lead_digit = lead_digit; #else unused( base ); unused( base2 ); unused( base2_offset ); unused( exp ); unused( neg_zero ); unused( lead_digit ); #endif return e; } ADT_Error adt_print_number( FileInfo* file, ADT_Node* node ) { GEN_ASSERT_NOT_NULL( file ); GEN_ASSERT_NOT_NULL( node ); if ( node->type != EADT_TYPE_INTEGER && node->type != EADT_TYPE_REAL ) { return EADT_ERROR_INVALID_TYPE; } #ifndef GEN_PARSER_DISABLE_ANALYSIS if ( node->neg_zero ) { _adt_fprintf( file, "-" ); } #endif switch ( node->type ) { case EADT_TYPE_INTEGER : { if ( node->props == EADT_PROPS_IS_HEX ) { _adt_fprintf( file, "0x%llx", ( long long )node->integer ); } else { _adt_fprintf( file, "%lld", ( long long )node->integer ); } } break; case EADT_TYPE_REAL : { if ( node->props == EADT_PROPS_NAN ) { _adt_fprintf( file, "NaN" ); } else if ( node->props == EADT_PROPS_NAN_NEG ) { _adt_fprintf( file, "-NaN" ); } else if ( node->props == EADT_PROPS_INFINITY ) { _adt_fprintf( file, "Infinity" ); } else if ( node->props == EADT_PROPS_INFINITY_NEG ) { _adt_fprintf( file, "-Infinity" ); } else if ( node->props == EADT_PROPS_TRUE ) { _adt_fprintf( file, "true" ); } else if ( node->props == EADT_PROPS_FALSE ) { _adt_fprintf( file, "false" ); } else if ( node->props == EADT_PROPS_NULL ) { _adt_fprintf( file, "null" ); #ifndef GEN_PARSER_DISABLE_ANALYSIS } else if ( node->props == EADT_PROPS_IS_EXP ) { _adt_fprintf( file, "%lld.%0*d%llde%lld", ( long long )node->base, node->base2_offset, 0, ( long long )node->base2, ( long long )node->exp ); } else if ( node->props == EADT_PROPS_IS_PARSED_REAL ) { if ( ! node->lead_digit ) _adt_fprintf( file, ".%0*d%lld", node->base2_offset, 0, ( long long )node->base2 ); else _adt_fprintf( file, "%lld.%0*d%lld", ( long long int )node->base2_offset, 0, ( int )node->base, ( long long )node->base2 ); #endif } else { _adt_fprintf( file, "%f", node->real ); } } break; } return EADT_ERROR_NONE; } ADT_Error adt_print_string( FileInfo* file, ADT_Node* node, char const* escaped_chars, char const* escape_symbol ) { GEN_ASSERT_NOT_NULL( file ); GEN_ASSERT_NOT_NULL( node ); GEN_ASSERT_NOT_NULL( escaped_chars ); if ( node->type != EADT_TYPE_STRING && node->type != EADT_TYPE_MULTISTRING ) { return EADT_ERROR_INVALID_TYPE; } /* escape string */ char const *p = node->string, *b = p; if ( ! p ) return EADT_ERROR_NONE; do { p = str_skip_any( p, escaped_chars ); _adt_fprintf( file, "%.*s", pointer_diff( b, p ), b ); if ( *p && ! ! str_find( escaped_chars, *p ) ) { _adt_fprintf( file, "%s%c", escape_symbol, *p ); p++; } b = p; } while ( *p ); return EADT_ERROR_NONE; } ADT_Error adt_str_to_number( ADT_Node* node ) { GEN_ASSERT( node ); if ( node->type == EADT_TYPE_REAL || node->type == EADT_TYPE_INTEGER ) return EADT_ERROR_ALREADY_CONVERTED; /* this is already converted/parsed */ if ( node->type != EADT_TYPE_STRING && node->type != EADT_TYPE_MULTISTRING ) { return EADT_ERROR_INVALID_TYPE; } adt_parse_number( node, ( char* )node->string ); return EADT_ERROR_NONE; } ADT_Error adt_str_to_number_strict( ADT_Node* node ) { GEN_ASSERT( node ); if ( node->type == EADT_TYPE_REAL || node->type == EADT_TYPE_INTEGER ) return EADT_ERROR_ALREADY_CONVERTED; /* this is already converted/parsed */ if ( node->type != EADT_TYPE_STRING && node->type != EADT_TYPE_MULTISTRING ) { return EADT_ERROR_INVALID_TYPE; } adt_parse_number_strict( node, ( char* )node->string ); return EADT_ERROR_NONE; } #undef _adt_fprintf #pragma endregion ADT #pragma region CSV #ifdef GEN_CSV_DEBUG # define GEN_CSV_ASSERT( msg ) GEN_PANIC( msg ) #else # define GEN_CSV_ASSERT( msg ) #endif u8 csv_parse_delimiter( CSV_Object* root, char* text, AllocatorInfo allocator, b32 has_header, char delim ) { CSV_Error error = ECSV_Error__NONE; GEN_ASSERT_NOT_NULL( root ); GEN_ASSERT_NOT_NULL( text ); zero_item( root ); adt_make_branch( root, allocator, NULL, has_header ? false : true ); char* currentChar = text; char* beginChar; char* endChar; ssize columnIndex = 0; ssize totalColumnIndex = 0; do { char delimiter = 0; currentChar = ccast( char*, str_trim( currentChar, false )); if ( *currentChar == 0 ) break; ADT_Node rowItem = { 0 }; rowItem.type = EADT_TYPE_STRING; #ifndef GEN_PARSER_DISABLE_ANALYSIS rowItem.name_style = EADT_NAME_STYLE_NO_QUOTES; #endif /* handle string literals */ if ( *currentChar == '"' ) { currentChar += 1; beginChar = currentChar; endChar = currentChar; rowItem.string = beginChar; #ifndef GEN_PARSER_DISABLE_ANALYSIS rowItem.name_style = EADT_NAME_STYLE_DOUBLE_QUOTE; #endif do { endChar = ccast( char*, str_skip( endChar, '"' )); if ( *endChar && *( endChar + 1 ) == '"' ) { endChar += 2; } else break; } while ( *endChar ); if ( *endChar == 0 ) { GEN_CSV_ASSERT( "unmatched quoted string" ); error = ECSV_Error__UNEXPECTED_END_OF_INPUT; return error; } *endChar = 0; currentChar = ccast( char*, str_trim( endChar + 1, true )); delimiter = * currentChar; /* unescape escaped quotes (so that unescaped text escapes :) */ { char* escapedChar = beginChar; do { if ( *escapedChar == '"' && *( escapedChar + 1 ) == '"' ) { mem_move( escapedChar, escapedChar + 1, str_len( escapedChar ) ); } escapedChar++; } while ( *escapedChar ); } } else if ( *currentChar == delim ) { delimiter = * currentChar; rowItem.string = ""; } else if ( *currentChar ) { /* regular data */ beginChar = currentChar; endChar = currentChar; rowItem.string = beginChar; do { endChar++; } while ( * endChar && * endChar != delim && * endChar != '\n' ); if ( * endChar ) { currentChar = ccast( char*, str_trim( endChar, true )); while ( char_is_space( *( endChar - 1 ) ) ) { endChar--; } delimiter = * currentChar; * endChar = 0; } else { delimiter = 0; currentChar = endChar; } /* check if number and process if so */ b32 skip_number = false; char* num_p = beginChar; // We only consider hexadecimal values if they start with 0x if ( str_len(num_p) > 2 && num_p[0] == '0' && (num_p[1] == 'x' || num_p[1] == 'X') ) { num_p += 2; // skip '0x' prefix do { if (!char_is_hex_digit(*num_p)) { skip_number = true; break; } } while (*num_p++); } else { skip_number = true; } if (!skip_number) { adt_str_to_number(&rowItem); } } if ( columnIndex >= scast(ssize, root->nodes.num()) ) { adt_append_arr( root, NULL ); } root->nodes[ columnIndex ].nodes.append( rowItem ); if ( delimiter == delim ) { columnIndex++; currentChar++; } else if ( delimiter == '\n' || delimiter == 0 ) { /* check if number of rows is not mismatched */ if ( totalColumnIndex < columnIndex ) totalColumnIndex = columnIndex; else if ( totalColumnIndex != columnIndex ) { GEN_CSV_ASSERT( "mismatched rows" ); error = ECSV_Error__MISMATCHED_ROWS; return error; } columnIndex = 0; if ( delimiter != 0 ) currentChar++; } } while ( *currentChar ); if ( root->nodes.num() == 0 ) { GEN_CSV_ASSERT( "unexpected end of input. stream is empty." ); error = ECSV_Error__UNEXPECTED_END_OF_INPUT; return error; } /* consider first row as a header. */ if ( has_header ) { for ( ssize i = 0; i < scast(ssize, root->nodes.num()); i++ ) { CSV_Object* col = root->nodes + i; CSV_Object* hdr = col->nodes; col->name = hdr->string; col->nodes.remove_at( 0 ); } } return error; } void csv_free( CSV_Object* obj ) { adt_destroy_branch( obj ); } void _csv_write_record( FileInfo* file, CSV_Object* node ) { switch ( node->type ) { case EADT_TYPE_STRING : { #ifndef GEN_PARSER_DISABLE_ANALYSIS switch ( node->name_style ) { case EADT_NAME_STYLE_DOUBLE_QUOTE : { str_fmt_file( file, "\"" ); adt_print_string( file, node, "\"", "\"" ); str_fmt_file( file, "\"" ); } break; case EADT_NAME_STYLE_NO_QUOTES : { #endif str_fmt_file( file, "%s", node->string ); #ifndef GEN_PARSER_DISABLE_ANALYSIS } break; } #endif } break; case EADT_TYPE_REAL : case EADT_TYPE_INTEGER : { adt_print_number( file, node ); } break; } } void _csv_write_header( FileInfo* file, CSV_Object* header ) { CSV_Object temp = *header; temp.string = temp.name; temp.type = EADT_TYPE_STRING; _csv_write_record( file, &temp ); } void csv_write_delimiter( FileInfo* file, CSV_Object* obj, char delimiter ) { GEN_ASSERT_NOT_NULL( file ); GEN_ASSERT_NOT_NULL( obj ); GEN_ASSERT( obj->nodes ); ssize cols = obj->nodes.num(); if ( cols == 0 ) return; ssize rows = obj->nodes[ 0 ].nodes.num(); if ( rows == 0 ) return; b32 has_headers = obj->nodes[ 0 ].name != NULL; if ( has_headers ) { for ( ssize i = 0; i < cols; i++ ) { _csv_write_header( file, &obj->nodes[ i ] ); if ( i + 1 != cols ) { str_fmt_file( file, "%c", delimiter ); } } str_fmt_file( file, "\n" ); } for ( ssize r = 0; r < rows; r++ ) { for ( ssize i = 0; i < cols; i++ ) { _csv_write_record( file, &obj->nodes[ i ].nodes[ r ] ); if ( i + 1 != cols ) { str_fmt_file( file, "%c", delimiter ); } } str_fmt_file( file, "\n" ); } } String csv_write_string_delimiter( AllocatorInfo a, CSV_Object* obj, char delimiter ) { FileInfo tmp; file_stream_new( &tmp, a ); csv_write_delimiter( &tmp, obj, delimiter ); ssize fsize; u8* buf = file_stream_buf( &tmp, &fsize ); String output = String::make_length( a, ( char* )buf, fsize ); file_close( &tmp ); return output; } #pragma endregion CSV #pragma endregion Parsing GEN_NS_END // GEN_ROLL_OWN_DEPENDENCIES #endif GEN_NS_BEGIN #pragma region StaticData // TODO : Convert global allocation strategy to use a slab allocation strategy. global AllocatorInfo GlobalAllocator; global Array Global_AllocatorBuckets; // TODO(Ed) : Make the code pool a dynamic arena global Array< Pool > CodePools = { nullptr }; global Array< Arena > StringArenas = { nullptr }; global StringTable StringCache; global Arena LexArena; global AllocatorInfo Allocator_DataArrays = heap(); global AllocatorInfo Allocator_CodePool = heap(); global AllocatorInfo Allocator_Lexer = heap(); global AllocatorInfo Allocator_StringArena = heap(); global AllocatorInfo Allocator_StringTable = heap(); global AllocatorInfo Allocator_TypeTable = heap(); #pragma endregion StaticData #pragma region Constants global Code access_public; global Code access_protected; global Code access_private; global CodeAttributes attrib_api_export; global CodeAttributes attrib_api_import; global Code module_global_fragment; global Code module_private_fragment; global Code fmt_newline; global CodeParam param_varadic; global CodePragma pragma_once; global CodePreprocessCond preprocess_else; global CodePreprocessCond preprocess_endif; global CodeSpecifiers spec_const; global CodeSpecifiers spec_consteval; global CodeSpecifiers spec_constexpr; global CodeSpecifiers spec_constinit; global CodeSpecifiers spec_extern_linkage; global CodeSpecifiers spec_final; global CodeSpecifiers spec_forceinline; global CodeSpecifiers spec_global; global CodeSpecifiers spec_inline; global CodeSpecifiers spec_internal_linkage; global CodeSpecifiers spec_local_persist; global CodeSpecifiers spec_mutable; global CodeSpecifiers spec_noexcept; global CodeSpecifiers spec_neverinline; global CodeSpecifiers spec_override; global CodeSpecifiers spec_ptr; global CodeSpecifiers spec_pure; global CodeSpecifiers spec_ref; global CodeSpecifiers spec_register; global CodeSpecifiers spec_rvalue; global CodeSpecifiers spec_static_member; global CodeSpecifiers spec_thread_local; global CodeSpecifiers spec_virtual; global CodeSpecifiers spec_volatile; global CodeType t_empty; global CodeType t_auto; global CodeType t_void; global CodeType t_int; global CodeType t_bool; global CodeType t_char; global CodeType t_wchar_t; global CodeType t_class; global CodeType t_typename; global Array< StringCached > PreprocessorDefines; #ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS global CodeType t_b32; global CodeType t_s8; global CodeType t_s16; global CodeType t_s32; global CodeType t_s64; global CodeType t_u8; global CodeType t_u16; global CodeType t_u32; global CodeType t_u64; global CodeType t_ssize; global CodeType t_usize; global CodeType t_f32; global CodeType t_f64; #endif #pragma endregion Constants #pragma region AST # define GEN_AST_BODY_CLASS_UNALLOWED_TYPES \ case PlatformAttributes: \ case Class_Body: \ case Enum_Body: \ case Extern_Linkage: \ case Function_Body: \ case Function_Fwd: \ case Global_Body: \ case Namespace: \ case Namespace_Body: \ case Operator: \ case Operator_Fwd: \ case Parameters: \ case Specifiers: \ case Struct_Body: \ case Typename: # define GEN_AST_BODY_STRUCT_UNALLOWED_TYPES GEN_AST_BODY_CLASS_UNALLOWED_TYPES # define GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES \ case Access_Public: \ case Access_Protected: \ case Access_Private: \ case PlatformAttributes: \ case Class_Body: \ case Enum_Body: \ case Extern_Linkage: \ case Friend: \ case Function_Body: \ case Function_Fwd: \ case Global_Body: \ case Namespace: \ case Namespace_Body: \ case Operator: \ case Operator_Fwd: \ case Operator_Member: \ case Operator_Member_Fwd: \ case Parameters: \ case Specifiers: \ case Struct_Body: \ case Typename: # define GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES \ case Access_Public: \ case Access_Protected: \ case Access_Private: \ case PlatformAttributes: \ case Class_Body: \ case Enum_Body: \ case Execution: \ case Friend: \ case Function_Body: \ case Namespace_Body: \ case Operator_Member: \ case Operator_Member_Fwd: \ case Parameters: \ case Specifiers: \ case Struct_Body: \ case Typename: # define GEN_AST_BODY_EXPORT_UNALLOWED_TYPES GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES # define GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES # define GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES \ case Access_Public: \ case Access_Protected: \ case Access_Private: \ case PlatformAttributes: \ case Class_Body: \ case Enum_Body: \ case Execution: \ case Friend: \ case Function_Body: \ case Namespace_Body: \ case Operator_Member: \ case Operator_Member_Fwd: \ case Parameters: \ case Specifiers: \ case Struct_Body: \ case Typename: Code Code::Global; Code Code::Invalid; // This serializes all the data-members in a "debug" format, where each member is printed with its associated value. char const* AST::debug_str() { String result = String::make_reserve( GlobalAllocator, kilobytes(1) ); if ( Parent ) result.append_fmt( "\n\tParent : %S %S", Parent->type_str(), Name ? Name : "" ); else result.append_fmt( "\n\tParent : %S", "Null" ); result.append_fmt( "\n\tName : %S", Name ? Name : "Null" ); result.append_fmt( "\n\tType : %S", type_str() ); result.append_fmt( "\n\tModule Flags : %S", to_str( ModuleFlags ) ); switch ( Type ) { using namespace ECode; case Invalid: case NewLine: case Access_Private: case Access_Protected: case Access_Public: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); break; case Untyped: case Execution: case Comment: case PlatformAttributes: case Preprocess_Define: case Preprocess_Include: case Preprocess_Pragma: case Preprocess_If: case Preprocess_ElIf: case Preprocess_Else: case Preprocess_IfDef: case Preprocess_IfNotDef: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tContent: %S", Content ); break; case Class: case Struct: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmd : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tParentAccess: %s", ParentType ? to_str( ParentAccess ) : "No Parent" ); result.append_fmt( "\n\tParentType : %s", ParentType ? ParentType->type_str() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Class_Fwd: case Struct_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmd : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tParentAccess: %s", ParentType ? to_str( ParentAccess ) : "No Parent" ); result.append_fmt( "\n\tParentType : %s", ParentType ? ParentType->type_str() : "Null" ); break; case Constructor: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tInitializerList: %S", InitializerList ? InitializerList->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Constructor_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tInitializerList: %S", InitializerList ? InitializerList->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); break; case Destructor: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Destructor_Fwd: break; case Enum: case Enum_Class: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tUnderlying Type : %S", UnderlyingType ? UnderlyingType->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Enum_Fwd: case Enum_Class_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tUnderlying Type : %S", UnderlyingType ? UnderlyingType->to_string() : "Null" ); break; case Extern_Linkage: case Namespace: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tBody: %S", Body ? Body->debug_str() : "Null" ); break; case Friend: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tDeclaration: %S", Declaration ? Declaration->to_string() : "Null" ); break; case Function: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes: %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tReturnType: %S", ReturnType ? ReturnType->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Function_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes: %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tReturnType: %S", ReturnType ? ReturnType->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); break; case Module: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); break; case Operator: case Operator_Member: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes: %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tReturnType: %S", ReturnType ? ReturnType->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); result.append_fmt( "\n\tOp : %S", to_str( Op ) ); break; case Operator_Fwd: case Operator_Member_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes: %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tReturnType: %S", ReturnType ? ReturnType->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tOp : %S", to_str( Op ) ); break; case Operator_Cast: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tValueType : %S", ValueType ? ValueType->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Operator_Cast_Fwd: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tValueType : %S", ValueType ? ValueType->to_string() : "Null" ); break; case Parameters: result.append_fmt( "\n\tNumEntries: %d", NumEntries ); result.append_fmt( "\n\tLast : %S", Last->Name ); result.append_fmt( "\n\tNext : %S", Next->Name ); result.append_fmt( "\n\tValueType : %S", ValueType ? ValueType->to_string() : "Null" ); result.append_fmt( "\n\tValue : %S", Value ? Value->to_string() : "Null" ); break; case Specifiers: { result.append_fmt( "\n\tNumEntries: %d", NumEntries ); result.append( "\n\tArrSpecs: " ); s32 idx = 0; s32 left = NumEntries; while ( left-- ) { StrC spec = ESpecifier::to_str( ArrSpecs[idx] ); result.append_fmt( "%.*s, ", spec.Len, spec.Ptr ); idx++; } result.append_fmt( "\n\tNextSpecs: %S", NextSpecs ? NextSpecs->debug_str() : "Null" ); } break; case Template: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tDeclaration: %S", Declaration ? Declaration->to_string() : "Null" ); break; case Typedef: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tUnderlyingType: %S", UnderlyingType ? UnderlyingType->to_string() : "Null" ); break; case Typename: result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tReturnType : %S", ReturnType ? ReturnType->to_string() : "Null" ); result.append_fmt( "\n\tParams : %S", Params ? Params->to_string() : "Null" ); result.append_fmt( "\n\tArrExpr : %S", ArrExpr ? ArrExpr->to_string() : "Null" ); break; case Union: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tAttributes: %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tBody : %S", Body ? Body->debug_str() : "Null" ); break; case Using: if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tUnderlyingType: %S", UnderlyingType ? UnderlyingType->to_string() : "Null" ); break; case Variable: if ( Parent && Parent->Type == Variable ) { // Its a NextVar result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tValue : %S", Value ? Value->to_string() : "Null" ); result.append_fmt( "\n\tBitfieldSize: %S", BitfieldSize ? BitfieldSize->to_string() : "Null" ); result.append_fmt( "\n\tNextVar : %S", NextVar ? NextVar->debug_str() : "Null" ); break; } if ( Prev ) result.append_fmt( "\n\tPrev: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); if ( Next ) result.append_fmt( "\n\tNext: %S %S", Prev->type_str(), Prev->Name ? Prev->Name : "Null" ); result.append_fmt( "\n\tInlineCmt : %S", InlineCmt ? InlineCmt->Content : "Null" ); result.append_fmt( "\n\tAttributes : %S", Attributes ? Attributes->to_string() : "Null" ); result.append_fmt( "\n\tSpecs : %S", Specs ? Specs->to_string() : "Null" ); result.append_fmt( "\n\tValueType : %S", ValueType ? ValueType->to_string() : "Null" ); result.append_fmt( "\n\tBitfieldSize: %S", BitfieldSize ? BitfieldSize->to_string() : "Null" ); result.append_fmt( "\n\tValue : %S", Value ? Value->to_string() : "Null" ); result.append_fmt( "\n\tNextVar : %S", NextVar ? NextVar->debug_str() : "Null" ); break; } return result; } AST* AST::duplicate() { using namespace ECode; AST* result = make_code().ast; mem_copy( result, this, sizeof( AST ) ); result->Parent = nullptr; return result; } String AST::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void AST::to_string( String& result ) { local_persist thread_local char SerializationLevel = 0; switch ( Type ) { using namespace ECode; case Invalid: #ifdef GEN_DONT_ALLOW_INVALID_CODE log_failure("Attempted to serialize invalid code! - %S", Parent ? Parent->debug_str() : Name ); #else result.append_fmt( "Invalid Code!" ); #endif break; case NewLine: result.append("\n"); break; case Untyped: case Execution: case Comment: case PlatformAttributes: result.append( Content ); break; case Access_Private: case Access_Protected: case Access_Public: result.append( Name ); break; case Class: cast().to_string_def( result ); break; case Class_Fwd: cast().to_string_fwd( result ); break; case Constructor: cast().to_string_def( result ); break; case Constructor_Fwd: cast().to_string_fwd( result ); break; case Destructor: cast().to_string_def( result ); break; case Destructor_Fwd: cast().to_string_fwd( result ); break; case Enum: cast().to_string_def( result ); break; case Enum_Fwd: cast().to_string_fwd( result ); break; case Enum_Class: cast().to_string_class_def( result ); break; case Enum_Class_Fwd: cast().to_string_class_fwd( result ); break; case Export_Body: cast().to_string_export( result ); break; case Extern_Linkage: cast().to_string( result ); break; case Friend: cast().to_string( result ); break; case Function: cast().to_string_def( result ); break; case Function_Fwd: cast().to_string_fwd( result ); break; case Module: cast().to_string( result ); break; case Namespace: cast().to_string( result ); break; case Operator: case Operator_Member: cast().to_string_def( result ); break; case Operator_Fwd: case Operator_Member_Fwd: cast().to_string_fwd( result ); break; case Operator_Cast: cast().to_string_def( result ); break; case Operator_Cast_Fwd: cast().to_string_fwd( result ); break; case Parameters: cast().to_string( result ); break; case Preprocess_Define: cast().to_string( result ); break; case Preprocess_If: cast().to_string_if( result ); break; case Preprocess_IfDef: cast().to_string_ifdef( result ); break; case Preprocess_IfNotDef: cast().to_string_ifndef( result ); break; case Preprocess_Include: cast().to_string( result ); break; case Preprocess_ElIf: cast().to_string_elif( result ); break; case Preprocess_Else: cast().to_string_else( result ); break; case Preprocess_EndIf: cast().to_string_endif( result ); break; case Preprocess_Pragma: cast().to_string( result ); break; case Specifiers: cast().to_string( result ); break; case Struct: cast().to_string_def( result ); break; case Struct_Fwd: cast().to_string_fwd( result ); break; case Template: cast().to_string( result ); break; case Typedef: cast().to_string( result ); break; case Typename: cast().to_string( result ); break; case Union: cast().to_string( result ); break; case Using: cast().to_string( result ); break; case Using_Namespace: cast().to_string_ns( result ); break; case Variable: cast().to_string( result ); break; case Enum_Body: case Class_Body: case Extern_Linkage_Body: case Function_Body: case Global_Body: case Namespace_Body: case Struct_Body: case Union_Body: cast().to_string( result ); break; } } bool AST::is_equal( AST* other ) { /* AST values are either some u32 value, a cached string, or a pointer to another AST. u32 values are compared by value. Cached strings are compared by pointer. AST nodes are compared with AST::is_equal. */ if ( other == nullptr ) { log_fmt( "AST::is_equal: other is null\nAST: %S", debug_str() ); return false; } if ( Type != other->Type ) { log_fmt("AST::is_equal: Type check failure with other\nAST: %S\nOther: %S" , debug_str() , other->debug_str() ); return false; } switch ( Type ) { using namespace ECode; #define check_member_val( val ) \ if ( val != other->val ) \ { \ log_fmt("\nAST::is_equal: Member - " #val " failed\n" \ "AST : %S\n" \ "Other: %S\n" \ , debug_str() \ , other->debug_str() \ ); \ \ return false; \ } #define check_member_str( str ) \ if ( str != other->str ) \ { \ log_fmt("\nAST::is_equal: Member string - "#str " failed\n" \ "AST : %S\n" \ "Other: %S\n" \ , debug_str() \ , other->debug_str() \ ); \ \ return false; \ } #define check_member_content( content ) \ if ( content != other->content ) \ { \ log_fmt("\nAST::is_equal: Member content - "#content " failed\n" \ "AST : %S\n" \ "Other: %S\n" \ , debug_str() \ , other->debug_str() \ ); \ \ log_fmt("Content cannot be trusted to be unique with this check " \ "so it must be verified by eye for now\n" \ "AST Content:\n%S\n" \ "Other Content:\n%S\n" \ , content.visualize_whitespace() \ , other->content.visualize_whitespace() \ ); \ } #define check_member_ast( ast ) \ if ( ast ) \ { \ if ( other->ast == nullptr ) \ { \ log_fmt("\nAST::is_equal: Failed for member " #ast " other equivalent param is null\n" \ "AST : %s\n" \ "Other: %s\n" \ "For ast member: %s\n" \ , debug_str() \ , other->debug_str() \ , ast->debug_str() \ ); \ \ return false; \ } \ \ if ( ! ast->is_equal( other->ast ) ) \ { \ log_fmt( "\nAST::is_equal: Failed for " #ast"\n" \ "AST : %S\n" \ "Other: %S\n" \ "For ast member: %S\n" \ "other's ast member: %S\n" \ , debug_str() \ , other->debug_str() \ , ast->debug_str() \ , other->ast->debug_str() \ ); \ \ return false; \ } \ } case NewLine: case Access_Public: case Access_Protected: case Access_Private: case Preprocess_Else: case Preprocess_EndIf: return true; // Comments are not validated. case Comment: return true; case Execution: case PlatformAttributes: case Untyped: { check_member_content( Content ); return true; } case Class_Fwd: case Struct_Fwd: { check_member_str( Name ); check_member_ast( ParentType ); check_member_val( ParentAccess ); check_member_ast( Attributes ); return true; } case Class: case Struct: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ParentType ); check_member_val( ParentAccess ); check_member_ast( Attributes ); check_member_ast( Body ); return true; } case Constructor: { check_member_ast( InitializerList ); check_member_ast( Params ); check_member_ast( Body ); return true; } case Constructor_Fwd: { check_member_ast( InitializerList ); check_member_ast( Params ); return true; } case Destructor: { check_member_ast( Specs ); check_member_ast( Body ); return true; } case Destructor_Fwd: { check_member_ast( Specs ); return true; } case Enum: case Enum_Class: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Attributes ); check_member_ast( UnderlyingType ); check_member_ast( Body ); return true; } case Enum_Fwd: case Enum_Class_Fwd: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Attributes ); check_member_ast( UnderlyingType ); return true; } case Extern_Linkage: { check_member_str( Name ); check_member_ast( Body ); return true; } case Friend: { check_member_str( Name ); check_member_ast( Declaration ); return true; } case Function: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ReturnType ); check_member_ast( Attributes ); check_member_ast( Specs ); check_member_ast( Params ); check_member_ast( Body ); return true; } case Function_Fwd: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ReturnType ); check_member_ast( Attributes ); check_member_ast( Specs ); check_member_ast( Params ); return true; } case Module: { check_member_val( ModuleFlags ); check_member_str( Name ); return true; } case Namespace: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Body ); return true; } case Operator: case Operator_Member: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ReturnType ); check_member_ast( Attributes ); check_member_ast( Specs ); check_member_ast( Params ); check_member_ast( Body ); return true; } case Operator_Fwd: case Operator_Member_Fwd: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ReturnType ); check_member_ast( Attributes ); check_member_ast( Specs ); check_member_ast( Params ); return true; } case Operator_Cast: { check_member_str( Name ); check_member_ast( Specs ); check_member_ast( ValueType ); check_member_ast( Body ); return true; } case Operator_Cast_Fwd: { check_member_str( Name ); check_member_ast( Specs ); check_member_ast( ValueType ); return true; } case Parameters: { if ( NumEntries > 1 ) { AST* curr = this; AST* curr_other = other; while ( curr != nullptr ) { if ( curr ) { if ( curr_other == nullptr ) { log_fmt("\nAST::is_equal: Failed for parameter, other equivalent param is null\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" , curr->debug_str() ); return false; } if ( curr->Name != curr_other->Name ) { log_fmt( "\nAST::is_equal: Failed for parameter name check\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" "other's ast member: %S\n" , debug_str() , other->debug_str() , curr->debug_str() , curr_other->debug_str() ); return false; } if ( curr->ValueType && ! curr->ValueType->is_equal(curr_other->ValueType) ) { log_fmt( "\nAST::is_equal: Failed for parameter value type check\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" "other's ast member: %S\n" , debug_str() , other->debug_str() , curr->debug_str() , curr_other->debug_str() ); return false; } if ( curr->Value && ! curr->Value->is_equal(curr_other->Value) ) { log_fmt( "\nAST::is_equal: Failed for parameter value check\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" "other's ast member: %S\n" , debug_str() , other->debug_str() , curr->debug_str() , curr_other->debug_str() ); return false; } } curr = curr->Next; curr_other = curr_other->Next; } check_member_val( NumEntries ); return true; } check_member_str( Name ); check_member_ast( ValueType ); check_member_ast( Value ); check_member_ast( ArrExpr ); return true; } case Preprocess_Define: { check_member_str( Name ); check_member_content( Content ); return true; } case Preprocess_If: case Preprocess_IfDef: case Preprocess_IfNotDef: case Preprocess_ElIf: { check_member_content( Content ); return true; } case Preprocess_Include: case Preprocess_Pragma: { check_member_content( Content ); return true; } case Specifiers: { check_member_val( NumEntries ); check_member_str( Name ); for ( s32 idx = 0; idx < NumEntries; ++idx ) { check_member_val( ArrSpecs[ idx ] ); } return true; } case Template: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Params ); check_member_ast( Declaration ); return true; } case Typedef: { check_member_val( IsFunction ); check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Specs ); check_member_ast( UnderlyingType ); return true; } case Typename: { check_member_val( IsParamPack ); check_member_str( Name ); check_member_ast( Specs ); check_member_ast( ArrExpr ); return true; } case Union: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( Attributes ); check_member_ast( Body ); return true; } case Using: case Using_Namespace: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( UnderlyingType ); check_member_ast( Attributes ); return true; } case Variable: { check_member_val( ModuleFlags ); check_member_str( Name ); check_member_ast( ValueType ); check_member_ast( BitfieldSize ); check_member_ast( Value ); check_member_ast( Attributes ); check_member_ast( Specs ); check_member_ast( NextVar ); return true; } case Class_Body: case Enum_Body: case Export_Body: case Global_Body: case Namespace_Body: case Struct_Body: case Union_Body: { check_member_ast( Front ); check_member_ast( Back ); AST* curr = Front; AST* curr_other = other->Front; while ( curr != nullptr ) { if ( curr_other == nullptr ) { log_fmt("\nAST::is_equal: Failed for body, other equivalent param is null\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" , curr->debug_str() ); return false; } if ( ! curr->is_equal( curr_other ) ) { log_fmt( "\nAST::is_equal: Failed for body\n" "AST : %S\n" "Other: %S\n" "For ast member: %S\n" "other's ast member: %S\n" , debug_str() , other->debug_str() , curr->debug_str() , curr_other->debug_str() ); return false; } curr = curr->Next; curr_other = curr_other->Next; } check_member_val( NumEntries ); return true; } #undef check_member_val #undef check_member_str #undef check_member_ast } return true; } bool AST::validate_body() { using namespace ECode; #define CheckEntries( Unallowed_Types ) \ do \ { \ for ( Code entry : cast() ) \ { \ switch ( entry->Type ) \ { \ Unallowed_Types \ log_failure( "AST::validate_body: Invalid entry in body %s", entry.debug_str() ); \ return false; \ } \ } \ } \ while (0); switch ( Type ) { case Class_Body: CheckEntries( GEN_AST_BODY_CLASS_UNALLOWED_TYPES ); break; case Enum_Body: for ( Code entry : cast() ) { if ( entry->Type != Untyped ) { log_failure( "AST::validate_body: Invalid entry in enum body (needs to be untyped or comment) %s", entry.debug_str() ); return false; } } break; case Export_Body: CheckEntries( GEN_AST_BODY_CLASS_UNALLOWED_TYPES ); break; case Extern_Linkage: CheckEntries( GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES ); break; case Function_Body: CheckEntries( GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES ); break; case Global_Body: for (Code entry : cast()) { switch (entry->Type) { case Access_Public: case Access_Protected: case Access_Private: case PlatformAttributes: case Class_Body: case Enum_Body: case Execution: case Friend: case Function_Body: case Global_Body: case Namespace_Body: case Operator_Member: case Operator_Member_Fwd: case Parameters: case Specifiers: case Struct_Body: case Typename: log_failure("AST::validate_body: Invalid entry in body %s", entry.debug_str()); return false; } } break; case Namespace_Body: CheckEntries( GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES ); break; case Struct_Body: CheckEntries( GEN_AST_BODY_STRUCT_UNALLOWED_TYPES ); break; case Union_Body: for ( Code entry : Body->cast() ) { if ( entry->Type != Untyped ) { log_failure( "AST::validate_body: Invalid entry in union body (needs to be untyped or comment) %s", entry.debug_str() ); return false; } } break; default: log_failure( "AST::validate_body: Invalid this AST does not have a body %s", debug_str() ); return false; } return false; #undef CheckEntries } String Code::to_string() { if ( ast == nullptr ) { log_failure( "Code::to_string: Cannot convert code to string, AST is null!" ); return { nullptr }; } return rcast( AST*, ast )->to_string(); } String CodeAttributes::to_string() { return ast->Content.duplicate( GlobalAllocator ); } String CodeBody::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Untyped: case Execution: result.append( raw()->Content ); break; case Enum_Body: case Class_Body: case Extern_Linkage_Body: case Function_Body: case Global_Body: case Namespace_Body: case Struct_Body: case Union_Body: to_string( result ); break; case Export_Body: to_string_export( result ); break; } return result; } void CodeBody::to_string( String& result ) { Code curr = ast->Front; s32 left = ast->NumEntries; while ( left -- ) { result.append_fmt( "%S", curr.to_string() ); ++curr; } } void CodeBody::to_string_export( String& result ) { result.append_fmt( "export\n{\n" ); Code curr = *this; s32 left = ast->NumEntries; while ( left-- ) { result.append_fmt( "%S", curr.to_string() ); ++curr; } result.append_fmt( "};\n" ); } String CodeComment::to_string() { return ast->Content.duplicate( GlobalAllocator ); } String CodeConstructor::to_string() { String result = String::make( GlobalAllocator, "" ); switch (ast->Type) { using namespace ECode; case Constructor: to_string_def( result ); break; case Constructor_Fwd: to_string_fwd( result ); break; } return result; } void CodeConstructor::to_string_def( String& result ) { AST* ClassStructParent = ast->Parent->Parent; if (ClassStructParent) { result.append( ClassStructParent->Name ); } else { result.append( ast->Name ); } if ( ast->Params ) result.append_fmt( "( %S )", ast->Params.to_string() ); else result.append( "()" ); if ( ast->InitializerList ) result.append_fmt( " : %S", ast->InitializerList.to_string() ); if ( ast->InlineCmt ) result.append_fmt( " // %S", ast->InlineCmt->Content ); result.append_fmt( "\n{\n%S\n}\n", ast->Body.to_string() ); } void CodeConstructor::to_string_fwd( String& result ) { AST* ClassStructParent = ast->Parent->Parent; if (ClassStructParent) { result.append( ClassStructParent->Name ); } else { result.append( ast->Name ); } if ( ast->Params ) result.append_fmt( "( %S )", ast->Params.to_string() ); else result.append_fmt("()"); if (ast->Body) result.append_fmt( " = %S", ast->Body.to_string() ); if ( ast->InlineCmt ) result.append_fmt( "; // %S\n", ast->InlineCmt->Content ); else result.append( ";\n" ); } String CodeClass::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Class: to_string_def( result ); break; case Class_Fwd: to_string_fwd( result ); break; } return result; } void CodeClass::to_string_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append( "class " ); if ( ast->Attributes ) { result.append_fmt( "%S ", ast->Attributes.to_string() ); } if ( ast->ParentType ) { char const* access_level = to_str( ast->ParentAccess ); result.append_fmt( "%S : %s %S", ast->Name, access_level, ast->ParentType.to_string() ); CodeType interface = ast->ParentType->Next->cast< CodeType >(); if ( interface ) result.append( "\n" ); while ( interface ) { result.append_fmt( ", %S", interface.to_string() ); interface = interface->Next ? interface->Next->cast< CodeType >() : CodeType { nullptr }; } } else if ( ast->Name ) { result.append( ast->Name ); } if ( ast->InlineCmt ) { result.append_fmt( " // %S", ast->InlineCmt->Content ); } result.append_fmt( "\n{\n%S\n}", ast->Body.to_string() ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) result.append(";\n"); } void CodeClass::to_string_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "class %S %S", ast->Attributes.to_string(), ast->Name ); else result.append_fmt( "class %S", ast->Name ); // Check if it can have an end-statement if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) { if ( ast->InlineCmt ) result.append_fmt( "; // %S\n", ast->InlineCmt->Content ); else result.append(";\n"); } } String CodeDefine::to_string() { return String::fmt_buf( GlobalAllocator, "#define %S %S\n", ast->Name, ast->Content ); } void CodeDefine::to_string( String& result ) { result.append_fmt( "#define %S %S\n", ast->Name, ast->Content ); } String CodeDestructor::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Destructor: to_string_def( result ); break; case Destructor_Fwd: to_string_fwd( result ); break; } return result; } void CodeDestructor::to_string_def( String& result ) { if ( ast->Name ) { result.append_fmt( "%S()", ast->Name ); } else if ( ast->Specs ) { if ( ast->Specs.has( ESpecifier::Virtual ) ) result.append_fmt( "virtual ~%S()", ast->Parent->Name ); else result.append_fmt( "~%S()", ast->Parent->Name ); } else result.append_fmt( "~%S()", ast->Parent->Name ); result.append_fmt( "\n{\n%S\n}\n", ast->Body.to_string() ); } void CodeDestructor::to_string_fwd( String& result ) { if ( ast->Specs ) { if ( ast->Specs.has( ESpecifier::Virtual ) ) result.append_fmt( "virtual ~%S();\n", ast->Parent->Name ); else result.append_fmt( "~%S()", ast->Parent->Name ); if ( ast->Specs.has( ESpecifier::Pure ) ) result.append( " = 0;" ); else if (ast->Body) result.append_fmt( " = %S;", ast->Body.to_string() ); } else result.append_fmt( "~%S();", ast->Parent->Name ); if ( ast->InlineCmt ) result.append_fmt( " %S", ast->InlineCmt->Content ); else result.append("\n"); } String CodeEnum::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Enum: to_string_def( result ); break; case Enum_Fwd: to_string_fwd( result ); break; case Enum_Class: to_string_class_def( result ); break; case Enum_Class_Fwd: to_string_class_fwd( result ); break; } return result; } void CodeEnum::to_string_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes || ast->UnderlyingType ) { result.append( "enum " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->UnderlyingType ) result.append_fmt( "%S : %S\n{\n%S\n}" , ast->Name , ast->UnderlyingType.to_string() , ast->Body.to_string() ); else result.append_fmt( "%S\n{\n%S\n}", ast->Name, ast->Body.to_string() ); } else result.append_fmt( "enum %S\n{\n%S\n}", ast->Name, ast->Body.to_string() ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) result.append(";\n"); } void CodeEnum::to_string_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); result.append_fmt( "enum %S : %S", ast->Name, ast->UnderlyingType.to_string() ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) { if ( ast->InlineCmt ) result.append_fmt("; %S", ast->InlineCmt->Content ); else result.append(";\n"); } } void CodeEnum::to_string_class_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes || ast->UnderlyingType ) { result.append( "enum class " ); if ( ast->Attributes ) { result.append_fmt( "%S ", ast->Attributes.to_string() ); } if ( ast->UnderlyingType ) { result.append_fmt( "%S : %S\n{\n%S\n}", ast->Name, ast->UnderlyingType.to_string(), ast->Body.to_string() ); } else { result.append_fmt( "%S\n{\n%S\n}", ast->Name, ast->Body.to_string() ); } } else { result.append_fmt( "enum class %S\n{\n%S\n}", ast->Body.to_string() ); } if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) result.append(";\n"); } void CodeEnum::to_string_class_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append( "enum class " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); result.append_fmt( "%S : %S", ast->Name, ast->UnderlyingType.to_string() ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) { if ( ast->InlineCmt ) result.append_fmt("; %S", ast->InlineCmt->Content ); else result.append(";\n"); } } String CodeExec::to_string() { return ast->Content.duplicate( GlobalAllocator ); } void CodeExtern::to_string( String& result ) { if ( ast->Body ) result.append_fmt( "extern \"%S\"\n{\n%S\n}\n", ast->Name, ast->Body.to_string() ); else result.append_fmt( "extern \"%S\"\n{}\n", ast->Name ); } String CodeInclude::to_string() { return String::fmt_buf( GlobalAllocator, "#include %S\n", ast->Content ); } void CodeInclude::to_string( String& result ) { result.append_fmt( "#include %S\n", ast->Content ); } String CodeFriend::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeFriend::to_string( String& result ) { result.append_fmt( "friend %S", ast->Declaration->to_string() ); if ( ast->Declaration->Type != ECode::Function && result[ result.length() - 1 ] != ';' ) { result.append( ";" ); } if ( ast->InlineCmt ) result.append_fmt(" %S", ast->InlineCmt->Content ); else result.append("\n"); } String CodeFn::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Function: to_string_def( result ); break; case Function_Fwd: to_string_fwd( result ); break; } return result; } void CodeFn::to_string_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export" ); if ( ast->Attributes ) result.append_fmt( " %S ", ast->Attributes.to_string() ); bool prefix_specs = false; if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); prefix_specs = true; } } } if ( ast->Attributes || prefix_specs ) result.append( "\n" ); if ( ast->ReturnType ) result.append_fmt( "%S %S(", ast->ReturnType.to_string(), ast->Name ); else result.append_fmt( "%S(", ast->Name ); if ( ast->Params ) result.append_fmt( "%S)", ast->Params.to_string() ); else result.append( ")" ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } result.append_fmt( "\n{\n%S\n}\n", ast->Body.to_string() ); } void CodeFn::to_string_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); b32 prefix_specs = false; if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) || ! (spec != ESpecifier::Pure) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); prefix_specs = true; } } } if ( ast->Attributes || prefix_specs ) { result.append("\n" ); } if ( ast->ReturnType ) result.append_fmt( "%S %S(", ast->ReturnType.to_string(), ast->Name ); else result.append_fmt( "%S(", ast->Name ); if ( ast->Params ) result.append_fmt( "%S)", ast->Params.to_string() ); else result.append( ")" ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } if ( ast->Specs && ast->Specs.has( ESpecifier::Pure ) >= 0 ) result.append( " = 0;" ); else if (ast->Body) result.append_fmt( " = %S;", ast->Body.to_string() ); if ( ast->InlineCmt ) result.append_fmt( "; %S", ast->InlineCmt->Content ); else result.append( ";\n" ); } String CodeModule::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeModule::to_string( String& result ) { if (((u32(ModuleFlag::Export) & u32(ast->ModuleFlags)) == u32(ModuleFlag::Export))) result.append("export "); if (((u32(ModuleFlag::Import) & u32(ast->ModuleFlags)) == u32(ModuleFlag::Import))) result.append("import "); result.append_fmt( "%S;\n", ast->Name ); } String CodeNS::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeNS::to_string( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append_fmt( "namespace %S\n{\n%S\n}\n", ast->Name , ast->Body.to_string() ); } String CodeOperator::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Operator: case Operator_Member: to_string_def( result ); break; case Operator_Fwd: case Operator_Member_Fwd: to_string_fwd( result ); break; } return result; } void CodeOperator::to_string_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } if ( ast->Attributes || ast->Specs ) { result.append("\n" ); } if ( ast->ReturnType ) result.append_fmt( "%S %S (", ast->ReturnType.to_string(), ast->Name ); if ( ast->Params ) result.append_fmt( "%S)", ast->Params.to_string() ); else result.append( ")" ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } result.append_fmt( "\n{\n%S\n}\n" , ast->Body.to_string() ); } void CodeOperator::to_string_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "%S\n", ast->Attributes.to_string() ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } if ( ast->Attributes || ast->Specs ) { result.append("\n" ); } result.append_fmt( "%S %S (", ast->ReturnType.to_string(), ast->Name ); if ( ast->Params ) result.append_fmt( "%S)", ast->Params.to_string() ); else result.append_fmt( ")" ); if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } } if ( ast->InlineCmt ) result.append_fmt( "; %S", ast->InlineCmt->Content ); else result.append( ";\n" ); } String CodeOpCast::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Operator_Cast: to_string_def( result ); break; case Operator_Cast_Fwd: to_string_fwd( result ); break; } return result; } void CodeOpCast::to_string_def( String& result ) { if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( "%*s ", spec_str.Len, spec_str.Ptr ); } } if ( ast->Name && ast->Name.length() ) result.append_fmt( "%Soperator %S()", ast->Name, ast->ValueType.to_string() ); else result.append_fmt( "operator %S()", ast->ValueType.to_string() ); for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %.*s", spec_str.Len, spec_str.Ptr ); } } result.append_fmt( "\n{\n%S\n}\n", ast->Body.to_string() ); return; } if ( ast->Name && ast->Name.length() ) result.append_fmt("%Soperator %S()\n{\n%S\n}\n", ast->Name, ast->ValueType.to_string(), ast->Body.to_string() ); else result.append_fmt("operator %S()\n{\n%S\n}\n", ast->ValueType.to_string(), ast->Body.to_string() ); } void CodeOpCast::to_string_fwd( String& result ) { if ( ast->Specs ) { for ( SpecifierT spec : ast->Specs ) { if ( ! ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( "%*s ", spec_str.Len, spec_str.Ptr ); } } result.append_fmt( "operator %S()", ast->ValueType.to_string() ); for ( SpecifierT spec : ast->Specs ) { if ( ESpecifier::is_trailing( spec ) ) { StrC spec_str = ESpecifier::to_str( spec ); result.append_fmt( " %*s", spec_str.Len, spec_str.Ptr ); } } if ( ast->InlineCmt ) result.append_fmt( "; %S", ast->InlineCmt->Content ); else result.append( ";\n" ); return; } if ( ast->InlineCmt ) result.append_fmt("operator %S(); %S", ast->ValueType.to_string() ); else result.append_fmt("operator %S();\n", ast->ValueType.to_string() ); } String CodeParam::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeParam::to_string( String& result ) { if ( ast->Macro ) { // Related to parsing: ( , ... ) result.append( ast->Macro.ast->Content ); // Could also be: ( , ... ) } if ( ast->Name ) { if ( ast->ValueType.ast == nullptr ) result.append_fmt( " %S", ast->Name ); else result.append_fmt( " %S %S", ast->ValueType.to_string(), ast->Name ); } else if ( ast->ValueType ) result.append_fmt( " %S", ast->ValueType.to_string() ); if ( ast->PostNameMacro ) { result.append_fmt(" %S", ast->PostNameMacro.to_string() ); } if ( ast->Value ) result.append_fmt( " = %S", ast->Value.to_string() ); if ( ast->NumEntries - 1 > 0 ) { for ( CodeParam param : ast->Next ) { result.append_fmt( ", %S", param.to_string() ); } } } String CodePreprocessCond::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Preprocess_If: to_string_if( result ); break; case Preprocess_IfDef: to_string_ifdef( result ); break; case Preprocess_IfNotDef: to_string_ifndef( result ); break; case Preprocess_ElIf: to_string_elif( result ); break; case Preprocess_Else: to_string_else( result ); break; case Preprocess_EndIf: to_string_endif( result ); break; } return result; } void CodePreprocessCond::to_string_if( String& result ) { result.append_fmt( "#if %S\n", ast->Content ); } void CodePreprocessCond::to_string_ifdef( String& result ) { result.append_fmt( "#ifdef %S\n", ast->Content ); } void CodePreprocessCond::to_string_ifndef( String& result ) { result.append_fmt( "#ifndef %S\n", ast->Content ); } void CodePreprocessCond::to_string_elif( String& result ) { result.append_fmt( "#elif %S\n", ast->Content ); } void CodePreprocessCond::to_string_else( String& result ) { result.append_fmt( "#else\n" ); } void CodePreprocessCond::to_string_endif( String& result ) { result.append_fmt( "#endif\n" ); } String CodePragma::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodePragma::to_string( String& result ) { result.append_fmt( "#pragma %S\n", ast->Content ); } String CodeSpecifiers::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeSpecifiers::to_string( String& result ) { s32 idx = 0; s32 left = ast->NumEntries; while ( left-- ) { StrC spec = ESpecifier::to_str( ast->ArrSpecs[idx] ); result.append_fmt( "%.*s ", spec.Len, spec.Ptr ); idx++; } } String CodeStruct::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Struct: to_string_def( result ); break; case Struct_Fwd: to_string_fwd( result ); break; } return result; } void CodeStruct::to_string_def( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append( "struct " ); if ( ast->Attributes ) { result.append_fmt( "%S ", ast->Attributes.to_string() ); } if ( ast->ParentType ) { char const* access_level = to_str( ast->ParentAccess ); result.append_fmt( "%S : %s %S", ast->Name, access_level, ast->ParentType.to_string() ); CodeType interface = ast->ParentType->Next->cast< CodeType >(); if ( interface ) result.append( "\n" ); while ( interface ) { result.append_fmt( ", %S", interface.to_string() ); interface = interface->Next ? interface->Next->cast< CodeType >() : CodeType { nullptr }; } } else if ( ast->Name ) { result.append( ast->Name ); } if ( ast->InlineCmt ) { result.append_fmt( " // %S", ast->InlineCmt->Content ); } result.append_fmt( "\n{\n%S\n}", ast->Body.to_string() ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) result.append(";\n"); } void CodeStruct::to_string_fwd( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "struct %S %S", ast->Attributes.to_string(), ast->Name ); else result.append_fmt( "struct %S", ast->Name ); if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) { if ( ast->InlineCmt ) result.append_fmt("; %S", ast->InlineCmt->Content ); else result.append(";\n"); } } String CodeTemplate::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeTemplate::to_string( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Params ) result.append_fmt( "template< %S >\n%S", ast->Params.to_string(), ast->Declaration.to_string() ); else result.append_fmt( "template<>\n%S", ast->Declaration.to_string() ); } String CodeTypedef::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeTypedef::to_string( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append( "typedef "); // Determines if the typedef is a function typename if ( ast->UnderlyingType->ReturnType ) result.append( ast->UnderlyingType.to_string() ); else result.append_fmt( "%S %S", ast->UnderlyingType.to_string(), ast->Name ); if ( ast->UnderlyingType->Type == ECode::Typename && ast->UnderlyingType->ArrExpr ) { result.append_fmt( "[ %S ];", ast->UnderlyingType->ArrExpr->to_string() ); AST* next_arr_expr = ast->UnderlyingType->ArrExpr->Next; while ( next_arr_expr ) { result.append_fmt( "[ %S ];", next_arr_expr->to_string() ); next_arr_expr = next_arr_expr->Next; } } else { result.append( ";" ); } if ( ast->InlineCmt ) result.append_fmt(" %S", ast->InlineCmt->Content); else result.append("\n"); } String CodeType::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeType::to_string( String& result ) { #if defined(GEN_USE_NEW_TYPENAME_PARSING) if ( ast->ReturnType && ast->Params ) { if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); else { if ( ast->Specs ) result.append_fmt( "%S ( %S ) ( %S ) %S", ast->ReturnType.to_string(), ast->Name, ast->Params.to_string(), ast->Specs.to_string() ); else result.append_fmt( "%S ( %S ) ( %S )", ast->ReturnType.to_string(), ast->Name, ast->Params.to_string() ); } break; } #else if ( ast->ReturnType && ast->Params ) { if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); else { if ( ast->Specs ) result.append_fmt( "%S %S ( %S ) %S", ast->ReturnType.to_string(), ast->Name, ast->Params.to_string(), ast->Specs.to_string() ); else result.append_fmt( "%S %S ( %S )", ast->ReturnType.to_string(), ast->Name, ast->Params.to_string() ); } return; } #endif if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->Specs ) result.append_fmt( "%S %S", ast->Name, ast->Specs.to_string() ); else result.append_fmt( "%S", ast->Name ); if ( ast->IsParamPack ) result.append("..."); } String CodeUnion::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeUnion::to_string( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); result.append( "union " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->Name ) { result.append_fmt( "%S\n{\n%S\n}" , ast->Name , ast->Body.to_string() ); } else { // Anonymous union result.append_fmt( "\n{\n%S\n}" , ast->Body.to_string() ); } if ( ast->Parent.ast == nullptr || ( ast->Parent->Type != ECode::Typedef && ast->Parent->Type != ECode::Variable ) ) result.append(";\n"); } String CodeUsing::to_string() { String result = String::make( GlobalAllocator, "" ); switch ( ast->Type ) { using namespace ECode; case Using: to_string( result ); break; case Using_Namespace: to_string_ns( result ); break; } return result; } void CodeUsing::to_string( String& result ) { if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes ) result.append_fmt( "%S ", ast->Attributes.to_string() ); if ( ast->UnderlyingType ) { result.append_fmt( "using %S = %S", ast->Name, ast->UnderlyingType.to_string() ); if ( ast->UnderlyingType->ArrExpr ) { result.append_fmt( "[ %S ]", ast->UnderlyingType->ArrExpr.to_string() ); AST* next_arr_expr = ast->UnderlyingType->ArrExpr->Next; while ( next_arr_expr ) { result.append_fmt( "[ %S ]", next_arr_expr->to_string() ); next_arr_expr = next_arr_expr->Next; } } result.append( ";" ); } else result.append_fmt( "using %S;", ast->Name ); if ( ast->InlineCmt ) result.append_fmt(" %S\n", ast->InlineCmt->Content ); else result.append("\n"); } void CodeUsing::to_string_ns( String& result ) { if ( ast->InlineCmt ) result.append_fmt( "using namespace $S; %S", ast->Name, ast->InlineCmt->Content ); else result.append_fmt( "using namespace %s;\n", ast->Name ); } String CodeVar::to_string() { String result = String::make( GlobalAllocator, "" ); to_string( result ); return result; } void CodeVar::to_string( String& result ) { if ( ast->Parent && ast->Parent->Type == ECode::Variable ) { // Its a comma-separated variable ( a NextVar ) if ( ast->Specs ) result.append_fmt( "%S ", ast->Specs.to_string() ); result.append( ast->Name ); if ( ast->ValueType->ArrExpr ) { result.append_fmt( "[ %S ]", ast->ValueType->ArrExpr.to_string() ); AST* next_arr_expr = ast->ValueType->ArrExpr->Next; while ( next_arr_expr ) { result.append_fmt( "[ %S ]", next_arr_expr->to_string() ); next_arr_expr = next_arr_expr->Next; } } if ( ast->Value ) { if ( ast->VarConstructorInit ) result.append_fmt( "( %S ", ast->Value.to_string() ); else result.append_fmt( " = %S", ast->Value.to_string() ); } // Keep the chain going... if ( ast->NextVar ) result.append_fmt( ", %S", ast->NextVar.to_string() ); if ( ast->VarConstructorInit ) result.append( " )"); return; } if ( bitfield_is_equal( u32, ast->ModuleFlags, ModuleFlag::Export )) result.append( "export " ); if ( ast->Attributes || ast->Specs ) { if ( ast->Attributes ) result.append_fmt( "%S ", ast->Specs.to_string() ); if ( ast->Specs ) result.append_fmt( "%S\n", ast->Specs.to_string() ); result.append_fmt( "%S %S", ast->ValueType.to_string(), ast->Name ); if ( ast->ValueType->ArrExpr ) { result.append_fmt( "[ %S ]", ast->ValueType->ArrExpr.to_string() ); AST* next_arr_expr = ast->ValueType->ArrExpr->Next; while ( next_arr_expr ) { result.append_fmt( "[ %S ]", next_arr_expr->to_string() ); next_arr_expr = next_arr_expr->Next; } } if ( ast->BitfieldSize ) result.append_fmt( " : %S", ast->BitfieldSize.to_string() ); if ( ast->Value ) { if ( ast->VarConstructorInit ) result.append_fmt( "( %S ", ast->Value.to_string() ); else result.append_fmt( " = %S", ast->Value.to_string() ); } if ( ast->NextVar ) result.append_fmt( ", %S", ast->NextVar.to_string() ); if ( ast->VarConstructorInit ) result.append( " )"); if ( ast->InlineCmt ) result.append_fmt("; %S", ast->InlineCmt->Content); else result.append( ";\n" ); return; } if ( ast->BitfieldSize ) result.append_fmt( "%S %S : %S", ast->ValueType.to_string(), ast->Name, ast->BitfieldSize.to_string() ); else if ( ast->ValueType->ArrExpr ) { result.append_fmt( "%S %S[ %S ]", ast->ValueType.to_string(), ast->Name, ast->ValueType->ArrExpr.to_string() ); AST* next_arr_expr = ast->ValueType->ArrExpr->Next; while ( next_arr_expr ) { result.append_fmt( "[ %S ]", next_arr_expr->to_string() ); next_arr_expr = next_arr_expr->Next; } } else result.append_fmt( "%S %S", ast->ValueType.to_string(), ast->Name ); if ( ast->Value ) { if ( ast->VarConstructorInit ) result.append_fmt( "( %S ", ast->Value.to_string() ); else result.append_fmt( " = %S", ast->Value.to_string() ); } if ( ast->NextVar ) result.append_fmt( ", %S", ast->NextVar.to_string() ); if ( ast->VarConstructorInit ) result.append( " )"); result.append( ";" ); if ( ast->InlineCmt ) result.append_fmt(" %S", ast->InlineCmt->Content); else result.append("\n"); } #pragma endregion AST #pragma region Interface namespace parser { internal void init(); internal void deinit(); } internal void* Global_Allocator_Proc( void* allocator_data, AllocType type, ssize size, ssize alignment, void* old_memory, ssize old_size, u64 flags ) { Arena* last = & Global_AllocatorBuckets.back(); switch ( type ) { case EAllocation_ALLOC: { if ( ( last->TotalUsed + size ) > last->TotalSize ) { Arena bucket = Arena::init_from_allocator( heap(), Global_BucketSize ); if ( bucket.PhysicalStart == nullptr ) GEN_FATAL( "Failed to create bucket for Global_AllocatorBuckets"); if ( ! Global_AllocatorBuckets.append( bucket ) ) GEN_FATAL( "Failed to append bucket to Global_AllocatorBuckets"); last = & Global_AllocatorBuckets.back(); } return alloc_align( * last, size, alignment ); } case EAllocation_FREE: { // Doesn't recycle. } break; case EAllocation_FREE_ALL: { // Memory::cleanup instead. } break; case EAllocation_RESIZE: { if ( last->TotalUsed + size > last->TotalSize ) { Arena bucket = Arena::init_from_allocator( heap(), Global_BucketSize ); if ( bucket.PhysicalStart == nullptr ) GEN_FATAL( "Failed to create bucket for Global_AllocatorBuckets"); if ( ! Global_AllocatorBuckets.append( bucket ) ) GEN_FATAL( "Failed to append bucket to Global_AllocatorBuckets"); last = & Global_AllocatorBuckets.back(); } void* result = alloc_align( last->Backing, size, alignment ); if ( result != nullptr && old_memory != nullptr ) { mem_copy( result, old_memory, old_size ); } return result; } } return nullptr; } internal void define_constants() { Code::Global = make_code(); Code::Global->Name = get_cached_string( txt("Global Code") ); Code::Global->Content = Code::Global->Name; Code::Invalid = make_code(); Code::Invalid.set_global(); t_empty = (CodeType) make_code(); t_empty->Type = ECode::Typename; t_empty->Name = get_cached_string( txt("") ); t_empty.set_global(); access_private = make_code(); access_private->Type = ECode::Access_Private; access_private->Name = get_cached_string( txt("private:\n") ); access_private.set_global(); access_protected = make_code(); access_protected->Type = ECode::Access_Protected; access_protected->Name = get_cached_string( txt("protected:\n") ); access_protected.set_global(); access_public = make_code(); access_public->Type = ECode::Access_Public; access_public->Name = get_cached_string( txt("public:\n") ); access_public.set_global(); attrib_api_export = def_attributes( code(GEN_API_Export_Code)); attrib_api_export.set_global(); attrib_api_import = def_attributes( code(GEN_API_Import_Code)); attrib_api_import.set_global(); module_global_fragment = make_code(); module_global_fragment->Type = ECode::Untyped; module_global_fragment->Name = get_cached_string( txt("module;") ); module_global_fragment->Content = module_global_fragment->Name; module_global_fragment.set_global(); module_private_fragment = make_code(); module_private_fragment->Type = ECode::Untyped; module_private_fragment->Name = get_cached_string( txt("module : private;") ); module_private_fragment->Content = module_private_fragment->Name; module_private_fragment.set_global(); fmt_newline = make_code(); fmt_newline->Type = ECode::NewLine; fmt_newline.set_global(); pragma_once = (CodePragma) make_code(); pragma_once->Type = ECode::Preprocess_Pragma; pragma_once->Name = get_cached_string( txt("once") ); pragma_once->Content = pragma_once->Name; pragma_once.set_global(); param_varadic = (CodeType) make_code(); param_varadic->Type = ECode::Parameters; param_varadic->Name = get_cached_string( txt("...") ); param_varadic->ValueType = t_empty; param_varadic.set_global(); preprocess_else = (CodePreprocessCond) make_code(); preprocess_else->Type = ECode::Preprocess_Else; preprocess_else.set_global(); preprocess_endif = (CodePreprocessCond) make_code(); preprocess_endif->Type = ECode::Preprocess_EndIf; preprocess_endif.set_global(); # define def_constant_code_type( Type_ ) \ t_##Type_ = def_type( name(Type_) ); \ t_##Type_.set_global(); def_constant_code_type( auto ); def_constant_code_type( void ); def_constant_code_type( int ); def_constant_code_type( bool ); def_constant_code_type( char ); def_constant_code_type( wchar_t ); def_constant_code_type( class ); def_constant_code_type( typename ); #ifdef GEN_DEFINE_LIBRARY_CODE_CONSTANTS t_b32 = def_type( name(b32) ); def_constant_code_type( s8 ); def_constant_code_type( s16 ); def_constant_code_type( s32 ); def_constant_code_type( s64 ); def_constant_code_type( u8 ); def_constant_code_type( u16 ); def_constant_code_type( u32 ); def_constant_code_type( u64 ); def_constant_code_type( ssize ); def_constant_code_type( usize ); def_constant_code_type( f32 ); def_constant_code_type( f64 ); #endif # undef def_constant_code_type # define def_constant_spec( Type_, ... ) \ spec_##Type_ = def_specifiers( num_args(__VA_ARGS__), __VA_ARGS__); \ spec_##Type_.set_global(); # pragma push_macro("forceinline") # pragma push_macro("global") # pragma push_macro("internal") # pragma push_macro("local_persist") # pragma push_macro("neverinline") # undef forceinline # undef global # undef internal # undef local_persist # undef neverinline def_constant_spec( const, ESpecifier::Const ); def_constant_spec( consteval, ESpecifier::Consteval ); def_constant_spec( constexpr, ESpecifier::Constexpr ); def_constant_spec( constinit, ESpecifier::Constinit ); def_constant_spec( extern_linkage, ESpecifier::External_Linkage ); def_constant_spec( final, ESpecifier::Final ); def_constant_spec( forceinline, ESpecifier::ForceInline ); def_constant_spec( global, ESpecifier::Global ); def_constant_spec( inline, ESpecifier::Inline ); def_constant_spec( internal_linkage, ESpecifier::Internal_Linkage ); def_constant_spec( local_persist, ESpecifier::Local_Persist ); def_constant_spec( mutable, ESpecifier::Mutable ); def_constant_spec( neverinline, ESpecifier::NeverInline ); def_constant_spec( noexcept, ESpecifier::NoExceptions ); def_constant_spec( override, ESpecifier::Override ); def_constant_spec( ptr, ESpecifier::Ptr ); def_constant_spec( pure, ESpecifier::Pure ) def_constant_spec( ref, ESpecifier::Ref ); def_constant_spec( register, ESpecifier::Register ); def_constant_spec( rvalue, ESpecifier::RValue ); def_constant_spec( static_member, ESpecifier::Static ); def_constant_spec( thread_local, ESpecifier::Thread_Local ); def_constant_spec( virtual, ESpecifier::Virtual ); def_constant_spec( volatile, ESpecifier::Volatile) spec_local_persist = def_specifiers( 1, ESpecifier::Local_Persist ); spec_local_persist.set_global(); # pragma pop_macro("forceinline") # pragma pop_macro("global") # pragma pop_macro("internal") # pragma pop_macro("local_persist") # pragma pop_macro("neverinline") # undef def_constant_spec } void init() { // Setup global allocator { GlobalAllocator = AllocatorInfo { & Global_Allocator_Proc, nullptr }; Global_AllocatorBuckets = Array::init_reserve( heap(), 128 ); if ( Global_AllocatorBuckets == nullptr ) GEN_FATAL( "Failed to reserve memory for Global_AllocatorBuckets"); Arena bucket = Arena::init_from_allocator( heap(), Global_BucketSize ); if ( bucket.PhysicalStart == nullptr ) GEN_FATAL( "Failed to create first bucket for Global_AllocatorBuckets"); Global_AllocatorBuckets.append( bucket ); } // Setup the arrays { CodePools = Array::init_reserve( Allocator_DataArrays, InitSize_DataArrays ); if ( CodePools == nullptr ) GEN_FATAL( "gen::init: Failed to initialize the CodePools array" ); StringArenas = Array::init_reserve( Allocator_DataArrays, InitSize_DataArrays ); if ( StringArenas == nullptr ) GEN_FATAL( "gen::init: Failed to initialize the StringArenas array" ); } // Setup the code pool and code entries arena. { Pool code_pool = Pool::init( Allocator_CodePool, CodePool_NumBlocks, sizeof(AST) ); if ( code_pool.PhysicalStart == nullptr ) GEN_FATAL( "gen::init: Failed to initialize the code pool" ); CodePools.append( code_pool ); LexArena = Arena::init_from_allocator( Allocator_Lexer, LexAllocator_Size ); Arena string_arena = Arena::init_from_allocator( Allocator_StringArena, SizePer_StringArena ); if ( string_arena.PhysicalStart == nullptr ) GEN_FATAL( "gen::init: Failed to initialize the string arena" ); StringArenas.append( string_arena ); } // Setup the hash tables { StringCache = StringTable::init( Allocator_StringTable ); if ( StringCache.Entries == nullptr ) GEN_FATAL( "gen::init: Failed to initialize the StringCache"); } // Preprocessor Defines PreprocessorDefines = Array::init_reserve( GlobalAllocator, kilobytes(1) ); define_constants(); parser::init(); } void deinit() { usize index = 0; usize left = CodePools.num(); do { Pool* code_pool = & CodePools[index]; code_pool->free(); index++; } while ( left--, left ); index = 0; left = StringArenas.num(); do { Arena* string_arena = & StringArenas[index]; string_arena->free(); index++; } while ( left--, left ); StringCache.destroy(); CodePools.free(); StringArenas.free(); LexArena.free(); PreprocessorDefines.free(); index = 0; left = Global_AllocatorBuckets.num(); do { Arena* bucket = & Global_AllocatorBuckets[ index ]; bucket->free(); index++; } while ( left--, left ); Global_AllocatorBuckets.free(); parser::deinit(); } void reset() { s32 index = 0; s32 left = CodePools.num(); do { Pool* code_pool = & CodePools[index]; code_pool->clear(); index++; } while ( left--, left ); index = 0; left = StringArenas.num(); do { Arena* string_arena = & StringArenas[index]; string_arena->TotalUsed = 0;; index++; } while ( left--, left ); StringCache.clear(); define_constants(); } AllocatorInfo get_string_allocator( s32 str_length ) { Arena* last = & StringArenas.back(); usize size_req = str_length + sizeof(String::Header) + sizeof(char*); if ( last->TotalUsed + ssize(size_req) > last->TotalSize ) { Arena new_arena = Arena::init_from_allocator( Allocator_StringArena, SizePer_StringArena ); if ( ! StringArenas.append( new_arena ) ) GEN_FATAL( "gen::get_string_allocator: Failed to allocate a new string arena" ); last = & StringArenas.back(); } return * last; } // Will either make or retrive a code string. StringCached get_cached_string( StrC str ) { s32 hash_length = str.Len > kilobytes(1) ? kilobytes(1) : str.Len; u64 key = crc32( str.Ptr, hash_length ); { StringCached* result = StringCache.get( key ); if ( result ) return * result; } String result = String::make( get_string_allocator( str.Len ), str ); StringCache.set( key, result ); return result; } // Used internally to retireve a Code object form the CodePool. Code make_code() { Pool* allocator = & CodePools.back(); if ( allocator->FreeList == nullptr ) { Pool code_pool = Pool::init( Allocator_CodePool, CodePool_NumBlocks, sizeof(AST) ); if ( code_pool.PhysicalStart == nullptr ) GEN_FATAL( "gen::make_code: Failed to allocate a new code pool - CodePool allcoator returned nullptr." ); if ( ! CodePools.append( code_pool ) ) GEN_FATAL( "gen::make_code: Failed to allocate a new code pool - CodePools failed to append new pool." ); allocator = & CodePools.back(); } Code result { rcast( AST*, alloc( * allocator, sizeof(AST) )) }; mem_set( result.ast, 0, sizeof(AST) ); // result->Type = ECode::Invalid; // result->Content = { nullptr }; // result->Prev = { nullptr }; // result->Next = { nullptr }; // result->Token = nullptr; // result->Parent = { nullptr }; // result->Name = { nullptr }; // result->Type = ECode::Invalid; // result->ModuleFlags = ModuleFlag::Invalid; // result->NumEntries = 0; return result; } void set_allocator_data_arrays( AllocatorInfo allocator ) { Allocator_DataArrays = allocator; } void set_allocator_code_pool( AllocatorInfo allocator ) { Allocator_CodePool = allocator; } void set_allocator_lexer( AllocatorInfo allocator ) { Allocator_Lexer = allocator; } void set_allocator_string_arena( AllocatorInfo allocator ) { Allocator_StringArena = allocator; } void set_allocator_string_table( AllocatorInfo allocator ) { Allocator_StringArena = allocator; } #pragma region Upfront enum class OpValidateResult : u32 { Fail, Global, Member }; OpValidateResult operator__validate( OperatorT op, CodeParam params_code, CodeType ret_type, CodeSpecifiers specifier ) { using namespace EOperator; if ( op == EOperator::Invalid ) { log_failure("gen::def_operator: op cannot be invalid"); return OpValidateResult::Fail; } #pragma region Helper Macros # define check_params() \ if ( ! params_code ) \ { \ log_failure("gen::def_operator: params is null and operator%s requires it", to_str(op)); \ return OpValidateResult::Fail; \ } \ if ( params_code->Type != ECode::Parameters ) \ { \ log_failure("gen::def_operator: params is not of Parameters type - %s", params_code.debug_str()); \ return OpValidateResult::Fail; \ } # define check_param_eq_ret() \ if ( ! is_member_symbol && ! params_code->ValueType.is_equal( ret_type) ) \ { \ log_failure("gen::def_operator: operator%s requires first parameter to equal return type\n" \ "param types: %s\n" \ "return type: %s", \ to_str(op).Ptr, \ params_code.debug_str(), \ ret_type.debug_str() \ ); \ return OpValidateResult::Fail; \ } #pragma endregion Helper Macros if ( ! ret_type ) { log_failure("gen::def_operator: ret_type is null but is required by operator%s", to_str(op)); } if ( ret_type->Type != ECode::Typename ) { log_failure("gen::def_operator: ret_type is not of typename type - %s", ret_type.debug_str()); return OpValidateResult::Fail; } bool is_member_symbol = false; switch ( op ) { # define specs( ... ) num_args( __VA_ARGS__ ), __VA_ARGS__ case Assign: check_params(); if ( params_code->NumEntries > 1 ) { log_failure("gen::def_operator: " "operator%s does not support non-member definition (more than one parameter provided) - %s", to_str(op), params_code.debug_str() ); return OpValidateResult::Fail; } is_member_symbol = true; break; case Assign_Add: case Assign_Subtract: case Assign_Multiply: case Assign_Divide: case Assign_Modulo: case Assign_BAnd: case Assign_BOr: case Assign_BXOr: case Assign_LShift: case Assign_RShift: check_params(); if ( params_code->NumEntries == 1 ) is_member_symbol = true; else check_param_eq_ret(); if (params_code->NumEntries > 2 ) { log_failure("gen::def_operator: operator%s may not be defined with more than two parametes - param count; %d\n%s" , to_str(op) , params_code->NumEntries , params_code.debug_str() ); return OpValidateResult::Fail; } break; case Increment: case Decrement: // If its not set, it just means its a prefix member op. if ( params_code ) { if ( params_code->Type != ECode::Parameters ) { log_failure("gen::def_operator: operator%s params code provided is not of Parameters type - %s" , to_str(op) , params_code.debug_str() ); return OpValidateResult::Fail; } switch ( params_code->NumEntries ) { case 1: if ( params_code->ValueType.is_equal( t_int ) ) is_member_symbol = true; else check_param_eq_ret(); break; case 2: check_param_eq_ret(); if ( ! params_code.get(1).is_equal( t_int ) ) { log_failure("gen::def_operator: " "operator%s requires second parameter of non-member definition to be int for post-decrement", to_str(op) ); return OpValidateResult::Fail; } break; default: log_failure("gen::def_operator: operator%s recieved unexpected number of parameters recived %d instead of 0-2" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } } break; case Unary_Plus: case Unary_Minus: if ( ! params_code ) is_member_symbol = true; else { if ( params_code->Type != ECode::Parameters ) { log_failure("gen::def_operator: params is not of Parameters type - %s", params_code.debug_str()); return OpValidateResult::Fail; } if ( params_code->ValueType.is_equal( ret_type ) ) { log_failure("gen::def_operator: " "operator%s is non-member symbol yet first paramter does not equal return type\n" "param type: %s\n" "return type: %s\n" , params_code.debug_str() , ret_type.debug_str() ); return OpValidateResult::Fail; } if ( params_code->NumEntries > 1 ) { log_failure("gen::def_operator: operator%s may not have more than one parameter - param count: %d" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } } break; case BNot: { // Some compilers let you do this... #if 0 if ( ! ret_type.is_equal( t_bool) ) { log_failure( "gen::def_operator: return type is not a boolean - %s", params_code.debug_str() ); return OpValidateResult::Fail; } #endif if ( ! params_code ) is_member_symbol = true; else { if ( params_code->Type != ECode::Parameters ) { log_failure( "gen::def_operator: params is not of Parameters type - %s", params_code.debug_str() ); return OpValidateResult::Fail; } if ( params_code->NumEntries > 1 ) { log_failure( "gen::def_operator: operator%s may not have more than one parameter - param count: %d", to_str( op ), params_code->NumEntries ); return OpValidateResult::Fail; } } break; } case Add: case Subtract: case Multiply: case Divide: case Modulo: case BAnd: case BOr: case BXOr: case LShift: case RShift: check_params(); switch ( params_code->NumEntries ) { case 1: is_member_symbol = true; break; case 2: if ( ! params_code->ValueType.is_equal( ret_type ) ) { log_failure("gen::def_operator: " "operator%s is non-member symbol yet first paramter does not equal return type\n" "param type: %s\n" "return type: %s\n" , params_code.debug_str() , ret_type.debug_str() ); return OpValidateResult::Fail; } break; default: log_failure("gen::def_operator: operator%s recieved unexpected number of paramters recived %d instead of 0-2" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } break; case UnaryNot: if ( ! params_code ) is_member_symbol = true; else { if ( params_code->Type != ECode::Parameters ) { log_failure("gen::def_operator: params is not of Parameters type - %s", params_code.debug_str()); return OpValidateResult::Fail; } if ( params_code->NumEntries != 1 ) { log_failure("gen::def_operator: operator%s recieved unexpected number of paramters recived %d instead of 0-1" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } } if ( ! ret_type.is_equal( t_bool )) { log_failure("gen::def_operator: operator%s return type must be of type bool - %s" , to_str(op) , ret_type.debug_str() ); return OpValidateResult::Fail; } break; case LAnd: case LOr: case LEqual: case LNot: case Lesser: case Greater: case LesserEqual: case GreaterEqual: check_params(); switch ( params_code->NumEntries ) { case 1: is_member_symbol = true; break; case 2: break; default: log_failure("gen::def_operator: operator%s recieved unexpected number of paramters recived %d instead of 1-2" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } break; case Indirection: case AddressOf: case MemberOfPointer: if ( params_code && params_code->NumEntries > 1) { log_failure("gen::def_operator: operator%s recieved unexpected number of paramters recived %d instead of 0-1" , to_str(op) , params_code->NumEntries ); return OpValidateResult::Fail; } else { is_member_symbol = true; } break; case PtrToMemOfPtr: if ( params_code ) { log_failure("gen::def_operator: operator%s expects no paramters - %s", to_str(op), params_code.debug_str()); return OpValidateResult::Fail; } break; case Subscript: case FunctionCall: case Comma: check_params(); break; case New: case Delete: // This library doesn't support validating new and delete yet. break; # undef specs } return is_member_symbol ? OpValidateResult::Member : OpValidateResult::Global; # undef check_params # undef check_ret_type # undef check_param_eq_ret } #pragma region Helper Marcos // This snippet is used in nearly all the functions. #define name_check( Context_, Name_ ) \ { \ if ( Name_.Len <= 0 ) \ { \ log_failure( "gen::" stringize(Context_) ": Invalid name length provided - %d", Name_.Len ); \ return CodeInvalid; \ } \ \ if ( Name_.Ptr == nullptr ) \ { \ log_failure( "gen::" stringize(Context_) ": name is null" ); \ return CodeInvalid; \ } \ } #define null_check( Context_, Code_ ) \ if ( ! Code_ ) \ { \ log_failure( "gen::" stringize(Context_) ": " stringize(Code_) " provided is null" ); \ return CodeInvalid; \ } #define null_or_invalid_check( Context_, Code_ ) \ { \ if ( ! Code_ ) \ { \ log_failure( "gen::" stringize(Context_) ": " stringize(Code_) " provided is null" ); \ return CodeInvalid; \ } \ \ if ( Code_->is_invalid() ) \ { \ log_failure("gen::" stringize(Context_) ": " stringize(Code_) " provided is invalid" ); \ return CodeInvalid; \ } \ } #define not_implemented( Context_ ) \ log_failure( "gen::%s: This function is not implemented" ); \ return CodeInvalid; #pragma endregion Helper Marcos /* The implementaiton of the upfront constructors involves doing three things: * Validate the arguments given to construct the intended type of AST is valid. * Construct said AST type. * Lock the AST (set to readonly) and return the valid object. If any of the validation fails, it triggers a call to log_failure with as much info the give the user so that they can hopefully identify the issue without having to debug too much (at least they can debug though...) The largest of the functions is related to operator overload definitions. The library validates a good protion of their form and thus the argument processing for is quite a bit. */ CodeAttributes def_attributes( StrC content ) { if ( content.Len <= 0 || content.Ptr == nullptr ) { log_failure( "gen::def_attributes: Invalid attributes provided" ); return CodeInvalid; } Code result = make_code(); result->Type = ECode::PlatformAttributes; result->Name = get_cached_string( content ); result->Content = result->Name; return (CodeAttributes) result; } CodeComment def_comment( StrC content ) { if ( content.Len <= 0 || content.Ptr == nullptr ) { log_failure( "gen::def_comment: Invalid comment provided:" ); return CodeInvalid; } static char line[ MaxCommentLineLength ]; String cmt_formatted = String::make_reserve( GlobalAllocator, kilobytes(1) ); char const* end = content.Ptr + content.Len; char const* scanner = content.Ptr; s32 curr = 0; do { char const* next = scanner; s32 length = 0; while ( next != end && scanner[ length ] != '\n' ) { next = scanner + length; length++; } length++; str_copy( line, scanner, length ); cmt_formatted.append_fmt( "//%.*s", length, line ); mem_set( line, 0, MaxCommentLineLength ); scanner += length; } while ( scanner <= end ); if ( cmt_formatted.back() != '\n' ) cmt_formatted.append( "\n" ); Code result = make_code(); result->Type = ECode::Comment; result->Name = get_cached_string( cmt_formatted ); result->Content = result->Name; cmt_formatted.free(); return (CodeComment) result; } CodeConstructor def_constructor( CodeParam params, Code initializer_list, Code body ) { using namespace ECode; if ( params && params->Type != Parameters ) { log_failure("gen::def_constructor: params must be of Parameters type - %s", params.debug_str()); return CodeInvalid; } CodeConstructor result = (CodeConstructor) make_code(); if ( params ) { result->Params = params; } if ( initializer_list ) { result->InitializerList = initializer_list; } if ( body ) { switch ( body->Type ) { case Function_Body: case Untyped: break; default: log_failure("gen::def_constructor: body must be either of Function_Body or Untyped type - %s", body.debug_str()); return CodeInvalid; } result->Type = Constructor; result->Body = body; } else { result->Type = Constructor_Fwd; } return result; } CodeClass def_class( StrC name , Code body , CodeType parent, AccessSpec parent_access , CodeAttributes attributes , ModuleFlag mflags , CodeType* interfaces, s32 num_interfaces ) { using namespace ECode; name_check( def_class, name ); if ( attributes && attributes->Type != PlatformAttributes ) { log_failure( "gen::def_class: attributes was not a 'PlatformAttributes' type: %s", attributes.debug_str() ); return CodeInvalid; } if ( parent && ( parent->Type != Class && parent->Type != Struct && parent->Type != Typename && parent->Type != Untyped ) ) { log_failure( "gen::def_class: parent provided is not type 'Class', 'Struct', 'Typeanme', or 'Untyped': %s", parent.debug_str() ); return CodeInvalid; } CodeClass result = (CodeClass) make_code(); result->Name = get_cached_string( name ); result->ModuleFlags = mflags; if ( body ) { switch ( body->Type ) { case Class_Body: case Untyped: break; default: log_failure("gen::def_class: body must be either of Class_Body or Untyped type - %s", body.debug_str()); return CodeInvalid; } result->Type = Class; result->Body = body; result->Body->Parent = result; // TODO(Ed): Review this? } else { result->Type = Class_Fwd; } if ( attributes ) result->Attributes = attributes; if ( parent ) { result->ParentAccess = parent_access; result->ParentType = parent; } if ( interfaces ) { for (s32 idx = 0; idx < num_interfaces; idx++ ) { result.add_interface( interfaces[idx] ); } } return result; } CodeDefine def_define( StrC name, StrC content ) { using namespace ECode; name_check( def_define, name ); // Defines can be empty definitions #if 0 if ( content.Len <= 0 || content.Ptr == nullptr ) { log_failure( "gen::def_define: Invalid value provided" ); return CodeInvalid; } #endif CodeDefine result = (CodeDefine) make_code(); result->Type = Preprocess_Define; result->Name = get_cached_string( name ); if ( content.Len <= 0 || content.Ptr == nullptr ) { result->Content = get_cached_string( txt("") ); } else result->Content = get_cached_string( content ); return result; } CodeDestructor def_destructor( Code body, CodeSpecifiers specifiers ) { using namespace ECode; if ( specifiers && specifiers->Type != Specifiers ) { log_failure( "gen::def_destructor: specifiers was not a 'Specifiers' type: %s", specifiers.debug_str() ); return CodeInvalid; } CodeDestructor result = (CodeDestructor) make_code(); if ( specifiers ) result->Specs = specifiers; if ( body ) { switch ( body->Type ) { case Function_Body: case Untyped: break; default: log_failure("gen::def_destructor: body must be either of Function_Body or Untyped type - %s", body.debug_str()); return CodeInvalid; } result->Type = Destructor; result->Body = body; } else { result->Type = Destructor_Fwd; } return result; } CodeEnum def_enum( StrC name , Code body, CodeType type , EnumT specifier, CodeAttributes attributes , ModuleFlag mflags ) { using namespace ECode; name_check( def_enum, name ); if ( type && type->Type != Typename ) { log_failure( "gen::def_enum: enum underlying type provided was not of type Typename: %s", type.debug_str() ); return CodeInvalid; } if ( attributes && attributes->Type != PlatformAttributes ) { log_failure( "gen::def_enum: attributes was not a 'PlatformAttributes' type: %s", attributes.debug_str() ); return CodeInvalid; } CodeEnum result = (CodeEnum) make_code(); result->Name = get_cached_string( name ); result->ModuleFlags = mflags; if ( body ) { switch ( body->Type ) { case Enum_Body: case Untyped: break; default: log_failure( "gen::def_enum: body must be of Enum_Body or Untyped type %s", body.debug_str()); return CodeInvalid; } result->Type = specifier == EnumClass ? Enum_Class : Enum; result->Body = body; } else { result->Type = specifier == EnumClass ? Enum_Class_Fwd : Enum_Fwd; } if ( attributes ) result->Attributes = attributes; if ( type ) { result->UnderlyingType = type; } else if ( result->Type != Enum_Class_Fwd && result->Type != Enum_Fwd ) { log_failure( "gen::def_enum: enum forward declaration must have an underlying type" ); return CodeInvalid; } return result; } CodeExec def_execution( StrC content ) { if ( content.Len <= 0 || content.Ptr == nullptr ) { log_failure( "gen::def_execution: Invalid execution provided" ); return CodeInvalid; } Code result = make_code(); result->Type = ECode::Execution; result->Name = get_cached_string( content ); result->Content = result->Name; return (CodeExec) result; } CodeExtern def_extern_link( StrC name, Code body ) { using namespace ECode; name_check( def_extern_linkage, name ); null_check( def_extern_linkage, body ); if ( body->Type != Extern_Linkage_Body && body->Type != Untyped ) { log_failure("gen::def_extern_linkage: body is not of extern_linkage or untyped type %s", body->debug_str()); return CodeInvalid; } CodeExtern result = (CodeExtern)make_code(); result->Type = Extern_Linkage; result->Name = get_cached_string( name ); result->Body = body; return (CodeExtern) result; } CodeFriend def_friend( Code declaration ) { using namespace ECode; null_check( def_friend, declaration ); switch ( declaration->Type ) { case Class_Fwd: case Function_Fwd: case Operator_Fwd: case Struct_Fwd: case Class: case Function: case Operator: case Struct: break; default: log_failure("gen::def_friend: requires declartion to have class, function, operator, or struct - %s", declaration->debug_str()); return CodeInvalid; } CodeFriend result = (CodeFriend) make_code(); result->Type = Friend; result->Declaration = declaration; return result; } CodeFn def_function( StrC name , CodeParam params , CodeType ret_type, Code body , CodeSpecifiers specifiers, CodeAttributes attributes , ModuleFlag mflags ) { using namespace ECode; name_check( def_function, name ); if ( params && params->Type != Parameters ) { log_failure( "gen::def_function: params was not a `Parameters` type: %s", params.debug_str() ); return CodeInvalid; } if ( ret_type && ret_type->Type != Typename ) { log_failure( "gen::def_function: ret_type was not a Typename: %s", ret_type.debug_str() ); return CodeInvalid; } if ( specifiers && specifiers->Type != Specifiers ) { log_failure( "gen::def_function: specifiers was not a `Specifiers` type: %s", specifiers.debug_str() ); return CodeInvalid; } if ( attributes && attributes->Type != PlatformAttributes ) { log_failure( "gen::def_function: attributes was not a `PlatformAttributes` type: %s", attributes.debug_str() ); return CodeInvalid; } CodeFn result = (CodeFn) make_code(); result->Name = get_cached_string( name ); result->ModuleFlags = mflags; if ( body ) { switch ( body->Type ) { case Function_Body: case Execution: case Untyped: break; default: { log_failure("gen::def_function: body must be either of Function_Body, Execution, or Untyped type. %s", body->debug_str()); return CodeInvalid; } } result->Type = Function; result->Body = body; } else { result->Type = Function_Fwd; } if ( attributes ) result->Attributes = attributes; if ( specifiers ) result->Specs = specifiers; if ( ret_type ) { result->ReturnType = ret_type; } else { result->ReturnType = t_void; } if ( params ) result->Params = params; return result; } CodeInclude def_include( StrC path, bool foreign ) { if ( path.Len <= 0 || path.Ptr == nullptr ) { log_failure( "gen::def_include: Invalid path provided - %d" ); return CodeInvalid; } StrC content = foreign ? to_str( str_fmt_buf( "<%.*s>", path.Len, path.Ptr )) : to_str( str_fmt_buf( "\"%.*s\"", path.Len, path.Ptr )); Code result = make_code(); result->Type = ECode::Preprocess_Include; result->Name = get_cached_string( content ); result->Content = result->Name; return (CodeInclude) result; } CodeModule def_module( StrC name, ModuleFlag mflags ) { name_check( def_module, name ); Code result = make_code(); result->Type = ECode::Module; result->Name = get_cached_string( name ); result->Content = result->Name; result->ModuleFlags = mflags; return (CodeModule) result; } CodeNS def_namespace( StrC name, Code body, ModuleFlag mflags ) { using namespace ECode; name_check( def_namespace, name ); null_check( def_namespace, body ); if ( body->Type != Namespace_Body && body->Type != Untyped ) { log_failure("gen::def_namespace: body is not of namespace or untyped type %s", body.debug_str()); return CodeInvalid; } CodeNS result = (CodeNS) make_code(); result->Type = Namespace; result->Name = get_cached_string( name ); result->ModuleFlags = mflags; result->Body = body; return result; } CodeOperator def_operator( OperatorT op, StrC nspace , CodeParam params_code, CodeType ret_type, Code body , CodeSpecifiers specifiers, CodeAttributes attributes , ModuleFlag mflags ) { using namespace ECode; if ( attributes && attributes->Type != PlatformAttributes ) { log_failure( "gen::def_operator: PlatformAttributes was provided but its not of attributes type: %s", attributes.debug_str() ); return CodeInvalid; } if ( specifiers && specifiers->Type != Specifiers ) { log_failure( "gen::def_operator: Specifiers was provided but its not of specifiers type: %s", specifiers.debug_str() ); return CodeInvalid; } OpValidateResult check_result = operator__validate( op, params_code, ret_type, specifiers ); if ( check_result == OpValidateResult::Fail ) { return CodeInvalid; } char const* name = nullptr; StrC op_str = to_str( op ); if ( nspace.Len > 0 ) name = str_fmt_buf( "%.*soperator %.*s", nspace.Len, nspace.Ptr, op_str.Len, op_str.Ptr ); else name = str_fmt_buf( "operator %.*s", op_str.Len, op_str.Ptr ); CodeOperator result = (CodeOperator) make_code(); result->Name = get_cached_string( { str_len(name), name } ); result->ModuleFlags = mflags; result->Op = op; if ( body ) { switch ( body->Type ) { case Function_Body: case Execution: case Untyped: break; default: { log_failure("gen::def_operator: body must be either of Function_Body, Execution, or Untyped type. %s", body->debug_str()); return CodeInvalid; } } result->Type = check_result == OpValidateResult::Global ? Operator : Operator_Member; result->Body = body; } else { result->Type = check_result == OpValidateResult::Global ? Operator_Fwd : Operator_Member_Fwd; } if ( attributes ) result->Attributes = attributes; if ( specifiers ) result->Specs = specifiers; result->ReturnType = ret_type; if (params_code) result->Params = params_code; return result; } CodeOpCast def_operator_cast( CodeType type, Code body, CodeSpecifiers const_spec ) { using namespace ECode; null_check( def_operator_cast, type ); if ( type->Type != Typename ) { log_failure( "gen::def_operator_cast: type is not a typename - %s", type.debug_str() ); return CodeInvalid; } CodeOpCast result = (CodeOpCast) make_code(); if (body) { result->Type = Operator_Cast; if ( body->Type != Function_Body && body->Type != Execution ) { log_failure( "gen::def_operator_cast: body is not of function body or execution type - %s", body.debug_str() ); return CodeInvalid; } result->Body = body; } else { result->Type = Operator_Cast_Fwd; } if ( const_spec ) { result->Specs = const_spec; } result->ValueType = type; return result; } CodeParam def_param( CodeType type, StrC name, Code value ) { using namespace ECode; name_check( def_param, name ); null_check( def_param, type ); if ( type->Type != Typename ) { log_failure( "gen::def_param: type is not a typename - %s", type.debug_str() ); return CodeInvalid; } if ( value && value->Type != Untyped ) { log_failure( "gen::def_param: value is not untyped - %s", value.debug_str() ); return CodeInvalid; } CodeParam result = (CodeParam) make_code(); result->Type = Parameters; result->Name = get_cached_string( name ); result->ValueType = type; if ( value ) result->Value = value; result->NumEntries++; return result; } CodePragma def_pragma( StrC directive ) { using namespace ECode; if ( directive.Len <= 0 || directive.Ptr == nullptr ) { log_failure( "gen::def_comment: Invalid comment provided:" ); return CodeInvalid; } CodePragma result = (CodePragma) make_code(); result->Type = Preprocess_Pragma; result->Content = get_cached_string( directive ); return result; } CodePreprocessCond def_preprocess_cond( EPreprocessCond type, StrC expr ) { using namespace ECode; if ( expr.Len <= 0 || expr.Ptr == nullptr ) { log_failure( "gen::def_comment: Invalid comment provided:" ); return CodeInvalid; } CodePreprocessCond result = (CodePreprocessCond) make_code(); result->Content = get_cached_string( expr ); switch (type) { case EPreprocessCond::If: result->Type = Preprocess_If; break; case EPreprocessCond::IfDef: result->Type = Preprocess_IfDef; break; case EPreprocessCond::IfNotDef: result->Type = Preprocess_IfNotDef; break; case EPreprocessCond::ElIf: result->Type = Preprocess_ElIf; break; } return result; } CodeSpecifiers def_specifier( SpecifierT spec ) { CodeSpecifiers result = (CodeSpecifiers) make_code(); result->Type = ECode::Specifiers; result.append( spec ); return result; } CodeStruct def_struct( StrC name , Code body , CodeType parent, AccessSpec parent_access , CodeAttributes attributes , ModuleFlag mflags , CodeType* interfaces, s32 num_interfaces ) { using namespace ECode; if ( attributes && attributes->Type != PlatformAttributes ) { log_failure( "gen::def_struct: attributes was not a `PlatformAttributes` type - %s", attributes.debug_str() ); return CodeInvalid; } if ( parent && parent->Type != Typename ) { log_failure( "gen::def_struct: parent was not a `Struct` type - %s", parent.debug_str() ); return CodeInvalid; } if ( body && body->Type != Struct_Body ) { log_failure( "gen::def_struct: body was not a Struct_Body type - %s", body.debug_str() ); return CodeInvalid; } CodeStruct result = (CodeStruct) make_code(); result->ModuleFlags = mflags; if ( name ) result->Name = get_cached_string( name ); if ( body ) { result->Type = Struct; result->Body = body; } else { result->Type = Struct_Fwd; } if ( attributes ) result->Attributes = attributes; if ( parent ) { result->ParentAccess = parent_access; result->ParentType = parent; } if ( interfaces ) { for (s32 idx = 0; idx < num_interfaces; idx++ ) { result.add_interface( interfaces[idx] ); } } return result; } CodeTemplate def_template( CodeParam params, Code declaration, ModuleFlag mflags ) { null_check( def_template, declaration ); if ( params && params->Type != ECode::Parameters ) { log_failure( "gen::def_template: params is not of parameters type - %s", params.debug_str() ); return CodeInvalid; } switch (declaration->Type ) { case ECode::Class: case ECode::Function: case ECode::Struct: case ECode::Variable: case ECode::Using: break; default: log_failure( "gen::def_template: declaration is not of class, function, struct, variable, or using type - %s", declaration.debug_str() ); } CodeTemplate result = (CodeTemplate) make_code(); result->Type = ECode::Template; result->ModuleFlags = mflags; result->Params = params; result->Declaration = declaration; return result; } CodeType def_type( StrC name, Code arrayexpr, CodeSpecifiers specifiers, CodeAttributes attributes ) { name_check( def_type, name ); if ( attributes && attributes->Type != ECode::PlatformAttributes ) { log_failure( "gen::def_type: attributes is not of attributes type - %s", attributes.debug_str() ); return CodeInvalid; } if ( specifiers && specifiers->Type != ECode::Specifiers ) { log_failure( "gen::def_type: specifiers is not of specifiers type - %s", specifiers.debug_str() ); return CodeInvalid; } if ( arrayexpr && arrayexpr->Type != ECode::Untyped ) { log_failure( "gen::def_type: arrayexpr is not of untyped type - %s", arrayexpr->debug_str() ); return CodeInvalid; } CodeType result = (CodeType) make_code(); result->Name = get_cached_string( name ); result->Type = ECode::Typename; if ( attributes ) result->Attributes = attributes; if ( specifiers ) result->Specs = specifiers; if ( arrayexpr ) result->ArrExpr = arrayexpr; return result; } CodeTypedef def_typedef( StrC name, Code type, CodeAttributes attributes, ModuleFlag mflags ) { using namespace ECode; null_check( def_typedef, type ); switch ( type->Type ) { case Class: case Class_Fwd: case Enum: case Enum_Fwd: case Enum_Class: case Enum_Class_Fwd: case Function_Fwd: case Struct: case Struct_Fwd: case Union: case Typename: break; default: log_failure( "gen::def_typedef: type was not a Class, Enum, Function Forward, Struct, Typename, or Union - %s", type.debug_str() ); return CodeInvalid; } if ( attributes && attributes->Type != ECode::PlatformAttributes ) { log_failure( "gen::def_typedef: attributes was not a PlatformAttributes - %s", attributes.debug_str() ); return CodeInvalid; } // Registering the type. Code registered_type = def_type( name ); if ( ! registered_type ) { log_failure( "gen::def_typedef: failed to register type" ); return CodeInvalid; } CodeTypedef result = (CodeTypedef) make_code(); result->Type = ECode::Typedef; result->ModuleFlags = mflags; result->UnderlyingType = type; if ( name.Len <= 0 ) { if (type->Type != Untyped) { log_failure( "gen::def_typedef: name was empty and type was not untyped (indicating its a function typedef) - %s", type.debug_str() ); return CodeInvalid; } result->Name = get_cached_string( type->Name ); result->IsFunction = true; } else { result->Name = get_cached_string( name ); result->IsFunction = false; } return result; } CodeUnion def_union( StrC name, Code body, CodeAttributes attributes, ModuleFlag mflags ) { null_check( def_union, body ); if ( body->Type != ECode::Union_Body ) { log_failure( "gen::def_union: body was not a Union_Body type - %s", body.debug_str() ); return CodeInvalid; } if ( attributes && attributes->Type != ECode::PlatformAttributes ) { log_failure( "gen::def_union: attributes was not a PlatformAttributes type - %s", attributes.debug_str() ); return CodeInvalid; } CodeUnion result = (CodeUnion) make_code(); result->ModuleFlags = mflags; result->Type = ECode::Union; if ( name.Ptr ) result->Name = get_cached_string( name ); result->Body = body; if ( attributes ) result->Attributes = attributes; return result; } CodeUsing def_using( StrC name, CodeType type , CodeAttributes attributes , ModuleFlag mflags ) { name_check( def_using, name ); null_check( def_using, type ); Code register_type = def_type( name ); if ( ! register_type ) { log_failure( "gen::def_using: failed to register type" ); return CodeInvalid; } if ( attributes && attributes->Type != ECode::PlatformAttributes ) { log_failure( "gen::def_using: attributes was not a PlatformAttributes type - %s", attributes.debug_str() ); return CodeInvalid; } CodeUsing result = (CodeUsing) make_code(); result->Name = get_cached_string( name ); result->ModuleFlags = mflags; result->Type = ECode::Using; result->UnderlyingType = type; if ( attributes ) result->Attributes = attributes; return result; } CodeUsing def_using_namespace( StrC name ) { name_check( def_using_namespace, name ); Code result = make_code(); result->Name = get_cached_string( name ); result->Content = result->Name; result->Type = ECode::Using_Namespace; return (CodeUsing) result; } CodeVar def_variable( CodeType type, StrC name, Code value , CodeSpecifiers specifiers, CodeAttributes attributes , ModuleFlag mflags ) { name_check( def_variable, name ); null_check( def_variable, type ); if ( attributes && attributes->Type != ECode::PlatformAttributes ) { log_failure( "gen::def_variable: attributes was not a `PlatformAttributes` type - %s", attributes.debug_str() ); return CodeInvalid; } if ( specifiers && specifiers->Type != ECode::Specifiers ) { log_failure( "gen::def_variable: specifiers was not a `Specifiers` type - %s", specifiers.debug_str() ); return CodeInvalid; } if ( type->Type != ECode::Typename ) { log_failure( "gen::def_variable: type was not a Typename - %s", type.debug_str() ); return CodeInvalid; } if ( value && value->Type != ECode::Untyped ) { log_failure( "gen::def_variable: value was not a `Untyped` type - %s", value.debug_str() ); return CodeInvalid; } CodeVar result = (CodeVar) make_code(); result->Name = get_cached_string( name ); result->Type = ECode::Variable; result->ModuleFlags = mflags; result->ValueType = type; if ( attributes ) result->Attributes = attributes; if ( specifiers ) result->Specs = specifiers; if ( value ) result->Value = value; return result; } #pragma region Helper Macros for def_**_body functions #define def_body_start( Name_ ) \ using namespace ECode; \ \ if ( num <= 0 ) \ { \ log_failure("gen::" stringize(Name_) ": num cannot be zero or negative"); \ return CodeInvalid; \ } #define def_body_code_array_start( Name_ ) \ using namespace ECode; \ \ if ( num <= 0 ) \ { \ log_failure("gen::" stringize(Name_) ": num cannot be zero or negative"); \ return CodeInvalid; \ } \ \ if ( codes == nullptr ) \ { \ log_failure("gen::" stringize(Name_)" : Provided a null array of codes"); \ return CodeInvalid; \ } #pragma endregion Helper Macros for def_**_body functions CodeBody def_class_body( s32 num, ... ) { def_body_start( def_class_body ); CodeBody result = ( CodeBody )make_code(); result->Type = Class_Body; va_list va; va_start( va, num ); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_class_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_CLASS_UNALLOWED_TYPES log_failure("gen::" "def_class_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_class_body( s32 num, Code* codes ) { def_body_code_array_start( def_class_body ); CodeBody result = (CodeBody) make_code(); result->Type = Function_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_class_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_CLASS_UNALLOWED_TYPES log_failure("gen::" "def_class_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_enum_body( s32 num, ... ) { def_body_start( def_enum_body ); CodeBody result = (CodeBody) make_code(); result->Type = Enum_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if ( ! entry ) { log_failure("gen::def_enum_body: Provided a null entry"); return CodeInvalid; } if ( entry->Type != Untyped && entry->Type != Comment ) { log_failure("gen::def_enum_body: Entry type is not allowed - %s. Must be of untyped or comment type.", entry.debug_str() ); return CodeInvalid; } result.append( entry ); } while ( num--, num > 0 ); va_end(va); return (CodeBody) result; } CodeBody def_enum_body( s32 num, Code* codes ) { def_body_code_array_start( def_enum_body ); CodeBody result = (CodeBody) make_code(); result->Type = Enum_Body; do { Code entry = *codes; if ( ! entry ) { log_failure("gen::def_enum_body: Provided a null entry"); return CodeInvalid; } if ( entry->Type != Untyped && entry->Type != Comment ) { log_failure("gen::def_enum_body: Entry type is not allowed: %s", entry.debug_str() ); return CodeInvalid; } result.append( entry ); } while ( codes++, num--, num > 0 ); return result; } CodeBody def_export_body( s32 num, ... ) { def_body_start( def_export_body ); CodeBody result = (CodeBody) make_code(); result->Type = Export_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_export_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_EXPORT_UNALLOWED_TYPES log_failure("gen::" "def_export_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_export_body( s32 num, Code* codes ) { def_body_code_array_start( def_export_body ); CodeBody result = (CodeBody) make_code(); result->Type = Export_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_export_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_EXPORT_UNALLOWED_TYPES log_failure("gen::" "def_export_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_extern_link_body( s32 num, ... ) { def_body_start( def_extern_linkage_body ); CodeBody result = (CodeBody) make_code(); result->Type = Extern_Linkage_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_extern_linkage_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES log_failure("gen::" "def_extern_linkage_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_extern_link_body( s32 num, Code* codes ) { def_body_code_array_start( def_extern_linkage_body ); CodeBody result = (CodeBody) make_code(); result->Type = Extern_Linkage_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_extern_linkage_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_EXTERN_LINKAGE_UNALLOWED_TYPES log_failure("gen::" "def_extern_linkage_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_function_body( s32 num, ... ) { def_body_start( def_function_body ); CodeBody result = (CodeBody) make_code(); result->Type = Function_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" stringize(def_function_body) ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES log_failure("gen::" stringize(def_function_body) ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_function_body( s32 num, Code* codes ) { def_body_code_array_start( def_function_body ); CodeBody result = (CodeBody) make_code(); result->Type = Function_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_function_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_FUNCTION_UNALLOWED_TYPES log_failure("gen::" "def_function_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_global_body( s32 num, ... ) { def_body_start( def_global_body ); CodeBody result = (CodeBody) make_code(); result->Type = Global_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_global_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { case Global_Body: result.append( entry.cast() ) ; continue; GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES log_failure("gen::" "def_global_body" ": Entry type is not allowed: %s", entry.debug_str()); return (*Code::Invalid.ast); default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_global_body( s32 num, Code* codes ) { def_body_code_array_start( def_global_body ); CodeBody result = (CodeBody) make_code(); result->Type = Global_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_global_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { case Global_Body: result.append( entry.cast() ) ; continue; GEN_AST_BODY_GLOBAL_UNALLOWED_TYPES log_failure("gen::" "def_global_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_namespace_body( s32 num, ... ) { def_body_start( def_namespace_body ); CodeBody result = (CodeBody) make_code(); result->Type = Namespace_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_namespace_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES log_failure("gen::" "def_namespace_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_namespace_body( s32 num, Code* codes ) { def_body_code_array_start( def_namespace_body ); CodeBody result = (CodeBody) make_code(); result->Type = Global_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_namespace_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_NAMESPACE_UNALLOWED_TYPES log_failure("gen::" "def_namespace_body" ": Entry type is not allowed: %s", entry.debug_str() ); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeParam def_params( s32 num, ... ) { def_body_start( def_params ); va_list va; va_start(va, num); Code_POD pod = va_arg(va, Code_POD); CodeParam param = pcast( CodeParam, pod ); null_check( def_params, param ); if ( param->Type != Parameters ) { log_failure( "gen::def_params: param %d is not a Parameters", num - num + 1 ); return CodeInvalid; } CodeParam result = (CodeParam) param.duplicate(); while ( -- num ) { pod = va_arg(va, Code_POD); param = pcast( CodeParam, pod ); if ( param->Type != Parameters ) { log_failure( "gen::def_params: param %d is not a Parameters", num - num + 1 ); return CodeInvalid; } result.append( param ); } va_end(va); return result; } CodeParam def_params( s32 num, CodeParam* codes ) { def_body_code_array_start( def_params ); # define check_current() \ if ( current.ast == nullptr ) \ { \ log_failure("gen::def_params: Provide a null code in codes array"); \ return CodeInvalid; \ } \ \ if (current->Type != Parameters ) \ { \ log_failure("gen::def_params: Code in coes array is not of paramter type - %s", current.debug_str() ); \ return CodeInvalid; \ } CodeParam current = (CodeParam) codes->duplicate(); check_current(); CodeParam result = (CodeParam) make_code(); result->Name = current->Name; result->Type = current->Type; result->ValueType = current->ValueType; while( codes++, current = * codes, num--, num > 0 ) { check_current(); result.append( current ); } # undef check_current return result; } CodeSpecifiers def_specifiers( s32 num, ... ) { if ( num <= 0 ) { log_failure("gen::def_specifiers: num cannot be zero or less"); return CodeInvalid; } if ( num > AST::ArrSpecs_Cap ) { log_failure("gen::def_specifiers: num of speciifers to define AST larger than AST specicifier capacity - %d", num); return CodeInvalid; } CodeSpecifiers result = (CodeSpecifiers) make_code(); result->Type = ECode::Specifiers; va_list va; va_start(va, num); do { SpecifierT type = (SpecifierT)va_arg(va, int); result.append( type ); } while ( --num, num ); va_end(va); return result; } CodeSpecifiers def_specifiers( s32 num, SpecifierT* specs ) { if ( num <= 0 ) { log_failure("gen::def_specifiers: num cannot be zero or less"); return CodeInvalid; } if ( num > AST::ArrSpecs_Cap ) { log_failure("gen::def_specifiers: num of speciifers to define AST larger than AST specicifier capacity - %d", num); return CodeInvalid; } CodeSpecifiers result = (CodeSpecifiers) make_code(); result->Type = ECode::Specifiers; s32 idx = 0; do { result.append( specs[idx] ); idx++; } while ( --num, num ); return result; } CodeBody def_struct_body( s32 num, ... ) { def_body_start( def_struct_body ); CodeBody result = (CodeBody) make_code(); result->Type = Struct_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast(Code, pod); if (!entry) { log_failure("gen::" "def_struct_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_STRUCT_UNALLOWED_TYPES log_failure("gen::" "def_struct_body" ": Entry type is not allowed: %s", entry.debug_str()); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); va_end(va); return result; } CodeBody def_struct_body( s32 num, Code* codes ) { def_body_code_array_start( def_struct_body ); CodeBody result = (CodeBody) make_code(); result->Type = Struct_Body; do { Code entry = *codes; codes++; if (!entry) { log_failure("gen::" "def_struct_body" ": Provided an null entry"); return CodeInvalid; } switch (entry->Type) { GEN_AST_BODY_STRUCT_UNALLOWED_TYPES log_failure("gen::" "def_struct_body" ": Entry type is not allowed: %s", entry.debug_str() ); return CodeInvalid; default: break; } result.append(entry); } while (num--, num > 0); return result; } CodeBody def_union_body( s32 num, ... ) { def_body_start( def_union_body ); CodeBody result = (CodeBody) make_code(); result->Type = Union_Body; va_list va; va_start(va, num); do { Code_POD pod = va_arg(va, Code_POD); Code entry = pcast( Code, pod ); if ( ! entry ) { log_failure("gen::def_union_body: Provided a null entry"); return CodeInvalid; } if ( entry->Type != Untyped && entry->Type != Comment ) { log_failure("gen::def_union_body: Entry type is not allowed - %s. Must be of untyped or comment type.", entry.debug_str() ); return CodeInvalid; } result.append( entry ); } while ( num--, num > 0 ); va_end(va); return result; } CodeBody def_union_body( s32 num, CodeUnion* codes ) { def_body_code_array_start( def_union_body ); CodeBody result = (CodeBody) make_code(); result->Type = Union_Body; do { Code entry = *codes; if ( ! entry ) { log_failure("gen::def_union_body: Provided a null entry"); return CodeInvalid; } if ( entry->Type != Untyped && entry->Type != Comment ) { log_failure("gen::def_union_body: Entry type is not allowed: %s", entry.debug_str() ); return CodeInvalid; } result.append( entry ); } while ( codes++, num--, num > 0 ); return (CodeBody) result; } # undef name_check # undef null_check # undef null_or_invalid_check # undef def_body_start # undef def_body_code_array_start #pragma endregion Upfront #pragma region Parsing namespace parser { namespace ETokType { #define GEN_DEFINE_ATTRIBUTE_TOKENS Entry( Attribute_API_Export, "GEN_API_Export_Code" ) Entry( Attribute_API_Import, "GEN_API_Import_Code" ) enum Type : u32 { Invalid, Access_Private, Access_Protected, Access_Public, Access_MemberSymbol, Access_StaticSymbol, Ampersand, Ampersand_DBL, Assign_Classifer, Attribute_Open, Attribute_Close, BraceCurly_Open, BraceCurly_Close, BraceSquare_Open, BraceSquare_Close, Capture_Start, Capture_End, Comment, Comment_End, Comment_Start, Char, Comma, Decl_Class, Decl_GNU_Attribute, Decl_MSVC_Attribute, Decl_Enum, Decl_Extern_Linkage, Decl_Friend, Decl_Module, Decl_Namespace, Decl_Operator, Decl_Struct, Decl_Template, Decl_Typedef, Decl_Using, Decl_Union, Identifier, Module_Import, Module_Export, NewLine, Number, Operator, Preprocess_Hash, Preprocess_Define, Preprocess_If, Preprocess_IfDef, Preprocess_IfNotDef, Preprocess_ElIf, Preprocess_Else, Preprocess_EndIf, Preprocess_Include, Preprocess_Pragma, Preprocess_Content, Preprocess_Macro, Preprocess_Unsupported, Spec_Alignas, Spec_Const, Spec_Consteval, Spec_Constexpr, Spec_Constinit, Spec_Explicit, Spec_Extern, Spec_Final, Spec_ForceInline, Spec_Global, Spec_Inline, Spec_Internal_Linkage, Spec_LocalPersist, Spec_Mutable, Spec_NeverInline, Spec_Override, Spec_Static, Spec_ThreadLocal, Spec_Volatile, Spec_Virtual, Star, Statement_End, StaticAssert, String, Type_Typename, Type_Unsigned, Type_Signed, Type_Short, Type_Long, Type_bool, Type_char, Type_int, Type_double, Type_MS_int8, Type_MS_int16, Type_MS_int32, Type_MS_int64, Type_MS_W64, Varadic_Argument, __Attributes_Start, Attribute_API_Export, Attribute_API_Import, NumTokens }; inline StrC to_str( Type type ) { local_persist StrC lookup[] { { sizeof( "__invalid__" ), "__invalid__" }, { sizeof( "private" ), "private" }, { sizeof( "protected" ), "protected" }, { sizeof( "public" ), "public" }, { sizeof( "." ), "." }, { sizeof( "::" ), "::" }, { sizeof( "&" ), "&" }, { sizeof( "&&" ), "&&" }, { sizeof( ":" ), ":" }, { sizeof( "[[" ), "[[" }, { sizeof( "]]" ), "]]" }, { sizeof( "{" ), "{" }, { sizeof( "}" ), "}" }, { sizeof( "[" ), "[" }, { sizeof( "]" ), "]" }, { sizeof( "(" ), "(" }, { sizeof( ")" ), ")" }, { sizeof( "__comment__" ), "__comment__" }, { sizeof( "__comment_end__" ), "__comment_end__" }, { sizeof( "__comment_start__" ), "__comment_start__" }, { sizeof( "__character__" ), "__character__" }, { sizeof( "," ), "," }, { sizeof( "class" ), "class" }, { sizeof( "__attribute__" ), "__attribute__" }, { sizeof( "__declspec" ), "__declspec" }, { sizeof( "enum" ), "enum" }, { sizeof( "extern" ), "extern" }, { sizeof( "friend" ), "friend" }, { sizeof( "module" ), "module" }, { sizeof( "namespace" ), "namespace" }, { sizeof( "operator" ), "operator" }, { sizeof( "struct" ), "struct" }, { sizeof( "template" ), "template" }, { sizeof( "typedef" ), "typedef" }, { sizeof( "using" ), "using" }, { sizeof( "union" ), "union" }, { sizeof( "__identifier__" ), "__identifier__" }, { sizeof( "import" ), "import" }, { sizeof( "export" ), "export" }, { sizeof( "__new_line__" ), "__new_line__" }, { sizeof( "__number__" ), "__number__" }, { sizeof( "__operator__" ), "__operator__" }, { sizeof( "#" ), "#" }, { sizeof( "define" ), "define" }, { sizeof( "if" ), "if" }, { sizeof( "ifdef" ), "ifdef" }, { sizeof( "ifndef" ), "ifndef" }, { sizeof( "elif" ), "elif" }, { sizeof( "else" ), "else" }, { sizeof( "endif" ), "endif" }, { sizeof( "include" ), "include" }, { sizeof( "pragma" ), "pragma" }, { sizeof( "__macro_content__" ), "__macro_content__" }, { sizeof( "__macro__" ), "__macro__" }, { sizeof( "__unsupported__" ), "__unsupported__" }, { sizeof( "alignas" ), "alignas" }, { sizeof( "const" ), "const" }, { sizeof( "consteval" ), "consteval" }, { sizeof( "constexpr" ), "constexpr" }, { sizeof( "constinit" ), "constinit" }, { sizeof( "explicit" ), "explicit" }, { sizeof( "extern" ), "extern" }, { sizeof( "final" ), "final" }, { sizeof( "forceinline" ), "forceinline" }, { sizeof( "global" ), "global" }, { sizeof( "inline" ), "inline" }, { sizeof( "internal" ), "internal" }, { sizeof( "local_persist" ), "local_persist" }, { sizeof( "mutable" ), "mutable" }, { sizeof( "neverinline" ), "neverinline" }, { sizeof( "override" ), "override" }, { sizeof( "static" ), "static" }, { sizeof( "thread_local" ), "thread_local" }, { sizeof( "volatile" ), "volatile" }, { sizeof( "virtual" ), "virtual" }, { sizeof( "*" ), "*" }, { sizeof( ";" ), ";" }, { sizeof( "static_assert" ), "static_assert" }, { sizeof( "__string__" ), "__string__" }, { sizeof( "typename" ), "typename" }, { sizeof( "unsigned" ), "unsigned" }, { sizeof( "signed" ), "signed" }, { sizeof( "short" ), "short" }, { sizeof( "long" ), "long" }, { sizeof( "bool" ), "bool" }, { sizeof( "char" ), "char" }, { sizeof( "int" ), "int" }, { sizeof( "double" ), "double" }, { sizeof( "__int8" ), "__int8" }, { sizeof( "__int16" ), "__int16" }, { sizeof( "__int32" ), "__int32" }, { sizeof( "__int64" ), "__int64" }, { sizeof( "_W64" ), "_W64" }, { sizeof( "..." ), "..." }, { sizeof( "__attrib_start__" ), "__attrib_start__" }, { sizeof( "GEN_API_Export_Code" ), "GEN_API_Export_Code" }, { sizeof( "GEN_API_Import_Code" ), "GEN_API_Import_Code" }, }; return lookup[type]; } inline Type to_type( StrC str ) { local_persist u32 keymap[NumTokens]; do_once_start for ( u32 index = 0; index < NumTokens; index++ ) { StrC enum_str = to_str( (Type)index ); keymap[index] = crc32( enum_str.Ptr, enum_str.Len - 1 ); } do_once_end u32 hash = crc32( str.Ptr, str.Len ); for ( u32 index = 0; index < NumTokens; index++ ) { if ( keymap[index] == hash ) return (Type)index; } return Invalid; } } // namespace ETokType using TokType = ETokType::Type; } // namespace parser namespace parser { enum TokFlags : u32 { TF_Operator = bit(0), TF_Assign = bit(1), TF_Preprocess = bit(2), TF_Preprocess_Cond = bit(3), TF_Attribute = bit(6), TF_AccessOperator = bit( 7 ), TF_AccessSpecifier = bit( 8 ), TF_Specifier = bit( 9 ), TF_EndDefinition = bit( 10 ), // Either ; or } TF_Formatting = bit( 11 ), TF_Literal = bit( 12 ), TF_Null = 0, }; struct Token { char const* Text; sptr Length; TokType Type; s32 Line; s32 Column; u32 Flags; operator bool() { return Text && Length && Type != TokType::Invalid; } operator StrC() { return { Length, Text }; } bool is_access_operator() { return bitfield_is_equal( u32, Flags, TF_AccessOperator ); } bool is_access_specifier() { return bitfield_is_equal( u32, Flags, TF_AccessSpecifier ); } bool is_attribute() { return bitfield_is_equal( u32, Flags, TF_Attribute ); } bool is_operator() { return bitfield_is_equal( u32, Flags, TF_Operator ); } bool is_preprocessor() { return bitfield_is_equal( u32, Flags, TF_Preprocess ); } bool is_preprocess_cond() { return bitfield_is_equal( u32, Flags, TF_Preprocess_Cond ); } bool is_specifier() { return bitfield_is_equal( u32, Flags, TF_Specifier ); } bool is_end_definition() { return bitfield_is_equal( u32, Flags, TF_EndDefinition ); } AccessSpec to_access_specifier() { return scast(AccessSpec, Type); } String to_string() { String result = String::make_reserve( GlobalAllocator, kilobytes(4) ); StrC type_str = ETokType::to_str( Type ); result.append_fmt( "Line: %d Column: %d, Type: %.*s Content: %.*s" , Line, Column , type_str.Len, type_str.Ptr , Length, Text ); return result; } }; constexpr Token NullToken { nullptr, 0, TokType::Invalid, false, 0, TF_Null }; struct TokArray { Array Arr; s32 Idx; bool __eat( TokType type ); Token& current( bool skip_formatting = true ) { if ( skip_formatting ) { while ( Arr[Idx].Type == TokType::NewLine || Arr[Idx].Type == TokType::Comment ) Idx++; } return Arr[Idx]; } Token& previous( bool skip_formatting = false ) { s32 idx = this->Idx; if ( skip_formatting ) { while ( Arr[idx].Type == TokType::NewLine ) idx--; return Arr[idx]; } return Arr[idx - 1]; } Token& next( bool skip_formatting = false ) { s32 idx = this->Idx; if ( skip_formatting ) { while ( Arr[idx].Type == TokType::NewLine ) idx++; return Arr[idx + 1]; } return Arr[idx + 1]; } Token& operator []( s32 idx ) { return Arr[idx]; } }; global Arena_256KB defines_map_arena; global HashTable defines; global Array Tokens; #define current ( * scanner ) #define move_forward() \ { \ if ( current == '\n' ) \ { \ line++; \ column = 1; \ } \ else \ { \ column++; \ } \ left--; \ scanner++; \ } #define SkipWhitespace() \ while ( left && char_is_space( current ) ) \ { \ move_forward(); \ } #define end_line() \ do \ { \ while ( left && current == ' ' ) \ { \ move_forward(); \ } \ if ( left && current == '\r' ) \ { \ move_forward(); \ move_forward(); \ } \ else if ( left && current == '\n' ) \ { \ move_forward(); \ } \ } \ while (0) enum { Lex_Continue, Lex_ReturnNull, }; forceinline s32 lex_preprocessor_directive( StrC& content , s32& left , char const*& scanner , s32& line , s32& column , HashTable& defines , Token& token ) { char const* hash = scanner; Tokens.append( { hash, 1, TokType::Preprocess_Hash, line, column, TF_Preprocess } ); move_forward(); SkipWhitespace(); token.Text = scanner; while (left && ! char_is_space(current) ) { move_forward(); token.Length++; } token.Type = ETokType::to_type( token ); bool is_preprocessor = token.Type >= TokType::Preprocess_Define && token.Type <= TokType::Preprocess_Pragma; if ( ! is_preprocessor ) { token.Type = TokType::Preprocess_Unsupported; // Its an unsupported directive, skip it s32 within_string = false; s32 within_char = false; while ( left ) { if ( current == '"' && ! within_char ) within_string ^= true; if ( current == '\'' && ! within_string ) within_char ^= true; if ( current == '\\' && ! within_string && ! within_char ) { move_forward(); token.Length++; if ( current == '\r' ) { move_forward(); token.Length++; } if ( current == '\n' ) { move_forward(); token.Length++; continue; } else { log_failure( "gen::Parser::lex: Invalid escape sequence '\\%c' (%d, %d)" " in preprocessor directive (%d, %d)\n%.100s" , current, line, column , token.Line, token.Column, token.Text ); break; } } if ( current == '\r' ) { move_forward(); token.Length++; } if ( current == '\n' ) { move_forward(); token.Length++; break; } move_forward(); token.Length++; } token.Length = token.Length + token.Text - hash; token.Text = hash; Tokens.append( token ); return Lex_Continue; // Skip found token, its all handled here. } if ( token.Type == TokType::Preprocess_Else || token.Type == TokType::Preprocess_EndIf ) { token.Flags |= TF_Preprocess_Cond; Tokens.append( token ); end_line(); return Lex_Continue; } else if ( token.Type >= TokType::Preprocess_If && token.Type <= TokType::Preprocess_ElIf ) { token.Flags |= TF_Preprocess_Cond; } Tokens.append( token ); SkipWhitespace(); if ( token.Type == TokType::Preprocess_Define ) { Token name = { scanner, 0, TokType::Identifier, line, column, TF_Preprocess }; name.Text = scanner; name.Length = 1; move_forward(); while ( left && ( char_is_alphanumeric(current) || current == '_' ) ) { move_forward(); name.Length++; } if ( left && current == '(' ) { move_forward(); name.Length++; } Tokens.append( name ); u64 key = crc32( name.Text, name.Length ); defines.set( key, name ); } Token preprocess_content = { scanner, 0, TokType::Preprocess_Content, line, column, TF_Preprocess }; if ( token.Type == TokType::Preprocess_Include ) { preprocess_content.Type = TokType::String; if ( current != '"' && current != '<' ) { String directive_str = String::fmt_buf( GlobalAllocator, "%.*s", min( 80, left + preprocess_content.Length ), token.Text ); log_failure( "gen::Parser::lex: Expected '\"' or '<' after #include, not '%c' (%d, %d)\n%s" , current , preprocess_content.Line , preprocess_content.Column , directive_str.Data ); return Lex_ReturnNull; } move_forward(); preprocess_content.Length++; while ( left && current != '"' && current != '>' ) { move_forward(); preprocess_content.Length++; } move_forward(); preprocess_content.Length++; if ( current == '\r' && scanner[1] == '\n' ) { move_forward(); move_forward(); } else if ( current == '\n' ) { move_forward(); } Tokens.append( preprocess_content ); return Lex_Continue; // Skip found token, its all handled here. } s32 within_string = false; s32 within_char = false; // SkipWhitespace(); while ( left ) { if ( current == '"' && ! within_char ) within_string ^= true; if ( current == '\'' && ! within_string ) within_char ^= true; if ( current == '\\' && ! within_string && ! within_char ) { move_forward(); preprocess_content.Length++; if ( current == '\r' ) { move_forward(); preprocess_content.Length++; } if ( current == '\n' ) { move_forward(); preprocess_content.Length++; continue; } else { String directive_str = String::make_length( GlobalAllocator, token.Text, token.Length ); String content_str = String::fmt_buf( GlobalAllocator, "%.*s", min( 400, left + preprocess_content.Length ), preprocess_content.Text ); log_failure( "gen::Parser::lex: Invalid escape sequence '\\%c' (%d, %d)" " in preprocessor directive '%s' (%d, %d)\n%s" , current, line, column , directive_str, preprocess_content.Line, preprocess_content.Column , content_str ); break; } } if ( current == '\r' ) { move_forward(); } if ( current == '\n' ) { move_forward(); break; } move_forward(); preprocess_content.Length++; } Tokens.append( preprocess_content ); return Lex_Continue; // Skip found token, its all handled here. } forceinline void lex_found_token( StrC& content , s32& left , char const*& scanner , s32& line , s32& column , HashTable& defines , Token& token ) { if ( token.Type != TokType::Invalid ) { Tokens.append( token ); return; } TokType type = ETokType::to_type( token ); if (type <= TokType::Access_Public && type >= TokType::Access_Private ) { token.Flags |= TF_AccessSpecifier; } if ( type > TokType::__Attributes_Start ) { token.Flags |= TF_Attribute; } if ( type == ETokType::Decl_Extern_Linkage ) { SkipWhitespace(); if ( current != '"' ) { type = ETokType::Spec_Extern; token.Flags |= TF_Specifier; } token.Type = type; Tokens.append( token ); return; } if ( ( type <= TokType::Star && type >= TokType::Spec_Alignas) || type == TokType::Ampersand || type == TokType::Ampersand_DBL ) { token.Type = type; token.Flags |= TF_Specifier; Tokens.append( token ); return; } if ( type != TokType::Invalid ) { token.Type = type; Tokens.append( token ); return; } u64 key = 0; if ( current == '(') key = crc32( token.Text, token.Length + 1 ); else key = crc32( token.Text, token.Length ); StrC* define = defines.get( key ); if ( define ) { token.Type = TokType::Preprocess_Macro; // Want to ignore any arguments the define may have as they can be execution expressions. if ( left && current == '(' ) { move_forward(); token.Length++; s32 level = 0; while ( left && (current != ')' || level > 0) ) { if ( current == '(' ) level++; else if ( current == ')' && level > 0 ) level--; move_forward(); token.Length++; } move_forward(); token.Length++; } if ( current == '\r' && scanner[1] == '\n' ) { move_forward(); } else if ( current == '\n' ) { move_forward(); } } else { token.Type = TokType::Identifier; } Tokens.append( token ); } neverinline // TokArray lex( Array tokens, StrC content ) TokArray lex( StrC content ) { s32 left = content.Len; char const* scanner = content.Ptr; char const* word = scanner; s32 word_length = 0; s32 line = 1; s32 column = 1; SkipWhitespace(); if ( left <= 0 ) { log_failure( "gen::lex: no tokens found (only whitespace provided)" ); return { { nullptr }, 0 }; } for ( StringCached entry : PreprocessorDefines ) { s32 length = 0; char const* scanner = entry.Data; while ( entry.length() > length && (char_is_alphanumeric( *scanner ) || *scanner == '_') ) { scanner++; length ++; } if ( scanner[0] == '(' ) { length++; } u64 key = crc32( entry.Data, length ); defines.set( key, entry ); } Tokens.clear(); while (left ) { #if 0 if (Tokens.num()) { log_fmt("\nLastTok: %S", Tokens.back().to_string()); } #endif Token token = { scanner, 0, TokType::Invalid, line, column, TF_Null }; bool is_define = false; if ( column == 1 ) { if ( current == '\r') { move_forward(); token.Length = 1; } if ( current == '\n' ) { move_forward(); token.Type = TokType::NewLine; token.Length++; Tokens.append( token ); continue; } } token.Length = 0; SkipWhitespace(); if ( left <= 0 ) break; switch ( current ) { case '#': { s32 result = lex_preprocessor_directive( content, left, scanner, line, column, defines, token ); switch ( result ) { case Lex_Continue: continue; case Lex_ReturnNull: return { { nullptr }, 0 }; } } case '.': { token.Text = scanner; token.Length = 1; token.Type = TokType::Access_MemberSymbol; token.Flags = TF_AccessOperator; if (left) { move_forward(); } if ( current == '.' ) { move_forward(); if( current == '.' ) { token.Length = 3; token.Type = TokType::Varadic_Argument; token.Flags = TF_Null; move_forward(); } else { String context_str = String::fmt_buf( GlobalAllocator, "%s", scanner, min( 100, left ) ); log_failure( "gen::lex: invalid varadic argument, expected '...' got '..%c' (%d, %d)\n%s", current, line, column, context_str ); } } goto FoundToken; } case '&' : { token.Text = scanner; token.Length = 1; token.Type = TokType::Ampersand; token.Flags |= TF_Operator; token.Flags |= TF_Specifier; if (left) move_forward(); if ( current == '&' ) // && { token.Length = 2; token.Type = TokType::Ampersand_DBL; if (left) move_forward(); } goto FoundToken; } case ':': { token.Text = scanner; token.Length = 1; token.Type = TokType::Assign_Classifer; // Can be either a classifier (ParentType, Bitfield width), or ternary else // token.Type = TokType::Colon; if (left) move_forward(); if ( current == ':' ) { move_forward(); token.Type = TokType::Access_StaticSymbol; token.Length++; } goto FoundToken; } case '{': { token.Text = scanner; token.Length = 1; token.Type = TokType::BraceCurly_Open; if (left) move_forward(); goto FoundToken; } case '}': { token.Text = scanner; token.Length = 1; token.Type = TokType::BraceCurly_Close; token.Flags = TF_EndDefinition; if (left) move_forward(); end_line(); goto FoundToken; } case '[': { token.Text = scanner; token.Length = 1; token.Type = TokType::BraceSquare_Open; if ( left ) { move_forward(); if ( current == ']' ) { token.Length = 2; token.Type = TokType::Operator; move_forward(); } } goto FoundToken; } case ']': { token.Text = scanner; token.Length = 1; token.Type = TokType::BraceSquare_Close; if (left) move_forward(); goto FoundToken; } case '(': { token.Text = scanner; token.Length = 1; token.Type = TokType::Capture_Start; if (left) move_forward(); goto FoundToken; } case ')': { token.Text = scanner; token.Length = 1; token.Type = TokType::Capture_End; if (left) move_forward(); goto FoundToken; } case '\'': { token.Text = scanner; token.Length = 1; token.Type = TokType::Char; token.Flags = TF_Literal; move_forward(); if ( left && current == '\\' ) { move_forward(); token.Length++; if ( current == '\'' ) { move_forward(); token.Length++; } } while ( left && current != '\'' ) { move_forward(); token.Length++; } if ( left ) { move_forward(); token.Length++; } goto FoundToken; } case ',': { token.Text = scanner; token.Length = 1; token.Type = TokType::Comma; token.Flags = TF_Operator; if (left) move_forward(); goto FoundToken; } case '*': { token.Text = scanner; token.Length = 1; token.Type = TokType::Star; token.Flags |= TF_Specifier; token.Flags |= TF_Operator; if (left) move_forward(); if ( current == '=' ) { token.Length++; token.Flags |= TF_Assign; // token.Type = TokType::Assign_Multiply; if ( left ) move_forward(); } goto FoundToken; } case ';': { token.Text = scanner; token.Length = 1; token.Type = TokType::Statement_End; token.Flags = TF_EndDefinition; if (left) move_forward(); end_line(); goto FoundToken; } case '"': { token.Text = scanner; token.Length = 1; token.Type = TokType::String; token.Flags |= TF_Literal; move_forward(); while ( left ) { if ( current == '"' ) { move_forward(); break; } if ( current == '\\' ) { move_forward(); token.Length++; if ( left ) { move_forward(); token.Length++; } continue; } move_forward(); token.Length++; } goto FoundToken; } case '?': { token.Text = scanner; token.Length = 1; token.Type = TokType::Operator; // token.Type = TokType::Ternary; token.Flags = TF_Operator; if (left) move_forward(); goto FoundToken; } case '=': { token.Text = scanner; token.Length = 1; token.Type = TokType::Operator; // token.Type = TokType::Assign; token.Flags = TF_Operator; token.Flags |= TF_Assign; if (left) move_forward(); if ( current == '=' ) { token.Length++; token.Flags = TF_Operator; if (left) move_forward(); } goto FoundToken; } case '+': { // token.Type = TokType::Add } case '%': { // token.Type = TokType::Modulo; } case '^': { // token.Type = TokType::B_XOr; } case '~': { // token.Type = TokType::Unary_Not; } case '!': { // token.Type = TokType::L_Not; } case '<': { // token.Type = TokType::Lesser; } case '>': { // token.Type = TokType::Greater; } case '|': { token.Text = scanner; token.Length = 1; token.Type = TokType::Operator; token.Flags = TF_Operator; // token.Type = TokType::L_Or; if (left) move_forward(); if ( current == '=' ) { token.Length++; token.Flags |= TF_Assign; // token.Flags |= TokFlags::Assignment; // token.Type = TokType::Assign_L_Or; if (left) move_forward(); } else while ( left && current == *(scanner - 1) && token.Length < 3 ) { token.Length++; if (left) move_forward(); } goto FoundToken; } // Dash is unfortunatlly a bit more complicated... case '-': { token.Text = scanner; token.Length = 1; token.Type = TokType::Operator; // token.Type = TokType::Subtract; token.Flags = TF_Operator; if ( left ) { move_forward(); if ( current == '>' ) { token.Length++; // token.Type = TokType::Access_PointerToMemberSymbol; token.Flags |= TF_AccessOperator; move_forward(); if ( current == '*' ) { // token.Type = TokType::Access_PointerToMemberOfPointerSymbol; token.Length++; move_forward(); } } else if ( current == '=' ) { token.Length++; // token.Type = TokType::Assign_Subtract; token.Flags |= TF_Assign; if (left) move_forward(); } else while ( left && current == *(scanner - 1) && token.Length < 3 ) { token.Length++; if (left) move_forward(); } } goto FoundToken; } case '/': { token.Text = scanner; token.Length = 1; token.Type = TokType::Operator; // token.Type = TokType::Divide; token.Flags = TF_Operator; move_forward(); if ( left ) { if ( current == '=' ) { // token.Type = TokeType::Assign_Divide; move_forward(); token.Length++; token.Flags = TF_Assign; } else if ( current == '/' ) { token.Type = TokType::Comment; token.Length = 2; token.Flags = TF_Null; move_forward(); while ( left && current != '\n' && current != '\r' ) { move_forward(); token.Length++; } if ( current == '\r' ) { move_forward(); token.Length++; } if ( current == '\n' ) { move_forward(); token.Length++; } Tokens.append( token ); continue; } else if ( current == '*' ) { token.Type = TokType::Comment; token.Length = 2; token.Flags = TF_Null; move_forward(); bool star = current == '*'; bool slash = scanner[1] == '/'; bool at_end = star && slash; while ( left && ! at_end ) { move_forward(); token.Length++; star = current == '*'; slash = scanner[1] == '/'; at_end = star && slash; } token.Length += 2; move_forward(); move_forward(); if ( current == '\r' ) { move_forward(); token.Length++; } if ( current == '\n' ) { move_forward(); token.Length++; } Tokens.append( token ); // end_line(); continue; } } goto FoundToken; } } if ( char_is_alpha( current ) || current == '_' ) { token.Text = scanner; token.Length = 1; move_forward(); while ( left && ( char_is_alphanumeric(current) || current == '_' ) ) { move_forward(); token.Length++; } goto FoundToken; } else if ( char_is_digit(current) ) { // This is a very brute force lex, no checks are done for validity of literal. token.Text = scanner; token.Length = 1; token.Type = TokType::Number; token.Flags = TF_Literal; move_forward(); if (left && ( current == 'x' || current == 'X' || current == 'b' || current == 'B' || current == 'o' || current == 'O' ) ) { move_forward(); token.Length++; while ( left && char_is_hex_digit(current) ) { move_forward(); token.Length++; } goto FoundToken; } while ( left && char_is_digit(current) ) { move_forward(); token.Length++; } if ( left && current == '.' ) { move_forward(); token.Length++; while ( left && char_is_digit(current) ) { move_forward(); token.Length++; } // Handle number literal suffixes in a botched way if (left && ( current == 'l' || current == 'L' || // long/long long current == 'u' || current == 'U' || // unsigned current == 'f' || current == 'F' || // float current == 'i' || current == 'I' || // imaginary current == 'z' || current == 'Z')) // complex { char prev = current; move_forward(); token.Length++; // Handle 'll'/'LL' as a special case when we just processed an 'l'/'L' if (left && (prev == 'l' || prev == 'L') && (current == 'l' || current == 'L')) { move_forward(); token.Length++; } } } goto FoundToken; } else { s32 start = max( 0, Tokens.num() - 100 ); log_fmt("\n%d\n", start); for ( s32 idx = start; idx < Tokens.num(); idx++ ) { log_fmt( "Token %d Type: %s : %.*s\n" , idx , ETokType::to_str( Tokens[ idx ].Type ).Ptr , Tokens[ idx ].Length, Tokens[ idx ].Text ); } String context_str = String::fmt_buf( GlobalAllocator, "%.*s", min( 100, left ), scanner ); log_failure( "Failed to lex token '%c' (%d, %d)\n%s", current, line, column, context_str ); // Skip to next whitespace since we can't know if anything else is valid until then. while ( left && ! char_is_space( current ) ) { move_forward(); } } FoundToken: lex_found_token( content, left, scanner, line, column, defines, token ); } if ( Tokens.num() == 0 ) { log_failure( "Failed to lex any tokens" ); return { { nullptr }, 0 }; } defines.clear(); // defines_map_arena.free(); return { Tokens, 0 }; } #undef current #undef move_forward #undef SkipWhitespace // namespace parser } namespace parser { // TODO(Ed) : Rename ETokType::Capture_Start, ETokType::Capture_End to Open_Parenthesis adn Close_Parenthesis constexpr bool dont_skip_formatting = false; struct StackNode { StackNode* Prev; Token Start; Token Name; // The name of the AST node (if parsed) StrC ProcName; // The name of the procedure }; struct ParseContext { TokArray Tokens; StackNode* Scope; void push( StackNode* node ) { node->Prev = Scope; Scope = node; #if 0 && Build_Debug log_fmt("\tEntering Context: %.*s\n", Scope->ProcName.Len, Scope->ProcName.Ptr ); #endif } void pop() { #if 0 && Build_Debug log_fmt("\tPopping Context: %.*s\n", Scope->ProcName.Len, Scope->ProcName.Ptr ); #endif Scope = Scope->Prev; } String to_string() { String result = String::make_reserve( GlobalAllocator, kilobytes(4) ); Token scope_start = Scope->Start; Token last_valid = Tokens.Idx >= Tokens.Arr.num() ? Tokens.Arr[Tokens.Arr.num() -1] : Tokens.current(); sptr length = scope_start.Length; char const* current = scope_start.Text + length; while ( current <= Tokens.Arr.back().Text && *current != '\n' && length < 74 ) { current++; length++; } String line = String::make( GlobalAllocator, { length, scope_start.Text } ); result.append_fmt("\tScope : %s\n", line ); line.free(); sptr dist = (sptr)last_valid.Text - (sptr)scope_start.Text + 2; sptr length_from_err = dist; String line_from_err = String::make( GlobalAllocator, { length_from_err, last_valid.Text } ); if ( length_from_err < 100 ) result.append_fmt("\t(%d, %d):%*c\n", last_valid.Line, last_valid.Column, length_from_err, '^' ); else result.append_fmt("\t(%d, %d)\n", last_valid.Line, last_valid.Column ); StackNode* curr_scope = Scope; s32 level = 0; do { if ( curr_scope->Name ) { result.append_fmt("\t%d: %s, AST Name: %.*s\n", level, curr_scope->ProcName.Ptr, curr_scope->Name.Length, curr_scope->Name.Text ); } else { result.append_fmt("\t%d: %s\n", level, curr_scope->ProcName.Ptr ); } curr_scope = curr_scope->Prev; level++; } while ( curr_scope ); return result; } }; global ParseContext Context; bool TokArray::__eat( TokType type ) { if ( Arr.num() - Idx <= 0 ) { log_failure( "No tokens left.\n%s", Context.to_string() ); return false; } if ( ( Arr[ Idx ].Type == TokType::NewLine && type != TokType::NewLine ) || ( Arr[ Idx ].Type == TokType::Comment && type != TokType::Comment ) ) { Idx++; } if ( Arr[Idx].Type != type ) { log_failure( "Parse Error, TokArray::eat, Expected: ' %s ' not ' %.*s ' (%d, %d)`\n%s" , ETokType::to_str(type).Ptr , Arr[Idx].Length, Arr[Idx].Text , current().Line , current().Column , Context.to_string() ); return false; } #if 0 && Build_Debug log_fmt("Ate: %S\n", Arr[Idx].to_string() ); #endif Idx++; return true; } internal void init() { Tokens = Array::init_reserve( LexArena , ( LexAllocator_Size - sizeof( Array::Header ) ) / sizeof(Token) ); defines_map_arena = Arena_256KB::init(); defines = HashTable::init_reserve( defines_map_arena, 256 ); } internal void deinit() { parser::Tokens = { nullptr }; } #pragma region Helper Macros # define check_parse_args( def ) \ if ( def.Len <= 0 ) \ { \ log_failure( "gen::" stringize(__func__) ": length must greater than 0" ); \ parser::Context.pop(); \ return CodeInvalid; \ } \ if ( def.Ptr == nullptr ) \ { \ log_failure( "gen::" stringize(__func__) ": def was null" ); \ parser::Context.pop(); \ return CodeInvalid; \ } # define currtok_noskip Context.Tokens.current( dont_skip_formatting ) # define currtok Context.Tokens.current() # define prevtok Context.Tokens.previous() # define nexttok Context.Tokens.next() # define eat( Type_ ) Context.Tokens.__eat( Type_ ) # define left ( Context.Tokens.Arr.num() - Context.Tokens.Idx ) #ifdef check #define CHECK_WAS_DEFINED #pragma push_macro("check") #undef check #endif # define check_noskip( Type_ ) ( left && currtok_noskip.Type == Type_ ) # define check( Type_ ) ( left && currtok.Type == Type_ ) # define push_scope() \ StackNode scope { nullptr, currtok_noskip, NullToken, txt( __func__ ) }; \ Context.push( & scope ) #pragma endregion Helper Macros // Procedure Forwards ( Entire parser internal parser interface ) internal Code parse_array_decl (); internal CodeAttributes parse_attributes (); internal CodeComment parse_comment (); internal Code parse_complicated_definition ( TokType which ); internal CodeBody parse_class_struct_body ( TokType which, Token name = NullToken ); internal Code parse_class_struct ( TokType which, bool inplace_def ); internal CodeDefine parse_define (); internal Code parse_expression (); internal Code parse_forward_or_definition ( TokType which, bool is_inplace ); internal CodeFn parse_function_after_name ( ModuleFlag mflags, CodeAttributes attributes, CodeSpecifiers specifiers, CodeType ret_type, Token name ); internal Code parse_function_body (); internal Code parse_global_nspace (); internal Code parse_global_nspace_constructor_destructor( CodeSpecifiers specifiers ); internal Token parse_identifier ( bool* possible_member_function = nullptr ); internal CodeInclude parse_include (); internal CodeOperator parse_operator_after_ret_type ( ModuleFlag mflags, CodeAttributes attributes, CodeSpecifiers specifiers, CodeType ret_type ); internal Code parse_operator_function_or_variable( bool expects_function, CodeAttributes attributes, CodeSpecifiers specifiers ); internal CodePragma parse_pragma (); internal CodeParam parse_params ( bool use_template_capture = false ); internal CodePreprocessCond parse_preprocess_cond (); internal Code parse_simple_preprocess ( TokType which ); internal Code parse_static_assert (); internal void parse_template_args ( Token& token ); internal CodeVar parse_variable_after_name ( ModuleFlag mflags, CodeAttributes attributes, CodeSpecifiers specifiers, CodeType type, StrC name ); internal CodeVar parse_variable_declaration_list (); internal CodeClass parse_class ( bool inplace_def = false ); internal CodeConstructor parse_constructor ( CodeSpecifiers specifiers ); internal CodeDestructor parse_destructor ( CodeSpecifiers specifiers = NoCode ); internal CodeEnum parse_enum ( bool inplace_def = false ); internal CodeBody parse_export_body (); internal CodeBody parse_extern_link_body(); internal CodeExtern parse_extern_link (); internal CodeFriend parse_friend (); internal CodeFn parse_function (); internal CodeNS parse_namespace (); internal CodeOpCast parse_operator_cast ( CodeSpecifiers specifiers = NoCode ); internal CodeStruct parse_struct ( bool inplace_def = false ); internal CodeVar parse_variable (); internal CodeTemplate parse_template (); internal CodeType parse_type ( bool from_template = false, bool* is_function = nullptr ); internal CodeTypedef parse_typedef (); internal CodeUnion parse_union ( bool inplace_def = false ); internal CodeUsing parse_using (); constexpr bool inplace_def = true; // Internal parsing functions constexpr bool strip_formatting_dont_preserve_newlines = false; /* This function was an attempt at stripping formatting from any c++ code. It has edge case failures that prevent it from being used in function bodies. */ internal String strip_formatting( StrC raw_text, bool preserve_newlines = true ) { String content = String::make_reserve( GlobalAllocator, raw_text.Len ); if ( raw_text.Len == 0 ) return content; #define cut_length ( scanner - raw_text.Ptr - last_cut ) #define cut_ptr ( raw_text.Ptr + last_cut ) #define pos ( sptr( scanner ) - sptr( raw_text.Ptr ) ) #define move_fwd() do { scanner++; tokleft--; } while(0) s32 tokleft = raw_text.Len; sptr last_cut = 0; char const* scanner = raw_text.Ptr; if ( scanner[0] == ' ' ) { move_fwd(); last_cut = 1; } bool within_string = false; bool within_char = false; bool must_keep_newline = false; while ( tokleft ) { // Skip over the content of string literals if ( scanner[0] == '"' ) { move_fwd(); while ( tokleft && ( scanner[0] != '"' || *( scanner - 1 ) == '\\' ) ) { if ( scanner[0] == '\\' && tokleft > 1 ) { scanner += 2; tokleft -= 2; } else { move_fwd(); } } // Skip the closing " if ( tokleft ) move_fwd(); content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Skip over the content of character literals if ( scanner[0] == '\'' ) { move_fwd(); while ( tokleft && ( scanner[0] != '\'' || ( *(scanner -1 ) == '\\' ) ) ) { move_fwd(); } // Skip the closing ' if ( tokleft ) move_fwd(); content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Block comments if ( tokleft > 1 && scanner[0] == '/' && scanner[1] == '*' ) { while ( tokleft > 1 && !(scanner[0] == '*' && scanner[1] == '/') ) move_fwd(); scanner += 2; tokleft -= 2; content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Line comments if ( tokleft > 1 && scanner[0] == '/' && scanner[1] == '/' ) { must_keep_newline = true; scanner += 2; tokleft -= 2; while ( tokleft && scanner[ 0 ] != '\n' ) move_fwd(); if (tokleft) move_fwd(); content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Tabs if (scanner[0] == '\t') { if (pos > last_cut) content.append(cut_ptr, cut_length); if ( content.back() != ' ' ) content.append(' '); move_fwd(); last_cut = sptr(scanner) - sptr(raw_text.Ptr); continue; } if ( tokleft > 1 && scanner[0] == '\r' && scanner[1] == '\n' ) { if ( must_keep_newline || preserve_newlines ) { must_keep_newline = false; scanner += 2; tokleft -= 2; content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } if ( pos > last_cut ) content.append( cut_ptr, cut_length ); // Replace with a space if ( content.back() != ' ' ) content.append( ' ' ); scanner += 2; tokleft -= 2; last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } if ( scanner[0] == '\n' ) { if ( must_keep_newline || preserve_newlines ) { must_keep_newline = false; move_fwd(); content.append( cut_ptr, cut_length ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } if ( pos > last_cut ) content.append( cut_ptr, cut_length ); // Replace with a space if ( content.back() != ' ' ) content.append( ' ' ); move_fwd(); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Escaped newlines if ( scanner[0] == '\\' ) { content.append( cut_ptr, cut_length ); s32 amount_to_skip = 1; if ( tokleft > 1 && scanner[1] == '\n' ) { amount_to_skip = 2; } else if ( tokleft > 2 && scanner[1] == '\r' && scanner[2] == '\n' ) { amount_to_skip = 3; } if ( amount_to_skip > 1 && pos == last_cut ) { scanner += amount_to_skip; tokleft -= amount_to_skip; } else move_fwd(); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); continue; } // Consectuive spaces if ( tokleft > 1 && char_is_space( scanner[0] ) && char_is_space( scanner[ 1 ] ) ) { content.append( cut_ptr, cut_length ); do { move_fwd(); } while ( tokleft && char_is_space( scanner[0] ) ); last_cut = sptr( scanner ) - sptr( raw_text.Ptr ); // Preserve only 1 space of formattting if ( content.back() != ' ' ) content.append( ' ' ); continue; } move_fwd(); } if ( last_cut < raw_text.Len ) { content.append( cut_ptr, raw_text.Len - last_cut ); } #undef cut_ptr #undef cut_length #undef pos #undef move_fwd return content; } internal Code parse_array_decl() { push_scope(); if ( check( TokType::Operator ) && currtok.Text[0] == '[' && currtok.Text[1] == ']' ) { Code array_expr = untyped_str( currtok ); eat( TokType::Operator ); // [] Context.pop(); return array_expr; } if ( check( TokType::BraceSquare_Open ) ) { eat( TokType::BraceSquare_Open ); // [ if ( left == 0 ) { log_failure( "Error, unexpected end of array declaration ( '[]' scope started )\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } if ( currtok.Type == TokType::BraceSquare_Close ) { log_failure( "Error, empty array expression in definition\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } Token untyped_tok = currtok; while ( left && currtok.Type != TokType::BraceSquare_Close ) { eat( currtok.Type ); } untyped_tok.Length = ( (sptr)prevtok.Text + prevtok.Length ) - (sptr)untyped_tok.Text; Code array_expr = untyped_str( untyped_tok ); // [ if ( left == 0 ) { log_failure( "Error, unexpected end of array declaration, expected ]\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } if ( currtok.Type != TokType::BraceSquare_Close ) { log_failure( "%s: Error, expected ] in array declaration, not %s\n%s", ETokType::to_str( currtok.Type ), Context.to_string() ); Context.pop(); return CodeInvalid; } eat( TokType::BraceSquare_Close ); // [ ] // Its a multi-dimensional array if ( check( TokType::BraceSquare_Open )) { Code adjacent_arr_expr = parse_array_decl(); // [ ][ ]... array_expr->Next = adjacent_arr_expr.ast; } Context.pop(); return array_expr; } Context.pop(); return { nullptr }; } internal inline CodeAttributes parse_attributes() { push_scope(); Token start = currtok; s32 len = 0; // There can be more than one attribute. If there is flatten them to a single string. // TODO(Ed): Support keeping an linked list of attributes similar to parameters while ( left && currtok.is_attribute() ) { if ( check( TokType::Attribute_Open ) ) { eat( TokType::Attribute_Open ); // [[ while ( left && currtok.Type != TokType::Attribute_Close ) { eat( currtok.Type ); } // [[ eat( TokType::Attribute_Close ); // [[ ]] len = ( ( sptr )prevtok.Text + prevtok.Length ) - ( sptr )start.Text; } else if ( check( TokType::Decl_GNU_Attribute ) ) { eat( TokType::Decl_GNU_Attribute ); eat( TokType::Capture_Start ); eat( TokType::Capture_Start ); // __attribute__(( while ( left && currtok.Type != TokType::Capture_End ) { eat( currtok.Type ); } // __attribute__(( eat( TokType::Capture_End ); eat( TokType::Capture_End ); // __attribute__(( )) len = ( ( sptr )prevtok.Text + prevtok.Length ) - ( sptr )start.Text; } else if ( check( TokType::Decl_MSVC_Attribute ) ) { eat( TokType::Decl_MSVC_Attribute ); eat( TokType::Capture_Start ); // __declspec( while ( left && currtok.Type != TokType::Capture_End ) { eat( currtok.Type ); } // __declspec( eat( TokType::Capture_End ); // __declspec( ) len = ( ( sptr )prevtok.Text + prevtok.Length ) - ( sptr )start.Text; } else if ( currtok.is_attribute() ) { eat( currtok.Type ); // // If its a macro based attribute, this could be a functional macro such as Unreal's UE_DEPRECATED(...) if ( check( TokType::Capture_Start)) { eat( TokType::Capture_Start ); s32 level = 0; while (left && currtok.Type != TokType::Capture_End && level == 0) { if (currtok.Type == TokType::Capture_Start) ++ level; if (currtok.Type == TokType::Capture_End) --level; eat(currtok.Type); } eat(TokType::Capture_End); } len = ( ( sptr )prevtok.Text + prevtok.Length ) - ( sptr )start.Text; // ( ... ) } } if ( len > 0 ) { StrC attribute_txt = { len, start.Text }; Context.pop(); String name_stripped = strip_formatting( attribute_txt, strip_formatting_dont_preserve_newlines ); Code result = make_code(); result->Type = ECode::PlatformAttributes; result->Name = get_cached_string( name_stripped ); result->Content = result->Name; // result->Token = return ( CodeAttributes )result; } Context.pop(); return { nullptr }; } internal Code parse_class_struct( TokType which, bool inplace_def = false ) { if ( which != TokType::Decl_Class && which != TokType::Decl_Struct ) { log_failure( "Error, expected class or struct, not %s\n%s", ETokType::to_str( which ), Context.to_string() ); return CodeInvalid; } Token name { nullptr, 0, TokType::Invalid }; AccessSpec access = AccessSpec::Default; CodeType parent = { nullptr }; CodeBody body = { nullptr }; CodeAttributes attributes = { nullptr }; ModuleFlag mflags = ModuleFlag::None; CodeClass result = CodeInvalid; if ( check(TokType::Module_Export) ) { mflags = ModuleFlag::Export; eat( TokType::Module_Export ); } // eat( which ); // attributes = parse_attributes(); // if ( check( TokType::Identifier ) ) { name = parse_identifier(); Context.Scope->Name = name; } // local_persist char interface_arr_mem[ kilobytes(4) ] {0}; Array interfaces = Array::init_reserve( Arena::init_from_memory(interface_arr_mem, kilobytes(4) ), 4 ); // TODO(Ed) : Make an AST_DerivedType, we'll store any arbitary derived type into there as a linear linked list of them. if ( check( TokType::Assign_Classifer ) ) { eat( TokType::Assign_Classifer ); // : if ( currtok.is_access_specifier() ) { access = currtok.to_access_specifier(); // : eat( currtok.Type ); } Token parent_tok = parse_identifier(); parent = def_type( parent_tok ); // : while ( check(TokType::Comma) ) { eat( TokType::Comma ); // : , if ( currtok.is_access_specifier() ) { eat(currtok.Type); } Token interface_tok = parse_identifier(); interfaces.append( def_type( interface_tok ) ); // : , ... } } if ( check( TokType::BraceCurly_Open ) ) { body = parse_class_struct_body( which, name ); } // : , ... { } CodeComment inline_cmt = NoCode; if ( ! inplace_def ) { Token stmt_end = currtok; eat( TokType::Statement_End ); // : , ... { }; if ( currtok_noskip.Type == TokType::Comment && currtok_noskip.Line == stmt_end.Line ) inline_cmt = parse_comment(); // : , ... { }; } if ( which == TokType::Decl_Class ) result = def_class( name, body, parent, access, attributes, mflags ); else result = def_struct( name, body, (CodeType)parent, access, attributes, mflags ); if ( inline_cmt ) result->InlineCmt = inline_cmt; interfaces.free(); return result; } internal neverinline CodeBody parse_class_struct_body( TokType which, Token name ) { using namespace ECode; push_scope(); eat( TokType::BraceCurly_Open ); // { CodeBody result = (CodeBody) make_code(); if ( which == TokType::Decl_Class ) result->Type = Class_Body; else result->Type = Struct_Body; while ( left && currtok_noskip.Type != TokType::BraceCurly_Close ) { Code member = Code::Invalid; CodeAttributes attributes = { nullptr }; CodeSpecifiers specifiers = { nullptr }; bool expects_function = false; // Context.Scope->Start = currtok_noskip; if ( currtok_noskip.Type == TokType::Preprocess_Hash ) eat( TokType::Preprocess_Hash ); switch ( currtok_noskip.Type ) { case TokType::Statement_End: { // TODO(Ed): Convert this to a general warning procedure log_fmt("Dangling end statement found %S\n", currtok_noskip.to_string()); eat( TokType::Statement_End ); continue; } case TokType::NewLine: member = fmt_newline; eat( TokType::NewLine ); break; case TokType::Comment: member = parse_comment(); break; case TokType::Access_Public: member = access_public; eat( TokType::Access_Public ); eat( TokType::Assign_Classifer ); // public: break; case TokType::Access_Protected: member = access_protected; eat( TokType::Access_Protected ); eat( TokType::Assign_Classifer ); // protected: break; case TokType::Access_Private: member = access_private; eat( TokType::Access_Private ); eat( TokType::Assign_Classifer ); // private: break; case TokType::Decl_Class: member = parse_complicated_definition( TokType::Decl_Class ); // class break; case TokType::Decl_Enum: member = parse_complicated_definition( TokType::Decl_Enum ); // enum break; case TokType::Decl_Friend: member = parse_friend(); // friend break; case TokType::Decl_Operator: member = parse_operator_cast(); // operator () break; case TokType::Decl_Struct: member = parse_complicated_definition( TokType::Decl_Struct ); // struct break; case TokType::Decl_Template: member = parse_template(); // template< ... > break; case TokType::Decl_Typedef: member = parse_typedef(); // typedef break; case TokType::Decl_Union: member = parse_complicated_definition( TokType::Decl_Union ); // union break; case TokType::Decl_Using: member = parse_using(); // using break; case TokType::Operator: if ( currtok.Text[0] != '~' ) { log_failure( "Operator token found in global body but not destructor unary negation\n%s", Context.to_string() ); return CodeInvalid; } member = parse_destructor(); // ~() break; case TokType::Preprocess_Define: member = parse_define(); // #define break; case TokType::Preprocess_Include: member = parse_include(); // #include break; case TokType::Preprocess_If: case TokType::Preprocess_IfDef: case TokType::Preprocess_IfNotDef: case TokType::Preprocess_ElIf: member = parse_preprocess_cond(); // # break; case TokType::Preprocess_Else: member = preprocess_else; eat( TokType::Preprocess_Else ); // #else break; case TokType::Preprocess_EndIf: member = preprocess_endif; eat( TokType::Preprocess_EndIf ); // #endif break; case TokType::Preprocess_Macro: member = parse_simple_preprocess( TokType::Preprocess_Macro ); // break; case TokType::Preprocess_Pragma: member = parse_pragma(); // #pragma break; case TokType::Preprocess_Unsupported: member = parse_simple_preprocess( TokType::Preprocess_Unsupported ); // # break; case TokType::StaticAssert: member = parse_static_assert(); // static_assert break; case TokType::Attribute_Open: case TokType::Decl_GNU_Attribute: case TokType::Decl_MSVC_Attribute: #define Entry( attribute, str ) case TokType::attribute: GEN_DEFINE_ATTRIBUTE_TOKENS #undef Entry { attributes = parse_attributes(); // } //! Fallthrough intended case TokType::Spec_Consteval: case TokType::Spec_Constexpr: case TokType::Spec_Constinit: case TokType::Spec_Explicit: case TokType::Spec_ForceInline: case TokType::Spec_Inline: case TokType::Spec_Mutable: case TokType::Spec_NeverInline: case TokType::Spec_Static: case TokType::Spec_Volatile: case TokType::Spec_Virtual: { SpecifierT specs_found[16] { ESpecifier::NumSpecifiers }; s32 NumSpecifiers = 0; while ( left && currtok.is_specifier() ) { SpecifierT spec = ESpecifier::to_type( currtok ); b32 ignore_spec = false; switch ( spec ) { case ESpecifier::Constexpr: case ESpecifier::Constinit: case ESpecifier::Explicit: case ESpecifier::Inline: case ESpecifier::ForceInline: case ESpecifier::Mutable: case ESpecifier::NeverInline: case ESpecifier::Static: case ESpecifier::Volatile: case ESpecifier::Virtual: break; case ESpecifier::Consteval: expects_function = true; break; case ESpecifier::Const : ignore_spec = true; break; default: log_failure( "Invalid specifier %s for variable\n%s", ESpecifier::to_str(spec), Context.to_string() ); Context.pop(); return CodeInvalid; } // Every specifier after would be considered part of the type type signature if (ignore_spec) break; specs_found[NumSpecifiers] = spec; NumSpecifiers++; eat( currtok.Type ); } if ( NumSpecifiers ) { specifiers = def_specifiers( NumSpecifiers, specs_found ); } // if ( currtok.is_attribute() ) { // Unfortuantely Unreal has code where there is attirbutes before specifiers CodeAttributes more_attributes = parse_attributes(); if ( attributes ) { String fused = String::make_reserve( GlobalAllocator, attributes->Content.length() + more_attributes->Content.length() ); fused.append_fmt( "%S %S", attributes->Content, more_attributes->Content ); attributes->Name = get_cached_string(fused); attributes->Content = attributes->Name; // } attributes = more_attributes; } if ( currtok.Type == TokType::Operator && currtok.Text[0] == '~' ) { member = parse_destructor( specifiers ); // ~() break; } if ( currtok.Type == TokType::Decl_Operator ) { member = parse_operator_cast( specifiers ); // operator () break; } } //! Fallthrough intentional case TokType::Identifier: case TokType::Spec_Const: case TokType::Type_Unsigned: case TokType::Type_Signed: case TokType::Type_Short: case TokType::Type_Long: case TokType::Type_bool: case TokType::Type_char: case TokType::Type_int: case TokType::Type_double: { if ( nexttok.Type == TokType::Capture_Start && name.Length && currtok.Type == TokType::Identifier ) { if ( str_compare( name.Text, currtok.Text, name.Length ) == 0 ) { member = parse_constructor( specifiers ); // () break; } } member = parse_operator_function_or_variable( expects_function, attributes, specifiers ); // operator ... // or // ... } break; default: Token untyped_tok = currtok; while ( left && currtok.Type != TokType::BraceCurly_Close ) { untyped_tok.Length = ( (sptr)currtok.Text + currtok.Length ) - (sptr)untyped_tok.Text; eat( currtok.Type ); } member = untyped_str( untyped_tok ); // Something unknown break; } if ( member == Code::Invalid ) { log_failure( "Failed to parse member\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } result.append( member ); } eat( TokType::BraceCurly_Close ); // { } Context.pop(); return result; } internal CodeComment parse_comment() { StackNode scope { nullptr, currtok_noskip, NullToken, txt( __func__ ) }; Context.push( & scope ); CodeComment result = (CodeComment) make_code(); result->Type = ECode::Comment; result->Content = get_cached_string( currtok_noskip ); result->Name = result->Content; // result->Token = currtok_noskip; eat( TokType::Comment ); Context.pop(); return result; } internal Code parse_complicated_definition( TokType which ) { push_scope(); bool is_inplace = false; TokArray tokens = Context.Tokens; s32 idx = tokens.Idx; s32 level = 0; for ( ; idx < tokens.Arr.num(); idx++ ) { if ( tokens[ idx ].Type == TokType::BraceCurly_Open ) level++; if ( tokens[ idx ].Type == TokType::BraceCurly_Close ) level--; if ( level == 0 && tokens[ idx ].Type == TokType::Statement_End ) break; } if ( ( idx - 2 ) == tokens.Idx ) { // Its a forward declaration only Code result = parse_forward_or_definition( which, is_inplace ); // ; Context.pop(); return result; } Token tok = tokens[ idx - 1 ]; if ( tok.is_specifier() && is_trailing( ESpecifier::to_type(tok)) ) { // (...) ...; s32 spec_idx = idx - 1; Token spec = tokens[spec_idx]; while ( spec.is_specifier() && is_trailing( ESpecifier::to_type(spec)) ) { -- spec_idx; spec = tokens[spec_idx]; } if ( tokens[spec_idx].Type == TokType::Capture_End ) { // Forward declaration with trailing specifiers for a procedure tok = tokens[spec_idx]; Code result = parse_operator_function_or_variable( false, { nullptr }, { nullptr } ); // , or Name> ... Context.pop(); return result; } log_failure( "Unsupported or bad member definition after %s declaration\n%s", to_str(which), Context.to_string() ); Context.pop(); return CodeInvalid; } if ( tok.Type == TokType::Identifier ) { tok = tokens[ idx - 2 ]; bool is_indirection = tok.Type == TokType::Ampersand || tok.Type == TokType::Star; bool ok_to_parse = false; if ( tok.Type == TokType::BraceCurly_Close ) { // Its an inplace definition // { ... } ; ok_to_parse = true; is_inplace = true; } else if ( tok.Type == TokType::Identifier && tokens[ idx - 3 ].Type == which ) { // Its a variable with type ID using namespace. // ; ok_to_parse = true; } else if ( tok.Type == TokType::Assign_Classifer && ( ( tokens[idx - 5].Type == which && tokens[idx - 4].Type == TokType::Decl_Class ) || ( tokens[idx - 4].Type == which)) ) { // Its a forward declaration of an enum // : ; // : ; ok_to_parse = true; Code result = parse_enum(); Context.pop(); return result; } else if ( is_indirection ) { // Its a indirection type with type ID using struct namespace. // * ; ok_to_parse = true; } if ( ! ok_to_parse ) { log_failure( "Unsupported or bad member definition after %s declaration\n%s", to_str(which), Context.to_string() ); Context.pop(); return CodeInvalid; } Code result = parse_operator_function_or_variable( false, { nullptr }, { nullptr } ); // , or Name> ... Context.pop(); return result; } else if ( tok.Type >= TokType::Type_Unsigned && tok.Type <= TokType::Type_MS_W64 ) { tok = tokens[ idx - 2 ]; if ( tok.Type != TokType::Assign_Classifer || ( ( tokens[idx - 5].Type != which && tokens[idx - 4].Type != TokType::Decl_Class ) && ( tokens[idx - 4].Type != which)) ) { log_failure( "Unsupported or bad member definition after %s declaration\n%s", to_str(which), Context.to_string() ); Context.pop(); return CodeInvalid; } // Its a forward declaration of an enum class // : ; // : ; Code result = parse_enum(); Context.pop(); return result; } else if ( tok.Type == TokType::BraceCurly_Close ) { // Its a definition Code result = parse_forward_or_definition( which, is_inplace ); // { ... }; Context.pop(); return result; } else if ( tok.Type == TokType::BraceSquare_Close ) { // Its an array definition Code result = parse_operator_function_or_variable( false, { nullptr }, { nullptr } ); // [ ... ]; Context.pop(); return result; } else { log_failure( "Unsupported or bad member definition after %s declaration\n%S", to_str(which).Ptr, Context.to_string() ); Context.pop(); return CodeInvalid; } } internal inline CodeDefine parse_define() { push_scope(); eat( TokType::Preprocess_Define ); // #define CodeDefine define = (CodeDefine) make_code(); define->Type = ECode::Preprocess_Define; if ( ! check( TokType::Identifier ) ) { log_failure( "Error, expected identifier after #define\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } Context.Scope->Name = currtok; define->Name = get_cached_string( currtok ); eat( TokType::Identifier ); // #define if ( ! check( TokType::Preprocess_Content )) { log_failure( "Error, expected content after #define %s\n%s", define->Name, Context.to_string() ); Context.pop(); return CodeInvalid; } if ( currtok.Length == 0 ) { define->Content = get_cached_string( currtok ); eat( TokType::Preprocess_Content ); // #define Context.pop(); return define; } define->Content = get_cached_string( strip_formatting( currtok, strip_formatting_dont_preserve_newlines ) ); eat( TokType::Preprocess_Content ); // #define Context.pop(); return define; } internal inline Code parse_assignment_expression() { Code expr = { nullptr }; eat( TokType::Operator ); // = Token expr_tok = currtok; if ( currtok.Type == TokType::Statement_End && currtok.Type != TokType::Comma ) { log_failure( "Expected expression after assignment operator\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } s32 level = 0; while ( left && currtok.Type != TokType::Statement_End && (currtok.Type != TokType::Comma || level > 0) ) { if (currtok.Type == TokType::BraceCurly_Open ) level++; if (currtok.Type == TokType::BraceCurly_Close ) level--; if (currtok.Type == TokType::Capture_Start) level++; else if (currtok.Type == TokType::Capture_End) level--; eat( currtok.Type ); } expr_tok.Length = ( ( sptr )currtok.Text + currtok.Length ) - ( sptr )expr_tok.Text - 1; expr = untyped_str( expr_tok ); // = return expr; } internal inline Code parse_forward_or_definition( TokType which, bool is_inplace ) { Code result = CodeInvalid; switch ( which ) { case TokType::Decl_Class: result = parse_class( is_inplace ); return result; case TokType::Decl_Enum: result = parse_enum( is_inplace ); return result; case TokType::Decl_Struct: result = parse_struct( is_inplace ); return result; case TokType::Decl_Union: result = parse_union( is_inplace ); return result; default: log_failure( "Error, wrong token type given to parse_complicated_definition " "(only supports class, enum, struct, union) \n%s" , Context.to_string() ); return CodeInvalid; } } // Function parsing is handled in multiple places because its initial signature is shared with variable parsing internal inline CodeFn parse_function_after_name( ModuleFlag mflags , CodeAttributes attributes , CodeSpecifiers specifiers , CodeType ret_type , Token name ) { push_scope(); CodeParam params = parse_params(); // ( ) // TODO(Ed), Review old comment : These have to be kept separate from the return type's specifiers. while ( left && currtok.is_specifier() ) { if ( specifiers.ast == nullptr ) { specifiers = def_specifier( ESpecifier::to_type(currtok) ); eat( currtok.Type ); continue; } specifiers.append( ESpecifier::to_type(currtok) ); eat( currtok.Type ); } // ( ) CodeBody body = NoCode; CodeComment inline_cmt = NoCode; if ( check( TokType::BraceCurly_Open ) ) { body = parse_function_body(); if ( body == Code::Invalid ) { Context.pop(); return CodeInvalid; } // ( ) { } } else if ( check(TokType::Operator) && currtok.Text[0] == '=' ) { eat(TokType::Operator); specifiers.append( ESpecifier::Pure ); eat( TokType::Number); Token stmt_end = currtok; eat( TokType::Statement_End ); // ( ) = 0; if ( currtok_noskip.Type == TokType::Comment && currtok_noskip.Line == stmt_end.Line ) inline_cmt = parse_comment(); // ( ) ; } else { Token stmt_end = currtok; eat( TokType::Statement_End ); // ( ) ; if ( currtok_noskip.Type == TokType::Comment && currtok_noskip.Line == stmt_end.Line ) inline_cmt = parse_comment(); // ( ) ; } using namespace ECode; String name_stripped = String::make( GlobalAllocator, name ); name_stripped.strip_space(); CodeFn result = (CodeFn) make_code(); result->Name = get_cached_string( name_stripped ); result->ModuleFlags = mflags; if ( body ) { switch ( body->Type ) { case Function_Body: case Untyped: break; default: { log_failure("Body must be either of Function_Body or Untyped type, %s\n%s", body.debug_str(), Context.to_string()); Context.pop(); return CodeInvalid; } } result->Type = Function; result->Body = body; } else { result->Type = Function_Fwd; } if ( attributes ) result->Attributes = attributes; if ( specifiers ) result->Specs = specifiers; result->ReturnType = ret_type; if ( params ) result->Params = params; if ( inline_cmt ) result->InlineCmt = inline_cmt; Context.pop(); return result; } internal Code parse_function_body() { using namespace ECode; push_scope(); eat( TokType::BraceCurly_Open ); CodeBody result = (CodeBody) make_code(); result->Type = Function_Body; // TODO : Support actual parsing of function body Token start = currtok_noskip; s32 level = 0; while ( left && ( currtok_noskip.Type != TokType::BraceCurly_Close || level > 0 ) ) { if ( currtok_noskip.Type == TokType::BraceCurly_Open ) level++; else if ( currtok_noskip.Type == TokType::BraceCurly_Close && level > 0 ) level--; eat( currtok_noskip.Type ); } Token previous = prevtok; s32 len = ( (sptr)prevtok.Text + prevtok.Length ) - (sptr)start.Text; if ( len > 0 ) { result.append( def_execution( { len, start.Text } ) ); } eat( TokType::BraceCurly_Close ); Context.pop(); return result; } internal neverinline CodeBody parse_global_nspace( CodeT which ) { using namespace ECode; push_scope(); if ( which != Namespace_Body && which != Global_Body && which != Export_Body && which != Extern_Linkage_Body ) return CodeInvalid; if ( which != Global_Body ) eat( TokType::BraceCurly_Open ); // { CodeBody result = (CodeBody) make_code(); result->Type = which; while ( left && currtok_noskip.Type != TokType::BraceCurly_Close ) { Code member = Code::Invalid; CodeAttributes attributes = { nullptr }; CodeSpecifiers specifiers = { nullptr }; bool expects_function = false; // Context.Scope->Start = currtok_noskip; if ( currtok_noskip.Type == TokType::Preprocess_Hash ) eat( TokType::Preprocess_Hash ); switch ( currtok_noskip.Type ) { case TokType::Statement_End: { // TODO(Ed): Convert this to a general warning procedure log_fmt("Dangling end statement found %S\n", currtok_noskip.to_string()); eat( TokType::Statement_End ); continue; } case TokType::NewLine: // Empty lines are auto skipped by Tokens.current() member = fmt_newline; eat( TokType::NewLine ); break; case TokType::Comment: member = parse_comment(); break; case TokType::Decl_Class: member = parse_complicated_definition( TokType::Decl_Class ); // class break; case TokType::Decl_Enum: member = parse_complicated_definition( TokType::Decl_Enum ); // enum break; case TokType::Decl_Extern_Linkage: if ( which == Extern_Linkage_Body ) log_failure( "Nested extern linkage\n%s", Context.to_string() ); member = parse_extern_link(); // extern "..." { ... } break; case TokType::Decl_Namespace: member = parse_namespace(); // namespace { ... } break; case TokType::Decl_Struct: member = parse_complicated_definition( TokType::Decl_Struct ); // struct ... break; case TokType::Decl_Template: member = parse_template(); // template<...> ... break; case TokType::Decl_Typedef: member = parse_typedef(); // typedef ... break; case TokType::Decl_Union: member = parse_complicated_definition( TokType::Decl_Union ); // union ... break; case TokType::Decl_Using: member = parse_using(); // using ... break; case TokType::Preprocess_Define: member = parse_define(); // #define ... break; case TokType::Preprocess_Include: member = parse_include(); // #include ... break; case TokType::Preprocess_If: case TokType::Preprocess_IfDef: case TokType::Preprocess_IfNotDef: case TokType::Preprocess_ElIf: member = parse_preprocess_cond(); // # ... break; case TokType::Preprocess_Else: member = preprocess_else; eat( TokType::Preprocess_Else ); // #else break; case TokType::Preprocess_EndIf: member = preprocess_endif; eat( TokType::Preprocess_EndIf ); // #endif break; case TokType::Preprocess_Macro: member = parse_simple_preprocess( TokType::Preprocess_Macro ); // break; case TokType::Preprocess_Pragma: member = parse_pragma(); // #pragma ... break; case TokType::Preprocess_Unsupported: member = parse_simple_preprocess( TokType::Preprocess_Unsupported ); // # ... break; case TokType::StaticAssert: member = parse_static_assert(); // static_assert( , ... ); break; case TokType::Module_Export: if ( which == Export_Body ) log_failure( "Nested export declaration\n%s", Context.to_string() ); member = parse_export_body(); // export { ... } break; case TokType::Module_Import: { not_implemented( context ); // import ... } //! Fallthrough intentional case TokType::Attribute_Open: case TokType::Decl_GNU_Attribute: case TokType::Decl_MSVC_Attribute: #define Entry( attribute, str ) case TokType::attribute: GEN_DEFINE_ATTRIBUTE_TOKENS #undef Entry { attributes = parse_attributes(); // } //! Fallthrough intentional case TokType::Spec_Consteval: case TokType::Spec_Constexpr: case TokType::Spec_Constinit: case TokType::Spec_Extern: case TokType::Spec_ForceInline: case TokType::Spec_Global: case TokType::Spec_Inline: case TokType::Spec_Internal_Linkage: case TokType::Spec_NeverInline: case TokType::Spec_Static: { SpecifierT specs_found[16] { ESpecifier::NumSpecifiers }; s32 NumSpecifiers = 0; while ( left && currtok.is_specifier() ) { SpecifierT spec = ESpecifier::to_type( currtok ); bool ignore_spec = false; switch ( spec ) { case ESpecifier::Constexpr: case ESpecifier::Constinit: case ESpecifier::ForceInline: case ESpecifier::Global: case ESpecifier::External_Linkage: case ESpecifier::Internal_Linkage: case ESpecifier::Inline: case ESpecifier::Mutable: case ESpecifier::NeverInline: case ESpecifier::Static: case ESpecifier::Volatile: break; case ESpecifier::Consteval: expects_function = true; break; case ESpecifier::Const: ignore_spec = true; break; default: StrC spec_str = ESpecifier::to_str(spec); log_failure( "Invalid specifier %.*s for variable\n%s", spec_str.Len, spec_str, Context.to_string() ); Context.pop(); return CodeInvalid; } if (ignore_spec) break; specs_found[NumSpecifiers] = spec; NumSpecifiers++; eat( currtok.Type ); } if ( NumSpecifiers ) { specifiers = def_specifiers( NumSpecifiers, specs_found ); } // } //! Fallthrough intentional case TokType::Identifier: case TokType::Spec_Const: case TokType::Type_Long: case TokType::Type_Short: case TokType::Type_Signed: case TokType::Type_Unsigned: case TokType::Type_bool: case TokType::Type_char: case TokType::Type_double: case TokType::Type_int: { Code constructor_destructor = parse_global_nspace_constructor_destructor( specifiers ); // Possible constructor implemented at global file scope. if ( constructor_destructor ) { member = constructor_destructor; break; } bool found_operator_cast_outside_class_implmentation = false; s32 idx = Context.Tokens.Idx; for ( ; idx < Context.Tokens.Arr.num(); idx++ ) { Token tok = Context.Tokens[ idx ]; if ( tok.Type == TokType::Identifier ) { idx++; tok = Context.Tokens[ idx ]; if ( tok.Type == TokType::Access_StaticSymbol ) continue; break; } if ( tok.Type == TokType::Decl_Operator ) found_operator_cast_outside_class_implmentation = true; break; } if ( found_operator_cast_outside_class_implmentation ) { member = parse_operator_cast( specifiers ); // ::operator () { ... } break; } member = parse_operator_function_or_variable( expects_function, attributes, specifiers ); // ... } } if ( member == Code::Invalid ) { log_failure( "Failed to parse member\n%s", Context.to_string() ); Context.pop(); return CodeInvalid; } // log_fmt("Global Body Member: %s", member->debug_str()); result.append( member ); } if ( which != Global_Body ) eat( TokType::BraceCurly_Close ); // { } Context.pop(); return result; } internal inline Code parse_global_nspace_constructor_destructor( CodeSpecifiers specifiers ) { Code result = { nullptr }; /* To check if a definition is for a constructor we can go straight to the opening parenthesis for its parameters From There we work backwards to see if we come across two identifiers with the same name between an member access :: operator, there can be template parameters on the left of the :: so we ignore those. Whats important is that its back to back. This has multiple possible faults. What we parse using this method may not filter out if something has a "return type" This is bad since technically you could have a namespace nested into another namespace with the same name. If this awful pattern is done the only way to distiguish with this coarse parse is to know there is no return type defined. TODO(Ed): We could fix this by attempting to parse a type, but we would have to have a way to have it soft fail and rollback. */ TokArray tokens = Context.Tokens; s32 idx = tokens.Idx; Token nav = tokens[ idx ]; for ( ; idx < tokens.Arr.num(); idx++, nav = tokens[ idx ] ) { if ( nav.Text[0] == '<' ) { // Skip templated expressions as they mey have expressions with the () operators s32 capture_level = 0; s32 template_level = 0; for ( ; idx < tokens.Arr.num(); idx++, nav = tokens[idx] ) { if (nav.Text[ 0 ] == '<') ++ template_level; if (nav.Text[ 0 ] == '>') -- template_level; if (nav.Type == TokType::Operator && nav.Text[1] == '>') -- template_level; if ( nav.Type == ETokType::Capture_Start) { if (template_level != 0 ) ++ capture_level; else break; } if ( template_level != 0 && nav.Type == ETokType::Capture_End) -- capture_level; } } if ( nav.Type == TokType::Capture_Start ) break; } -- idx; Token tok_right = tokens[idx]; Token tok_left = NullToken; if (tok_right.Type != TokType::Identifier) { // We're not dealing with a constructor if there is no identifier right before the opening of a parameter's scope. return result; } -- idx; tok_left = tokens[idx]; // ... bool possible_destructor = false; if ( tok_left.Type == TokType::Operator && tok_left.Text[0] == '~') { possible_destructor = true; -- idx; tok_left = tokens[idx]; } if ( tok_left.Type != TokType::Access_StaticSymbol ) return result; -- idx; tok_left = tokens[idx]; // ... :: // We search toward the left until we find the next valid identifier s32 capture_level = 0; s32 template_level = 0; while ( idx != tokens.Idx ) { if (tok_left.Text[ 0 ] == '<') ++ template_level; if (tok_left.Text[ 0 ] == '>') -- template_level; if (tok_left.Type == TokType::Operator && tok_left.Text[1] == '>') -- template_level; if ( template_level != 0 && tok_left.Type == ETokType::Capture_Start) ++ capture_level; if ( template_level != 0 && tok_left.Type == ETokType::Capture_End) -- capture_level; if ( capture_level == 0 && template_level == 0 && tok_left.Type == TokType::Identifier ) break; -- idx; tok_left = tokens[idx]; } bool is_same = str_compare( tok_right.Text, tok_left.Text, tok_right.Length ) == 0; if (tok_left.Type == TokType::Identifier && is_same) { // We have found the pattern we desired if (possible_destructor) { // :: ~ ( result = parse_destructor( specifiers ); } else { // :: ( result = parse_constructor( specifiers ); } } return result; } // TODO(Ed): I want to eventually change the identifier to its own AST type. // This would allow distinction of the qualifier for a symbol :: // This would also allow internal Token parse_identifier( bool* possible_member_function ) { push_scope(); Token name = currtok; Context.Scope->Name = name; eat( TokType::Identifier ); // parse_template_args( name ); //