ed/Odin
1
0
Fork 0
mirror of https://github.com/Ed94/Odin.git synced 2026-06-13 09:22:22 -07:00
Code Issues Packages Projects Releases Wiki Activity

Merge remote-tracking branch 'origin/master'

Browse Source
This commit is contained in:
Benoit Jacquier
2022-08-27 16:22:37 +02:00
parent 00f2e911a7 c82d7d3d87
commit 4e5337412a
109 changed files with 4860 additions and 3397 deletions
Download Patch File Download Diff File Expand all files Collapse all files
build_odin.sh
+34 -22
View File
@@ -1,12 +1,20 @@
#!/usr/bin/env bash
set -eu
GIT_SHA=$(git rev-parse --short HEAD)
: ${CXX=clang++}
: ${CPPFLAGS=}
: ${CXXFLAGS=}
: ${LDFLAGS=}
: ${ODIN_VERSION=dev-$(date +"%Y-%m")}
CPPFLAGS="$CPPFLAGS -DODIN_VERSION_RAW=\"$ODIN_VERSION\""
CXXFLAGS="$CXXFLAGS -std=c++14"
LDFLAGS="$LDFLAGS -pthread -lm -lstdc++"
GIT_SHA=$(git rev-parse --short HEAD || :)
if [ "$GIT_SHA" ]; then CPPFLAGS="$CPPFLAGS -DGIT_SHA=\"$GIT_SHA\""; fi
DISABLED_WARNINGS="-Wno-switch -Wno-macro-redefined -Wno-unused-value"
LDFLAGS="-pthread -lm -lstdc++"
CFLAGS="-std=c++14 -DGIT_SHA=\"$GIT_SHA\""
CFLAGS="$CFLAGS -DODIN_VERSION_RAW=\"dev-$(date +"%Y-%m")\""
CC=clang
OS=$(uname)
panic() {
@@ -18,13 +26,13 @@ version() { echo "$@" | awk -F. '{ printf("%d%03d%03d%03d\n", $1,$2,$3,$4); }';
config_darwin() {
ARCH=$(uname -m)
LLVM_CONFIG=llvm-config
: ${LLVM_CONFIG=llvm-config}
# allow for arm only llvm's with version 13
if [ ARCH == arm64 ]; then
MIN_LLVM_VERSION=("13.0.0")
else
# allow for x86 / amd64 all llvm versions begining from 11
# allow for x86 / amd64 all llvm versions beginning from 11
MIN_LLVM_VERSION=("11.1.0")
fi
@@ -37,34 +45,38 @@ config_darwin() {
fi
LDFLAGS="$LDFLAGS -liconv -ldl"
CFLAGS="$CFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
CXXFLAGS="$CXXFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
LDFLAGS="$LDFLAGS -lLLVM-C"
}
config_freebsd() {
LLVM_CONFIG=/usr/local/bin/llvm-config11
: ${LLVM_CONFIG=/usr/local/bin/llvm-config11}
CFLAGS="$CFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
CXXFLAGS="$CXXFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
LDFLAGS="$LDFLAGS $($LLVM_CONFIG --libs core native --system-libs)"
}
config_openbsd() {
LLVM_CONFIG=/usr/local/bin/llvm-config
: ${LLVM_CONFIG=/usr/local/bin/llvm-config}
LDFLAGS="$LDFLAGS -liconv"
CFLAGS="$CFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
CXXFLAGS="$CXXFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
LDFLAGS="$LDFLAGS $($LLVM_CONFIG --libs core native --system-libs)"
}
config_linux() {
if which llvm-config > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config
elif which llvm-config-11 > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config-11
elif which llvm-config-11-64 > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config-11-64
else
panic "Unable to find LLVM-config"
: ${LLVM_CONFIG=}
if [ ! "$LLVM_CONFIG" ]; then
if which llvm-config > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config
elif which llvm-config-11 > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config-11
elif which llvm-config-11-64 > /dev/null 2>&1; then
LLVM_CONFIG=llvm-config-11-64
else
panic "Unable to find LLVM-config"
fi
fi
MIN_LLVM_VERSION=("11.0.0")
@@ -74,7 +86,7 @@ config_linux() {
fi
LDFLAGS="$LDFLAGS -ldl"
CFLAGS="$CFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
CXXFLAGS="$CXXFLAGS $($LLVM_CONFIG --cxxflags --ldflags)"
LDFLAGS="$LDFLAGS $($LLVM_CONFIG --libs core native --system-libs)"
}
@@ -97,7 +109,7 @@ build_odin() {
esac
set -x
$CC src/main.cpp src/libtommath.cpp $DISABLED_WARNINGS $CFLAGS $EXTRAFLAGS $LDFLAGS -o odin
$CXX src/main.cpp src/libtommath.cpp $DISABLED_WARNINGS $CPPFLAGS $CXXFLAGS $EXTRAFLAGS $LDFLAGS -o odin
set +x
}
core/bufio/scanner.odin
+1 -1
View File
@@ -66,7 +66,7 @@ scanner_destroy :: proc(s: ^Scanner) {
}
// Returns the first non-EOF error that was encounted by the scanner
// Returns the first non-EOF error that was encountered by the scanner
scanner_error :: proc(s: ^Scanner) -> Scanner_Error {
switch s._err {
case .EOF, nil:
core/c/libc/math.odin
+1 -1
View File
@@ -331,7 +331,7 @@ fmin :: proc{libc_fmin, libc_fminf}
fma :: proc{libc_fma, libc_fmaf}
// But retain the 'f' suffix-variant functions as well so they can be used,
// a trick is used here where we use explicit procedrual overloading of one
// a trick is used here where we use explicit procedural overloading of one
// procedure. This is done because the foreign block is marked @(private) and
// aliasing functions does not remove privateness from the entity.
acosf :: proc{libc_acosf}
core/container/priority_queue/priority_queue.odin
-1
View File
@@ -85,7 +85,6 @@ _shift_down :: proc(pq: ^$Q/Priority_Queue($T), i0, n: int) -> bool {
_shift_up :: proc(pq: ^$Q/Priority_Queue($T), j: int) {
j := j
queue := pq.queue[:]
n := builtin.len(queue)
for 0 <= j {
i := (j-1)/2
if i == j || !pq.less(queue[j], queue[i]) {
core/crypto/README.md
+1 -1
View File
@@ -81,7 +81,7 @@ The crypto package is not thread-safe at the moment. This may change in the futu
### Disclaimer
The algorithms were ported out of curiosity and due to interest in the field.
We have not had any of the code verified by a third party or tested/fuzzed by any automatic means.
Whereever we were able to find official test vectors, those were used to verify the implementation.
Wherever we were able to find official test vectors, those were used to verify the implementation.
We do not recommend using them in a production environment, without any additional testing and/or verification.
### ToDo
core/crypto/_fiat/README.md
+1 -1
View File
@@ -30,6 +30,6 @@ equivalence.
For the most part, alterations to the base fiat-crypto generated code was
kept to a minimum, to aid auditability. This results in a somewhat
ideosyncratic style, and in some cases minor performance penalties.
idiosyncratic style, and in some cases minor performance penalties.
[1]: https://github.com/mit-plv/fiat-crypto
core/crypto/siphash/siphash.odin
+1 -1
View File
@@ -233,7 +233,7 @@ init :: proc(ctx: ^Context, key: []byte, c_rounds, d_rounds: int) {
}
update :: proc(ctx: ^Context, data: []byte) {
assert(ctx.is_initialized, "crypto/siphash: Context is not initalized")
assert(ctx.is_initialized, "crypto/siphash: Context is not initialized")
ctx.last_block = len(data) / 8 * 8
ctx.buf = data
i := 0
core/encoding/hxa/hxa.odin
+1 -1
View File
@@ -107,7 +107,7 @@ Node :: struct {
/* Conventions */
/* ------------
Much of HxA's use is based on convention. HxA lets users store arbitrary data in its structure that can be parsed but whose semantic meaning does not need to be understood.
A few conventions are hard, and some are soft. Hard convention that a user HAS to follow in order to produce a valid file. Hard conventions simplify parsing becaus the parser can make some assumptions. Soft convenbtions are basicly recomendations of how to store common data.
A few conventions are hard, and some are soft. Hard convention that a user HAS to follow in order to produce a valid file. Hard conventions simplify parsing becaus the parser can make some assumptions. Soft convenbtions are basically recomendations of how to store common data.
If you use HxA for something not covered by the conventions but need a convention for your use case. Please let us know so that we can add it!
*/
core/encoding/json/marshal.odin
+215 -40
View File
@@ -17,25 +17,54 @@ Marshal_Error :: union #shared_nil {
io.Error,
}
marshal :: proc(v: any, allocator := context.allocator) -> (data: []byte, err: Marshal_Error) {
// careful with MJSON maps & non quotes usage as keys without whitespace will lead to bad results
Marshal_Options :: struct {
// output based on spec
spec: Specification,
// use line breaks & tab|spaces
pretty: bool,
// spacing
use_spaces: bool,
spaces: int,
// state
indentation: int,
// option to output uint in JSON5 & MJSON
write_uint_as_hex: bool,
// mjson output options
mjson_keys_use_quotes: bool,
mjson_keys_use_equal_sign: bool,
// mjson state
mjson_skipped_first_braces_start: bool,
mjson_skipped_first_braces_end: bool,
}
marshal :: proc(v: any, opt: Marshal_Options = {}, allocator := context.allocator) -> (data: []byte, err: Marshal_Error) {
b := strings.builder_make(allocator)
defer if err != nil {
strings.builder_destroy(&b)
}
marshal_to_builder(&b, v) or_return
opt := opt
marshal_to_builder(&b, v, &opt) or_return
if len(b.buf) != 0 {
data = b.buf[:]
}
return data, nil
}
marshal_to_builder :: proc(b: ^strings.Builder, v: any) -> Marshal_Error {
return marshal_to_writer(strings.to_writer(b), v)
marshal_to_builder :: proc(b: ^strings.Builder, v: any, opt: ^Marshal_Options) -> Marshal_Error {
return marshal_to_writer(strings.to_writer(b), v, opt)
}
marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
marshal_to_writer :: proc(w: io.Writer, v: any, opt: ^Marshal_Options) -> (err: Marshal_Error) {
if v == nil {
io.write_string(w, "null") or_return
return
@@ -56,6 +85,7 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
case i16: u = u128(i)
case i32: u = u128(i)
case i64: u = u128(i)
case i128: u = u128(i)
case int: u = u128(i)
case u8: u = u128(i)
case u16: u = u128(i)
@@ -82,7 +112,21 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
case u128be: u = u128(i)
}
s := strconv.append_bits_128(buf[:], u, 10, info.signed, 8*ti.size, "0123456789", nil)
s: string
// allow uints to be printed as hex
if opt.write_uint_as_hex && (opt.spec == .JSON5 || opt.spec == .MJSON) {
switch i in a {
case u8, u16, u32, u64, u128:
s = strconv.append_bits_128(buf[:], u, 16, info.signed, 8*ti.size, "0123456789abcdef", { .Prefix })
case:
s = strconv.append_bits_128(buf[:], u, 10, info.signed, 8*ti.size, "0123456789", nil)
}
} else {
s = strconv.append_bits_128(buf[:], u, 10, info.signed, 8*ti.size, "0123456789", nil)
}
io.write_string(w, s) or_return
@@ -147,6 +191,9 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
case runtime.Type_Info_Multi_Pointer:
return .Unsupported_Type
case runtime.Type_Info_Soa_Pointer:
return .Unsupported_Type
case runtime.Type_Info_Procedure:
return .Unsupported_Type
@@ -166,52 +213,48 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
return .Unsupported_Type
case runtime.Type_Info_Array:
io.write_byte(w, '[') or_return
opt_write_start(w, opt, '[') or_return
for i in 0..<info.count {
if i > 0 { io.write_string(w, ", ") or_return }
opt_write_iteration(w, opt, i) or_return
data := uintptr(v.data) + uintptr(i*info.elem_size)
marshal_to_writer(w, any{rawptr(data), info.elem.id}) or_return
marshal_to_writer(w, any{rawptr(data), info.elem.id}, opt) or_return
}
io.write_byte(w, ']') or_return
opt_write_end(w, opt, ']') or_return
case runtime.Type_Info_Enumerated_Array:
index := runtime.type_info_base(info.index).variant.(runtime.Type_Info_Enum)
io.write_byte(w, '[') or_return
opt_write_start(w, opt, '[') or_return
for i in 0..<info.count {
if i > 0 { io.write_string(w, ", ") or_return }
opt_write_iteration(w, opt, i) or_return
data := uintptr(v.data) + uintptr(i*info.elem_size)
marshal_to_writer(w, any{rawptr(data), info.elem.id}) or_return
marshal_to_writer(w, any{rawptr(data), info.elem.id}, opt) or_return
}
io.write_byte(w, ']') or_return
opt_write_end(w, opt, ']') or_return
case runtime.Type_Info_Dynamic_Array:
io.write_byte(w, '[') or_return
opt_write_start(w, opt, '[') or_return
array := cast(^mem.Raw_Dynamic_Array)v.data
for i in 0..<array.len {
if i > 0 { io.write_string(w, ", ") or_return }
opt_write_iteration(w, opt, i) or_return
data := uintptr(array.data) + uintptr(i*info.elem_size)
marshal_to_writer(w, any{rawptr(data), info.elem.id}) or_return
marshal_to_writer(w, any{rawptr(data), info.elem.id}, opt) or_return
}
io.write_byte(w, ']') or_return
opt_write_end(w, opt, ']') or_return
case runtime.Type_Info_Slice:
io.write_byte(w, '[') or_return
opt_write_start(w, opt, '[') or_return
slice := cast(^mem.Raw_Slice)v.data
for i in 0..<slice.len {
if i > 0 { io.write_string(w, ", ") or_return }
opt_write_iteration(w, opt, i) or_return
data := uintptr(slice.data) + uintptr(i*info.elem_size)
marshal_to_writer(w, any{rawptr(data), info.elem.id}) or_return
marshal_to_writer(w, any{rawptr(data), info.elem.id}, opt) or_return
}
io.write_byte(w, ']') or_return
opt_write_end(w, opt, ']') or_return
case runtime.Type_Info_Map:
m := (^mem.Raw_Map)(v.data)
opt_write_start(w, opt, '{') or_return
io.write_byte(w, '{') or_return
if m != nil {
if info.generated_struct == nil {
return .Unsupported_Type
@@ -223,31 +266,50 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
entry_size := ed.elem_size
for i in 0..<entries.len {
if i > 0 { io.write_string(w, ", ") or_return }
opt_write_iteration(w, opt, i) or_return
data := uintptr(entries.data) + uintptr(i*entry_size)
key := rawptr(data + entry_type.offsets[2])
value := rawptr(data + entry_type.offsets[3])
marshal_to_writer(w, any{key, info.key.id}) or_return
io.write_string(w, ": ") or_return
marshal_to_writer(w, any{value, info.value.id}) or_return
// check for string type
{
v := any{key, info.key.id}
ti := runtime.type_info_base(type_info_of(v.id))
a := any{v.data, ti.id}
name: string
#partial switch info in ti.variant {
case runtime.Type_Info_String:
switch s in a {
case string: name = s
case cstring: name = string(s)
}
opt_write_key(w, opt, name) or_return
case: return .Unsupported_Type
}
}
marshal_to_writer(w, any{value, info.value.id}, opt) or_return
}
}
io.write_byte(w, '}') or_return
opt_write_end(w, opt, '}') or_return
case runtime.Type_Info_Struct:
io.write_byte(w, '{') or_return
opt_write_start(w, opt, '{') or_return
for name, i in info.names {
if i > 0 { io.write_string(w, ", ") or_return }
io.write_quoted_string(w, name) or_return
io.write_string(w, ": ") or_return
opt_write_iteration(w, opt, i) or_return
opt_write_key(w, opt, name) or_return
id := info.types[i].id
data := rawptr(uintptr(v.data) + info.offsets[i])
marshal_to_writer(w, any{data, id}) or_return
marshal_to_writer(w, any{data, id}, opt) or_return
}
io.write_byte(w, '}') or_return
opt_write_end(w, opt, '}') or_return
case runtime.Type_Info_Union:
tag_ptr := uintptr(v.data) + info.tag_offset
@@ -270,11 +332,11 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
io.write_string(w, "null") or_return
} else {
id := info.variants[tag-1].id
return marshal_to_writer(w, any{v.data, id})
return marshal_to_writer(w, any{v.data, id}, opt)
}
case runtime.Type_Info_Enum:
return marshal_to_writer(w, any{v.data, info.base.id})
return marshal_to_writer(w, any{v.data, info.base.id}, opt)
case runtime.Type_Info_Bit_Set:
is_bit_set_different_endian_to_platform :: proc(ti: ^runtime.Type_Info) -> bool {
@@ -330,3 +392,116 @@ marshal_to_writer :: proc(w: io.Writer, v: any) -> (err: Marshal_Error) {
return
}
// write key as quoted string or with optional quotes in mjson
opt_write_key :: proc(w: io.Writer, opt: ^Marshal_Options, name: string) -> (err: io.Error) {
switch opt.spec {
case .JSON, .JSON5:
io.write_quoted_string(w, name) or_return
io.write_string(w, ": ") or_return
case .MJSON:
if opt.mjson_keys_use_quotes {
io.write_quoted_string(w, name) or_return
} else {
io.write_string(w, name) or_return
}
if opt.mjson_keys_use_equal_sign {
io.write_string(w, " = ") or_return
} else {
io.write_string(w, ": ") or_return
}
}
return
}
// insert start byte and increase indentation on pretty
opt_write_start :: proc(w: io.Writer, opt: ^Marshal_Options, c: byte) -> (err: io.Error) {
// skip mjson starting braces
if opt.spec == .MJSON && !opt.mjson_skipped_first_braces_start {
opt.mjson_skipped_first_braces_start = true
return
}
io.write_byte(w, c) or_return
opt.indentation += 1
if opt.pretty {
io.write_byte(w, '\n') or_return
}
return
}
// insert comma seperation and write indentations
opt_write_iteration :: proc(w: io.Writer, opt: ^Marshal_Options, iteration: int) -> (err: io.Error) {
switch opt.spec {
case .JSON, .JSON5:
if iteration > 0 {
io.write_string(w, ", ") or_return
if opt.pretty {
io.write_byte(w, '\n') or_return
}
}
opt_write_indentation(w, opt) or_return
case .MJSON:
if iteration > 0 {
// on pretty no commas necessary
if opt.pretty {
io.write_byte(w, '\n') or_return
} else {
// comma seperation necessary for non pretty output!
io.write_string(w, ", ") or_return
}
}
opt_write_indentation(w, opt) or_return
}
return
}
// decrease indent, write spacing and insert end byte
opt_write_end :: proc(w: io.Writer, opt: ^Marshal_Options, c: byte) -> (err: io.Error) {
if opt.spec == .MJSON && opt.mjson_skipped_first_braces_start && !opt.mjson_skipped_first_braces_end {
if opt.indentation == 0 {
opt.mjson_skipped_first_braces_end = true
return
}
}
opt.indentation -= 1
if opt.pretty {
io.write_byte(w, '\n') or_return
opt_write_indentation(w, opt) or_return
}
io.write_byte(w, c) or_return
return
}
// writes current indentation level based on options
opt_write_indentation :: proc(w: io.Writer, opt: ^Marshal_Options) -> (err: io.Error) {
if !opt.pretty {
return
}
if opt.use_spaces {
spaces := opt.spaces == 0 ? 4 : opt.spaces
for _ in 0..<opt.indentation * spaces {
io.write_byte(w, ' ') or_return
}
} else {
for _ in 0..<opt.indentation {
io.write_byte(w, '\t') or_return
}
}
return
}
core/encoding/json/unmarshal.odin
+2 -2
View File
@@ -325,7 +325,7 @@ unmarshal_object :: proc(p: ^Parser, v: any, end_token: Token_Kind) -> (err: Unm
UNSUPPORTED_TYPE := Unsupported_Type_Error{v.id, p.curr_token}
if end_token == .Close_Brace {
assert(expect_token(p, .Open_Brace) == nil)
unmarshal_expect_token(p, .Open_Brace)
}
v := v
@@ -473,7 +473,7 @@ unmarshal_object :: proc(p: ^Parser, v: any, end_token: Token_Kind) -> (err: Unm
}
if end_token == .Close_Brace {
assert(expect_token(p, .Close_Brace) == nil)
unmarshal_expect_token(p, .Close_Brace)
}
return
}
core/fmt/fmt.odin
+30 -2
View File
@@ -1031,6 +1031,15 @@ fmt_pointer :: proc(fi: ^Info, p: rawptr, verb: rune) {
}
}
fmt_soa_pointer :: proc(fi: ^Info, p: runtime.Raw_Soa_Pointer, verb: rune) {
io.write_string(fi.writer, "#soa{data=0x", &fi.n)
_fmt_int(fi, u64(uintptr(p.data)), 16, false, 8*size_of(rawptr), __DIGITS_UPPER)
io.write_string(fi.writer, ", index=", &fi.n)
_fmt_int(fi, u64(p.index), 10, false, 8*size_of(rawptr), __DIGITS_UPPER)
io.write_string(fi.writer, "}", &fi.n)
}
enum_value_to_string :: proc(val: any) -> (string, bool) {
v := val
v.id = runtime.typeid_base(v.id)
@@ -1867,6 +1876,10 @@ fmt_value :: proc(fi: ^Info, v: any, verb: rune) {
fmt_pointer(fi, ptr, verb)
}
case runtime.Type_Info_Soa_Pointer:
ptr := (^runtime.Raw_Soa_Pointer)(v.data)^
fmt_soa_pointer(fi, ptr, verb)
case runtime.Type_Info_Multi_Pointer:
ptr := (^rawptr)(v.data)^
if ptr == nil {
@@ -2046,18 +2059,33 @@ fmt_value :: proc(fi: ^Info, v: any, verb: rune) {
ed := runtime.type_info_base(gs.types[1]).variant.(runtime.Type_Info_Dynamic_Array)
entry_type := ed.elem.variant.(runtime.Type_Info_Struct)
entry_size := ed.elem_size
/*
NOTE: The layout of a `map` is as follows:
map[Key]Value
## Internal Layout
struct {
hashes: []int,
entries: [dynamic]struct{
hash: uintptr,
next: int,
key: Key,
value: Value,
},
}
*/
for i in 0..<entries.len {
if i > 0 { io.write_string(fi.writer, ", ", &fi.n) }
data := uintptr(entries.data) + uintptr(i*entry_size)
key := data + entry_type.offsets[2]
key := data + entry_type.offsets[2] // key: Key
fmt_arg(&Info{writer = fi.writer}, any{rawptr(key), info.key.id}, 'v')
io.write_string(fi.writer, "=", &fi.n)
value := data + entry_type.offsets[3]
value := data + entry_type.offsets[3] // value: Value
fmt_arg(fi, any{rawptr(value), info.value.id}, 'v')
}
}
core/image/common.odin
+5 -5
View File
@@ -475,7 +475,7 @@ return_single_channel :: proc(img: ^Image, channel: Channel) -> (res: ^Image, ok
}
// Does the image have 1 or 2 channels, a valid bit depth (8 or 16),
// Is the pointer valid, are the dimenions valid?
// Is the pointer valid, are the dimensions valid?
is_valid_grayscale_image :: proc(img: ^Image) -> (ok: bool) {
// Were we actually given a valid image?
if img == nil {
@@ -495,7 +495,7 @@ is_valid_grayscale_image :: proc(img: ^Image) -> (ok: bool) {
// This returns 0 if any of the inputs is zero.
bytes_expected := compute_buffer_size(img.width, img.height, img.channels, img.depth)
// If the dimenions are invalid or the buffer size doesn't match the image characteristics, bail.
// If the dimensions are invalid or the buffer size doesn't match the image characteristics, bail.
if bytes_expected == 0 || bytes_expected != len(img.pixels.buf) || img.width * img.height > MAX_DIMENSIONS {
return false
}
@@ -504,7 +504,7 @@ is_valid_grayscale_image :: proc(img: ^Image) -> (ok: bool) {
}
// Does the image have 3 or 4 channels, a valid bit depth (8 or 16),
// Is the pointer valid, are the dimenions valid?
// Is the pointer valid, are the dimensions valid?
is_valid_color_image :: proc(img: ^Image) -> (ok: bool) {
// Were we actually given a valid image?
if img == nil {
@@ -524,7 +524,7 @@ is_valid_color_image :: proc(img: ^Image) -> (ok: bool) {
// This returns 0 if any of the inputs is zero.
bytes_expected := compute_buffer_size(img.width, img.height, img.channels, img.depth)
// If the dimenions are invalid or the buffer size doesn't match the image characteristics, bail.
// If the dimensions are invalid or the buffer size doesn't match the image characteristics, bail.
if bytes_expected == 0 || bytes_expected != len(img.pixels.buf) || img.width * img.height > MAX_DIMENSIONS {
return false
}
@@ -533,7 +533,7 @@ is_valid_color_image :: proc(img: ^Image) -> (ok: bool) {
}
// Does the image have 1..4 channels, a valid bit depth (8 or 16),
// Is the pointer valid, are the dimenions valid?
// Is the pointer valid, are the dimensions valid?
is_valid_image :: proc(img: ^Image) -> (ok: bool) {
// Were we actually given a valid image?
if img == nil {
core/image/png/example.odin
+1 -1
View File
@@ -219,7 +219,7 @@ write_image_as_ppm :: proc(filename: string, image: ^image.Image) -> (success: b
defer close(fd)
write_string(fd,
fmt.tprintf("P6\n%v %v\n%v\n", width, height, (1 << uint(depth) - 1)),
fmt.tprintf("P6\n%v %v\n%v\n", width, height, uint(1 << uint(depth) - 1)),
)
if channels == 3 {
core/image/png/png.odin
+3 -3
View File
@@ -1002,7 +1002,7 @@ load_from_context :: proc(ctx: ^$C, options := Options{}, allocator := context.a
o16 = o16[out_image_channels:]
}
case:
unreachable("We should never seen # channels other than 1-4 inclusive.")
panic("We should never seen # channels other than 1-4 inclusive.")
}
img.pixels = t
@@ -1195,7 +1195,7 @@ load_from_context :: proc(ctx: ^$C, options := Options{}, allocator := context.a
o = o[out_image_channels:]
}
case:
unreachable("We should never seen # channels other than 1-4 inclusive.")
panic("We should never seen # channels other than 1-4 inclusive.")
}
img.pixels = t
@@ -1206,7 +1206,7 @@ load_from_context :: proc(ctx: ^$C, options := Options{}, allocator := context.a
This may change if we ever don't expand 1, 2 and 4 bit images. But, those raw
returns will likely bypass this processing pipeline.
*/
unreachable("We should never see bit depths other than 8, 16 and 'Paletted' here.")
panic("We should never see bit depths other than 8, 16 and 'Paletted' here.")
}
return img, nil
core/intrinsics/intrinsics.odin
+3
View File
@@ -295,6 +295,9 @@ objc_register_selector :: proc($name: string) -> objc_SEL ---
objc_find_class :: proc($name: string) -> objc_Class ---
objc_register_class :: proc($name: string) -> objc_Class ---
valgrind_client_request :: proc(default: uintptr, request: uintptr, a0, a1, a2, a3, a4: uintptr) -> uintptr ---
// Internal compiler use only
__entry_point :: proc() ---
core/log/file_console_logger.odin
+2 -2
View File
@@ -56,7 +56,7 @@ create_console_logger :: proc(lowest := Level.Debug, opt := Default_Console_Logg
return Logger{file_console_logger_proc, data, lowest, opt}
}
destroy_console_logger :: proc(log: ^Logger) {
destroy_console_logger :: proc(log: Logger) {
free(log.data)
}
@@ -95,7 +95,7 @@ file_console_logger_proc :: proc(logger_data: rawptr, level: Level, text: string
fmt.sbprintf(&buf, "[%s] ", data.ident)
}
//TODO(Hoej): When we have better atomics and such, make this thread-safe
fmt.fprintf(h, "%s %s\n", strings.to_string(buf), text)
fmt.fprintf(h, "%s%s\n", strings.to_string(buf), text)
}
do_level_header :: proc(opts: Options, level: Level, str: ^strings.Builder) {
core/log/log.odin
+5 -6
View File
@@ -6,7 +6,6 @@ import "core:fmt"
// NOTE(bill, 2019-12-31): These are defined in `package runtime` as they are used in the `context`. This is to prevent an import definition cycle.
Level :: runtime.Logger_Level
/*
Logger_Level :: enum {
Debug = 0,
@@ -16,8 +15,8 @@ Logger_Level :: enum {
Fatal = 40,
}
*/
Level :: runtime.Logger_Level
Option :: runtime.Logger_Option
/*
Option :: enum {
Level,
@@ -30,11 +29,12 @@ Option :: enum {
Terminal_Color
}
*/
Option :: runtime.Logger_Option
Options :: runtime.Logger_Options
/*
Options :: bit_set[Option];
*/
Options :: runtime.Logger_Options
Full_Timestamp_Opts :: Options{
.Date,
@@ -52,12 +52,11 @@ Location_File_Opts :: Options{
}
Logger_Proc :: runtime.Logger_Proc
/*
Logger_Proc :: #type proc(data: rawptr, level: Level, text: string, options: Options, location := #caller_location);
*/
Logger_Proc :: runtime.Logger_Proc
Logger :: runtime.Logger
/*
Logger :: struct {
procedure: Logger_Proc,
@@ -66,6 +65,7 @@ Logger :: struct {
options: Logger_Options,
}
*/
Logger :: runtime.Logger
nil_logger_proc :: proc(data: rawptr, level: Level, text: string, options: Options, location := #caller_location) {
// Do nothing
@@ -75,7 +75,6 @@ nil_logger :: proc() -> Logger {
return Logger{nil_logger_proc, nil, Level.Debug, nil}
}
// TODO(bill): Should these be redesigned so that they are do not rely upon `package fmt`?
debugf :: proc(fmt_str: string, args: ..any, location := #caller_location) {
logf(level=.Debug, fmt_str=fmt_str, args=args, location=location)
}
core/log/log_allocator.odin
+107
View File
@@ -0,0 +1,107 @@
package log
import "core:runtime"
Log_Allocator :: struct {
allocator: runtime.Allocator,
level: Level,
prefix: string,
locked: bool,
}
log_allocator_init :: proc(la: ^Log_Allocator, level: Level, allocator := context.allocator, prefix := "") {
la.allocator = allocator
la.level = level
la.prefix = prefix
la.locked = false
}
log_allocator :: proc(la: ^Log_Allocator) -> runtime.Allocator {
return runtime.Allocator{
procedure = log_allocator_proc,
data = la,
}
}
log_allocator_proc :: proc(allocator_data: rawptr, mode: runtime.Allocator_Mode,
size, alignment: int,
old_memory: rawptr, old_size: int, location := #caller_location) -> ([]byte, runtime.Allocator_Error) {
la := (^Log_Allocator)(allocator_data)
padding := " " if la.prefix != "" else ""
if !la.locked {
la.locked = true
defer la.locked = false
switch mode {
case .Alloc:
logf(
level=la.level,
fmt_str = "%s%s>>> ALLOCATOR(mode=.Alloc, size=%d, alignment=%d)",
args = {la.prefix, padding, size, alignment},
location = location,
)
case .Free:
if old_size != 0 {
logf(
level=la.level,
fmt_str = "%s%s<<< ALLOCATOR(mode=.Free, ptr=%p, size=%d)",
args = {la.prefix, padding, old_memory, old_size},
location = location,
)
} else {
logf(
level=la.level,
fmt_str = "%s%s<<< ALLOCATOR(mode=.Free, ptr=%p)",
args = {la.prefix, padding, old_memory},
location = location,
)
}
case .Free_All:
logf(
level=la.level,
fmt_str = "%s%s<<< ALLOCATOR(mode=.Free_All)",
args = {la.prefix, padding},
location = location,
)
case .Resize:
logf(
level=la.level,
fmt_str = "%s%s>>> ALLOCATOR(mode=.Resize, ptr=%p, old_size=%d, size=%d, alignment=%d)",
args = {la.prefix, padding, old_memory, old_size, size, alignment},
location = location,
)
case .Query_Features:
logf(
level=la.level,
fmt_str = "%s%ALLOCATOR(mode=.Query_Features)",
args = {la.prefix, padding},
location = location,
)
case .Query_Info:
logf(
level=la.level,
fmt_str = "%s%ALLOCATOR(mode=.Query_Info)",
args = {la.prefix, padding},
location = location,
)
}
}
data, err := la.allocator.procedure(la.allocator.data, mode, size, alignment, old_memory, old_size, location)
if !la.locked {
la.locked = true
defer la.locked = false
if err != nil {
logf(
level=la.level,
fmt_str = "%s%ALLOCATOR ERROR=%v",
args = {la.prefix, padding, error},
location = location,
)
}
}
return data, err
}
core/math/big/prime.odin
+1 -1
View File
@@ -449,7 +449,7 @@ internal_int_is_prime :: proc(a: ^Int, miller_rabin_trials := int(-1), miller_ra
in the loop is non-zero, although very low.
-- NOTE(Jeroen): This is not yet true in Odin, but I have some ideas.
If the BPSW test and/or the addtional Frobenious test have been
If the BPSW test and/or the additional Frobenious test have been
performed instead of just the Miller-Rabin test with the bases 2 and 3,
a single extra test should suffice, so such a very unlikely event will not do much harm.
core/math/linalg/general.odin
+3 -3
View File
@@ -94,7 +94,7 @@ quaternion_cross :: proc(q1, q2: $Q) -> (q3: Q) where IS_QUATERNION(Q) {
vector_cross :: proc{scalar_cross, vector_cross2, vector_cross3}
cross :: proc{scalar_cross, vector_cross2, vector_cross3, quaternion_cross}
vector_normalize :: proc(v: $T/[$N]$E) -> T where IS_NUMERIC(E) {
vector_normalize :: proc(v: $T/[$N]$E) -> T where IS_FLOAT(E) {
return v / length(v)
}
quaternion_normalize :: proc(q: $Q) -> Q where IS_QUATERNION(Q) {
@@ -102,7 +102,7 @@ quaternion_normalize :: proc(q: $Q) -> Q where IS_QUATERNION(Q) {
}
normalize :: proc{vector_normalize, quaternion_normalize}
vector_normalize0 :: proc(v: $T/[$N]$E) -> T where IS_NUMERIC(E) {
vector_normalize0 :: proc(v: $T/[$N]$E) -> T where IS_FLOAT(E) {
m := length(v)
return 0 if m == 0 else v/m
}
@@ -113,7 +113,7 @@ quaternion_normalize0 :: proc(q: $Q) -> Q where IS_QUATERNION(Q) {
normalize0 :: proc{vector_normalize0, quaternion_normalize0}
vector_length :: proc(v: $T/[$N]$E) -> E where IS_NUMERIC(E) {
vector_length :: proc(v: $T/[$N]$E) -> E where IS_FLOAT(E) {
return math.sqrt(dot(v, v))
}
core/math/math.odin
+36 -10
View File
@@ -185,16 +185,23 @@ log :: proc{
log_f64, log_f64le, log_f64be,
}
log2_f16 :: logb_f16
log2_f16le :: logb_f16le
log2_f16be :: logb_f16be
log2_f32 :: logb_f32
log2_f32le :: logb_f32le
log2_f32be :: logb_f32be
log2_f64 :: logb_f64
log2_f64le :: logb_f64le
log2_f64be :: logb_f64be
log2 :: logb
log2_f16 :: proc "contextless" (x: f16) -> f16 { return log(f16(x), f16(2.0)) }
log2_f16le :: proc "contextless" (x: f16le) -> f16le { return f16le(log_f16(f16(x), f16(2.0))) }
log2_f16be :: proc "contextless" (x: f16be) -> f16be { return f16be(log_f16(f16(x), f16(2.0))) }
log2_f32 :: proc "contextless" (x: f32) -> f32 { return log(f32(x), f32(2.0)) }
log2_f32le :: proc "contextless" (x: f32le) -> f32le { return f32le(log_f32(f32(x), f32(2.0))) }
log2_f32be :: proc "contextless" (x: f32be) -> f32be { return f32be(log_f32(f32(x), f32(2.0))) }
log2_f64 :: proc "contextless" (x: f64) -> f64 { return log(f64(x), f64(2.0)) }
log2_f64le :: proc "contextless" (x: f64le) -> f64le { return f64le(log_f64(f64(x), f64(2.0))) }
log2_f64be :: proc "contextless" (x: f64be) -> f64be { return f64be(log_f64(f64(x), f64(2.0))) }
log2 :: proc{
log2_f16, log2_f16le, log2_f16be,
log2_f32, log2_f32le, log2_f32be,
log2_f64, log2_f64le, log2_f64be,
}
log10_f16 :: proc "contextless" (x: f16) -> f16 { return ln(x)/LN10 }
log10_f16le :: proc "contextless" (x: f16le) -> f16le { return f16le(log10_f16(f16(x))) }
@@ -607,6 +614,25 @@ floor_mod :: proc "contextless" (x, y: $T) -> T
return r
}
divmod :: #force_inline proc "contextless" (x, y: $T) -> (div, mod: T)
where intrinsics.type_is_integer(T) {
div = x / y
mod = x % y
return
}
floor_divmod :: #force_inline proc "contextless" (x, y: $T) -> (div, mod: T)
where intrinsics.type_is_integer(T) {
div = x / y
mod = x % y
if (div > 0 && y < 0) || (mod < 0 && y > 0) {
div -= 1
mod += y
}
return
}
modf_f16 :: proc "contextless" (x: f16) -> (int: f16, frac: f16) {
shift :: F16_SHIFT
mask :: F16_MASK
core/mem/alloc.odin
+9 -85
View File
@@ -61,114 +61,38 @@ DEFAULT_PAGE_SIZE ::
4 * 1024
alloc :: proc(size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> rawptr {
if size == 0 {
return nil
}
if allocator.procedure == nil {
return nil
}
data, err := allocator.procedure(allocator.data, Allocator_Mode.Alloc, size, alignment, nil, 0, loc)
_ = err
data, _ := runtime.mem_alloc(size, alignment, allocator, loc)
return raw_data(data)
}
alloc_bytes :: proc(size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> ([]byte, Allocator_Error) {
if size == 0 {
return nil, nil
}
if allocator.procedure == nil {
return nil, nil
}
return allocator.procedure(allocator.data, Allocator_Mode.Alloc, size, alignment, nil, 0, loc)
return runtime.mem_alloc(size, alignment, allocator, loc)
}
free :: proc(ptr: rawptr, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if ptr == nil {
return nil
}
if allocator.procedure == nil {
return nil
}
_, err := allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, ptr, 0, loc)
return err
return runtime.mem_free(ptr, allocator, loc)
}
free_bytes :: proc(bytes: []byte, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if bytes == nil {
return nil
}
if allocator.procedure == nil {
return nil
}
_, err := allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, raw_data(bytes), len(bytes), loc)
return err
return runtime.mem_free_bytes(bytes, allocator, loc)
}
free_all :: proc(allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if allocator.procedure != nil {
_, err := allocator.procedure(allocator.data, Allocator_Mode.Free_All, 0, 0, nil, 0, loc)
return err
}
return nil
return runtime.mem_free_all(allocator, loc)
}
resize :: proc(ptr: rawptr, old_size, new_size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> rawptr {
if allocator.procedure == nil {
return nil
}
if new_size == 0 {
if ptr != nil {
allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, ptr, old_size, loc)
}
return nil
} else if ptr == nil {
_, err := allocator.procedure(allocator.data, Allocator_Mode.Alloc, new_size, alignment, nil, 0, loc)
_ = err
return nil
}
data, err := allocator.procedure(allocator.data, Allocator_Mode.Resize, new_size, alignment, ptr, old_size, loc)
if err == .Mode_Not_Implemented {
data, err = allocator.procedure(allocator.data, Allocator_Mode.Alloc, new_size, alignment, nil, 0, loc)
if err != nil {
return nil
}
runtime.copy(data, byte_slice(ptr, old_size))
_, err = allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, ptr, old_size, loc)
return raw_data(data)
}
data, _ := runtime.mem_resize(ptr, old_size, new_size, alignment, allocator, loc)
return raw_data(data)
}
resize_bytes :: proc(old_data: []byte, new_size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> ([]byte, Allocator_Error) {
if allocator.procedure == nil {
return nil, nil
}
ptr := raw_data(old_data)
old_size := len(old_data)
if new_size == 0 {
if ptr != nil {
_, err := allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, ptr, old_size, loc)
return nil, err
}
return nil, nil
} else if ptr == nil {
return allocator.procedure(allocator.data, Allocator_Mode.Alloc, new_size, alignment, nil, 0, loc)
}
data, err := allocator.procedure(allocator.data, Allocator_Mode.Resize, new_size, alignment, ptr, old_size, loc)
if err == .Mode_Not_Implemented {
data, err = allocator.procedure(allocator.data, Allocator_Mode.Alloc, new_size, alignment, nil, 0, loc)
if err != nil {
return data, err
}
runtime.copy(data, old_data)
_, err = allocator.procedure(allocator.data, Allocator_Mode.Free, 0, 0, ptr, old_size, loc)
}
return data, err
return runtime.mem_resize(raw_data(old_data), len(old_data), new_size, alignment, allocator, loc)
}
query_features :: proc(allocator: Allocator, loc := #caller_location) -> (set: Allocator_Mode_Set) {
if allocator.procedure != nil {
allocator.procedure(allocator.data, Allocator_Mode.Query_Features, 0, 0, &set, 0, loc)
allocator.procedure(allocator.data, .Query_Features, 0, 0, &set, 0, loc)
return set
}
return nil
@@ -177,7 +101,7 @@ query_features :: proc(allocator: Allocator, loc := #caller_location) -> (set: A
query_info :: proc(pointer: rawptr, allocator: Allocator, loc := #caller_location) -> (props: Allocator_Query_Info) {
props.pointer = pointer
if allocator.procedure != nil {
allocator.procedure(allocator.data, Allocator_Mode.Query_Info, 0, 0, &props, 0, loc)
allocator.procedure(allocator.data, .Query_Info, 0, 0, &props, 0, loc)
}
return
}
core/mem/allocators.odin
+29 -6
View File
@@ -31,6 +31,14 @@ Arena_Temp_Memory :: struct {
}
arena_init :: proc(a: ^Arena, data: []byte) {
a.data = data
a.offset = 0
a.peak_used = 0
a.temp_count = 0
}
@(deprecated="prefer 'mem.arena_init'")
init_arena :: proc(a: ^Arena, data: []byte) {
a.data = data
a.offset = 0
@@ -293,6 +301,14 @@ Stack :: struct {
peak_used: int,
}
stack_init :: proc(s: ^Stack, data: []byte) {
s.data = data
s.prev_offset = 0
s.curr_offset = 0
s.peak_used = 0
}
@(deprecated="prefer 'mem.stack_init'")
init_stack :: proc(s: ^Stack, data: []byte) {
s.data = data
s.prev_offset = 0
@@ -445,27 +461,34 @@ Small_Stack_Allocation_Header :: struct {
// Small_Stack is a stack-like allocator which uses the smallest possible header but at the cost of non-strict memory freeing order
Small_Stack :: struct {
data: []byte,
offset: int,
data: []byte,
offset: int,
peak_used: int,
}
small_stack_init :: proc(s: ^Small_Stack, data: []byte) {
s.data = data
s.offset = 0
s.peak_used = 0
}
@(deprecated="prefer 'small_stack_init'")
init_small_stack :: proc(s: ^Small_Stack, data: []byte) {
s.data = data
s.offset = 0
s.data = data
s.offset = 0
s.peak_used = 0
}
small_stack_allocator :: proc(stack: ^Small_Stack) -> Allocator {
return Allocator{
procedure = small_stack_allocator_proc,
data = stack,
data = stack,
}
}
small_stack_allocator_proc :: proc(allocator_data: rawptr, mode: Allocator_Mode,
size, alignment: int,
old_memory: rawptr, old_size: int, ocation := #caller_location) -> ([]byte, Allocator_Error) {
old_memory: rawptr, old_size: int, location := #caller_location) -> ([]byte, Allocator_Error) {
s := cast(^Small_Stack)allocator_data
if s.data == nil {
core/mem/mem.odin
+1 -42
View File
@@ -54,48 +54,7 @@ compare :: proc "contextless" (a, b: []byte) -> int {
}
compare_byte_ptrs :: proc "contextless" (a, b: ^byte, n: int) -> int #no_bounds_check {
switch {
case a == b:
return 0
case a == nil:
return -1
case b == nil:
return -1
case n == 0:
return 0
}
x := slice_ptr(a, n)
y := slice_ptr(b, n)
SU :: size_of(uintptr)
fast := n/SU + 1
offset := (fast-1)*SU
curr_block := 0
if n < SU {
fast = 0
}
la := slice_ptr((^uintptr)(a), fast)
lb := slice_ptr((^uintptr)(b), fast)
for /**/; curr_block < fast; curr_block += 1 {
if la[curr_block] ~ lb[curr_block] != 0 {
for pos := curr_block*SU; pos < n; pos += 1 {
if x[pos] ~ y[pos] != 0 {
return (int(x[pos]) - int(y[pos])) < 0 ? -1 : +1
}
}
}
}
for /**/; offset < n; offset += 1 {
if x[offset] ~ y[offset] != 0 {
return (int(x[offset]) - int(y[offset])) < 0 ? -1 : +1
}
}
return 0
return runtime.memory_compare(a, b, n)
}
check_zero :: proc(data: []byte) -> bool {
core/mem/raw.odin
+1
View File
@@ -8,6 +8,7 @@ Raw_Cstring :: runtime.Raw_Cstring
Raw_Slice :: runtime.Raw_Slice
Raw_Dynamic_Array :: runtime.Raw_Dynamic_Array
Raw_Map :: runtime.Raw_Map
Raw_Soa_Pointer :: runtime.Raw_Soa_Pointer
Raw_Complex64 :: struct {real, imag: f32}
Raw_Complex128 :: struct {real, imag: f64}
core/mem/virtual/arena_util.odin
+5
View File
@@ -1,5 +1,10 @@
package mem_virtual
arena_init :: proc{
static_arena_init,
growing_arena_init,
}
arena_temp_begin :: proc{
static_arena_temp_begin,
growing_arena_temp_begin,
core/mem/virtual/growing_arena.odin
+11 -4
View File
@@ -13,6 +13,13 @@ Growing_Arena :: struct {
DEFAULT_MINIMUM_BLOCK_SIZE :: 1<<20 // 1 MiB should be enough
growing_arena_init :: proc(arena: ^Static_Arena, reserved: uint = DEFAULT_MINIMUM_BLOCK_SIZE) -> (err: Allocator_Error) {
arena.block = memory_block_alloc(0, reserved, {}) or_return
arena.total_used = 0
arena.total_reserved = arena.block.reserved
return
}
growing_arena_alloc :: proc(arena: ^Growing_Arena, min_size: int, alignment: int) -> (data: []byte, err: Allocator_Error) {
align_forward_offset :: proc "contextless" (arena: ^Growing_Arena, alignment: int) -> uint #no_bounds_check {
alignment_offset := uint(0)
@@ -37,7 +44,7 @@ growing_arena_alloc :: proc(arena: ^Growing_Arena, min_size: int, alignment: int
block_size := max(size, arena.minimum_block_size)
new_block := memory_block_alloc(block_size, block_size, {}) or_return
new_block := memory_block_alloc(size, block_size, {}) or_return
new_block.prev = arena.curr_block
arena.curr_block = new_block
arena.total_reserved += new_block.reserved
@@ -95,9 +102,9 @@ growing_arena_allocator :: proc(arena: ^Growing_Arena) -> mem.Allocator {
}
growing_arena_allocator_proc :: proc(allocator_data: rawptr, mode: mem.Allocator_Mode,
size, alignment: int,
old_memory: rawptr, old_size: int,
location := #caller_location) -> (data: []byte, err: Allocator_Error) {
size, alignment: int,
old_memory: rawptr, old_size: int,
location := #caller_location) -> (data: []byte, err: Allocator_Error) {
arena := (^Growing_Arena)(allocator_data)
switch mode {
core/mem/virtual/virtual_darwin.odin
+148
View File
@@ -0,0 +1,148 @@
//+build darwin
//+private
package mem_virtual
foreign import libc "System.framework"
import "core:c"
PROT_NONE :: 0x0 /* [MC2] no permissions */
PROT_READ :: 0x1 /* [MC2] pages can be read */
PROT_WRITE :: 0x2 /* [MC2] pages can be written */
PROT_EXEC :: 0x4 /* [MC2] pages can be executed */
// Sharing options
MAP_SHARED :: 0x1 /* [MF|SHM] share changes */
MAP_PRIVATE :: 0x2 /* [MF|SHM] changes are private */
// Other flags
MAP_FIXED :: 0x0010 /* [MF|SHM] interpret addr exactly */
MAP_RENAME :: 0x0020 /* Sun: rename private pages to file */
MAP_NORESERVE :: 0x0040 /* Sun: don't reserve needed swap area */
MAP_RESERVED0080 :: 0x0080 /* previously unimplemented MAP_INHERIT */
MAP_NOEXTEND :: 0x0100 /* for MAP_FILE, don't change file size */
MAP_HASSEMAPHORE :: 0x0200 /* region may contain semaphores */
MAP_NOCACHE :: 0x0400 /* don't cache pages for this mapping */
MAP_JIT :: 0x0800 /* Allocate a region that will be used for JIT purposes */
// Mapping type
MAP_FILE :: 0x0000 /* map from file (default) */
MAP_ANONYMOUS :: 0x1000 /* allocated from memory, swap space */
/*
* The MAP_RESILIENT_* flags can be used when the caller wants to map some
* possibly unreliable memory and be able to access it safely, possibly
* getting the wrong contents rather than raising any exception.
* For safety reasons, such mappings have to be read-only (PROT_READ access
* only).
*
* MAP_RESILIENT_CODESIGN:
* accessing this mapping will not generate code-signing violations,
* even if the contents are tainted.
* MAP_RESILIENT_MEDIA:
* accessing this mapping will not generate an exception if the contents
* are not available (unreachable removable or remote media, access beyond
* end-of-file, ...). Missing contents will be replaced with zeroes.
*/
MAP_RESILIENT_CODESIGN :: 0x2000 /* no code-signing failures */
MAP_RESILIENT_MEDIA :: 0x4000 /* no backing-store failures */
MAP_32BIT :: 0x8000 /* Return virtual addresses <4G only */
// Flags used to support translated processes.
MAP_TRANSLATED_ALLOW_EXECUTE :: 0x20000 /* allow execute in translated processes */
MAP_UNIX03 :: 0x40000 /* UNIX03 compliance */
// Process memory locking
MCL_CURRENT :: 0x0001 /* [ML] Lock only current memory */
MCL_FUTURE :: 0x0002 /* [ML] Lock all future memory as well */
MADV_NORMAL :: 0 /* [MC1] no further special treatment */
MADV_RANDOM :: 1 /* [MC1] expect random page refs */
MADV_SEQUENTIAL :: 2 /* [MC1] expect sequential page refs */
MADV_WILLNEED :: 3 /* [MC1] will need these pages */
MADV_DONTNEED :: 4 /* [MC1] dont need these pages */
MADV_FREE :: 5 /* pages unneeded, discard contents */
MADV_ZERO_WIRED_PAGES :: 6 /* zero the wired pages that have not been unwired before the entry is deleted */
MADV_FREE_REUSABLE :: 7 /* pages can be reused (by anyone) */
MADV_FREE_REUSE :: 8 /* caller wants to reuse those pages */
MADV_CAN_REUSE :: 9
MADV_PAGEOUT :: 10 /* page out now (internal only) */
// msync() flags
MS_ASYNC :: 0x0001 /* [MF|SIO] return immediately */
MS_INVALIDATE :: 0x0002 /* [MF|SIO] invalidate all cached data */
MS_SYNC :: 0x0010 /* [MF|SIO] msync synchronously */
MS_KILLPAGES :: 0x0004 /* invalidate pages, leave mapped */
MS_DEACTIVATE :: 0x0008 /* deactivate pages, leave mapped */
// Return bits from mincore
MINCORE_INCORE :: 0x1 /* Page is incore */
MINCORE_REFERENCED :: 0x2 /* Page has been referenced by us */
MINCORE_MODIFIED :: 0x4 /* Page has been modified by us */
MINCORE_REFERENCED_OTHER :: 0x8 /* Page has been referenced */
MINCORE_MODIFIED_OTHER :: 0x10 /* Page has been modified */
MINCORE_PAGED_OUT :: 0x20 /* Page has been paged out */
MINCORE_COPIED :: 0x40 /* Page has been copied */
MINCORE_ANONYMOUS :: 0x80 /* Page belongs to an anonymous object */
// Allocation failure result
MAP_FAILED : rawptr = rawptr(~uintptr(0))
foreign libc {
@(link_name="mlockall") _mlockall :: proc(flags: c.int) -> c.int ---
@(link_name="munlockall") _munlockall :: proc() -> c.int ---
@(link_name="mlock") _mlock :: proc(addr: rawptr, len: c.size_t) -> c.int ---
@(link_name="mmap") _mmap :: proc(addr: rawptr, len: c.size_t, prot: c.int, flags: c.int, fd: c.int, offset: int) -> rawptr ---
@(link_name="mprotect") _mprotect :: proc(addr: rawptr, len: c.size_t, prot: c.int) -> c.int ---
@(link_name="msync") _msync :: proc(addr: rawptr, len: c.size_t) -> c.int ---
@(link_name="munlock") _munlock :: proc(addr: rawptr, len: c.size_t) -> c.int ---
@(link_name="munmap") _munmap :: proc(addr: rawptr, len: c.size_t) -> c.int ---
@(link_name="shm_open") _shm_open :: proc(name: cstring, oflag: c.int, #c_vararg args: ..any) -> c.int ---
@(link_name="shm_unlink") _shm_unlink :: proc(name: cstring) -> c.int ---
@(link_name="posix_madvise") _posix_madvise :: proc(addr: rawptr, len: c.size_t, advice: c.int) -> c.int ---
@(link_name="madvise") _madvise :: proc(addr: rawptr, len: c.size_t, advice: c.int) -> c.int ---
@(link_name="mincore") _mincore :: proc(addr: rawptr, len: c.size_t, vec: cstring) -> c.int ---
@(link_name="minherit") _minherit :: proc(addr: rawptr, len: c.size_t, inherit: c.int) -> c.int ---
}
_reserve :: proc "contextless" (size: uint) -> (data: []byte, err: Allocator_Error) {
result := _mmap(nil, size, PROT_NONE, MAP_PRIVATE|MAP_ANONYMOUS, -1, 0)
if result == MAP_FAILED {
return nil, .Out_Of_Memory
}
return ([^]byte)(uintptr(result))[:size], nil
}
_commit :: proc "contextless" (data: rawptr, size: uint) -> Allocator_Error {
result := _mprotect(data, size, PROT_READ|PROT_WRITE)
if result != 0 {
return .Out_Of_Memory
}
return nil
}
_decommit :: proc "contextless" (data: rawptr, size: uint) {
_mprotect(data, size, PROT_NONE)
_madvise(data, size, MADV_FREE)
}
_release :: proc "contextless" (data: rawptr, size: uint) {
_munmap(data, size)
}
_protect :: proc "contextless" (data: rawptr, size: uint, flags: Protect_Flags) -> bool {
pflags: c.int
pflags = PROT_NONE
if .Read in flags { pflags |= PROT_READ }
if .Write in flags { pflags |= PROT_WRITE }
if .Execute in flags { pflags |= PROT_EXEC }
err := _mprotect(data, size, pflags)
return err != 0
}
_platform_memory_init :: proc() {
DEFAULT_PAGE_SIZE = 4096
// is power of two
assert(DEFAULT_PAGE_SIZE != 0 && (DEFAULT_PAGE_SIZE & (DEFAULT_PAGE_SIZE-1)) == 0)
}
core/mem/virtual/virtual_linux.odin
+1 -1
View File
@@ -48,7 +48,7 @@ munmap :: proc "contextless" (addr: rawptr, length: uint) -> c.int {
}
mprotect :: proc "contextless" (addr: rawptr, length: uint, prot: c.int) -> c.int {
res := intrinsics.syscall(unix.SYS_mprotect, uintptr(addr), uintptr(length), uint(prot))
res := intrinsics.syscall(unix.SYS_mprotect, uintptr(addr), uintptr(length), uintptr(prot))
return c.int(res)
}
core/odin/ast/ast.odin
+37 -1
View File
@@ -552,13 +552,20 @@ unparen_expr :: proc(expr: ^Expr) -> (val: ^Expr) {
return
}
Field_Flags :: distinct bit_set[Field_Flag]
Field_Flag :: enum {
Invalid,
Unknown,
Ellipsis,
Using,
No_Alias,
C_Vararg,
Auto_Cast,
Any_Int,
Subtype,
By_Ptr,
Results,
Tags,
@@ -566,11 +573,38 @@ Field_Flag :: enum {
Typeid_Token,
}
Field_Flags :: distinct bit_set[Field_Flag]
field_flag_strings := [Field_Flag]string{
.Invalid = "",
.Unknown = "",
.Ellipsis = "..",
.Using = "using",
.No_Alias = "#no_alias",
.C_Vararg = "#c_vararg",
.Auto_Cast = "auto_cast",
.Any_Int = "#any_int",
.Subtype = "#subtype",
.By_Ptr = "#by_ptr",
.Results = "results",
.Tags = "field tag",
.Default_Parameters = "default parameters",
.Typeid_Token = "typeid",
}
field_hash_flag_strings := []struct{key: string, flag: Field_Flag}{
{"no_alias", .No_Alias},
{"c_vararg", .C_Vararg},
{"any_int", .Any_Int},
{"subtype", .Subtype},
{"by_ptr", .By_Ptr},
}
Field_Flags_Struct :: Field_Flags{
.Using,
.Tags,
.Subtype,
}
Field_Flags_Record_Poly_Params :: Field_Flags{
.Typeid_Token,
@@ -583,6 +617,7 @@ Field_Flags_Signature :: Field_Flags{
.C_Vararg,
.Auto_Cast,
.Any_Int,
.By_Ptr,
.Default_Parameters,
}
@@ -665,6 +700,7 @@ Proc_Type :: struct {
Pointer_Type :: struct {
using node: Expr,
tag: ^Expr,
pointer: tokenizer.Pos,
elem: ^Expr,
}
core/odin/ast/clone.odin
+1
View File
@@ -286,6 +286,7 @@ clone_node :: proc(node: ^Node) -> ^Node {
r.results = auto_cast clone(r.results)
case ^Pointer_Type:
r.elem = clone(r.elem)
r.tag = clone(r.tag)
case ^Multi_Pointer_Type:
r.elem = clone(r.elem)
case ^Array_Type:
core/odin/doc-format/doc_format.odin
+2
View File
@@ -186,6 +186,7 @@ Type_Kind :: enum u32le {
Relative_Slice = 21,
Multi_Pointer = 22,
Matrix = 23,
Soa_Pointer = 24,
}
Type_Elems_Cap :: 4
@@ -245,6 +246,7 @@ Type :: struct {
// .Relative_Slice - 2 types: 0=slice type, 1=base integer
// .Multi_Pointer - 1 type: 0=element
// .Matrix - 1 type: 0=element
// .Soa_Pointer - 1 type: 0=element
types: Array(Type_Index),
// Used by:
core/odin/parser/parser.odin
+40 -78
View File
@@ -245,12 +245,7 @@ peek_token :: proc(p: ^Parser, lookahead := 0) -> (tok: tokenizer.Token) {
return
}
skip_possible_newline :: proc(p: ^Parser) -> bool {
if .Optional_Semicolons not_in p.flags {
return false
}
prev := p.curr_tok
if tokenizer.is_newline(prev) {
if tokenizer.is_newline(p.curr_tok) {
advance_token(p)
return true
}
@@ -1611,20 +1606,6 @@ new_ast_field :: proc(names: []^ast.Expr, type: ^ast.Expr, default_value: ^ast.E
return field
}
Field_Prefix :: enum {
Invalid,
Unknown,
Using,
No_Alias,
C_Vararg,
Auto_Cast,
Any_Int,
}
Field_Prefixes :: distinct bit_set[Field_Prefix]
Expr_And_Flags :: struct {
expr: ^ast.Expr,
flags: ast.Field_Flags,
@@ -1666,7 +1647,7 @@ convert_to_ident_list :: proc(p: ^Parser, list: []Expr_And_Flags, ignore_flags,
return idents[:]
}
is_token_field_prefix :: proc(p: ^Parser) -> Field_Prefix {
is_token_field_prefix :: proc(p: ^Parser) -> ast.Field_Flag {
#partial switch p.curr_tok.kind {
case .EOF:
return .Invalid
@@ -1677,17 +1658,15 @@ is_token_field_prefix :: proc(p: ^Parser) -> Field_Prefix {
advance_token(p)
return .Auto_Cast
case .Hash:
tok: tokenizer.Token
advance_token(p)
defer advance_token(p)
#partial switch p.curr_tok.kind {
case .Ident:
switch p.curr_tok.text {
case "no_alias":
return .No_Alias
case "c_vararg":
return .C_Vararg
case "any_int":
return .Any_Int
tok = p.curr_tok
advance_token(p)
if tok.kind == .Ident {
for kf in ast.field_hash_flag_strings {
if kf.key == tok.text {
return kf.flag
}
}
}
return .Unknown
@@ -1695,8 +1674,8 @@ is_token_field_prefix :: proc(p: ^Parser) -> Field_Prefix {
return .Invalid
}
parse_field_prefixes :: proc(p: ^Parser) -> ast.Field_Flags {
counts: [len(Field_Prefix)]int
parse_field_prefixes :: proc(p: ^Parser) -> (flags: ast.Field_Flags) {
counts: [len(ast.Field_Flag)]int
for {
kind := is_token_field_prefix(p)
@@ -1712,31 +1691,17 @@ parse_field_prefixes :: proc(p: ^Parser) -> ast.Field_Flags {
counts[kind] += 1
}
flags: ast.Field_Flags
for kind in Field_Prefix {
for kind in ast.Field_Flag {
count := counts[kind]
switch kind {
case .Invalid, .Unknown: // Ignore
case .Using:
if count > 1 { error(p, p.curr_tok.pos, "multiple 'using' in this field list") }
if count > 0 { flags += {.Using} }
case .No_Alias:
if count > 1 { error(p, p.curr_tok.pos, "multiple '#no_alias' in this field list") }
if count > 0 { flags += {.No_Alias} }
case .C_Vararg:
if count > 1 { error(p, p.curr_tok.pos, "multiple '#c_vararg' in this field list") }
if count > 0 { flags += {.C_Vararg} }
case .Auto_Cast:
if count > 1 { error(p, p.curr_tok.pos, "multiple 'auto_cast' in this field list") }
if count > 0 { flags += {.Auto_Cast} }
case .Any_Int:
if count > 1 { error(p, p.curr_tok.pos, "multiple '#any_int' in this field list") }
if count > 0 { flags += {.Any_Int} }
if kind == .Invalid || kind == .Unknown {
// Ignore
} else {
if count > 1 { error(p, p.curr_tok.pos, "multiple '%s' in this field list", ast.field_flag_strings[kind]) }
if count > 0 { flags += {kind} }
}
}
return flags
return
}
check_field_flag_prefixes :: proc(p: ^Parser, name_count: int, allowed_flags, set_flags: ast.Field_Flags) -> (flags: ast.Field_Flags) {
@@ -1748,19 +1713,13 @@ check_field_flag_prefixes :: proc(p: ^Parser, name_count: int, allowed_flags, se
for flag in ast.Field_Flag {
if flag not_in allowed_flags && flag in flags {
switch flag {
case .Using:
error(p, p.curr_tok.pos, "'using' is not allowed within this field list")
case .No_Alias:
error(p, p.curr_tok.pos, "'#no_alias' is not allowed within this field list")
case .C_Vararg:
error(p, p.curr_tok.pos, "'#c_vararg' is not allowed within this field list")
case .Auto_Cast:
error(p, p.curr_tok.pos, "'auto_cast' is not allowed within this field list")
case .Any_Int:
error(p, p.curr_tok.pos, "'#any_int' is not allowed within this field list")
#partial switch flag {
case .Unknown, .Invalid:
// ignore
case .Tags, .Ellipsis, .Results, .Default_Parameters, .Typeid_Token:
panic("Impossible prefixes")
case:
error(p, p.curr_tok.pos, "'%s' is not allowed within this field list", ast.field_flag_strings[flag])
}
flags -= {flag}
}
@@ -2271,7 +2230,7 @@ parse_operand :: proc(p: ^Parser, lhs: bool) -> ^ast.Expr {
return parse_call_expr(p, bd)
case "soa", "simd":
case "soa":
bd := ast.new(ast.Basic_Directive, tok.pos, end_pos(name))
bd.tok = tok
bd.name = name.text
@@ -2280,6 +2239,20 @@ parse_operand :: proc(p: ^Parser, lhs: bool) -> ^ast.Expr {
#partial switch t in type.derived_expr {
case ^ast.Array_Type: t.tag = bd
case ^ast.Dynamic_Array_Type: t.tag = bd
case ^ast.Pointer_Type: t.tag = bd
case:
error(p, original_type.pos, "expected an array or pointer type after #%s", name.text)
}
return original_type
case "simd":
bd := ast.new(ast.Basic_Directive, tok.pos, end_pos(name))
bd.tok = tok
bd.name = name.text
original_type := parse_type(p)
type := ast.unparen_expr(original_type)
#partial switch t in type.derived_expr {
case ^ast.Array_Type: t.tag = bd
case:
error(p, original_type.pos, "expected an array type after #%s", name.text)
}
@@ -2631,7 +2604,6 @@ parse_operand :: proc(p: ^Parser, lhs: bool) -> ^ast.Expr {
tok := expect_token(p, .Union)
poly_params: ^ast.Field_List
align: ^ast.Expr
is_maybe: bool
is_no_nil: bool
is_shared_nil: bool
@@ -2656,10 +2628,7 @@ parse_operand :: proc(p: ^Parser, lhs: bool) -> ^ast.Expr {
}
align = parse_expr(p, true)
case "maybe":
if is_maybe {
error(p, tag.pos, "duplicate union tag '#%s'", tag.text)
}
is_maybe = true
error(p, tag.pos, "#%s functionality has now been merged with standard 'union' functionality", tag.text)
case "no_nil":
if is_no_nil {
error(p, tag.pos, "duplicate union tag '#%s'", tag.text)
@@ -2676,19 +2645,12 @@ parse_operand :: proc(p: ^Parser, lhs: bool) -> ^ast.Expr {
}
p.expr_level = prev_level
if is_no_nil && is_maybe {
error(p, p.curr_tok.pos, "#maybe and #no_nil cannot be applied together")
}
if is_no_nil && is_shared_nil {
error(p, p.curr_tok.pos, "#shared_nil and #no_nil cannot be applied together")
}
if is_shared_nil && is_maybe {
error(p, p.curr_tok.pos, "#maybe and #shared_nil cannot be applied together")
}
union_kind := ast.Union_Type_Kind.Normal
switch {
case is_maybe: union_kind = .maybe
case is_no_nil: union_kind = .no_nil
case is_shared_nil: union_kind = .shared_nil
}
core/os/os2/user.odin
+10 -10
View File
@@ -6,19 +6,19 @@ import "core:runtime"
user_cache_dir :: proc(allocator: runtime.Allocator) -> (dir: string, err: Error) {
#partial switch ODIN_OS {
case .Windows:
dir = get_env("LocalAppData")
dir = get_env("LocalAppData", allocator)
if dir != "" {
dir = strings.clone_safe(dir, allocator) or_return
}
case .Darwin:
dir = get_env("HOME")
dir = get_env("HOME", allocator)
if dir != "" {
dir = strings.concatenate_safe({dir, "/Library/Caches"}, allocator) or_return
}
case: // All other UNIX systems
dir = get_env("XDG_CACHE_HOME")
dir = get_env("XDG_CACHE_HOME", allocator)
if dir == "" {
dir = get_env("HOME")
dir = get_env("HOME", allocator)
if dir == "" {
return
}
@@ -34,19 +34,19 @@ user_cache_dir :: proc(allocator: runtime.Allocator) -> (dir: string, err: Error
user_config_dir :: proc(allocator: runtime.Allocator) -> (dir: string, err: Error) {
#partial switch ODIN_OS {
case .Windows:
dir = get_env("AppData")
dir = get_env("AppData", allocator)
if dir != "" {
dir = strings.clone_safe(dir, allocator) or_return
}
case .Darwin:
dir = get_env("HOME")
dir = get_env("HOME", allocator)
if dir != "" {
dir = strings.concatenate_safe({dir, "/Library/Application Support"}, allocator) or_return
}
case: // All other UNIX systems
dir = get_env("XDG_CACHE_HOME")
dir = get_env("XDG_CACHE_HOME", allocator)
if dir == "" {
dir = get_env("HOME")
dir = get_env("HOME", allocator)
if dir == "" {
return
}
@@ -59,13 +59,13 @@ user_config_dir :: proc(allocator: runtime.Allocator) -> (dir: string, err: Erro
return
}
user_home_dir :: proc() -> (dir: string, err: Error) {
user_home_dir :: proc(allocator: runtime.Allocator) -> (dir: string, err: Error) {
env := "HOME"
#partial switch ODIN_OS {
case .Windows:
env = "USERPROFILE"
}
if v := get_env(env); v != "" {
if v := get_env(env, allocator); v != "" {
return v, nil
}
return "", .Invalid_Path
core/os/os_linux.odin
+1 -1
View File
@@ -311,7 +311,7 @@ _unix_seek :: proc(fd: Handle, offset: i64, whence: int) -> i64 {
low := uintptr(offset & 0xFFFFFFFF)
high := uintptr(offset >> 32)
result: i64
res := i64(intrinsics.syscall(unix.SYS__llseek, uintptr(fd), high, low, &result, uintptr(whence)))
res := i64(intrinsics.syscall(unix.SYS__llseek, uintptr(fd), high, low, uintptr(&result), uintptr(whence)))
return -1 if res < 0 else result
}
}
core/path/filepath/match.odin
+1 -1
View File
@@ -271,7 +271,7 @@ _glob :: proc(dir, pattern: string, matches: ^[dynamic]string, allocator := cont
}
d, derr := os.open(dir)
d, derr := os.open(dir, os.O_RDONLY)
if derr != 0 {
return
}
core/reflect/reflect.odin
+39 -24
View File
@@ -1,7 +1,6 @@
package reflect
import "core:runtime"
import "core:mem"
import "core:intrinsics"
_ :: intrinsics
@@ -34,6 +33,7 @@ Type_Info_Simd_Vector :: runtime.Type_Info_Simd_Vector
Type_Info_Relative_Pointer :: runtime.Type_Info_Relative_Pointer
Type_Info_Relative_Slice :: runtime.Type_Info_Relative_Slice
Type_Info_Matrix :: runtime.Type_Info_Matrix
Type_Info_Soa_Pointer :: runtime.Type_Info_Soa_Pointer
Type_Info_Enum_Value :: runtime.Type_Info_Enum_Value
@@ -68,6 +68,7 @@ Type_Kind :: enum {
Relative_Pointer,
Relative_Slice,
Matrix,
Soa_Pointer,
}
@@ -102,6 +103,7 @@ type_kind :: proc(T: typeid) -> Type_Kind {
case Type_Info_Relative_Pointer: return .Relative_Pointer
case Type_Info_Relative_Slice: return .Relative_Slice
case Type_Info_Matrix: return .Matrix
case Type_Info_Soa_Pointer: return .Soa_Pointer
}
}
@@ -194,6 +196,7 @@ typeid_elem :: proc(id: typeid) -> typeid {
}
case Type_Info_Pointer: return v.elem.id
case Type_Info_Multi_Pointer: return v.elem.id
case Type_Info_Soa_Pointer: return v.elem.id
case Type_Info_Array: return v.elem.id
case Type_Info_Enumerated_Array: return v.elem.id
case Type_Info_Slice: return v.elem.id
@@ -220,7 +223,7 @@ align_of_typeid :: proc(T: typeid) -> int {
as_bytes :: proc(v: any) -> []byte {
if v != nil {
sz := size_of_typeid(v.id)
return mem.slice_ptr((^byte)(v.data), sz)
return ([^]byte)(v.data)[:sz]
}
return nil
}
@@ -262,19 +265,19 @@ length :: proc(val: any) -> int {
return a.count
case Type_Info_Slice:
return (^mem.Raw_Slice)(val.data).len
return (^runtime.Raw_Slice)(val.data).len
case Type_Info_Dynamic_Array:
return (^mem.Raw_Dynamic_Array)(val.data).len
return (^runtime.Raw_Dynamic_Array)(val.data).len
case Type_Info_Map:
return (^mem.Raw_Map)(val.data).entries.len
return (^runtime.Raw_Map)(val.data).entries.len
case Type_Info_String:
if a.is_cstring {
return len((^cstring)(val.data)^)
} else {
return (^mem.Raw_String)(val.data).len
return (^runtime.Raw_String)(val.data).len
}
}
return 0
@@ -297,10 +300,10 @@ capacity :: proc(val: any) -> int {
return a.count
case Type_Info_Dynamic_Array:
return (^mem.Raw_Dynamic_Array)(val.data).cap
return (^runtime.Raw_Dynamic_Array)(val.data).cap
case Type_Info_Map:
return (^mem.Raw_Map)(val.data).entries.cap
return (^runtime.Raw_Map)(val.data).entries.cap
}
return 0
}
@@ -340,14 +343,14 @@ index :: proc(val: any, i: int, loc := #caller_location) -> any {
return any{data, a.elem.id}
case Type_Info_Slice:
raw := (^mem.Raw_Slice)(val.data)
raw := (^runtime.Raw_Slice)(val.data)
runtime.bounds_check_error_loc(loc, i, raw.len)
offset := uintptr(a.elem.size * i)
data := rawptr(uintptr(raw.data) + offset)
return any{data, a.elem.id}
case Type_Info_Dynamic_Array:
raw := (^mem.Raw_Dynamic_Array)(val.data)
raw := (^runtime.Raw_Dynamic_Array)(val.data)
runtime.bounds_check_error_loc(loc, i, raw.len)
offset := uintptr(a.elem.size * i)
data := rawptr(uintptr(raw.data) + offset)
@@ -356,7 +359,7 @@ index :: proc(val: any, i: int, loc := #caller_location) -> any {
case Type_Info_String:
if a.is_cstring { return nil }
raw := (^mem.Raw_String)(val.data)
raw := (^runtime.Raw_String)(val.data)
runtime.bounds_check_error_loc(loc, i, raw.len)
offset := uintptr(size_of(u8) * i)
data := rawptr(uintptr(raw.data) + offset)
@@ -725,6 +728,17 @@ get_union_variant_raw_tag :: proc(a: any) -> i64 {
panic("expected a union to reflect.get_union_variant_raw_tag")
}
get_union_variant :: proc(a: any) -> any {
if a == nil {
return nil
}
id := union_variant_typeid(a)
if id == nil {
return nil
}
return any{a.data, id}
}
set_union_variant_raw_tag :: proc(a: any, tag: i64) {
if a == nil { return }
@@ -822,17 +836,17 @@ set_union_value :: proc(dst: any, value: any) -> bool {
ti := runtime.type_info_base(type_info_of(dst.id))
if info, ok := ti.variant.(runtime.Type_Info_Union); ok {
if value.id == nil {
mem.zero(dst.data, ti.size)
intrinsics.mem_zero(dst.data, ti.size)
return true
}
if ti.id == runtime.typeid_base(value.id) {
mem.copy(dst.data, value.data, ti.size)
intrinsics.mem_copy(dst.data, value.data, ti.size)
return true
}
if type_info_union_is_pure_maybe(info) {
if variant := info.variants[0]; variant.id == value.id {
mem.copy(dst.data, value.data, variant.size)
intrinsics.mem_copy(dst.data, value.data, variant.size)
return true
}
return false
@@ -844,7 +858,7 @@ set_union_value :: proc(dst: any, value: any) -> bool {
if !info.no_nil {
tag += 1
}
mem.copy(dst.data, value.data, variant.size)
intrinsics.mem_copy(dst.data, value.data, variant.size)
set_union_variant_raw_tag(dst, tag)
return true
}
@@ -1337,11 +1351,11 @@ as_raw_data :: proc(a: any) -> (value: rawptr, valid: bool) {
case Type_Info_Slice:
valid = true
value = (^mem.Raw_Slice)(a.data).data
value = (^runtime.Raw_Slice)(a.data).data
case Type_Info_Dynamic_Array:
valid = true
value = (^mem.Raw_Dynamic_Array)(a.data).data
value = (^runtime.Raw_Dynamic_Array)(a.data).data
}
return
@@ -1383,7 +1397,7 @@ equal :: proc(a, b: any, including_indirect_array_recursion := false, recursion_
}
if .Simple_Compare in t.flags {
return mem.compare_byte_ptrs((^byte)(a.data), (^byte)(b.data), t.size) == 0
return runtime.memory_compare(a.data, b.data, t.size) == 0
}
t = runtime.type_info_core(t)
@@ -1419,8 +1433,9 @@ equal :: proc(a, b: any, including_indirect_array_recursion := false, recursion_
Type_Info_Enum,
Type_Info_Simd_Vector,
Type_Info_Relative_Pointer,
Type_Info_Soa_Pointer,
Type_Info_Matrix:
return mem.compare_byte_ptrs((^byte)(a.data), (^byte)(b.data), t.size) == 0
return runtime.memory_compare(a.data, b.data, t.size) == 0
case Type_Info_String:
if v.is_cstring {
@@ -1474,8 +1489,8 @@ equal :: proc(a, b: any, including_indirect_array_recursion := false, recursion_
if !including_indirect_array_recursion {
return false
}
array_a := (^mem.Raw_Slice)(a.data)
array_b := (^mem.Raw_Slice)(b.data)
array_a := (^runtime.Raw_Slice)(a.data)
array_b := (^runtime.Raw_Slice)(b.data)
if array_a.len != array_b.len {
return false
}
@@ -1494,8 +1509,8 @@ equal :: proc(a, b: any, including_indirect_array_recursion := false, recursion_
if !including_indirect_array_recursion {
return false
}
array_a := (^mem.Raw_Dynamic_Array)(a.data)
array_b := (^mem.Raw_Dynamic_Array)(b.data)
array_a := (^runtime.Raw_Dynamic_Array)(a.data)
array_b := (^runtime.Raw_Dynamic_Array)(b.data)
if array_a.len != array_b.len {
return false
}
@@ -1503,7 +1518,7 @@ equal :: proc(a, b: any, including_indirect_array_recursion := false, recursion_
return true
}
if .Simple_Compare in v.elem.flags {
return mem.compare_byte_ptrs((^byte)(array_a.data), (^byte)(array_b.data), array_a.len * v.elem.size) == 0
return runtime.memory_compare((^byte)(array_a.data), (^byte)(array_b.data), array_a.len * v.elem.size) == 0
}
for i in 0..<array_a.len {
core/reflect/types.odin
+18
View File
@@ -68,6 +68,11 @@ are_types_identical :: proc(a, b: ^Type_Info) -> bool {
y := b.variant.(Type_Info_Multi_Pointer) or_return
return are_types_identical(x.elem, y.elem)
case Type_Info_Soa_Pointer:
y := b.variant.(Type_Info_Soa_Pointer) or_return
return are_types_identical(x.elem, y.elem)
case Type_Info_Procedure:
y := b.variant.(Type_Info_Procedure) or_return
switch {
@@ -256,6 +261,11 @@ is_multi_pointer :: proc(info: ^Type_Info) -> bool {
_, ok := type_info_base(info).variant.(Type_Info_Multi_Pointer)
return ok
}
is_soa_pointer :: proc(info: ^Type_Info) -> bool {
if info == nil { return false }
_, ok := type_info_base(info).variant.(Type_Info_Soa_Pointer)
return ok
}
is_pointer_internally :: proc(info: ^Type_Info) -> bool {
if info == nil { return false }
#partial switch v in info.variant {
@@ -292,6 +302,11 @@ is_dynamic_map :: proc(info: ^Type_Info) -> bool {
_, ok := type_info_base(info).variant.(Type_Info_Map)
return ok
}
is_bit_set :: proc(info: ^Type_Info) -> bool {
if info == nil { return false }
_, ok := type_info_base(info).variant.(Type_Info_Bit_Set)
return ok
}
is_slice :: proc(info: ^Type_Info) -> bool {
if info == nil { return false }
_, ok := type_info_base(info).variant.(Type_Info_Slice)
@@ -437,6 +452,9 @@ write_type_writer :: proc(w: io.Writer, ti: ^Type_Info, n_written: ^int = nil) -
case Type_Info_Multi_Pointer:
io.write_string(w, "[^]", &n) or_return
write_type(w, info.elem, &n) or_return
case Type_Info_Soa_Pointer:
io.write_string(w, "#soa ^", &n) or_return
write_type(w, info.elem, &n) or_return
case Type_Info_Procedure:
io.write_string(w, "proc", &n) or_return
if info.params == nil {
core/runtime/core.odin
+10
View File
@@ -176,6 +176,9 @@ Type_Info_Matrix :: struct {
column_count: int,
// Total element count = column_count * elem_stride
}
Type_Info_Soa_Pointer :: struct {
elem: ^Type_Info,
}
Type_Info_Flag :: enum u8 {
Comparable = 0,
@@ -217,6 +220,7 @@ Type_Info :: struct {
Type_Info_Relative_Pointer,
Type_Info_Relative_Slice,
Type_Info_Matrix,
Type_Info_Soa_Pointer,
},
}
@@ -403,6 +407,12 @@ Raw_Cstring :: struct {
data: [^]byte,
}
Raw_Soa_Pointer :: struct {
data: rawptr,
index: int,
}
/*
// Defined internally by the compiler
core/runtime/core_builtin.odin
+61 -54
View File
@@ -143,7 +143,7 @@ free_all :: proc{mem_free_all}
@builtin
delete_string :: proc(str: string, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
return mem_free(raw_data(str), allocator, loc)
return mem_free_with_size(raw_data(str), len(str), allocator, loc)
}
@builtin
delete_cstring :: proc(str: cstring, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
@@ -151,17 +151,24 @@ delete_cstring :: proc(str: cstring, allocator := context.allocator, loc := #cal
}
@builtin
delete_dynamic_array :: proc(array: $T/[dynamic]$E, loc := #caller_location) -> Allocator_Error {
return mem_free(raw_data(array), array.allocator, loc)
return mem_free_with_size(raw_data(array), cap(array)*size_of(E), array.allocator, loc)
}
@builtin
delete_slice :: proc(array: $T/[]$E, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
return mem_free(raw_data(array), allocator, loc)
return mem_free_with_size(raw_data(array), len(array)*size_of(E), allocator, loc)
}
@builtin
delete_map :: proc(m: $T/map[$K]$V, loc := #caller_location) -> Allocator_Error {
Entry :: struct {
hash: uintptr,
next: int,
key: K,
value: V,
}
raw := transmute(Raw_Map)m
err := delete_slice(raw.hashes, raw.entries.allocator, loc)
err1 := mem_free(raw.entries.data, raw.entries.allocator, loc)
err1 := mem_free_with_size(raw.entries.data, raw.entries.cap*size_of(Entry), raw.entries.allocator, loc)
if err == nil {
err = err1
}
@@ -335,68 +342,80 @@ delete_key :: proc(m: ^$T/map[$K]$V, key: K) -> (deleted_key: K, deleted_value:
@builtin
append_elem :: proc(array: ^$T/[dynamic]$E, arg: E, loc := #caller_location) {
append_elem :: proc(array: ^$T/[dynamic]$E, arg: E, loc := #caller_location) -> int {
if array == nil {
return
return 0
}
if cap(array) < len(array)+1 {
cap := 2 * cap(array) + max(8, 1)
_ = reserve(array, cap, loc)
}
if cap(array)-len(array) > 0 {
a := (^Raw_Dynamic_Array)(array)
when size_of(E) != 0 {
data := ([^]E)(a.data)
assert(condition=data != nil, loc=loc)
data[a.len] = arg
when size_of(E) == 0 {
array.len += 1
return 1
} else {
if cap(array) < len(array)+1 {
cap := 2 * cap(array) + max(8, 1)
_ = reserve(array, cap, loc)
}
a.len += 1
if cap(array)-len(array) > 0 {
a := (^Raw_Dynamic_Array)(array)
when size_of(E) != 0 {
data := ([^]E)(a.data)
assert(condition=data != nil, loc=loc)
data[a.len] = arg
}
a.len += 1
return 1
}
return 0
}
}
@builtin
append_elems :: proc(array: ^$T/[dynamic]$E, args: ..E, loc := #caller_location) {
append_elems :: proc(array: ^$T/[dynamic]$E, args: ..E, loc := #caller_location) -> int {
if array == nil {
return
return 0
}
arg_len := len(args)
if arg_len <= 0 {
return
return 0
}
if cap(array) < len(array)+arg_len {
cap := 2 * cap(array) + max(8, arg_len)
_ = reserve(array, cap, loc)
}
arg_len = min(cap(array)-len(array), arg_len)
if arg_len > 0 {
a := (^Raw_Dynamic_Array)(array)
when size_of(E) != 0 {
data := ([^]E)(a.data)
assert(condition=data != nil, loc=loc)
intrinsics.mem_copy(&data[a.len], raw_data(args), size_of(E) * arg_len)
when size_of(E) == 0 {
array.len += arg_len
return arg_len
} else {
if cap(array) < len(array)+arg_len {
cap := 2 * cap(array) + max(8, arg_len)
_ = reserve(array, cap, loc)
}
a.len += arg_len
arg_len = min(cap(array)-len(array), arg_len)
if arg_len > 0 {
a := (^Raw_Dynamic_Array)(array)
when size_of(E) != 0 {
data := ([^]E)(a.data)
assert(condition=data != nil, loc=loc)
intrinsics.mem_copy(&data[a.len], raw_data(args), size_of(E) * arg_len)
}
a.len += arg_len
}
return arg_len
}
}
// The append_string built-in procedure appends a string to the end of a [dynamic]u8 like type
@builtin
append_elem_string :: proc(array: ^$T/[dynamic]$E/u8, arg: $A/string, loc := #caller_location) {
append_elem_string :: proc(array: ^$T/[dynamic]$E/u8, arg: $A/string, loc := #caller_location) -> int {
args := transmute([]E)arg
append_elems(array=array, args=args, loc=loc)
return append_elems(array=array, args=args, loc=loc)
}
// The append_string built-in procedure appends multiple strings to the end of a [dynamic]u8 like type
@builtin
append_string :: proc(array: ^$T/[dynamic]$E/u8, args: ..string, loc := #caller_location) {
append_string :: proc(array: ^$T/[dynamic]$E/u8, args: ..string, loc := #caller_location) -> (n: int) {
for arg in args {
append(array = array, args = transmute([]E)(arg), loc = loc)
n += append(array = array, args = transmute([]E)(arg), loc = loc)
}
return
}
// The append built-in procedure appends elements to the end of a dynamic array
@@ -404,11 +423,13 @@ append_string :: proc(array: ^$T/[dynamic]$E/u8, args: ..string, loc := #caller_
@builtin
append_nothing :: proc(array: ^$T/[dynamic]$E, loc := #caller_location) {
append_nothing :: proc(array: ^$T/[dynamic]$E, loc := #caller_location) -> int {
if array == nil {
return
return 0
}
prev_len := len(array)
resize(array, len(array)+1)
return len(array)-prev_len
}
@@ -779,17 +800,3 @@ unimplemented :: proc(message := "", loc := #caller_location) -> ! {
}
p("not yet implemented", message, loc)
}
@builtin
@(disabled=ODIN_DISABLE_ASSERT)
unreachable :: proc(message := "", loc := #caller_location) -> ! {
p := context.assertion_failure_proc
if p == nil {
p = default_assertion_failure_proc
}
if message != "" {
p("internal error", message, loc)
} else {
p("internal error", "entered unreachable code", loc)
}
}
core/runtime/dynamic_array_internal.odin
+7 -3
View File
@@ -29,11 +29,15 @@ __dynamic_array_reserve :: proc(array_: rawptr, elem_size, elem_align: int, cap:
new_size := cap * elem_size
allocator := array.allocator
new_data, err := allocator.procedure(allocator.data, .Resize, new_size, elem_align, array.data, old_size, loc)
new_data, err := mem_resize(array.data, old_size, new_size, elem_align, allocator, loc)
if err != nil {
return false
}
if new_data != nil || elem_size == 0 {
if elem_size == 0 {
array.data = raw_data(new_data)
array.cap = cap
return true
} else if new_data != nil {
array.data = raw_data(new_data)
array.cap = min(cap, len(new_data)/elem_size)
return true
@@ -59,7 +63,7 @@ __dynamic_array_shrink :: proc(array_: rawptr, elem_size, elem_align: int, new_c
new_size := new_cap * elem_size
allocator := array.allocator
new_data, err := allocator.procedure(allocator.data, .Resize, new_size, elem_align, array.data, old_size, loc)
new_data, err := mem_resize(array.data, old_size, new_size, elem_align, allocator, loc)
if err != nil {
return
}
core/runtime/dynamic_map_internal.odin
+8 -5
View File
@@ -194,12 +194,15 @@ __slice_resize :: proc(array_: ^$T/[]$E, new_count: int, allocator: Allocator, l
new_size := new_count*size_of(T)
new_data, err := mem_resize(array.data, old_size, new_size, align_of(T), allocator, loc)
if new_data == nil || err != nil {
if err != nil {
return false
}
array.data = new_data
array.len = new_count
return true
if new_data != nil || size_of(E) == 0 {
array.data = raw_data(new_data)
array.len = new_count
return true
}
return false
}
__dynamic_map_reset_entries :: proc(using header: Map_Header, loc := #caller_location) {
@@ -207,7 +210,7 @@ __dynamic_map_reset_entries :: proc(using header: Map_Header, loc := #caller_loc
m.hashes[i] = -1
}
for i in 0 ..< m.entries.len {
for i in 0..<m.entries.len {
entry_header := __dynamic_map_get_entry(header, i)
entry_hash := __get_map_hash_from_entry(header, entry_header)
entry_header.next = -1
core/runtime/internal.odin
+61 -37
View File
@@ -103,7 +103,7 @@ mem_zero :: proc "contextless" (data: rawptr, len: int) -> rawptr {
if data == nil {
return nil
}
if len < 0 {
if len <= 0 {
return data
}
intrinsics.mem_zero(data, len)
@@ -111,22 +111,18 @@ mem_zero :: proc "contextless" (data: rawptr, len: int) -> rawptr {
}
mem_copy :: proc "contextless" (dst, src: rawptr, len: int) -> rawptr {
if src == nil {
return dst
if src != nil && dst != src && len > 0 {
// NOTE(bill): This _must_ be implemented like C's memmove
intrinsics.mem_copy(dst, src, len)
}
// NOTE(bill): This _must_ be implemented like C's memmove
intrinsics.mem_copy(dst, src, len)
return dst
}
mem_copy_non_overlapping :: proc "contextless" (dst, src: rawptr, len: int) -> rawptr {
if src == nil {
return dst
if src != nil && dst != src && len > 0 {
// NOTE(bill): This _must_ be implemented like C's memcpy
intrinsics.mem_copy_non_overlapping(dst, src, len)
}
// NOTE(bill): This _must_ be implemented like C's memcpy
intrinsics.mem_copy_non_overlapping(dst, src, len)
return dst
}
@@ -142,28 +138,38 @@ mem_alloc_bytes :: #force_inline proc(size: int, alignment: int = DEFAULT_ALIGNM
return allocator.procedure(allocator.data, .Alloc, size, alignment, nil, 0, loc)
}
mem_alloc :: #force_inline proc(size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> (rawptr, Allocator_Error) {
if size == 0 {
mem_alloc :: #force_inline proc(size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> ([]byte, Allocator_Error) {
if size == 0 || allocator.procedure == nil {
return nil, nil
}
if allocator.procedure == nil {
return nil, nil
}
data, err := allocator.procedure(allocator.data, .Alloc, size, alignment, nil, 0, loc)
return raw_data(data), err
return allocator.procedure(allocator.data, .Alloc, size, alignment, nil, 0, loc)
}
mem_free :: #force_inline proc(ptr: rawptr, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if ptr == nil {
return .None
}
if allocator.procedure == nil {
return .None
if ptr == nil || allocator.procedure == nil {
return nil
}
_, err := allocator.procedure(allocator.data, .Free, 0, 0, ptr, 0, loc)
return err
}
mem_free_with_size :: #force_inline proc(ptr: rawptr, byte_count: int, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if ptr == nil || allocator.procedure == nil {
return nil
}
_, err := allocator.procedure(allocator.data, .Free, 0, 0, ptr, byte_count, loc)
return err
}
mem_free_bytes :: #force_inline proc(bytes: []byte, allocator := context.allocator, loc := #caller_location) -> Allocator_Error {
if bytes == nil || allocator.procedure == nil {
return nil
}
_, err := allocator.procedure(allocator.data, .Free, 0, 0, raw_data(bytes), len(bytes), loc)
return err
}
mem_free_all :: #force_inline proc(allocator := context.allocator, loc := #caller_location) -> (err: Allocator_Error) {
if allocator.procedure != nil {
_, err = allocator.procedure(allocator.data, .Free_All, 0, 0, nil, 0, loc)
@@ -171,21 +177,34 @@ mem_free_all :: #force_inline proc(allocator := context.allocator, loc := #calle
return
}
mem_resize :: #force_inline proc(ptr: rawptr, old_size, new_size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> (new_ptr: rawptr, err: Allocator_Error) {
new_data: []byte
switch {
case allocator.procedure == nil:
return
case new_size == 0:
new_data, err = allocator.procedure(allocator.data, .Free, 0, 0, ptr, 0, loc)
case ptr == nil:
new_data, err = allocator.procedure(allocator.data, .Alloc, new_size, alignment, nil, 0, loc)
case:
new_data, err = allocator.procedure(allocator.data, .Resize, new_size, alignment, ptr, old_size, loc)
mem_resize :: proc(ptr: rawptr, old_size, new_size: int, alignment: int = DEFAULT_ALIGNMENT, allocator := context.allocator, loc := #caller_location) -> ([]byte, Allocator_Error) {
if allocator.procedure == nil {
return nil, nil
}
new_ptr = raw_data(new_data)
return
if new_size == 0 {
if ptr != nil {
_, err := allocator.procedure(allocator.data, .Free, 0, 0, ptr, old_size, loc)
return nil, err
}
return nil, nil
} else if ptr == nil {
return allocator.procedure(allocator.data, .Alloc, new_size, alignment, nil, 0, loc)
} else if old_size == new_size && uintptr(ptr) % uintptr(alignment) == 0 {
return ([^]byte)(ptr)[:old_size], nil
}
data, err := allocator.procedure(allocator.data, .Resize, new_size, alignment, ptr, old_size, loc)
if err == .Mode_Not_Implemented {
data, err = allocator.procedure(allocator.data, .Alloc, new_size, alignment, nil, 0, loc)
if err != nil {
return data, err
}
copy(data, ([^]byte)(ptr)[:old_size])
_, err = allocator.procedure(allocator.data, .Free, 0, 0, ptr, old_size, loc)
}
return data, err
}
memory_equal :: proc "contextless" (x, y: rawptr, n: int) -> bool {
switch {
case n == 0: return true
@@ -341,7 +360,12 @@ string_eq :: proc "contextless" (lhs, rhs: string) -> bool {
string_cmp :: proc "contextless" (a, b: string) -> int {
x := transmute(Raw_String)a
y := transmute(Raw_String)b
return memory_compare(x.data, y.data, min(x.len, y.len))
ret := memory_compare(x.data, y.data, min(x.len, y.len))
if ret == 0 && x.len != y.len {
return -1 if x.len < y.len else +1
}
return ret
}
string_ne :: #force_inline proc "contextless" (a, b: string) -> bool { return !string_eq(a, b) }
core/runtime/print.odin
+3
View File
@@ -228,6 +228,9 @@ print_type :: proc "contextless" (ti: ^Type_Info) {
case Type_Info_Multi_Pointer:
print_string("[^]")
print_type(info.elem)
case Type_Info_Soa_Pointer:
print_string("#soa ^")
print_type(info.elem)
case Type_Info_Procedure:
print_string("proc")
if info.params == nil {
core/runtime/procs.odin
+19 -9
View File
@@ -6,7 +6,7 @@ when ODIN_NO_CRT && ODIN_OS == .Windows {
@(private="file")
@(default_calling_convention="stdcall")
foreign lib {
RtlMoveMemory :: proc(dst, src: rawptr, length: int) ---
RtlMoveMemory :: proc(dst, s: rawptr, length: int) ---
RtlFillMemory :: proc(dst: rawptr, length: int, fill: i32) ---
}
@@ -40,24 +40,34 @@ when ODIN_NO_CRT && ODIN_OS == .Windows {
@(link_name="memmove", linkage="strong", require)
memmove :: proc "c" (dst, src: rawptr, len: int) -> rawptr {
if dst != src {
d, s := ([^]byte)(dst), ([^]byte)(src)
d, s := ([^]byte)(dst), ([^]byte)(src)
if d == s || len == 0 {
return dst
}
if d > s && uintptr(d)-uintptr(s) < uintptr(len) {
for i := len-1; i >= 0; i -= 1 {
d[i] = s[i]
}
return dst
}
return dst
if s > d && uintptr(s)-uintptr(d) < uintptr(len) {
for i := 0; i < len; i += 1 {
d[i] = s[i]
}
return dst
}
return memcpy(dst, src, len)
}
@(link_name="memcpy", linkage="strong", require)
memcpy :: proc "c" (dst, src: rawptr, len: int) -> rawptr {
if dst != src {
d, s := ([^]byte)(dst), ([^]byte)(src)
for i := len-1; i >= 0; i -= 1 {
d, s := ([^]byte)(dst), ([^]byte)(src)
if d != s {
for i := 0; i < len; i += 1 {
d[i] = s[i]
}
}
return dst
return d
}
} else {
core/slice/slice.odin
+2 -2
View File
@@ -14,14 +14,14 @@ _ :: mem
Turn a pointer and a length into a slice.
*/
from_ptr :: proc "contextless" (ptr: ^$T, count: int) -> []T {
return ([^]T)(ptr)[:count]
return ([^]T)(ptr)[:count]
}
/*
Turn a pointer and a length into a byte slice.
*/
bytes_from_ptr :: proc "contextless" (ptr: rawptr, byte_count: int) -> []byte {
return ([^]byte)(ptr)[:byte_count]
return ([^]byte)(ptr)[:byte_count]
}
/*
core/sort/sort.odin
+6 -1
View File
@@ -684,5 +684,10 @@ compare_f64s :: proc(a, b: f64) -> int {
compare_strings :: proc(a, b: string) -> int {
x := transmute(mem.Raw_String)a
y := transmute(mem.Raw_String)b
return mem.compare_byte_ptrs(x.data, y.data, min(x.len, y.len))
ret := mem.compare_byte_ptrs(x.data, y.data, min(x.len, y.len))
if ret == 0 && x.len != y.len {
return -1 if x.len < y.len else +1
}
return ret
}
core/strconv/strconv.odin
+31 -18
View File
@@ -2,11 +2,13 @@ package strconv
import "core:unicode/utf8"
parse_bool :: proc(s: string) -> (result: bool = false, ok: bool) {
parse_bool :: proc(s: string, n: ^int = nil) -> (result: bool = false, ok: bool) {
switch s {
case "1", "t", "T", "true", "TRUE", "True":
if n != nil { n^ = len(s) }
return true, true
case "0", "f", "F", "false", "FALSE", "False":
if n != nil { n^ = len(s) }
return false, true
}
return
@@ -32,10 +34,13 @@ _digit_value :: proc(r: rune) -> int {
// n, ok := strconv.parse_i64_of_base("-1234eeee", 10);
// assert(n == -1234 && ok);
// ```
parse_i64_of_base :: proc(str: string, base: int) -> (value: i64, ok: bool) {
parse_i64_of_base :: proc(str: string, base: int, n: ^int = nil) -> (value: i64, ok: bool) {
assert(base <= 16, "base must be 1-16")
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -87,8 +92,9 @@ parse_i64_of_base :: proc(str: string, base: int) -> (value: i64, ok: bool) {
// n, ok = strconv.parse_i64_maybe_prefixed("0xeeee");
// assert(n == 0xeeee && ok);
// ```
parse_i64_maybe_prefixed :: proc(str: string) -> (value: i64, ok: bool) {
parse_i64_maybe_prefixed :: proc(str: string, n: ^int = nil) -> (value: i64, ok: bool) {
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -155,9 +161,10 @@ parse_i64 :: proc{parse_i64_maybe_prefixed, parse_i64_of_base}
// n, ok = strconv.parse_u64_of_base("5678eeee", 16);
// assert(n == 0x5678eeee && ok);
// ```
parse_u64_of_base :: proc(str: string, base: int) -> (value: u64, ok: bool) {
parse_u64_of_base :: proc(str: string, base: int, n: ^int = nil) -> (value: u64, ok: bool) {
assert(base <= 16, "base must be 1-16")
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -198,8 +205,9 @@ parse_u64_of_base :: proc(str: string, base: int) -> (value: u64, ok: bool) {
// n, ok = strconv.parse_u64_maybe_prefixed("0xeeee");
// assert(n == 0xeeee && ok);
// ```
parse_u64_maybe_prefixed :: proc(str: string) -> (value: u64, ok: bool) {
parse_u64_maybe_prefixed :: proc(str: string, n: ^int = nil) -> (value: u64, ok: bool) {
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -259,11 +267,11 @@ parse_u64 :: proc{parse_u64_maybe_prefixed, parse_u64_of_base}
// n, ok = strconv.parse_int("0xffff"); // with prefix and inferred base
// assert(n == 0xffff && ok);
// ```
parse_int :: proc(s: string, base := 0) -> (value: int, ok: bool) {
parse_int :: proc(s: string, base := 0, n: ^int = nil) -> (value: int, ok: bool) {
v: i64 = ---
switch base {
case 0: v, ok = parse_i64_maybe_prefixed(s)
case: v, ok = parse_i64_of_base(s, base)
case 0: v, ok = parse_i64_maybe_prefixed(s, n)
case: v, ok = parse_i64_of_base(s, base, n)
}
value = int(v)
return
@@ -289,11 +297,11 @@ parse_int :: proc(s: string, base := 0) -> (value: int, ok: bool) {
// n, ok = strconv.parse_uint("0xffff"); // with prefix and inferred base
// assert(n == 0xffff && ok);
// ```
parse_uint :: proc(s: string, base := 0) -> (value: uint, ok: bool) {
parse_uint :: proc(s: string, base := 0, n: ^int = nil) -> (value: uint, ok: bool) {
v: u64 = ---
switch base {
case 0: v, ok = parse_u64_maybe_prefixed(s)
case: v, ok = parse_u64_of_base(s, base)
case 0: v, ok = parse_u64_maybe_prefixed(s, n)
case: v, ok = parse_u64_of_base(s, base, n)
}
value = uint(v)
return
@@ -309,10 +317,11 @@ parse_uint :: proc(s: string, base := 0) -> (value: uint, ok: bool) {
// n, ok := strconv.parse_i128_of_base("-1234eeee", 10);
// assert(n == -1234 && ok);
// ```
parse_i128_of_base :: proc(str: string, base: int) -> (value: i128, ok: bool) {
parse_i128_of_base :: proc(str: string, base: int, n: ^int = nil) -> (value: i128, ok: bool) {
assert(base <= 16, "base must be 1-16")
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -364,8 +373,9 @@ parse_i128_of_base :: proc(str: string, base: int) -> (value: i128, ok: bool) {
// n, ok = strconv.parse_i128_maybe_prefixed("0xeeee");
// assert(n == 0xeeee && ok);
// ```
parse_i128_maybe_prefixed :: proc(str: string) -> (value: i128, ok: bool) {
parse_i128_maybe_prefixed :: proc(str: string, n: ^int = nil) -> (value: i128, ok: bool) {
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -432,9 +442,10 @@ parse_i128 :: proc{parse_i128_maybe_prefixed, parse_i128_of_base}
// n, ok = strconv.parse_u128_of_base("5678eeee", 16);
// assert(n == 0x5678eeee && ok);
// ```
parse_u128_of_base :: proc(str: string, base: int) -> (value: u128, ok: bool) {
parse_u128_of_base :: proc(str: string, base: int, n: ^int = nil) -> (value: u128, ok: bool) {
assert(base <= 16, "base must be 1-16")
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -475,8 +486,9 @@ parse_u128_of_base :: proc(str: string, base: int) -> (value: u128, ok: bool) {
// n, ok = strconv.parse_u128_maybe_prefixed("0xeeee");
// assert(n == 0xeeee && ok);
// ```
parse_u128_maybe_prefixed :: proc(str: string) -> (value: u128, ok: bool) {
parse_u128_maybe_prefixed :: proc(str: string, n: ^int = nil) -> (value: u128, ok: bool) {
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
@@ -535,9 +547,9 @@ parse_u128 :: proc{parse_u128_maybe_prefixed, parse_u128_of_base}
// n, ok = strconv.parse_f32("12.34");
// assert(n == 12.34 && ok);
// ```
parse_f32 :: proc(s: string) -> (value: f32, ok: bool) {
parse_f32 :: proc(s: string, n: ^int = nil) -> (value: f32, ok: bool) {
v: f64 = ---
v, ok = parse_f64(s)
v, ok = parse_f64(s, n)
return f32(v), ok
}
@@ -553,8 +565,9 @@ parse_f32 :: proc(s: string) -> (value: f32, ok: bool) {
// n, ok = strconv.parse_f32("12.34");
// assert(n == 12.34 && ok);
// ```
parse_f64 :: proc(str: string) -> (value: f64, ok: bool) {
parse_f64 :: proc(str: string, n: ^int = nil) -> (value: f64, ok: bool) {
s := str
defer if n != nil { n^ = len(str)-len(s) }
if s == "" {
return
}
core/strings/intern.odin
+11 -11
View File
@@ -31,31 +31,31 @@ intern_destroy :: proc(m: ^Intern) {
// returns the `text` string from the intern map - gets set if it didnt exist yet
// the returned string lives as long as the map entry lives
intern_get :: proc(m: ^Intern, text: string) -> string {
entry := _intern_get_entry(m, text)
#no_bounds_check return string(entry.str[:entry.len])
intern_get :: proc(m: ^Intern, text: string) -> (str: string, err: runtime.Allocator_Error) {
entry := _intern_get_entry(m, text) or_return
#no_bounds_check return string(entry.str[:entry.len]), nil
}
// returns the `text` cstring from the intern map - gets set if it didnt exist yet
// the returned cstring lives as long as the map entry lives
intern_get_cstring :: proc(m: ^Intern, text: string) -> cstring {
entry := _intern_get_entry(m, text)
return cstring(&entry.str[0])
intern_get_cstring :: proc(m: ^Intern, text: string) -> (str: cstring, err: runtime.Allocator_Error) {
entry := _intern_get_entry(m, text) or_return
return cstring(&entry.str[0]), nil
}
// looks up wether the `text` string exists in the map, returns the entry
// sets & allocates the entry if it wasnt set yet
_intern_get_entry :: proc(m: ^Intern, text: string) -> ^Intern_Entry #no_bounds_check {
_intern_get_entry :: proc(m: ^Intern, text: string) -> (new_entry: ^Intern_Entry, err: runtime.Allocator_Error) #no_bounds_check {
if prev, ok := m.entries[text]; ok {
return prev
return prev, nil
}
if m.allocator.procedure == nil {
m.allocator = context.allocator
}
entry_size := int(offset_of(Intern_Entry, str)) + len(text) + 1
ptr, _ := runtime.mem_alloc(entry_size, align_of(Intern_Entry), m.allocator)
new_entry := (^Intern_Entry)(ptr)
bytes := runtime.mem_alloc(entry_size, align_of(Intern_Entry), m.allocator) or_return
new_entry = (^Intern_Entry)(raw_data(bytes))
new_entry.len = len(text)
copy(new_entry.str[:new_entry.len], text)
@@ -63,5 +63,5 @@ _intern_get_entry :: proc(m: ^Intern, text: string) -> ^Intern_Entry #no_bounds_
key := string(new_entry.str[:new_entry.len])
m.entries[key] = new_entry
return new_entry
return new_entry, nil
}
core/sync/futex_windows.odin
+24 -2
View File
@@ -15,18 +15,40 @@ foreign import Ntdll "system:Ntdll.lib"
@(default_calling_convention="stdcall")
foreign Ntdll {
RtlWaitOnAddress :: proc(Address: rawptr, CompareAddress: rawptr, AddressSize: uint, Timeout: ^i64) -> i32 ---
RtlNtStatusToDosError :: proc(status: i32) -> u32 ---
SetLastError :: proc(err: u32) ---
}
/*
NOTE(bill, 2022-08-17)
WaitOnAddress is implemented on top of RtlWaitOnAddress
BUT requires taking the return value of it and if it is non-zero
converting that status to a DOS error and then SetLastError
If this is not done, then things don't work as expected when
and error occurs
GODDAMN MICROSOFT!
*/
CustomWaitOnAddress :: proc "stdcall" (Address: rawptr, CompareAddress: rawptr, AddressSize: uint, Timeout: ^i64) -> bool {
status := RtlWaitOnAddress(Address, CompareAddress, AddressSize, Timeout)
if status != 0 {
SetLastError(RtlNtStatusToDosError(status))
}
return status == 0
}
_futex_wait :: proc(f: ^Futex, expect: u32) -> bool {
expect := expect
return 0 == RtlWaitOnAddress(f, &expect, size_of(expect), nil)
return CustomWaitOnAddress(f, &expect, size_of(expect), nil)
}
_futex_wait_with_timeout :: proc(f: ^Futex, expect: u32, duration: time.Duration) -> bool {
expect := expect
// NOTE(bill): for some bizarre reason, this has be a negative number
timeout := -i64(duration / 100)
return 0 == RtlWaitOnAddress(f, &expect, size_of(expect), &timeout)
return CustomWaitOnAddress(f, &expect, size_of(expect), &timeout)
}
_futex_signal :: proc(f: ^Futex) {
core/sys/unix/syscalls_linux.odin
+3 -3
View File
@@ -1568,7 +1568,7 @@ sys_gettid :: proc "contextless" () -> int {
}
sys_getrandom :: proc "contextless" (buf: [^]byte, buflen: int, flags: uint) -> int {
return cast(int)intrinsics.syscall(SYS_getrandom, buf, cast(uintptr)(buflen), cast(uintptr)(flags))
return cast(int)intrinsics.syscall(SYS_getrandom, uintptr(buf), uintptr(buflen), uintptr(flags))
}
sys_open :: proc "contextless" (path: cstring, flags: int, mode: int = 0o000) -> int {
@@ -1622,7 +1622,7 @@ sys_lseek :: proc "contextless" (fd: int, offset: i64, whence: int) -> i64 {
low := uintptr(offset & 0xFFFFFFFF)
high := uintptr(offset >> 32)
result: i64
res := i64(intrinsics.syscall(SYS__llseek, uintptr(fd), high, low, &result, uintptr(whence)))
res := i64(intrinsics.syscall(SYS__llseek, uintptr(fd), high, low, uintptr(&result), uintptr(whence)))
return res if res < 0 else result
}
}
@@ -1748,7 +1748,7 @@ sys_unlink :: proc "contextless" (path: cstring) -> int {
}
sys_unlinkat :: proc "contextless" (dfd: int, path: cstring, flag: int = 0) -> int {
return int(intrinsics.syscall(SYS_unlinkat, uintptr(dfd), uintptr(rawptr(path)), flag))
return int(intrinsics.syscall(SYS_unlinkat, uintptr(dfd), uintptr(rawptr(path)), uintptr(flag)))
}
sys_rmdir :: proc "contextless" (path: cstring) -> int {
core/sys/valgrind/callgrind.odin
+63
View File
@@ -0,0 +1,63 @@
//+build amd64
package sys_valgrind
import "core:intrinsics"
Callgrind_Client_Request :: enum uintptr {
Dump_Stats = 'C'<<24 | 'T'<<16,
Zero_Stats,
Toggle_Collect,
Dump_Stats_At,
Start_Instrumentation,
Stop_Instrumentation,
}
@(require_results)
callgrind_client_request_expr :: proc "c" (default: uintptr, request: Callgrind_Client_Request, a0, a1, a2, a3, a4: uintptr) -> uintptr {
return intrinsics.valgrind_client_request(default, uintptr(request), a0, a1, a2, a3, a4)
}
callgrind_client_request_stmt :: proc "c" (request: Callgrind_Client_Request, a0, a1, a2, a3, a4: uintptr) {
_ = intrinsics.valgrind_client_request(0, uintptr(request), a0, a1, a2, a3, a4)
}
// Dump current state of cost centres, and zero them afterwards.
dump_stats :: proc "c" () {
callgrind_client_request_stmt(.Dump_Stats, 0, 0, 0, 0, 0)
}
// Zero cost centres
zero_stats :: proc "c" () {
callgrind_client_request_stmt(.Zero_Stats, 0, 0, 0, 0, 0)
}
// Toggles collection state.
// The collection state specifies whether the happening of events should be noted or
// if they are to be ignored. Events are noted by increment of counters in a cost centre.
toggle_collect :: proc "c" () {
callgrind_client_request_stmt(.Toggle_Collect, 0, 0, 0, 0, 0)
}
// Dump current state of cost centres, and zero them afterwards.
// The argument is appended to a string stating the reason which triggered
// the dump. This string is written as a description field into the
// profile data dump.
dump_stats_at :: proc "c" (pos_str: rawptr) {
callgrind_client_request_stmt(.Dump_Stats_At, uintptr(pos_str), 0, 0, 0, 0)
}
// Start full callgrind instrumentation if not already switched on.
// When cache simulation is done, it will flush the simulated cache;
// this will lead to an artificial cache warmup phase afterwards with
// cache misses which would not have happened in reality.
start_instrumentation :: proc "c" () {
callgrind_client_request_stmt(.Start_Instrumentation, 0, 0, 0, 0, 0)
}
// Stop full callgrind instrumentation if not already switched off.
// This flushes Valgrinds translation cache, and does no additional instrumentation
// afterwards, which effectivly will run at the same speed as the "none" tool (ie. at minimal slowdown).
// Use this to bypass Callgrind aggregation for uninteresting code parts.
// To start Callgrind in this mode to ignore the setup phase, use the option "--instr-atstart=no".
stop_instrumentation :: proc "c" () {
callgrind_client_request_stmt(.Stop_Instrumentation, 0, 0, 0, 0, 0)
}
core/sys/valgrind/memcheck.odin
+169
View File
@@ -0,0 +1,169 @@
//+build amd64
package sys_valgrind
import "core:intrinsics"
Mem_Check_Client_Request :: enum uintptr {
Make_Mem_No_Access = 'M'<<24 | 'C'<<16,
Make_Mem_Undefined,
Make_Mem_Defined,
Discard,
Check_Mem_Is_Addressable,
Check_Mem_Is_Defined,
Do_Leak_Check,
Count_Leaks,
Get_Vbits,
Set_Vbits,
Create_Block,
Make_Mem_Defined_If_Addressable,
Count_Leak_Blocks,
Enable_Addr_Error_Reporting_In_Range,
Disable_Addr_Error_Reporting_In_Range,
}
@(require_results)
mem_check_client_request_expr :: proc "c" (default: uintptr, request: Mem_Check_Client_Request, a0, a1, a2, a3, a4: uintptr) -> uintptr {
return intrinsics.valgrind_client_request(default, uintptr(request), a0, a1, a2, a3, a4)
}
mem_check_client_request_stmt :: proc "c" (request: Mem_Check_Client_Request, a0, a1, a2, a3, a4: uintptr) {
_ = intrinsics.valgrind_client_request(0, uintptr(request), a0, a1, a2, a3, a4)
}
// Mark memory at `raw_data(qzz)` as unaddressable for `len(qzz)` bytes.
// Returns true when run on Valgrind and false otherwise.
make_mem_no_access :: proc "c" (qzz: []byte) -> bool {
return 0 != mem_check_client_request_expr(0, .Make_Mem_No_Access, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Mark memory at `raw_data(qzz)` as addressable but undefined for `len(qzz)` bytes.
// Returns true when run on Valgrind and false otherwise.
make_mem_undefined :: proc "c" (qzz: []byte) -> bool {
return 0 != mem_check_client_request_expr(0, .Make_Mem_Undefined, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Mark memory at `raw_data(qzz)` as addressable for `len(qzz)` bytes.
// Returns true when run on Valgrind and false otherwise.
make_mem_defined :: proc "c" (qzz: []byte) -> bool {
return 0 != mem_check_client_request_expr(0, .Make_Mem_Defined, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Check that memory at `raw_data(qzz)` is addressable for `len(qzz)` bytes.
// If suitable addressibility is not established, Valgrind prints an error
// message and returns the address of the first offending byte.
// Otherwise it returns zero.
check_mem_is_addressable :: proc "c" (qzz: []byte) -> uintptr {
return mem_check_client_request_expr(0, .Check_Mem_Is_Addressable, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Check that memory at `raw_data(qzz)` is addressable and defined for `len(qzz)` bytes.
// If suitable addressibility and definedness are not established,
// Valgrind prints an error message and returns the address of the first
// offending byte. Otherwise it returns zero.
check_mem_is_defined :: proc "c" (qzz: []byte) -> uintptr {
return mem_check_client_request_expr(0, .Check_Mem_Is_Defined, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Similar to `make_mem_defined(qzz)` except that addressability is not altered:
// bytes which are addressable are marked as defined, but those which
// are not addressable are left unchanged.
// Returns true when run on Valgrind and false otherwise.
make_mem_defined_if_addressable :: proc "c" (qzz: []byte) -> bool {
return 0 != mem_check_client_request_expr(0, .Make_Mem_Defined_If_Addressable, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Create a block-description handle.
// The description is an ascii string which is included in any messages
// pertaining to addresses within the specified memory range.
// Has no other effect on the properties of the memory range.
create_block :: proc "c" (qzz: []u8, desc: cstring) -> bool {
return 0 != mem_check_client_request_expr(0, .Create_Block, uintptr(raw_data(qzz)), uintptr(len(qzz)), uintptr(rawptr(desc)), 0, 0)
}
// Discard a block-description-handle. Returns true for an invalid handle, false for a valid handle.
discard :: proc "c" (blk_index: uintptr) -> bool {
return 0 != mem_check_client_request_expr(0, .Discard, 0, blk_index, 0, 0, 0)
}
// Do a full memory leak check (like `--leak-check=full`) mid-execution.
leak_check :: proc "c" () {
mem_check_client_request_stmt(.Do_Leak_Check, 0, 0, 0, 0, 0)
}
// Same as `leak_check()` but only showing the entries for which there was an increase
// in leaked bytes or leaked nr of blocks since the previous leak search.
added_leak_check :: proc "c" () {
mem_check_client_request_stmt(.Do_Leak_Check, 0, 1, 0, 0, 0)
}
// Same as `added_leak_check()` but showing entries with increased or decreased
// leaked bytes/blocks since previous leak search.
changed_leak_check :: proc "c" () {
mem_check_client_request_stmt(.Do_Leak_Check, 0, 2, 0, 0, 0)
}
// Do a summary memory leak check (like `--leak-check=summary`) mid-execution.
quick_leak_check :: proc "c" () {
mem_check_client_request_stmt(.Do_Leak_Check, 1, 0, 0, 0, 0)
}
Count_Result :: struct {
leaked: uint,
dubious: uint,
reachable: uint,
suppressed: uint,
}
count_leaks :: proc "c" () -> (res: Count_Result) {
mem_check_client_request_stmt(
.Count_Leaks,
uintptr(&res.leaked),
uintptr(&res.dubious),
uintptr(&res.reachable),
uintptr(&res.suppressed),
0,
)
return
}
count_leak_blocks :: proc "c" () -> (res: Count_Result) {
mem_check_client_request_stmt(
.Count_Leak_Blocks,
uintptr(&res.leaked),
uintptr(&res.dubious),
uintptr(&res.reachable),
uintptr(&res.suppressed),
0,
)
return
}
// Get the validity data for addresses zza and copy it
// into the provided zzvbits array. Return values:
// 0 - if not running on valgrind
// 1 - success
// 2 - [previously indicated unaligned arrays; these are now allowed]
// 3 - if any parts of zzsrc/zzvbits are not addressable.
// The metadata is not copied in cases 0, 2 or 3 so it should be
// impossible to segfault your system by using this call.
get_vbits :: proc(zza, zzvbits: []byte) -> u8 {
// assert requires a `context` thus these procedures cannot `proc "c"`
assert(len(zzvbits) >= len(zza)/8)
return u8(mem_check_client_request_expr(0, .Get_Vbits, uintptr(raw_data(zza)), uintptr(raw_data(zzvbits)), uintptr(len(zza)), 0, 0))
}
// Set the validity data for addresses zza, copying it
// from the provided zzvbits array. Return values:
// 0 - if not running on valgrind
// 1 - success
// 2 - [previously indicated unaligned arrays; these are now allowed]
// 3 - if any parts of zza/zzvbits are not addressable.
// The metadata is not copied in cases 0, 2 or 3 so it should be
// impossible to segfault your system by using this call.
set_vbits :: proc(zzvbits, zza: []byte) -> u8 {
// assert requires a `context` thus these procedures cannot `proc "c"`
assert(len(zzvbits) >= len(zza)/8)
return u8(mem_check_client_request_expr(0, .Set_Vbits, uintptr(raw_data(zza)), uintptr(raw_data(zzvbits)), uintptr(len(zza)), 0, 0))
}
// (Re-)enable reporting of addressing errors in the specified address range.
enable_addr_error_reporting_in_range :: proc "c" (qzz: []byte) -> uintptr {
return mem_check_client_request_expr(0, .Enable_Addr_Error_Reporting_In_Range, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
// Disable reporting of addressing errors in the specified address range.
disable_addr_error_reporting_in_range :: proc "c" (qzz: []byte) -> uintptr {
return mem_check_client_request_expr(0, .Disable_Addr_Error_Reporting_In_Range, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
core/sys/valgrind/valgrind.odin
+182
View File
@@ -0,0 +1,182 @@
//+build amd64
package sys_valgrind
import "core:intrinsics"
Client_Request :: enum uintptr {
Running_On_Valgrind = 4097,
Discard_Translations = 4098,
Client_Call0 = 4353,
Client_Call1 = 4354,
Client_Call2 = 4355,
Client_Call3 = 4356,
Count_Errors = 4609,
Gdb_Monitor_Command = 4610,
Malloc_Like_Block = 4865,
Resize_Inplace_Block = 4875,
Free_Like_Block = 4866,
Create_Mem_Pool = 4867,
Destroy_Mem_Pool = 4868,
Mem_Pool_Alloc = 4869,
Mem_Pool_Free = 4870,
Mem_Pool_Trim = 4871,
Move_Mem_Pool = 4872,
Mem_Pool_Change = 4873,
Mem_Pool_Exists = 4874,
Printf = 5121,
Printf_Backtrace = 5122,
Printf_Valist_By_Ref = 5123,
Printf_Backtrace_Valist_By_Ref = 5124,
Stack_Register = 5377,
Stack_Deregister = 5378,
Stack_Change = 5379,
Load_Pdb_Debug_Info = 5633,
Map_Ip_To_Src_Loc = 5889,
Change_Err_Disablement = 6145,
Vex_Init_For_Iri = 6401,
Inner_Threads = 6402,
}
@(require_results)
client_request_expr :: proc "c" (default: uintptr, request: Client_Request, a0, a1, a2, a3, a4: uintptr) -> uintptr {
return intrinsics.valgrind_client_request(default, uintptr(request), a0, a1, a2, a3, a4)
}
client_request_stmt :: proc "c" (request: Client_Request, a0, a1, a2, a3, a4: uintptr) {
_ = intrinsics.valgrind_client_request(0, uintptr(request), a0, a1, a2, a3, a4)
}
// Returns the number of Valgrinds this code is running under
// 0 - running natively
// 1 - running under Valgrind
// 2 - running under Valgrind which is running under another Valgrind
running_on_valgrind :: proc "c" () -> uintptr {
return client_request_expr(0, .Running_On_Valgrind, 0, 0, 0, 0, 0)
}
// Discard translation of code in the slice qzz. Useful if you are debugging a JIT-er or some such,
// since it provides a way to make sure valgrind will retranslate the invalidated area.
discard_translations :: proc "c" (qzz: []byte) {
client_request_stmt(.Discard_Translations, uintptr(raw_data(qzz)), uintptr(len(qzz)), 0, 0, 0)
}
non_simd_call0 :: proc "c" (p: proc "c" (uintptr) -> uintptr) -> uintptr {
return client_request_expr(0, .Client_Call0, uintptr(rawptr(p)), 0, 0, 0, 0)
}
non_simd_call1 :: proc "c" (p: proc "c" (uintptr, uintptr) -> uintptr, a0: uintptr) -> uintptr {
return client_request_expr(0, .Client_Call1, uintptr(rawptr(p)), a0, 0, 0, 0)
}
non_simd_call2 :: proc "c" (p: proc "c" (uintptr, uintptr, uintptr) -> uintptr, a0, a1: uintptr) -> uintptr {
return client_request_expr(0, .Client_Call2, uintptr(rawptr(p)), a0, a1, 0, 0)
}
non_simd_call3 :: proc "c" (p: proc "c" (uintptr, uintptr, uintptr, uintptr) -> uintptr, a0, a1, a2: uintptr) -> uintptr {
return client_request_expr(0, .Client_Call3, uintptr(rawptr(p)), a0, a1, a2, 0)
}
// Counts the number of errors that have been recorded by a tool.
count_errrors :: proc "c" () -> uint {
return uint(client_request_expr(0, .Count_Errors, 0, 0, 0, 0, 0))
}
monitor_command :: proc "c" (command: cstring) -> bool {
return 0 != client_request_expr(0, .Gdb_Monitor_Command, uintptr(rawptr(command)), 0, 0, 0, 0)
}
malloc_like_block :: proc "c" (mem: []byte, rz_b: uintptr, is_zeroed: bool) {
client_request_stmt(.Malloc_Like_Block, uintptr(raw_data(mem)), uintptr(len(mem)), rz_b, uintptr(is_zeroed), 0)
}
resize_inplace_block :: proc "c" (old_mem: []byte, new_size: uint, rz_b: uintptr) {
client_request_stmt(.Resize_Inplace_Block, uintptr(raw_data(old_mem)), uintptr(len(old_mem)), uintptr(new_size), rz_b, 0)
}
free_like_block :: proc "c" (addr: rawptr, rz_b: uintptr) {
client_request_stmt(.Free_Like_Block, uintptr(addr), rz_b, 0, 0, 0)
}
Mem_Pool_Flags :: distinct bit_set[Mem_Pool_Flag; uintptr]
Mem_Pool_Flag :: enum uintptr {
Auto_Free = 0,
Meta_Pool = 1,
}
// Create a memory pool.
create_mem_pool :: proc "c" (pool: rawptr, rz_b: uintptr, is_zeroed: bool, flags: Mem_Pool_Flags) {
client_request_stmt(.Create_Mem_Pool, uintptr(pool), rz_b, uintptr(is_zeroed), transmute(uintptr)flags, 0)
}
// Destroy a memory pool.
destroy_mem_pool :: proc "c" (pool: rawptr) {
client_request_stmt(.Destroy_Mem_Pool, uintptr(pool), 0, 0, 0, 0)
}
// Associate a section of memory with a memory pool.
mem_pool_alloc :: proc "c" (pool: rawptr, mem: []byte) {
client_request_stmt(.Mem_Pool_Alloc, uintptr(pool), uintptr(raw_data(mem)), uintptr(len(mem)), 0, 0)
}
// Disassociate a section of memory from a memory pool.
mem_pool_free :: proc "c" (pool: rawptr, addr: rawptr) {
client_request_stmt(.Mem_Pool_Free, uintptr(pool), uintptr(addr), 0, 0, 0)
}
// Disassociate parts of a section of memory outside a particular range.
mem_pool_trim :: proc "c" (pool: rawptr, mem: []byte) {
client_request_stmt(.Mem_Pool_Trim, uintptr(pool), uintptr(raw_data(mem)), uintptr(len(mem)), 0, 0)
}
// Resize and/or move a section of memory associated with a memory pool.
move_mem_pool :: proc "c" (pool_a, pool_b: rawptr) {
client_request_stmt(.Move_Mem_Pool, uintptr(pool_a), uintptr(pool_b), 0, 0, 0)
}
// Resize and/or move a section of memory associated with a memory pool.
mem_pool_change :: proc "c" (pool: rawptr, addr_a: rawptr, mem: []byte) {
client_request_stmt(.Mem_Pool_Change, uintptr(pool), uintptr(addr_a), uintptr(raw_data(mem)), uintptr(len(mem)), 0)
}
// Return true if a memory pool exists
mem_pool_exists :: proc "c" (pool: rawptr) -> bool {
return 0 != client_request_expr(0, .Mem_Pool_Exists, uintptr(pool), 0, 0, 0, 0)
}
// Mark a section of memory as being a stack. Returns a stack id.
stack_register :: proc "c" (stack: []byte) -> (stack_id: uintptr) {
ptr := uintptr(raw_data(stack))
return client_request_expr(0, .Stack_Register, ptr, ptr+uintptr(len(stack)), 0, 0, 0)
}
// Unmark a section of memory associated with a stack id as being a stack.
stack_deregister :: proc "c" (id: uintptr) {
client_request_stmt(.Stack_Deregister, id, 0, 0, 0, 0)
}
// Change the start and end address of the stack id with the `new_stack` slice.
stack_change :: proc "c" (id: uint, new_stack: []byte) {
ptr := uintptr(raw_data(new_stack))
client_request_stmt(.Stack_Change, uintptr(id), ptr, ptr + uintptr(len(new_stack)), 0, 0)
}
// Disable error reporting for the current thread/
// It behaves in a stack-like way, meaning you can safely call this multiple times
// given that `enable_error_reporting()` is called the same number of times to
// re-enable the error reporting.
// The first call of this macro disables reporting.
// Subsequent calls have no effect except to increase the number of `enable_error_reporting()`
// calls needed to re-enable reporting.
// Child threads do not inherit this setting from their parents;
// they are always created with reporting enabled.
disable_error_reporting :: proc "c" () {
client_request_stmt(.Change_Err_Disablement, 1, 0, 0, 0, 0)
}
// Re-enable error reporting
enable_error_reporting :: proc "c" () {
client_request_stmt(.Change_Err_Disablement, ~uintptr(0), 0, 0, 0, 0)
}
inner_threads :: proc "c" (qzz: rawptr) {
client_request_stmt(.Inner_Threads, uintptr(qzz), 0, 0, 0, 0)
}
// Map a code address to a source file name and line number.
// `buf64` must point to a 64-byte buffer in the caller's address space.
// The result will be dumped in there and is guaranteed to be zero terminated.
// If no info is found, the first byte is set to zero.
map_ip_to_src_loc :: proc "c" (addr: rawptr, buf64: ^[64]byte) -> uintptr {
return client_request_expr(0, .Map_Ip_To_Src_Loc, uintptr(addr), uintptr(buf64), 0, 0, 0)
}
core/sys/wasm/wasi/wasi_api.odin
+171 -259
View File
@@ -1148,6 +1148,156 @@ foreign wasi {
*/
how: sdflags_t,
) -> errno_t ---
/**
* Return a description of the given preopened file descriptor.
*/
fd_prestat_dir_name :: proc(
fd: fd_t,
/**
* A buffer into which to write the preopened directory name.
*/
path: string,
) -> errno_t ---
/**
* Create a directory.
* Note: This is similar to `mkdirat` in POSIX.
*/
path_create_directory :: proc(
fd: fd_t,
/**
* The path at which to create the directory.
*/
path: string,
) -> errno_t ---
/**
* Adjust the timestamps of a file or directory.
* Note: This is similar to `utimensat` in POSIX.
*/
path_filestat_set_times :: proc(
fd: fd_t,
/**
* Flags determining the method of how the path is resolved.
*/
flags: lookupflags_t,
/**
* The path of the file or directory to operate on.
*/
path: string,
/**
* The desired values of the data access timestamp.
*/
atim: timestamp_t,
/**
* The desired values of the data modification timestamp.
*/
mtim: timestamp_t,
/**
* A bitmask indicating which timestamps to adjust.
*/
fst_flags: fstflags_t,
) -> errno_t ---
/**
* Remove a directory.
* Return `errno::notempty` if the directory is not empty.
* Note: This is similar to `unlinkat(fd, path, AT_REMOVEDIR)` in POSIX.
*/
path_remove_directory :: proc(
fd: fd_t,
/**
* The path to a directory to remove.
*/
path: string,
) -> errno_t ---
/**
* Create a hard link.
* Note: This is similar to `linkat` in POSIX.
*/
path_link :: proc(
old_fd: fd_t,
/**
* Flags determining the method of how the path is resolved.
*/
old_flags: lookupflags_t,
/**
* The source path from which to link.
*/
old_path: string,
/**
* The working directory at which the resolution of the new path starts.
*/
new_fd: fd_t,
/**
* The destination path at which to create the hard link.
*/
new_path: string,
) -> errno_t ---
/**
* Rename a file or directory.
* Note: This is similar to `renameat` in POSIX.
*/
path_rename :: proc(
fd: fd_t,
/**
* The source path of the file or directory to rename.
*/
old_path: string,
/**
* The working directory at which the resolution of the new path starts.
*/
new_fd: fd_t,
/**
* The destination path to which to rename the file or directory.
*/
new_path: string,
) -> errno_t ---
/**
* Create a symbolic link.
* Note: This is similar to `symlinkat` in POSIX.
*/
path_symlink :: proc(
/**
* The contents of the symbolic link.
*/
old_path: string,
fd: fd_t,
/**
* The destination path at which to create the symbolic link.
*/
new_path: string,
) -> errno_t ---
/**
* Unlink a file.
* Return `errno::isdir` if the path refers to a directory.
* Note: This is similar to `unlinkat(fd, path, 0)` in POSIX.
*/
path_unlink_file :: proc(
fd: fd_t,
/**
* The path to a file to unlink.
*/
path: string,
) -> errno_t ---
/**
* Write high-quality random data into a buffer.
* This function blocks when the implementation is unable to immediately
* provide sufficient high-quality random data.
* This function may execute slowly, so when large mounts of random data are
* required, it's advisable to use this function to seed a pseudo-random
* number generator, rather than to provide the random data directly.
*/
random_get :: proc(
/**
* The buffer to fill with random data.
*/
buf: []u8,
) -> errno_t ---
}
/**
@@ -1250,7 +1400,7 @@ fd_pread :: proc "c" (
*/
offset: filesize_t,
) -> (n: size_t, err: errno_t) {
err = wasi_fd_pread(fd, raw_data(iovs), len(iovs), offset, &n)
err = wasi_fd_pread(fd, iovs, offset, &n)
return
}
/**
@@ -1281,7 +1431,7 @@ fd_pwrite :: proc "c" (
*/
offset: filesize_t,
) -> (n: size_t, err: errno_t) {
err = wasi_fd_pwrite(fd, raw_data(iovs), len(iovs), offset, &n)
err = wasi_fd_pwrite(fd, iovs, offset, &n)
return
}
/**
@@ -1297,7 +1447,7 @@ fd_read :: proc "c" (
*/
iovs: []iovec_t,
) -> (n: size_t, err: errno_t) {
err = wasi_fd_read(fd, raw_data(iovs), len(iovs), &n)
err = wasi_fd_read(fd, iovs, &n)
return
}
/**
@@ -1324,7 +1474,7 @@ fd_readdir :: proc "c" (
*/
cookie: dircookie_t,
) -> (n: size_t, err: errno_t) {
err = wasi_fd_readdir(fd, raw_data(buf), len(buf), cookie, &n)
err = wasi_fd_readdir(fd, buf, cookie, &n)
return
}
/**
@@ -1370,7 +1520,7 @@ fd_write :: proc "c" (
*/
iovs: []ciovec_t,
) -> (n: size_t, err: errno_t) {
err = wasi_fd_write(fd, raw_data(iovs), len(iovs), &n)
err = wasi_fd_write(fd, iovs, &n)
return
}
/**
@@ -1390,7 +1540,7 @@ path_filestat_get :: proc "c" (
*/
path: string,
) -> (offset: filestat_t, err: errno_t) {
err = wasi_path_filestat_get(fd, flags, raw_data(path), len(path), &offset)
err = wasi_path_filestat_get(fd, flags, path, &offset)
return
}
/**
@@ -1432,7 +1582,7 @@ path_open :: proc "c" (
fs_rights_inheriting: rights_t,
fdflags: fdflags_t,
) -> (file: fd_t, err: errno_t) {
err = wasi_path_open(fd, dirflags, raw_data(path), len(path), oflags, fs_rights_base, fs_rights_inheriting, fdflags, &file)
err = wasi_path_open(fd, dirflags, path, oflags, fs_rights_base, fs_rights_inheriting, fdflags, &file)
return
}
/**
@@ -1452,7 +1602,7 @@ path_readlink :: proc "c" (
*/
buf: []u8,
) -> (n: size_t, err: errno_t) {
err = wasi_path_readlink(fd, raw_data(path), len(path), raw_data(buf), len(buf), &n)
err = wasi_path_readlink(fd, path, buf, &n)
return
}
/**
@@ -1495,7 +1645,7 @@ sock_recv :: proc "c" (
*/
ri_flags: riflags_t,
) -> (n: size_t, flags: roflags_t, err: errno_t) {
err = wasi_sock_recv(fd, raw_data(ri_data), len(ri_data), ri_flags, &n, &flags)
err = wasi_sock_recv(fd, ri_data, ri_flags, &n, &flags)
return
}
/**
@@ -1516,172 +1666,11 @@ sock_send :: proc "c" (
*/
si_flags: siflags_t,
) -> (n: size_t, err: errno_t) {
err = wasi_sock_send(fd, raw_data(si_data), len(si_data), si_flags, &n)
err = wasi_sock_send(fd, si_data, si_flags, &n)
return
}
/**
* Return a description of the given preopened file descriptor.
*/
fd_prestat_dir_name :: proc(
fd: fd_t,
/**
* A buffer into which to write the preopened directory name.
*/
path: string,
) -> errno_t {
return wasm_fd_prestat_dir_name(fd, raw_data(path), len(path))
}
/**
* Create a directory.
* Note: This is similar to `mkdirat` in POSIX.
*/
path_create_directory :: proc(
fd: fd_t,
/**
* The path at which to create the directory.
*/
path: string,
) -> errno_t {
return wasm_path_create_directory(fd, raw_data(path), len(path))
}
/**
* Adjust the timestamps of a file or directory.
* Note: This is similar to `utimensat` in POSIX.
*/
path_filestat_set_times :: proc(
fd: fd_t,
/**
* Flags determining the method of how the path is resolved.
*/
flags: lookupflags_t,
/**
* The path of the file or directory to operate on.
*/
path: string,
/**
* The desired values of the data access timestamp.
*/
atim: timestamp_t,
/**
* The desired values of the data modification timestamp.
*/
mtim: timestamp_t,
/**
* A bitmask indicating which timestamps to adjust.
*/
fst_flags: fstflags_t,
) -> errno_t {
return wasm_path_filestat_set_times(fd, flags, raw_data(path), len(path), atim, mtim, fst_flags)
}
/**
* Remove a directory.
* Return `errno::notempty` if the directory is not empty.
* Note: This is similar to `unlinkat(fd, path, AT_REMOVEDIR)` in POSIX.
*/
path_remove_directory :: proc(
fd: fd_t,
/**
* The path to a directory to remove.
*/
path: string,
) -> errno_t {
return wasm_path_remove_directory(fd, raw_data(path), len(path))
}
/**
* Create a hard link.
* Note: This is similar to `linkat` in POSIX.
*/
path_link :: proc(
old_fd: fd_t,
/**
* Flags determining the method of how the path is resolved.
*/
old_flags: lookupflags_t,
/**
* The source path from which to link.
*/
old_path: string,
/**
* The working directory at which the resolution of the new path starts.
*/
new_fd: fd_t,
/**
* The destination path at which to create the hard link.
*/
new_path: string,
) -> errno_t {
return wasm_path_link(old_fd, old_flags, raw_data(old_path), len(old_path), new_fd, raw_data(new_path), len(new_path))
}
/**
* Rename a file or directory.
* Note: This is similar to `renameat` in POSIX.
*/
path_rename :: proc(
fd: fd_t,
/**
* The source path of the file or directory to rename.
*/
old_path: string,
/**
* The working directory at which the resolution of the new path starts.
*/
new_fd: fd_t,
/**
* The destination path to which to rename the file or directory.
*/
new_path: string,
) -> errno_t {
return wasm_path_rename(fd, raw_data(old_path), len(old_path), new_fd, raw_data(new_path), len(new_path))
}
/**
* Create a symbolic link.
* Note: This is similar to `symlinkat` in POSIX.
*/
path_symlink :: proc(
/**
* The contents of the symbolic link.
*/
old_path: string,
fd: fd_t,
/**
* The destination path at which to create the symbolic link.
*/
new_path: string,
) -> errno_t {
return wasm_path_symlink(raw_data(old_path), len(old_path), fd, raw_data(new_path), len(new_path))
}
/**
* Unlink a file.
* Return `errno::isdir` if the path refers to a directory.
* Note: This is similar to `unlinkat(fd, path, 0)` in POSIX.
*/
path_unlink_file :: proc(
fd: fd_t,
/**
* The path to a file to unlink.
*/
path: string,
) -> errno_t {
return wasm_path_unlink_file(fd, raw_data(path), len(path))
}
/**
* Write high-quality random data into a buffer.
* This function blocks when the implementation is unable to immediately
* provide sufficient high-quality random data.
* This function may execute slowly, so when large mounts of random data are
* required, it's advisable to use this function to seed a pseudo-random
* number generator, rather than to provide the random data directly.
*/
random_get :: proc(
/**
* The buffer to fill with random data.
*/
buf: []u8,
) -> errno_t {
return wasm_random_get(raw_data(buf), len(buf))
}
@@ -1722,8 +1711,7 @@ foreign wasi {
@(link_name="fd_pread")
wasi_fd_pread :: proc(
fd: fd_t,
iovs: [^]iovec_t,
iovs_len: size_t,
iovs: []iovec_t,
offset: filesize_t,
retptr0: ^size_t,
) -> errno_t ---
@@ -1735,23 +1723,20 @@ foreign wasi {
@(link_name="fd_pwrite")
wasi_fd_pwrite :: proc(
fd: fd_t,
iovs: [^]ciovec_t,
iovs_len: size_t,
iovs: []ciovec_t,
offset: filesize_t,
retptr0: ^size_t,
) -> errno_t ---
@(link_name="fd_read")
wasi_fd_read :: proc(
fd: fd_t,
iovs: [^]iovec_t,
iovs_len: size_t,
iovs: []iovec_t,
retptr0: ^size_t,
) -> errno_t ---
@(link_name="fd_readdir")
wasi_fd_readdir :: proc(
fd: fd_t,
buf: [^]u8,
buf_len: size_t,
buf: []u8,
cookie: dircookie_t,
retptr0: ^size_t,
) -> errno_t ---
@@ -1770,8 +1755,7 @@ foreign wasi {
@(link_name="fd_write")
wasi_fd_write :: proc(
fd: fd_t,
iovs: [^]ciovec_t,
iovs_len: size_t,
iovs: []ciovec_t,
retptr0: ^size_t,
) -> errno_t ---
@(link_name="path_filestat_get")
@@ -1781,16 +1765,14 @@ foreign wasi {
/**
* The path of the file or directory to inspect.
*/
path: [^]u8,
path_len: size_t,
path: string,
retptr0: ^filestat_t,
) -> errno_t ---
@(link_name="path_open")
wasi_path_open :: proc(
fd: fd_t,
dirflags: lookupflags_t,
path: [^]u8,
path_len: size_t,
path: string,
oflags: oflags_t,
fs_rights_base: rights_t,
fs_rights_inheriting: rights_t,
@@ -1800,10 +1782,8 @@ foreign wasi {
@(link_name="path_readlink")
wasi_path_readlink :: proc(
fd: fd_t,
path: [^]u8,
path_len: size_t,
buf: [^]u8,
buf_len: size_t,
path: string,
buf: []u8,
retptr0: ^size_t,
) -> errno_t ---
@(link_name="poll_oneoff")
@@ -1816,8 +1796,7 @@ foreign wasi {
@(link_name="sock_recv")
wasi_sock_recv :: proc(
fd: fd_t,
ri_data: [^]iovec_t,
ri_data_len: size_t,
ri_data: []iovec_t,
ri_flags: riflags_t,
retptr0: ^size_t,
retptr1: ^roflags_t,
@@ -1825,75 +1804,8 @@ foreign wasi {
@(link_name="sock_send")
wasi_sock_send :: proc(
fd: fd_t,
si_data: [^]ciovec_t,
si_data_len: size_t,
si_data: []ciovec_t,
si_flags: siflags_t,
retptr0: ^size_t,
) -> errno_t ---
@(link_name="fd_prestat_dir_name")
wasm_fd_prestat_dir_name :: proc(
fd: fd_t,
path: [^]u8,
path_len: size_t,
) -> errno_t ---
@(link_name="path_create_directory")
wasm_path_create_directory :: proc(
fd: fd_t,
path: [^]u8,
path_len: size_t,
) -> errno_t ---
@(link_name="path_filestat_set_times")
wasm_path_filestat_set_times :: proc(
fd: fd_t,
flags: lookupflags_t,
path: [^]u8,
path_len: size_t,
atim: timestamp_t,
mtim: timestamp_t,
fst_flags: fstflags_t,
) -> errno_t ---
@(link_name="path_remove_directory")
wasm_path_remove_directory :: proc(
fd: fd_t,
path: [^]u8,
path_len: size_t,
) -> errno_t ---
@(link_name="path_link")
wasm_path_link :: proc(
old_fd: fd_t,
old_flags: lookupflags_t,
old_path: [^]u8,
old_path_len: size_t,
new_fd: fd_t,
new_path: [^]u8,
new_path_len: size_t,
) -> errno_t ---
@(link_name="path_rename")
wasm_path_rename :: proc(
fd: fd_t,
old_path: [^]u8,
old_path_len: size_t,
new_fd: fd_t,
new_path: [^]u8,
new_path_len: size_t,
) -> errno_t ---
@(link_name="path_symlink")
wasm_path_symlink :: proc(
old_path: [^]u8,
old_path_len: size_t,
fd: fd_t,
new_path: [^]u8,
new_path_len: size_t,
) -> errno_t ---
@(link_name="path_unlink_file")
wasm_path_unlink_file :: proc(
fd: fd_t,
path: [^]u8,
path_len: size_t,
) -> errno_t ---
@(link_name="random_get")
wasm_random_get :: proc(
buf: [^]u8,
buf_len: size_t,
) -> errno_t ---
}
core/sys/windows/kernel32.odin
+2 -2
View File
@@ -290,10 +290,10 @@ foreign kernel32 {
InitializeSRWLock :: proc(SRWLock: ^SRWLOCK) ---
AcquireSRWLockExclusive :: proc(SRWLock: ^SRWLOCK) ---
TryAcquireSRWLockExclusive :: proc(SRWLock: ^SRWLOCK) -> BOOL ---
TryAcquireSRWLockExclusive :: proc(SRWLock: ^SRWLOCK) -> BOOLEAN ---
ReleaseSRWLockExclusive :: proc(SRWLock: ^SRWLOCK) ---
AcquireSRWLockShared :: proc(SRWLock: ^SRWLOCK) ---
TryAcquireSRWLockShared :: proc(SRWLock: ^SRWLOCK) -> BOOL ---
TryAcquireSRWLockShared :: proc(SRWLock: ^SRWLOCK) -> BOOLEAN ---
ReleaseSRWLockShared :: proc(SRWLock: ^SRWLOCK) ---
InitializeConditionVariable :: proc(ConditionVariable: ^CONDITION_VARIABLE) ---
core/sys/windows/user32.odin
+33 -2
View File
@@ -18,6 +18,7 @@ foreign user32 {
RegisterClassW :: proc(lpWndClass: ^WNDCLASSW) -> ATOM ---
RegisterClassExW :: proc(^WNDCLASSEXW) -> ATOM ---
UnregisterClassW :: proc(lpClassName: LPCWSTR, hInstance: HINSTANCE) -> BOOL ---
CreateWindowExW :: proc(
dwExStyle: DWORD,
@@ -41,6 +42,7 @@ foreign user32 {
GetTopWindow :: proc(hWnd: HWND) -> HWND ---
SetForegroundWindow :: proc(hWnd: HWND) -> BOOL ---
GetForegroundWindow :: proc() -> HWND ---
UpdateWindow :: proc(hWnd: HWND) -> BOOL ---
SetActiveWindow :: proc(hWnd: HWND) -> HWND ---
GetActiveWindow :: proc() -> HWND ---
@@ -94,6 +96,7 @@ foreign user32 {
GetSystemMetrics :: proc(nIndex: c_int) -> c_int ---
AdjustWindowRect :: proc(lpRect: LPRECT, dwStyle: DWORD, bMenu: BOOL) -> BOOL ---
AdjustWindowRectEx :: proc(lpRect: LPRECT, dwStyle: DWORD, bMenu: BOOL, dwExStyle: DWORD) -> BOOL ---
AdjustWindowRectExForDpi :: proc(lpRect: LPRECT, dwStyle: DWORD, bMenu: BOOL, dwExStyle: DWORD, dpi: UINT) -> BOOL ---
SystemParametersInfoW :: proc(uiAction, uiParam: UINT, pvParam: PVOID, fWinIni: UINT) -> BOOL ---
@@ -136,7 +139,19 @@ foreign user32 {
SetCursor :: proc(hCursor: HCURSOR) -> HCURSOR ---
EnumDisplaySettingsW :: proc(lpszDeviceName: LPCWSTR, iModeNum: DWORD, lpDevMode: ^DEVMODEW) -> BOOL ---
MonitorFromPoint :: proc(pt: POINT, dwFlags: Monitor_From_Flags) -> HMONITOR ---
MonitorFromRect :: proc(lprc: LPRECT, dwFlags: Monitor_From_Flags) -> HMONITOR ---
MonitorFromWindow :: proc(hwnd: HWND, dwFlags: Monitor_From_Flags) -> HMONITOR ---
EnumDisplayMonitors :: proc(hdc: HDC, lprcClip: LPRECT, lpfnEnum: Monitor_Enum_Proc, dwData: LPARAM) -> BOOL ---
SetThreadDpiAwarenessContext :: proc(dpiContext: DPI_AWARENESS_CONTEXT) -> DPI_AWARENESS_CONTEXT ---
GetThreadDpiAwarenessContext :: proc() -> DPI_AWARENESS_CONTEXT ---
GetWindowDpiAwarenessContext :: proc(hwnd: HWND) -> DPI_AWARENESS_CONTEXT ---
GetDpiFromDpiAwarenessContext :: proc(value: DPI_AWARENESS_CONTEXT) -> UINT ---
GetDpiForWindow :: proc(hwnd: HWND) -> UINT ---
SetProcessDpiAwarenessContext :: proc(value: DPI_AWARENESS_CONTEXT) -> BOOL ---
BroadcastSystemMessageW :: proc(
flags: DWORD,
lpInfo: LPDWORD,
@@ -220,7 +235,7 @@ when ODIN_ARCH == .amd64 {
SetClassLongPtrW :: SetClassLongW
GetWindowLongPtrW :: GetWindowLongW
SetWindowLongPtrW :: GetWindowLongW
SetWindowLongPtrW :: SetWindowLongW
}
GET_SC_WPARAM :: #force_inline proc "contextless" (wParam: WPARAM) -> c_int {
@@ -246,3 +261,19 @@ GET_XBUTTON_WPARAM :: #force_inline proc "contextless" (wParam: WPARAM) -> WORD
MAKEINTRESOURCEW :: #force_inline proc "contextless" (#any_int i: int) -> LPWSTR {
return cast(LPWSTR)uintptr(WORD(i))
}
Monitor_From_Flags :: enum DWORD {
MONITOR_DEFAULTTONULL = 0x00000000, // Returns NULL
MONITOR_DEFAULTTOPRIMARY = 0x00000001, // Returns a handle to the primary display monitor
MONITOR_DEFAULTTONEAREST = 0x00000002, // Returns a handle to the display monitor that is nearest to the window
}
Monitor_Enum_Proc :: #type proc "stdcall" (HMONITOR, HDC, LPRECT, LPARAM) -> BOOL
USER_DEFAULT_SCREEN_DPI :: 96
DPI_AWARENESS_CONTEXT :: distinct HANDLE
DPI_AWARENESS_CONTEXT_UNAWARE :: DPI_AWARENESS_CONTEXT(~uintptr(0)) // -1
DPI_AWARENESS_CONTEXT_SYSTEM_AWARE :: DPI_AWARENESS_CONTEXT(~uintptr(1)) // -2
DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE :: DPI_AWARENESS_CONTEXT(~uintptr(2)) // -3
DPI_AWARENESS_CONTEXT_PER_MONITOR_AWARE_V2 :: DPI_AWARENESS_CONTEXT(~uintptr(3)) // -4
DPI_AWARENESS_CONTEXT_UNAWARE_GDISCALED :: DPI_AWARENESS_CONTEXT(~uintptr(4)) // -5
core/sys/windows/wgl.odin
+1 -1
View File
@@ -62,7 +62,7 @@ GetExtensionsStringARBType :: #type proc "c" (HDC) -> cstring
// Procedures
wglCreateContextAttribsARB: CreateContextAttribsARBType
wglChoosePixelFormatARB: ChoosePixelFormatARBType
wglSwapIntervalExt: SwapIntervalEXTType
wglSwapIntervalEXT: SwapIntervalEXTType
wglGetExtensionsStringARB: GetExtensionsStringARBType
core/sys/windows/wglext.odin
+147
View File
@@ -0,0 +1,147 @@
// +build windows
package sys_windows
// WGL_ARB_buffer_region
WGL_FRONT_COLOR_BUFFER_BIT_ARB :: 0x00000001
WGL_BACK_COLOR_BUFFER_BIT_ARB :: 0x00000002
WGL_DEPTH_BUFFER_BIT_ARB :: 0x00000004
WGL_STENCIL_BUFFER_BIT_ARB :: 0x00000008
wglCreateBufferRegionARBType :: #type proc "c" (hDC: HDC, iLayerPlane: c_int, uType: UINT) -> HANDLE
wglDeleteBufferRegionARBType :: #type proc "c" (hRegion: HANDLE)
wglSaveBufferRegionARBType :: #type proc "c" (hRegion: HANDLE, x: c_int, y: c_int, width: c_int, height: c_int) -> BOOL
wglRestoreBufferRegionARBType :: #type proc "c" (hRegion: HANDLE, x: c_int, y: c_int, width: c_int, height: c_int, xSrc: c_int, ySrc: c_int) -> BOOL
// wglCreateBufferRegionARB: wglCreateBufferRegionARBType
// wglDeleteBufferRegionARB: wglDeleteBufferRegionARBType
// wglSaveBufferRegionARB: wglSaveBufferRegionARBType
// wglRestoreBufferRegionARB: wglRestoreBufferRegionARBType
// WGL_ARB_context_flush_control
WGL_CONTEXT_RELEASE_BEHAVIOR_ARB :: 0x2097
WGL_CONTEXT_RELEASE_BEHAVIOR_NONE_ARB :: 0
WGL_CONTEXT_RELEASE_BEHAVIOR_FLUSH_ARB :: 0x2098
// WGL_ARB_create_context
WGL_CONTEXT_DEBUG_BIT_ARB :: 0x0001
WGL_CONTEXT_FORWARD_COMPATIBLE_BIT_ARB :: 0x0002
WGL_CONTEXT_MAJOR_VERSION_ARB :: 0x2091
WGL_CONTEXT_MINOR_VERSION_ARB :: 0x2092
WGL_CONTEXT_LAYER_PLANE_ARB :: 0x2093
WGL_CONTEXT_FLAGS_ARB :: 0x2094
ERROR_INVALID_VERSION_ARB :: 0x2095
// WGL_ARB_create_context_no_error
WGL_CONTEXT_OPENGL_NO_ERROR_ARB :: 0x31B3
// WGL_ARB_create_context_profile
WGL_CONTEXT_PROFILE_MASK_ARB :: 0x9126
WGL_CONTEXT_CORE_PROFILE_BIT_ARB :: 0x0001
WGL_CONTEXT_COMPATIBILITY_PROFILE_BIT_ARB :: 0x0002
ERROR_INVALID_PROFILE_ARB :: 0x2096
// WGL_ARB_create_context_robustness
WGL_CONTEXT_ROBUST_ACCESS_BIT_ARB :: 0x00000004
WGL_LOSE_CONTEXT_ON_RESET_ARB :: 0x8252
WGL_CONTEXT_RESET_NOTIFICATION_STRATEGY_ARB :: 0x8256
WGL_NO_RESET_NOTIFICATION_ARB :: 0x8261
// WGL_ARB_framebuffer_sRGB
WGL_FRAMEBUFFER_SRGB_CAPABLE_ARB :: 0x20A9
// WGL_ARB_make_current_read
ERROR_INVALID_PIXEL_TYPE_ARB :: 0x2043
ERROR_INCOMPATIBLE_DEVICE_CONTEXTS_ARB :: 0x2054
wglMakeContextCurrentARBType :: #type proc "c" (hDrawDC: HDC, hReadDC:HDC, hglrc: HGLRC) -> BOOL
wglGetCurrentReadDCARBType :: #type proc "c" () -> HDC
// wglMakeContextCurrentARB: wglMakeContextCurrentARBType
// wglGetCurrentReadDCARB: wglGetCurrentReadDCARBType
// WGL_ARB_multisample
WGL_SAMPLE_BUFFERS_ARB :: 0x2041
WGL_SAMPLES_ARB :: 0x2042
// WGL_ARB_pbuffer
HPBUFFERARB :: distinct rawptr
WGL_DRAW_TO_PBUFFER_ARB :: 0x202D
WGL_MAX_PBUFFER_PIXELS_ARB :: 0x202E
WGL_MAX_PBUFFER_WIDTH_ARB :: 0x202F
WGL_MAX_PBUFFER_HEIGHT_ARB :: 0x2030
WGL_PBUFFER_LARGEST_ARB :: 0x2033
WGL_PBUFFER_WIDTH_ARB :: 0x2034
WGL_PBUFFER_HEIGHT_ARB :: 0x2035
WGL_PBUFFER_LOST_ARB :: 0x2036
wglCreatePbufferARBType :: #type proc "c" (hDC: HDC, iPixelFormat, iWidth, iHeight: c_int, piAttribList: [^]c_int) -> HPBUFFERARB
wglGetPbufferDCARBType :: #type proc "c" (hPbuffer: HPBUFFERARB) -> HDC
wglReleasePbufferDCARBType :: #type proc "c" (hPbuffer: HPBUFFERARB, hDC: HDC) -> c_int
wglDestroyPbufferARBType :: #type proc "c" (hPbuffer: HPBUFFERARB) -> BOOL
wglQueryPbufferARBType :: #type proc "c" (hPbuffer: HPBUFFERARB, iAttribute: c_int, piValue: ^c_int) -> BOOL
// wglCreatePbufferARB: wglCreatePbufferARBType
// wglGetPbufferDCARB: wglGetPbufferDCARBType
// wglReleasePbufferDCARB: wglReleasePbufferDCARBType
// wglDestroyPbufferARB: wglDestroyPbufferARBType
// wglQueryPbufferARB: wglQueryPbufferARBType
// WGL_ARB_pixel_format
WGL_NUMBER_PIXEL_FORMATS_ARB :: 0x2000
WGL_DRAW_TO_WINDOW_ARB :: 0x2001
WGL_DRAW_TO_BITMAP_ARB :: 0x2002
WGL_ACCELERATION_ARB :: 0x2003
WGL_NEED_PALETTE_ARB :: 0x2004
WGL_NEED_SYSTEM_PALETTE_ARB :: 0x2005
WGL_SWAP_LAYER_BUFFERS_ARB :: 0x2006
WGL_SWAP_METHOD_ARB :: 0x2007
WGL_NUMBER_OVERLAYS_ARB :: 0x2008
WGL_NUMBER_UNDERLAYS_ARB :: 0x2009
WGL_TRANSPARENT_ARB :: 0x200A
WGL_TRANSPARENT_RED_VALUE_ARB :: 0x2037
WGL_TRANSPARENT_GREEN_VALUE_ARB :: 0x2038
WGL_TRANSPARENT_BLUE_VALUE_ARB :: 0x2039
WGL_TRANSPARENT_ALPHA_VALUE_ARB :: 0x203A
WGL_TRANSPARENT_INDEX_VALUE_ARB :: 0x203B
WGL_SHARE_DEPTH_ARB :: 0x200C
WGL_SHARE_STENCIL_ARB :: 0x200D
WGL_SHARE_ACCUM_ARB :: 0x200E
WGL_SUPPORT_GDI_ARB :: 0x200F
WGL_SUPPORT_OPENGL_ARB :: 0x2010
WGL_DOUBLE_BUFFER_ARB :: 0x2011
WGL_STEREO_ARB :: 0x2012
WGL_PIXEL_TYPE_ARB :: 0x2013
WGL_COLOR_BITS_ARB :: 0x2014
WGL_RED_BITS_ARB :: 0x2015
WGL_RED_SHIFT_ARB :: 0x2016
WGL_GREEN_BITS_ARB :: 0x2017
WGL_GREEN_SHIFT_ARB :: 0x2018
WGL_BLUE_BITS_ARB :: 0x2019
WGL_BLUE_SHIFT_ARB :: 0x201A
WGL_ALPHA_BITS_ARB :: 0x201B
WGL_ALPHA_SHIFT_ARB :: 0x201C
WGL_ACCUM_BITS_ARB :: 0x201D
WGL_ACCUM_RED_BITS_ARB :: 0x201E
WGL_ACCUM_GREEN_BITS_ARB :: 0x201F
WGL_ACCUM_BLUE_BITS_ARB :: 0x2020
WGL_ACCUM_ALPHA_BITS_ARB :: 0x2021
WGL_DEPTH_BITS_ARB :: 0x2022
WGL_STENCIL_BITS_ARB :: 0x2023
WGL_AUX_BUFFERS_ARB :: 0x2024
WGL_NO_ACCELERATION_ARB :: 0x2025
WGL_GENERIC_ACCELERATION_ARB :: 0x2026
WGL_FULL_ACCELERATION_ARB :: 0x2027
WGL_SWAP_EXCHANGE_ARB :: 0x2028
WGL_SWAP_COPY_ARB :: 0x2029
WGL_SWAP_UNDEFINED_ARB :: 0x202A
WGL_TYPE_RGBA_ARB :: 0x202B
WGL_TYPE_COLORINDEX_ARB :: 0x202C
wglGetPixelFormatAttribivARBType :: #type proc "c" (hdc: HDC, iPixelFormat, iLayerPlane: c_int, nAttributes: UINT, piAttributes: [^]c_int, piValues: [^]c_int) -> BOOL
wglGetPixelFormatAttribfvARBType :: #type proc "c" (hdc: HDC, iPixelFormat, iLayerPlane: c_int, nAttributes: UINT, piAttributes: [^]c_int, pfValues: [^]f32) -> BOOL
// wglGetPixelFormatAttribivARB: wglGetPixelFormatAttribivARBType
// wglGetPixelFormatAttribfvARB: wglGetPixelFormatAttribfvARBType
// WGL_ARB_pixel_format_float
WGL_TYPE_RGBA_FLOAT_ARB :: 0x21A0
core/sys/windows/window_messages.odin
+39
View File
@@ -153,6 +153,7 @@ BM_CLICK :: 0x00f5
BM_GETIMAGE :: 0x00f6
BM_SETIMAGE :: 0x00f7
BM_SETDONTCLICK :: 0x00f8
WM_INPUT_DEVICE_CHANGE :: 0x00fe
WM_INPUT :: 0x00ff
WM_KEYDOWN :: 0x0100
WM_KEYFIRST :: 0x0100
@@ -165,6 +166,7 @@ WM_SYSCHAR :: 0x0106
WM_SYSDEADCHAR :: 0x0107
WM_UNICHAR :: 0x0109
WM_KEYLAST :: 0x0109
UNICODE_NOCHAR :: 0xFFFF
WM_WNT_CONVERTREQUESTEX :: 0x0109
WM_CONVERTREQUEST :: 0x010a
WM_CONVERTRESULT :: 0x010b
@@ -279,6 +281,27 @@ WM_ENTERSIZEMOVE :: 0x0231
WM_EXITSIZEMOVE :: 0x0232
WM_DROPFILES :: 0x0233
WM_MDIREFRESHMENU :: 0x0234
WM_POINTERDEVICECHANGE :: 0x0238
WM_POINTERDEVICEINRANGE :: 0x0239
WM_POINTERDEVICEOUTOFRANGE :: 0x023a
WM_TOUCH :: 0x0240
WM_NCPOINTERUPDATE :: 0x0241
WM_NCPOINTERDOWN :: 0x0242
WM_NCPOINTERUP :: 0x0243
WM_POINTERUPDATE :: 0x0245
WM_POINTERDOWN :: 0x0246
WM_POINTERUP :: 0x0247
WM_POINTERENTER :: 0x0249
WM_POINTERLEAVE :: 0x024a
WM_POINTERACTIVATE :: 0x024b
WM_POINTERCAPTURECHANGED :: 0x024c
WM_TOUCHHITTESTING :: 0x024d
WM_POINTERWHEEL :: 0x024e
WM_POINTERHWHEEL :: 0x024f
DM_POINTERHITTEST :: 0x0250
WM_POINTERROUTEDTO :: 0x0251
WM_POINTERROUTEDAWAY :: 0x0252
WM_POINTERROUTEDRELEASED :: 0x0253
WM_IME_REPORT :: 0x0280
WM_IME_SETCONTEXT :: 0x0281
WM_IME_NOTIFY :: 0x0282
@@ -295,6 +318,13 @@ WM_NCMOUSEHOVER :: 0x02a0
WM_MOUSEHOVER :: 0x02a1
WM_NCMOUSELEAVE :: 0x02a2
WM_MOUSELEAVE :: 0x02a3
WM_WTSSESSION_CHANGE :: 0x02b1
WM_TABLET_FIRST :: 0x02c0
WM_TABLET_LAST :: 0x02df
WM_DPICHANGED :: 0x02e0
WM_DPICHANGED_BEFOREPARENT :: 0x02e2
WM_DPICHANGED_AFTERPARENT :: 0x02e3
WM_GETDPISCALEDSIZE :: 0x02e4
WM_CUT :: 0x0300
WM_COPY :: 0x0301
WM_PASTE :: 0x0302
@@ -317,6 +347,15 @@ WM_HOTKEY :: 0x0312
WM_PRINT :: 0x0317
WM_PRINTCLIENT :: 0x0318
WM_APPCOMMAND :: 0x0319
WM_THEMECHANGED :: 0x031A
WM_CLIPBOARDUPDATE :: 0x031D
WM_DWMCOMPOSITIONCHANGED :: 0x031E
WM_DWMNCRENDERINGCHANGED :: 0x031F
WM_DWMCOLORIZATIONCOLORCHANGED:: 0x0320
WM_DWMWINDOWMAXIMIZEDCHANGE :: 0x0321
WM_DWMSENDICONICTHUMBNAIL :: 0x0323
WM_DWMSENDICONICLIVEPREVIEWBITMAP :: 0x0326
WM_GETTITLEBARINFOEX :: 0x033F
WM_HANDHELDFIRST :: 0x0358
WM_HANDHELDLAST :: 0x035f
WM_AFXFIRST :: 0x0360
core/text/i18n/gettext.odin
+2 -2
View File
@@ -99,14 +99,14 @@ parse_mo_from_bytes :: proc(data: []byte, options := DEFAULT_PARSE_OPTIONS, plur
}
for k in keys {
interned_key := strings.intern_get(&translation.intern, string(k))
interned_key, _ := strings.intern_get(&translation.intern, string(k))
interned_vals := make([]string, len(keys))
last_val: string
i := 0
for v in vals {
interned_vals[i] = strings.intern_get(&translation.intern, string(v))
interned_vals[i], _ = strings.intern_get(&translation.intern, string(v))
last_val = interned_vals[i]
i += 1
}
core/text/i18n/qt_linguist.odin
+5 -5
View File
@@ -59,9 +59,9 @@ parse_qt_linguist_from_bytes :: proc(data: []byte, options := DEFAULT_PARSE_OPTI
return translation, .TS_File_Expected_Context_Name,
}
section_name := strings.intern_get(&translation.intern, "")
section_name, _ := strings.intern_get(&translation.intern, "")
if !options.merge_sections {
section_name = strings.intern_get(&translation.intern, ts.elements[section_name_id].value)
section_name, _ = strings.intern_get(&translation.intern, ts.elements[section_name_id].value)
}
if section_name not_in translation.k_v {
@@ -92,8 +92,8 @@ parse_qt_linguist_from_bytes :: proc(data: []byte, options := DEFAULT_PARSE_OPTI
return translation, .TS_File_Expected_Translation
}
source := strings.intern_get(&translation.intern, ts.elements[source_id].value)
xlat := strings.intern_get(&translation.intern, ts.elements[translation_id].value)
source, _ := strings.intern_get(&translation.intern, ts.elements[source_id].value)
xlat, _ := strings.intern_get(&translation.intern, ts.elements[translation_id].value)
if source in section {
return translation, .Duplicate_Key
@@ -124,7 +124,7 @@ parse_qt_linguist_from_bytes :: proc(data: []byte, options := DEFAULT_PARSE_OPTI
if !numerus_found {
break
}
numerus := strings.intern_get(&translation.intern, ts.elements[numerus_id].value)
numerus, _ := strings.intern_get(&translation.intern, ts.elements[numerus_id].value)
section[source][num_plurals] = numerus
num_plurals += 1
src/build_settings.cpp
+46 -64
View File
@@ -116,6 +116,7 @@ struct TargetMetrics {
TargetArchKind arch;
isize word_size;
isize max_align;
isize max_simd_align;
String target_triplet;
String target_data_layout;
TargetABIKind abi;
@@ -204,7 +205,7 @@ enum BuildPath : u8 {
BuildPath_Main_Package, // Input Path to the package directory (or file) we're building.
BuildPath_RC, // Input Path for .rc file, can be set with `-resource:`.
BuildPath_RES, // Output Path for .res file, generated from previous.
BuildPath_Win_SDK_Root, // windows_sdk_root
BuildPath_Win_SDK_Bin_Path, // windows_sdk_bin_path
BuildPath_Win_SDK_UM_Lib, // windows_sdk_um_library_path
BuildPath_Win_SDK_UCRT_Lib, // windows_sdk_ucrt_library_path
BuildPath_VS_EXE, // vs_exe_path
@@ -228,14 +229,16 @@ struct BuildContext {
bool ODIN_DISABLE_ASSERT; // Whether the default 'assert' et al is disabled in code or not
bool ODIN_DEFAULT_TO_NIL_ALLOCATOR; // Whether the default allocator is a "nil" allocator or not (i.e. it does nothing)
bool ODIN_FOREIGN_ERROR_PROCEDURES;
bool ODIN_VALGRIND_SUPPORT;
ErrorPosStyle ODIN_ERROR_POS_STYLE;
TargetEndianKind endian_kind;
// In bytes
i64 word_size; // Size of a pointer, must be >= 4
i64 max_align; // max alignment, must be >= 1 (and typically >= word_size)
i64 word_size; // Size of a pointer, must be >= 4
i64 max_align; // max alignment, must be >= 1 (and typically >= word_size)
i64 max_simd_align; // max alignment, must be >= 1 (and typically >= word_size)
CommandKind command_kind;
String command;
@@ -338,15 +341,13 @@ bool global_ignore_warnings(void) {
gb_global TargetMetrics target_windows_i386 = {
TargetOs_windows,
TargetArch_i386,
4,
8,
4, 4, 8,
str_lit("i386-pc-windows-msvc"),
};
gb_global TargetMetrics target_windows_amd64 = {
TargetOs_windows,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-pc-windows-msvc"),
str_lit("e-m:w-i64:64-f80:128-n8:16:32:64-S128"),
};
@@ -354,24 +355,21 @@ gb_global TargetMetrics target_windows_amd64 = {
gb_global TargetMetrics target_linux_i386 = {
TargetOs_linux,
TargetArch_i386,
4,
8,
4, 4, 8,
str_lit("i386-pc-linux-gnu"),
};
gb_global TargetMetrics target_linux_amd64 = {
TargetOs_linux,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-pc-linux-gnu"),
str_lit("e-m:w-i64:64-f80:128-n8:16:32:64-S128"),
};
gb_global TargetMetrics target_linux_arm64 = {
TargetOs_linux,
TargetArch_arm64,
8,
16,
8, 8, 16,
str_lit("aarch64-linux-elf"),
str_lit("e-m:o-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64"),
};
@@ -379,8 +377,7 @@ gb_global TargetMetrics target_linux_arm64 = {
gb_global TargetMetrics target_linux_arm32 = {
TargetOs_linux,
TargetArch_arm32,
4,
8,
4, 4, 8,
str_lit("arm-linux-gnu"),
str_lit("e-m:o-p:32:32-Fi8-i64:64-v128:64:128-a:0:32-n32-S64"),
};
@@ -388,8 +385,7 @@ gb_global TargetMetrics target_linux_arm32 = {
gb_global TargetMetrics target_darwin_amd64 = {
TargetOs_darwin,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-apple-darwin"),
str_lit("e-m:o-i64:64-f80:128-n8:16:32:64-S128"),
};
@@ -397,8 +393,7 @@ gb_global TargetMetrics target_darwin_amd64 = {
gb_global TargetMetrics target_darwin_arm64 = {
TargetOs_darwin,
TargetArch_arm64,
8,
16,
8, 8, 16,
str_lit("arm64-apple-macosx11.0.0"),
str_lit("e-m:o-i64:64-i128:128-n32:64-S128"), // TODO(bill): Is this correct?
};
@@ -406,16 +401,14 @@ gb_global TargetMetrics target_darwin_arm64 = {
gb_global TargetMetrics target_freebsd_i386 = {
TargetOs_freebsd,
TargetArch_i386,
4,
8,
4, 4, 8,
str_lit("i386-unknown-freebsd-elf"),
};
gb_global TargetMetrics target_freebsd_amd64 = {
TargetOs_freebsd,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-unknown-freebsd-elf"),
str_lit("e-m:w-i64:64-f80:128-n8:16:32:64-S128"),
};
@@ -423,8 +416,7 @@ gb_global TargetMetrics target_freebsd_amd64 = {
gb_global TargetMetrics target_openbsd_amd64 = {
TargetOs_openbsd,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-unknown-openbsd-elf"),
str_lit("e-m:e-p270:32:32-p271:32:32-p272:64:64-i64:64-f80:128-n8:16:32:64-S128"),
};
@@ -432,62 +424,48 @@ gb_global TargetMetrics target_openbsd_amd64 = {
gb_global TargetMetrics target_essence_amd64 = {
TargetOs_essence,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-pc-none-elf"),
};
gb_global TargetMetrics target_freestanding_wasm32 = {
TargetOs_freestanding,
TargetArch_wasm32,
4,
8,
4, 8, 16,
str_lit("wasm32-freestanding-js"),
str_lit(""),
str_lit("e-m:e-p:32:32-i64:64-n32:64-S128"),
};
gb_global TargetMetrics target_js_wasm32 = {
TargetOs_js,
TargetArch_wasm32,
4,
8,
4, 8, 16,
str_lit("wasm32-js-js"),
str_lit(""),
};
gb_global TargetMetrics target_js_wasm64 = {
TargetOs_js,
TargetArch_wasm64,
8,
16,
str_lit("wasm64-js-js"),
str_lit(""),
str_lit("e-m:e-p:32:32-i64:64-n32:64-S128"),
};
gb_global TargetMetrics target_wasi_wasm32 = {
TargetOs_wasi,
TargetArch_wasm32,
4,
8,
4, 8, 16,
str_lit("wasm32-wasi-js"),
str_lit(""),
str_lit("e-m:e-p:32:32-i64:64-n32:64-S128"),
};
// gb_global TargetMetrics target_freestanding_wasm64 = {
// TargetOs_freestanding,
// TargetArch_wasm64,
// 8,
// 16,
// str_lit("wasm64-freestanding-js"),
// str_lit(""),
// };
gb_global TargetMetrics target_js_wasm64 = {
TargetOs_js,
TargetArch_wasm64,
8, 8, 16,
str_lit("wasm64-js-js"),
str_lit(""),
};
gb_global TargetMetrics target_freestanding_amd64_sysv = {
TargetOs_freestanding,
TargetArch_amd64,
8,
16,
8, 8, 16,
str_lit("x86_64-pc-none-gnu"),
str_lit("e-m:w-i64:64-f80:128-n8:16:32:64-S128"),
TargetABI_SysV,
@@ -516,7 +494,7 @@ gb_global NamedTargetMetrics named_targets[] = {
{ str_lit("freestanding_wasm32"), &target_freestanding_wasm32 },
{ str_lit("wasi_wasm32"), &target_wasi_wasm32 },
{ str_lit("js_wasm32"), &target_js_wasm32 },
{ str_lit("js_wasm64"), &target_js_wasm64 },
// { str_lit("js_wasm64"), &target_js_wasm64 },
{ str_lit("freestanding_amd64_sysv"), &target_freestanding_amd64_sysv },
};
@@ -1083,14 +1061,16 @@ void init_build_context(TargetMetrics *cross_target) {
GB_ASSERT(metrics->arch != TargetArch_Invalid);
GB_ASSERT(metrics->word_size > 1);
GB_ASSERT(metrics->max_align > 1);
GB_ASSERT(metrics->max_simd_align > 1);
bc->metrics = *metrics;
bc->ODIN_OS = target_os_names[metrics->os];
bc->ODIN_ARCH = target_arch_names[metrics->arch];
bc->endian_kind = target_endians[metrics->arch];
bc->word_size = metrics->word_size;
bc->max_align = metrics->max_align;
bc->ODIN_OS = target_os_names[metrics->os];
bc->ODIN_ARCH = target_arch_names[metrics->arch];
bc->endian_kind = target_endians[metrics->arch];
bc->word_size = metrics->word_size;
bc->max_align = metrics->max_align;
bc->max_simd_align = metrics->max_simd_align;
bc->link_flags = str_lit(" ");
#if defined(DEFAULT_TO_THREADED_CHECKER)
@@ -1190,6 +1170,8 @@ void init_build_context(TargetMetrics *cross_target) {
bc->optimization_level = gb_clamp(bc->optimization_level, 0, 3);
bc->ODIN_VALGRIND_SUPPORT = is_arch_x86() && build_context.metrics.os != TargetOs_windows;
#undef LINK_FLAG_X64
#undef LINK_FLAG_386
}
@@ -1336,7 +1318,7 @@ bool init_build_paths(String init_filename) {
if ((bc->command_kind & Command__does_build) && (!bc->ignore_microsoft_magic)) {
// NOTE(ic): It would be nice to extend this so that we could specify the Visual Studio version that we want instead of defaulting to the latest.
Find_Result_Utf8 find_result = find_visual_studio_and_windows_sdk_utf8();
Find_Result find_result = find_visual_studio_and_windows_sdk();
defer (mc_free_all());
if (find_result.windows_sdk_version == 0) {
@@ -1357,8 +1339,8 @@ bool init_build_paths(String init_filename) {
if (find_result.windows_sdk_um_library_path.len > 0) {
GB_ASSERT(find_result.windows_sdk_ucrt_library_path.len > 0);
if (find_result.windows_sdk_root.len > 0) {
bc->build_paths[BuildPath_Win_SDK_Root] = path_from_string(ha, find_result.windows_sdk_root);
if (find_result.windows_sdk_bin_path.len > 0) {
bc->build_paths[BuildPath_Win_SDK_Bin_Path] = path_from_string(ha, find_result.windows_sdk_bin_path);
}
if (find_result.windows_sdk_um_library_path.len > 0) {
src/check_builtin.cpp
+539 -453
View File
File diff suppressed because it is too large Load Diff
src/check_decl.cpp
+1 -1
View File
@@ -320,7 +320,7 @@ void check_type_decl(CheckerContext *ctx, Entity *e, Ast *init_expr, Type *def)
} else if (is_type_any(e->type)) {
error(init_expr, "'distinct' cannot be applied to 'any'");
is_distinct = false;
} else if (is_type_simd_vector(e->type)) {
} else if (is_type_simd_vector(e->type) || is_type_soa_pointer(e->type)) {
gbString str = type_to_string(e->type);
error(init_expr, "'distinct' cannot be applied to '%s'", str);
gb_string_free(str);
src/check_expr.cpp
+128 -12
View File
@@ -119,6 +119,29 @@ void check_or_else_split_types(CheckerContext *c, Operand *x, String const &name
void check_or_else_expr_no_value_error(CheckerContext *c, String const &name, Operand const &x, Type *type_hint);
void check_or_return_split_types(CheckerContext *c, Operand *x, String const &name, Type **left_type_, Type **right_type_);
bool is_diverging_expr(Ast *expr);
enum LoadDirectiveResult {
LoadDirective_Success = 0,
LoadDirective_Error = 1,
LoadDirective_NotFound = 2,
};
bool is_load_directive_call(Ast *call) {
call = unparen_expr(call);
if (call->kind != Ast_CallExpr) {
return false;
}
ast_node(ce, CallExpr, call);
if (ce->proc->kind != Ast_BasicDirective) {
return false;
}
ast_node(bd, BasicDirective, ce->proc);
String name = bd->name.string;
return name == "load";
}
LoadDirectiveResult check_load_directive(CheckerContext *c, Operand *operand, Ast *call, Type *type_hint, bool err_on_not_found);
void check_did_you_mean_print(DidYouMeanAnswers *d, char const *prefix = "") {
auto results = did_you_mean_results(d);
@@ -795,6 +818,10 @@ i64 check_distance_between_types(CheckerContext *c, Operand *operand, Type *type
}
if (is_type_matrix(dst)) {
if (are_types_identical(src, dst)) {
return 5;
}
Type *dst_elem = base_array_type(dst);
i64 distance = check_distance_between_types(c, operand, dst_elem);
if (distance >= 0) {
@@ -2051,7 +2078,7 @@ bool check_is_not_addressable(CheckerContext *c, Operand *o) {
return false;
}
return o->mode != Addressing_Variable;
return o->mode != Addressing_Variable && o->mode != Addressing_SoaVariable;
}
void check_unary_expr(CheckerContext *c, Operand *o, Token op, Ast *node) {
@@ -2068,9 +2095,6 @@ void check_unary_expr(CheckerContext *c, Operand *o, Token op, Ast *node) {
error(op, "Cannot take the pointer address of '%s' which is a procedure parameter", str);
} else {
switch (o->mode) {
case Addressing_SoaVariable:
error(op, "Cannot take the pointer address of '%s' as it is an indirect index of an SOA struct", str);
break;
case Addressing_Constant:
error(op, "Cannot take the pointer address of '%s' which is a constant", str);
break;
@@ -2098,7 +2122,19 @@ void check_unary_expr(CheckerContext *c, Operand *o, Token op, Ast *node) {
return;
}
o->type = alloc_type_pointer(o->type);
if (o->mode == Addressing_SoaVariable) {
ast_node(ue, UnaryExpr, node);
if (ast_node_expect(ue->expr, Ast_IndexExpr)) {
ast_node(ie, IndexExpr, ue->expr);
Type *soa_type = type_of_expr(ie->expr);
GB_ASSERT(is_type_soa_struct(soa_type));
o->type = alloc_type_soa_pointer(soa_type);
} else {
o->type = alloc_type_pointer(o->type);
}
} else {
o->type = alloc_type_pointer(o->type);
}
switch (o->mode) {
case Addressing_OptionalOk:
@@ -2495,8 +2531,17 @@ void check_shift(CheckerContext *c, Operand *x, Operand *y, Ast *node, Type *typ
x->expr->tav.is_lhs = true;
}
x->mode = Addressing_Value;
if (type_hint && is_type_integer(type_hint)) {
x->type = type_hint;
if (type_hint) {
if (is_type_integer(type_hint)) {
x->type = type_hint;
} else {
gbString x_str = expr_to_string(x->expr);
gbString to_type = type_to_string(type_hint);
error(node, "Conversion of shifted operand '%s' to '%s' is not allowed", x_str, to_type);
gb_string_free(x_str);
gb_string_free(to_type);
x->mode = Addressing_Invalid;
}
}
// x->value = x_val;
return;
@@ -2512,7 +2557,7 @@ void check_shift(CheckerContext *c, Operand *x, Operand *y, Ast *node, Type *typ
// TODO(bill): Should we support shifts for fixed arrays and #simd vectors?
if (!is_type_integer(x->type)) {
gbString err_str = expr_to_string(y->expr);
gbString err_str = expr_to_string(x->expr);
error(node, "Shift operand '%s' must be an integer", err_str);
gb_string_free(err_str);
x->mode = Addressing_Invalid;
@@ -7388,9 +7433,59 @@ ExprKind check_or_else_expr(CheckerContext *c, Operand *o, Ast *node, Type *type
String name = oe->token.string;
Ast *arg = oe->x;
Ast *default_value = oe->y;
Operand x = {};
Operand y = {};
// NOTE(bill, 2022-08-11): edge case to handle #load(path) or_else default
if (is_load_directive_call(arg)) {
LoadDirectiveResult res = check_load_directive(c, &x, arg, type_hint, false);
// Allow for chaining of '#load(path) or_else #load(path)'
if (!(is_load_directive_call(default_value) && res == LoadDirective_Success)) {
bool y_is_diverging = false;
check_expr_base(c, &y, default_value, x.type);
switch (y.mode) {
case Addressing_NoValue:
if (is_diverging_expr(y.expr)) {
// Allow
y.mode = Addressing_Value;
y_is_diverging = true;
} else {
error_operand_no_value(&y);
y.mode = Addressing_Invalid;
}
break;
case Addressing_Type:
error_operand_not_expression(&y);
y.mode = Addressing_Invalid;
break;
}
if (y.mode == Addressing_Invalid) {
o->mode = Addressing_Value;
o->type = t_invalid;
o->expr = node;
return Expr_Expr;
}
if (!y_is_diverging) {
check_assignment(c, &y, x.type, name);
if (y.mode != Addressing_Constant) {
error(y.expr, "expected a constant expression on the right-hand side of 'or_else' in conjuction with '#load'");
}
}
}
if (res == LoadDirective_Success) {
*o = x;
} else {
*o = y;
}
o->expr = node;
return Expr_Expr;
}
check_multi_expr_with_type_hint(c, &x, arg, type_hint);
if (x.mode == Addressing_Invalid) {
o->mode = Addressing_Value;
@@ -7398,9 +7493,25 @@ ExprKind check_or_else_expr(CheckerContext *c, Operand *o, Ast *node, Type *type
o->expr = node;
return Expr_Expr;
}
bool y_is_diverging = false;
check_expr_base(c, &y, default_value, x.type);
switch (y.mode) {
case Addressing_NoValue:
if (is_diverging_expr(y.expr)) {
// Allow
y.mode = Addressing_Value;
y_is_diverging = true;
} else {
error_operand_no_value(&y);
y.mode = Addressing_Invalid;
}
break;
case Addressing_Type:
error_operand_not_expression(&y);
y.mode = Addressing_Invalid;
break;
}
check_multi_expr_with_type_hint(c, &y, default_value, x.type);
error_operand_no_value(&y);
if (y.mode == Addressing_Invalid) {
o->mode = Addressing_Value;
o->type = t_invalid;
@@ -7414,7 +7525,9 @@ ExprKind check_or_else_expr(CheckerContext *c, Operand *o, Ast *node, Type *type
add_type_and_value(&c->checker->info, arg, x.mode, x.type, x.value);
if (left_type != nullptr) {
check_assignment(c, &y, left_type, name);
if (!y_is_diverging) {
check_assignment(c, &y, left_type, name);
}
} else {
check_or_else_expr_no_value_error(c, name, x, type_hint);
}
@@ -9358,6 +9471,9 @@ ExprKind check_expr_base_internal(CheckerContext *c, Operand *o, Ast *node, Type
if (t->kind == Type_Pointer && !is_type_empty_union(t->Pointer.elem)) {
o->mode = Addressing_Variable;
o->type = t->Pointer.elem;
} else if (t->kind == Type_SoaPointer) {
o->mode = Addressing_SoaVariable;
o->type = type_deref(t);
} else if (t->kind == Type_RelativePointer) {
if (o->mode != Addressing_Variable) {
gbString str = expr_to_string(o->expr);
src/check_stmt.cpp
+54 -5
View File
@@ -1,8 +1,5 @@
bool is_diverging_stmt(Ast *stmt) {
if (stmt->kind != Ast_ExprStmt) {
return false;
}
Ast *expr = unparen_expr(stmt->ExprStmt.expr);
bool is_diverging_expr(Ast *expr) {
expr = unparen_expr(expr);
if (expr->kind != Ast_CallExpr) {
return false;
}
@@ -26,6 +23,12 @@ bool is_diverging_stmt(Ast *stmt) {
t = base_type(t);
return t != nullptr && t->kind == Type_Proc && t->Proc.diverging;
}
bool is_diverging_stmt(Ast *stmt) {
if (stmt->kind != Ast_ExprStmt) {
return false;
}
return is_diverging_expr(stmt->ExprStmt.expr);
}
bool contains_deferred_call(Ast *node) {
if (node->viral_state_flags & ViralStateFlag_ContainsDeferredProcedure) {
@@ -1393,6 +1396,23 @@ bool check_stmt_internal_builtin_proc_id(Ast *expr, BuiltinProcId *id_) {
return id != BuiltinProc_Invalid;
}
bool check_expr_is_stack_variable(Ast *expr) {
expr = unparen_expr(expr);
Entity *e = entity_of_node(expr);
if (e && e->kind == Entity_Variable) {
if (e->flags & (EntityFlag_Static|EntityFlag_Using)) {
// okay
} else if (e->Variable.thread_local_model.len != 0) {
// okay
} else if (e->scope) {
if ((e->scope->flags & (ScopeFlag_Global|ScopeFlag_File|ScopeFlag_Type)) == 0) {
return true;
}
}
}
return false;
}
void check_stmt_internal(CheckerContext *ctx, Ast *node, u32 flags) {
u32 mod_flags = flags & (~Stmt_FallthroughAllowed);
switch (node->kind) {
@@ -1444,6 +1464,12 @@ void check_stmt_internal(CheckerContext *ctx, Ast *node, u32 flags) {
AstSelectorCallExpr *se = &expr->SelectorCallExpr;
ast_node(ce, CallExpr, se->call);
Type *t = base_type(type_of_expr(ce->proc));
if (t == nullptr) {
gbString expr_str = expr_to_string(ce->proc);
error(node, "'%s' is not a value field nor procedure", expr_str);
gb_string_free(expr_str);
return;
}
if (t->kind == Type_Proc) {
do_require = t->Proc.require_results;
} else if (check_stmt_internal_builtin_proc_id(ce->proc, &builtin_id)) {
@@ -1675,6 +1701,29 @@ void check_stmt_internal(CheckerContext *ctx, Ast *node, u32 flags) {
if (is_type_untyped(o->type)) {
update_untyped_expr_type(ctx, o->expr, e->type, true);
}
// NOTE(bill): This is very basic escape analysis
// This needs to be improved tremendously, and a lot of it done during the
// middle-end (or LLVM side) to improve checks and error messages
Ast *expr = unparen_expr(o->expr);
if (expr->kind == Ast_UnaryExpr && expr->UnaryExpr.op.kind == Token_And) {
Ast *x = unparen_expr(expr->UnaryExpr.expr);
if (x->kind == Ast_CompoundLit) {
error(expr, "Cannot return the address to a stack value from a procedure");
} else if (x->kind == Ast_IndexExpr) {
Ast *array = x->IndexExpr.expr;
if (is_type_array_like(type_of_expr(array)) && check_expr_is_stack_variable(array)) {
gbString t = type_to_string(type_of_expr(array));
error(expr, "Cannot return the address to an element of stack variable from a procedure, of type %s", t);
gb_string_free(t);
}
} else {
if (check_expr_is_stack_variable(x)) {
error(expr, "Cannot return the address to a stack variable from a procedure");
}
}
}
}
}
case_end;
src/check_type.cpp
+24 -9
View File
@@ -695,11 +695,6 @@ void check_union_type(CheckerContext *ctx, Type *union_type, Ast *node, Array<Op
error(ut->align, "A union with #no_nil must have at least 2 variants");
}
break;
case UnionType_maybe:
if (variants.count != 1) {
error(ut->align, "A union with #maybe must have at 1 variant, got %lld", cast(long long)variants.count);
}
break;
}
if (ut->align != nullptr) {
@@ -2698,9 +2693,12 @@ bool check_type_internal(CheckerContext *ctx, Ast *e, Type **type, Type *named_t
case_ast_node(ue, UnaryExpr, e);
switch (ue->op.kind) {
case Token_Pointer:
*type = alloc_type_pointer(check_type(ctx, ue->expr));
set_base_type(named_type, *type);
return true;
{
Type *elem = check_type(ctx, ue->expr);
*type = alloc_type_pointer(elem);
set_base_type(named_type, *type);
return true;
}
}
case_end;
@@ -2726,7 +2724,24 @@ bool check_type_internal(CheckerContext *ctx, Ast *e, Type **type, Type *named_t
elem = o.type;
}
*type = alloc_type_pointer(elem);
if (pt->tag != nullptr) {
GB_ASSERT(pt->tag->kind == Ast_BasicDirective);
String name = pt->tag->BasicDirective.name.string;
if (name == "soa") {
// TODO(bill): generic #soa pointers
if (is_type_soa_struct(elem)) {
*type = alloc_type_soa_pointer(elem);
} else {
error(pt->tag, "#soa pointers require an #soa record type as the element");
*type = alloc_type_pointer(elem);
}
} else {
error(pt->tag, "Invalid tag applied to pointer, got #%.*s", LIT(name));
*type = alloc_type_pointer(elem);
}
} else {
*type = alloc_type_pointer(elem);
}
set_base_type(named_type, *type);
return true;
case_end;
src/checker.cpp
+18
View File
@@ -1037,6 +1037,9 @@ void init_universal(void) {
add_global_bool_constant("ODIN_FOREIGN_ERROR_PROCEDURES", bc->ODIN_FOREIGN_ERROR_PROCEDURES);
add_global_bool_constant("ODIN_DISALLOW_RTTI", bc->disallow_rtti);
add_global_bool_constant("ODIN_VALGRIND_SUPPORT", bc->ODIN_VALGRIND_SUPPORT);
// Builtin Procedures
for (isize i = 0; i < gb_count_of(builtin_procs); i++) {
@@ -1170,6 +1173,8 @@ void init_checker_info(CheckerInfo *i) {
mutex_init(&i->objc_types_mutex);
map_init(&i->objc_msgSend_types, a);
mutex_init(&i->load_file_mutex);
string_map_init(&i->load_file_cache, a);
}
void destroy_checker_info(CheckerInfo *i) {
@@ -1205,6 +1210,8 @@ void destroy_checker_info(CheckerInfo *i) {
mutex_destroy(&i->objc_types_mutex);
map_destroy(&i->objc_msgSend_types);
mutex_init(&i->load_file_mutex);
string_map_destroy(&i->load_file_cache);
}
CheckerContext make_checker_context(Checker *c) {
@@ -1947,6 +1954,11 @@ void add_type_info_type_internal(CheckerContext *c, Type *t) {
add_type_info_type_internal(c, bt->Matrix.elem);
break;
case Type_SoaPointer:
add_type_info_type_internal(c, bt->SoaPointer.elem);
break;
default:
GB_PANIC("Unhandled type: %*.s %d", LIT(type_strings[bt->kind]), bt->kind);
break;
@@ -2164,6 +2176,10 @@ void add_min_dep_type_info(Checker *c, Type *t) {
add_min_dep_type_info(c, bt->Matrix.elem);
break;
case Type_SoaPointer:
add_min_dep_type_info(c, bt->SoaPointer.elem);
break;
default:
GB_PANIC("Unhandled type: %*.s", LIT(type_strings[bt->kind]));
break;
@@ -2756,6 +2772,7 @@ void init_core_type_info(Checker *c) {
t_type_info_relative_pointer = find_core_type(c, str_lit("Type_Info_Relative_Pointer"));
t_type_info_relative_slice = find_core_type(c, str_lit("Type_Info_Relative_Slice"));
t_type_info_matrix = find_core_type(c, str_lit("Type_Info_Matrix"));
t_type_info_soa_pointer = find_core_type(c, str_lit("Type_Info_Soa_Pointer"));
t_type_info_named_ptr = alloc_type_pointer(t_type_info_named);
t_type_info_integer_ptr = alloc_type_pointer(t_type_info_integer);
@@ -2784,6 +2801,7 @@ void init_core_type_info(Checker *c) {
t_type_info_relative_pointer_ptr = alloc_type_pointer(t_type_info_relative_pointer);
t_type_info_relative_slice_ptr = alloc_type_pointer(t_type_info_relative_slice);
t_type_info_matrix_ptr = alloc_type_pointer(t_type_info_matrix);
t_type_info_soa_pointer_ptr = alloc_type_pointer(t_type_info_soa_pointer);
}
void init_mem_allocator(Checker *c) {
src/checker.hpp
+9
View File
@@ -287,6 +287,12 @@ struct ObjcMsgData {
ObjcMsgKind kind;
Type *proc_type;
};
struct LoadFileCache {
String path;
gbFileError file_error;
String data;
StringMap<u64> hashes;
};
// CheckerInfo stores all the symbol information for a type-checked program
struct CheckerInfo {
@@ -363,6 +369,9 @@ struct CheckerInfo {
BlockingMutex objc_types_mutex;
PtrMap<Ast *, ObjcMsgData> objc_msgSend_types;
BlockingMutex load_file_mutex;
StringMap<LoadFileCache *> load_file_cache;
};
struct CheckerContext {
src/checker_builtin_procs.hpp
+10 -2
View File
@@ -40,6 +40,8 @@ enum BuiltinProcId {
BuiltinProc_hadamard_product,
BuiltinProc_matrix_flatten,
BuiltinProc_unreachable,
BuiltinProc_DIRECTIVE, // NOTE(bill): This is used for specialized hash-prefixed procedures
// "Intrinsics"
@@ -289,6 +291,8 @@ BuiltinProc__type_end,
BuiltinProc_wasm_memory_atomic_wait32,
BuiltinProc_wasm_memory_atomic_notify32,
BuiltinProc_valgrind_client_request,
BuiltinProc_COUNT,
};
gb_global BuiltinProc builtin_procs[BuiltinProc_COUNT] = {
@@ -330,6 +334,8 @@ gb_global BuiltinProc builtin_procs[BuiltinProc_COUNT] = {
{STR_LIT("hadamard_product"), 2, false, Expr_Expr, BuiltinProcPkg_builtin},
{STR_LIT("matrix_flatten"), 1, false, Expr_Expr, BuiltinProcPkg_builtin},
{STR_LIT("unreachable"), 0, false, Expr_Expr, BuiltinProcPkg_builtin, /*diverging*/true},
{STR_LIT(""), 0, true, Expr_Expr, BuiltinProcPkg_builtin}, // DIRECTIVE
@@ -341,7 +347,7 @@ gb_global BuiltinProc builtin_procs[BuiltinProc_COUNT] = {
{STR_LIT("alloca"), 2, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("cpu_relax"), 0, false, Expr_Stmt, BuiltinProcPkg_intrinsics},
{STR_LIT("trap"), 0, false, Expr_Stmt, BuiltinProcPkg_intrinsics, /*diverging*/true},
{STR_LIT("trap"), 0, false, Expr_Expr, BuiltinProcPkg_intrinsics, /*diverging*/true},
{STR_LIT("debug_trap"), 0, false, Expr_Stmt, BuiltinProcPkg_intrinsics, /*diverging*/false},
{STR_LIT("read_cycle_counter"), 0, false, Expr_Expr, BuiltinProcPkg_intrinsics},
@@ -434,7 +440,7 @@ gb_global BuiltinProc builtin_procs[BuiltinProc_COUNT] = {
{STR_LIT("simd_neg"), 1, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("simd_abs"), 2, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("simd_abs"), 1, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("simd_min"), 2, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("simd_max"), 2, false, Expr_Expr, BuiltinProcPkg_intrinsics},
@@ -578,4 +584,6 @@ gb_global BuiltinProc builtin_procs[BuiltinProc_COUNT] = {
{STR_LIT("wasm_memory_size"), 1, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("wasm_memory_atomic_wait32"), 3, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("wasm_memory_atomic_notify32"), 2, false, Expr_Expr, BuiltinProcPkg_intrinsics},
{STR_LIT("valgrind_client_request"), 7, false, Expr_Expr, BuiltinProcPkg_intrinsics},
};
src/docs_format.cpp
+1 -1
View File
@@ -83,6 +83,7 @@ enum OdinDocTypeKind : u32 {
OdinDocType_RelativeSlice = 21,
OdinDocType_MultiPointer = 22,
OdinDocType_Matrix = 23,
OdinDocType_SoaPointer = 24,
};
enum OdinDocTypeFlag_Basic : u32 {
@@ -98,7 +99,6 @@ enum OdinDocTypeFlag_Struct : u32 {
enum OdinDocTypeFlag_Union : u32 {
OdinDocTypeFlag_Union_polymorphic = 1<<0,
OdinDocTypeFlag_Union_no_nil = 1<<1,
OdinDocTypeFlag_Union_maybe = 1<<2,
OdinDocTypeFlag_Union_shared_nil = 1<<3,
};
src/docs_writer.cpp
+4
View File
@@ -532,6 +532,10 @@ OdinDocTypeIndex odin_doc_type(OdinDocWriter *w, Type *type) {
doc_type.kind = OdinDocType_MultiPointer;
doc_type.types = odin_doc_type_as_slice(w, type->MultiPointer.elem);
break;
case Type_SoaPointer:
doc_type.kind = OdinDocType_SoaPointer;
doc_type.types = odin_doc_type_as_slice(w, type->SoaPointer.elem);
break;
case Type_Array:
doc_type.kind = OdinDocType_Array;
doc_type.elem_count_len = 1;
src/gb/gb.h
+1 -1
View File
@@ -90,7 +90,7 @@ extern "C" {
#error This operating system is not supported
#endif
#if defined(GB_SYSTEM_OPENBSD)
#if defined(GB_SYSTEM_UNIX)
#include <sys/wait.h>
#endif
src/llvm_abi.cpp
+17 -11
View File
@@ -62,7 +62,7 @@ bool lb_is_type_kind(LLVMTypeRef type, LLVMTypeKind kind) {
return LLVMGetTypeKind(type) == kind;
}
LLVMTypeRef lb_function_type_to_llvm_ptr(lbFunctionType *ft, bool is_var_arg) {
LLVMTypeRef lb_function_type_to_llvm_raw(lbFunctionType *ft, bool is_var_arg) {
unsigned arg_count = cast(unsigned)ft->args.count;
unsigned offset = 0;
@@ -108,10 +108,16 @@ LLVMTypeRef lb_function_type_to_llvm_ptr(lbFunctionType *ft, bool is_var_arg) {
}
unsigned total_arg_count = arg_index;
LLVMTypeRef func_type = LLVMFunctionType(ret, args, total_arg_count, is_var_arg);
return LLVMPointerType(func_type, 0);
return func_type;
}
// LLVMTypeRef lb_function_type_to_llvm_ptr(lbFunctionType *ft, bool is_var_arg) {
// LLVMTypeRef func_type = lb_function_type_to_llvm_raw(ft, is_var_arg);
// return LLVMPointerType(func_type, 0);
// }
void lb_add_function_type_attributes(LLVMValueRef fn, lbFunctionType *ft, ProcCallingConvention calling_convention) {
if (ft == nullptr) {
return;
@@ -217,7 +223,7 @@ i64 lb_sizeof(LLVMTypeRef type) {
break;
case LLVMArrayTypeKind:
{
LLVMTypeRef elem = LLVMGetElementType(type);
LLVMTypeRef elem = OdinLLVMGetArrayElementType(type);
i64 elem_size = lb_sizeof(elem);
i64 count = LLVMGetArrayLength(type);
i64 size = count * elem_size;
@@ -229,7 +235,7 @@ i64 lb_sizeof(LLVMTypeRef type) {
return 8;
case LLVMVectorTypeKind:
{
LLVMTypeRef elem = LLVMGetElementType(type);
LLVMTypeRef elem = OdinLLVMGetVectorElementType(type);
i64 elem_size = lb_sizeof(elem);
i64 count = LLVMGetVectorSize(type);
i64 size = count * elem_size;
@@ -277,18 +283,18 @@ i64 lb_alignof(LLVMTypeRef type) {
}
break;
case LLVMArrayTypeKind:
return lb_alignof(LLVMGetElementType(type));
return lb_alignof(OdinLLVMGetArrayElementType(type));
case LLVMX86_MMXTypeKind:
return 8;
case LLVMVectorTypeKind:
{
// TODO(bill): This appears to be correct but LLVM isn't necessarily "great" with regards to documentation
LLVMTypeRef elem = LLVMGetElementType(type);
LLVMTypeRef elem = OdinLLVMGetVectorElementType(type);
i64 elem_size = lb_sizeof(elem);
i64 count = LLVMGetVectorSize(type);
i64 size = count * elem_size;
return gb_clamp(next_pow2(size), 1, build_context.max_align);
return gb_clamp(next_pow2(size), 1, build_context.max_simd_align);
}
}
@@ -787,7 +793,7 @@ namespace lbAbiAmd64SysV {
case LLVMArrayTypeKind:
{
i64 len = LLVMGetArrayLength(t);
LLVMTypeRef elem = LLVMGetElementType(t);
LLVMTypeRef elem = OdinLLVMGetArrayElementType(t);
i64 elem_sz = lb_sizeof(elem);
for (i64 i = 0; i < len; i++) {
classify_with(elem, cls, ix, off + i*elem_sz);
@@ -797,7 +803,7 @@ namespace lbAbiAmd64SysV {
case LLVMVectorTypeKind:
{
i64 len = LLVMGetVectorSize(t);
LLVMTypeRef elem = LLVMGetElementType(t);
LLVMTypeRef elem = OdinLLVMGetVectorElementType(t);
i64 elem_sz = lb_sizeof(elem);
LLVMTypeKind elem_kind = LLVMGetTypeKind(elem);
RegClass reg = RegClass_NoClass;
@@ -907,7 +913,7 @@ namespace lbAbiArm64 {
if (len == 0) {
return false;
}
LLVMTypeRef elem = LLVMGetElementType(type);
LLVMTypeRef elem = OdinLLVMGetArrayElementType(type);
LLVMTypeRef base_type = nullptr;
unsigned member_count = 0;
if (is_homogenous_aggregate(c, elem, &base_type, &member_count)) {
@@ -1123,7 +1129,7 @@ namespace lbAbiWasm {
}
if (sz <= MAX_DIRECT_STRUCT_SIZE) {
if (kind == LLVMArrayTypeKind) {
if (is_basic_register_type(LLVMGetElementType(type))) {
if (is_basic_register_type(OdinLLVMGetArrayElementType(type))) {
return true;
}
} else if (kind == LLVMStructTypeKind) {
src/llvm_backend.cpp
+5 -6
View File
@@ -739,11 +739,11 @@ lbProcedure *lb_create_startup_runtime(lbModule *main_module, lbProcedure *start
lb_begin_procedure_body(p);
if (startup_type_info) {
LLVMBuildCall2(p->builder, LLVMGetElementType(lb_type(main_module, startup_type_info->type)), startup_type_info->value, nullptr, 0, "");
LLVMBuildCall2(p->builder, lb_type_internal_for_procedures_raw(main_module, startup_type_info->type), startup_type_info->value, nullptr, 0, "");
}
if (objc_names) {
LLVMBuildCall2(p->builder, LLVMGetElementType(lb_type(main_module, objc_names->type)), objc_names->value, nullptr, 0, "");
LLVMBuildCall2(p->builder, lb_type_internal_for_procedures_raw(main_module, objc_names->type), objc_names->value, nullptr, 0, "");
}
for_array(i, global_variables) {
@@ -762,7 +762,7 @@ lbProcedure *lb_create_startup_runtime(lbModule *main_module, lbProcedure *start
if (init_expr != nullptr) {
lbValue init = lb_build_expr(p, init_expr);
if (init.value == nullptr) {
LLVMTypeRef global_type = LLVMGetElementType(LLVMTypeOf(var->var.value));
LLVMTypeRef global_type = llvm_addr_type(p->module, var->var);
if (is_type_untyped_undef(init.type)) {
// LLVMSetInitializer(var->var.value, LLVMGetUndef(global_type));
LLVMSetInitializer(var->var.value, LLVMConstNull(global_type));
@@ -805,8 +805,7 @@ lbProcedure *lb_create_startup_runtime(lbModule *main_module, lbProcedure *start
lb_emit_store(p, data, lb_emit_conv(p, gp, t_rawptr));
lb_emit_store(p, ti, lb_type_info(main_module, var_type));
} else {
LLVMTypeRef pvt = LLVMTypeOf(var->var.value);
LLVMTypeRef vt = LLVMGetElementType(pvt);
LLVMTypeRef vt = llvm_addr_type(p->module, var->var);
lbValue src0 = lb_emit_conv(p, var->init, t);
LLVMValueRef src = OdinLLVMBuildTransmute(p, src0.value, vt);
LLVMValueRef dst = var->var.value;
@@ -933,7 +932,7 @@ lbProcedure *lb_create_main_procedure(lbModule *m, lbProcedure *startup_runtime)
GB_ASSERT(LLVMIsConstant(vals[1]));
GB_ASSERT(LLVMIsConstant(vals[2]));
LLVMValueRef dst = LLVMConstInBoundsGEP(all_tests_array.value, indices, gb_count_of(indices));
LLVMValueRef dst = LLVMConstInBoundsGEP2(llvm_addr_type(m, all_tests_array), all_tests_array.value, indices, gb_count_of(indices));
LLVMValueRef src = llvm_const_named_struct(m, t_Internal_Test, vals, gb_count_of(vals));
LLVMBuildStore(p->builder, src, dst);
src/llvm_backend.hpp
+28 -5
View File
@@ -42,6 +42,18 @@
#define ODIN_LLVM_MINIMUM_VERSION_12 0
#endif
#if LLVM_VERSION_MAJOR > 13 || (LLVM_VERSION_MAJOR == 13 && LLVM_VERSION_MINOR >= 0 && LLVM_VERSION_PATCH > 0)
#define ODIN_LLVM_MINIMUM_VERSION_13 1
#else
#define ODIN_LLVM_MINIMUM_VERSION_13 0
#endif
#if LLVM_VERSION_MAJOR > 14 || (LLVM_VERSION_MAJOR == 14 && LLVM_VERSION_MINOR >= 0 && LLVM_VERSION_PATCH > 0)
#define ODIN_LLVM_MINIMUM_VERSION_14 1
#else
#define ODIN_LLVM_MINIMUM_VERSION_14 0
#endif
struct lbProcedure;
struct lbValue {
@@ -115,6 +127,7 @@ struct lbModule {
AstPackage *pkg; // associated
PtrMap<Type *, LLVMTypeRef> types;
PtrMap<Type *, LLVMTypeRef> func_raw_types;
PtrMap<void *, lbStructFieldRemapping> struct_field_remapping; // Key: LLVMTypeRef or Type *
i32 internal_type_level;
@@ -299,7 +312,11 @@ struct lbProcedure {
#if !ODIN_LLVM_MINIMUM_VERSION_14
#define LLVMConstGEP2(Ty__, ConstantVal__, ConstantIndices__, NumIndices__) LLVMConstGEP(ConstantVal__, ConstantIndices__, NumIndices__)
#define LLVMConstInBoundsGEP2(Ty__, ConstantVal__, ConstantIndices__, NumIndices__) LLVMConstInBoundsGEP(ConstantVal__, ConstantIndices__, NumIndices__)
#define LLVMBuildPtrDiff2(Builder__, Ty__, LHS__, RHS__, Name__) LLVMBuildPtrDiff(Builder__, LHS__, RHS__, Name__)
#endif
bool lb_init_generator(lbGenerator *gen, Checker *c);
@@ -314,7 +331,8 @@ lbProcedure *lb_create_procedure(lbModule *module, Entity *entity, bool ignore_b
void lb_end_procedure(lbProcedure *p);
LLVMTypeRef lb_type(lbModule *m, Type *type);
LLVMTypeRef lb_type(lbModule *m, Type *type);
LLVMTypeRef llvm_get_element_type(LLVMTypeRef type);
lbBlock *lb_create_block(lbProcedure *p, char const *name, bool append=false);
@@ -327,7 +345,7 @@ lbValue lb_const_int(lbModule *m, Type *type, u64 value);
lbAddr lb_addr(lbValue addr);
Type *lb_addr_type(lbAddr const &addr);
LLVMTypeRef lb_addr_lb_type(lbAddr const &addr);
LLVMTypeRef llvm_addr_type(lbModule *module, lbValue addr_val);
void lb_addr_store(lbProcedure *p, lbAddr addr, lbValue value);
lbValue lb_addr_load(lbProcedure *p, lbAddr const &addr);
lbValue lb_emit_load(lbProcedure *p, lbValue v);
@@ -339,8 +357,9 @@ lbValue lb_build_expr(lbProcedure *p, Ast *expr);
lbAddr lb_build_addr(lbProcedure *p, Ast *expr);
void lb_build_stmt_list(lbProcedure *p, Array<Ast *> const &stmts);
lbValue lb_build_gep(lbProcedure *p, lbValue const &value, i32 index) ;
lbValue lb_emit_epi(lbProcedure *p, lbValue const &value, isize index);
lbValue lb_emit_epi(lbModule *m, lbValue const &value, isize index);
lbValue lb_emit_array_epi(lbModule *m, lbValue s, isize index);
lbValue lb_emit_struct_ep(lbProcedure *p, lbValue s, i32 index);
lbValue lb_emit_struct_ev(lbProcedure *p, lbValue s, i32 index);
lbValue lb_emit_array_epi(lbProcedure *p, lbValue value, isize index);
@@ -480,6 +499,7 @@ LLVMTypeRef lb_type_padding_filler(lbModule *m, i64 padding, i64 padding_align);
LLVMValueRef llvm_basic_shuffle(lbProcedure *p, LLVMValueRef vector, LLVMValueRef mask);
LLVMValueRef lb_call_intrinsic(lbProcedure *p, const char *name, LLVMValueRef* args, unsigned arg_count, LLVMTypeRef* types, unsigned type_count);
void lb_mem_copy_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile=false);
void lb_mem_copy_non_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile=false);
LLVMValueRef lb_mem_zero_ptr_internal(lbProcedure *p, LLVMValueRef ptr, LLVMValueRef len, unsigned alignment, bool is_volatile);
@@ -488,6 +508,9 @@ i64 lb_max_zero_init_size(void) {
return cast(i64)(4*build_context.word_size);
}
LLVMTypeRef OdinLLVMGetArrayElementType(LLVMTypeRef type);
LLVMTypeRef OdinLLVMGetVectorElementType(LLVMTypeRef type);
#define LB_STARTUP_RUNTIME_PROC_NAME "__$startup_runtime"
#define LB_STARTUP_TYPE_INFO_PROC_NAME "__$startup_type_info"
#define LB_TYPE_INFO_DATA_NAME "__$type_info_data"
src/llvm_backend_const.cpp
+8 -7
View File
@@ -10,11 +10,12 @@ bool lb_is_const(lbValue value) {
return false;
}
bool lb_is_const_or_global(lbValue value) {
if (lb_is_const(value)) {
return true;
}
// TODO remove use of LLVMGetElementType
#if 0
if (LLVMGetValueKind(value.value) == LLVMGlobalVariableValueKind) {
LLVMTypeRef t = LLVMGetElementType(LLVMTypeOf(value.value));
if (!lb_is_type_kind(t, LLVMPointerTypeKind)) {
@@ -23,6 +24,7 @@ bool lb_is_const_or_global(lbValue value) {
LLVMTypeRef elem = LLVMGetElementType(t);
return lb_is_type_kind(elem, LLVMFunctionTypeKind);
}
#endif
return false;
}
@@ -389,8 +391,8 @@ lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, bool allow_loc
if (is_type_slice(type)) {
if (value.kind == ExactValue_String) {
GB_ASSERT(is_type_u8_slice(type));
res.value = lb_find_or_add_entity_string_byte_slice(m, value.value_string).value;
GB_ASSERT(is_type_slice(type));
res.value = lb_find_or_add_entity_string_byte_slice_with_type(m, value.value_string, original_type).value;
return res;
} else {
ast_node(cl, CompoundLit, value.value_compound);
@@ -418,7 +420,7 @@ lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, bool allow_loc
{
LLVMValueRef indices[2] = {llvm_zero(m), llvm_zero(m)};
LLVMValueRef ptr = LLVMBuildInBoundsGEP(p->builder, array_data, indices, 2, "");
LLVMValueRef ptr = LLVMBuildInBoundsGEP2(p->builder, llvm_type, array_data, indices, 2, "");
LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), count, true);
lbAddr slice = lb_add_local_generated(p, type, false);
lb_fill_slice(p, slice, {ptr, alloc_type_pointer(elem)}, {len, t_int});
@@ -445,7 +447,7 @@ lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, bool allow_loc
{
LLVMValueRef indices[2] = {llvm_zero(m), llvm_zero(m)};
LLVMValueRef ptr = LLVMConstInBoundsGEP(array_data, indices, 2);
LLVMValueRef ptr = LLVMConstInBoundsGEP2(lb_type(m, t), array_data, indices, 2);
LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), count, true);
LLVMValueRef values[2] = {ptr, len};
@@ -1007,7 +1009,7 @@ lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, bool allow_loc
for (isize i = 0; i < value_count; i++) {
LLVMValueRef val = old_values[i];
if (!LLVMIsConstant(val)) {
LLVMValueRef dst = LLVMBuildStructGEP(p->builder, v.addr.value, cast(unsigned)i, "");
LLVMValueRef dst = LLVMBuildStructGEP2(p->builder, llvm_addr_type(p->module, v.addr), v.addr.value, cast(unsigned)i, "");
LLVMBuildStore(p->builder, val, dst);
}
}
@@ -1041,7 +1043,6 @@ lbValue lb_const_value(lbModule *m, Type *type, ExactValue value, bool allow_loc
i64 v = big_int_to_i64(&tav.value.value_integer);
i64 lower = type->BitSet.lower;
u64 index = cast(u64)(v-lower);
gb_printf_err("index: %llu\n", index);
BigInt bit = {};
big_int_from_u64(&bit, index);
big_int_shl(&bit, &one, &bit);
src/llvm_backend_expr.cpp
+1049 -1268
View File
File diff suppressed because it is too large Load Diff
src/llvm_backend_general.cpp
+292 -128
View File
@@ -56,6 +56,7 @@ void lb_init_module(lbModule *m, Checker *c) {
gbAllocator a = heap_allocator();
map_init(&m->types, a);
map_init(&m->func_raw_types, a);
map_init(&m->struct_field_remapping, a);
map_init(&m->values, a);
map_init(&m->soa_values, a);
@@ -174,7 +175,8 @@ struct lbLoopData {
struct lbCompoundLitElemTempData {
Ast * expr;
lbValue value;
i32 elem_index;
i64 elem_index;
i64 elem_length;
lbValue gep;
};
@@ -211,6 +213,45 @@ void lb_loop_end(lbProcedure *p, lbLoopData const &data) {
}
// This emits a GEP at 0, index
lbValue lb_emit_epi(lbProcedure *p, lbValue const &value, isize index) {
GB_ASSERT(is_type_pointer(value.type));
Type *type = type_deref(value.type);
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(p->module, t_int), 0, false),
LLVMConstInt(lb_type(p->module, t_int), cast(unsigned long long)index, false),
};
LLVMTypeRef llvm_type = lb_type(p->module, type);
lbValue res = {};
Type *ptr = base_array_type(type);
res.type = alloc_type_pointer(ptr);
if (LLVMIsConstant(value.value)) {
res.value = LLVMConstGEP2(llvm_type, value.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP2(p->builder, llvm_type, value.value, indices, gb_count_of(indices), "");
}
return res;
}
// This emits a GEP at 0, index
lbValue lb_emit_epi(lbModule *m, lbValue const &value, isize index) {
GB_ASSERT(is_type_pointer(value.type));
GB_ASSERT(LLVMIsConstant(value.value));
Type *type = type_deref(value.type);
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(m, t_int), 0, false),
LLVMConstInt(lb_type(m, t_int), cast(unsigned long long)index, false),
};
lbValue res = {};
Type *ptr = base_array_type(type);
res.type = alloc_type_pointer(ptr);
res.value = LLVMConstGEP2(lb_type(m, type), value.value, indices, gb_count_of(indices));
return res;
}
LLVMValueRef llvm_zero(lbModule *m) {
return LLVMConstInt(lb_type(m, t_int), 0, false);
}
@@ -341,9 +382,6 @@ Type *lb_addr_type(lbAddr const &addr) {
}
return type_deref(addr.addr.type);
}
LLVMTypeRef lb_addr_lb_type(lbAddr const &addr) {
return LLVMGetElementType(LLVMTypeOf(addr.addr.value));
}
lbValue lb_addr_get_ptr(lbProcedure *p, lbAddr const &addr) {
if (addr.addr.value == nullptr) {
@@ -530,6 +568,13 @@ void lb_emit_slice_bounds_check(lbProcedure *p, Token token, lbValue low, lbValu
}
}
unsigned lb_try_get_alignment(LLVMValueRef addr_ptr, unsigned default_alignment) {
if (LLVMIsAGlobalValue(addr_ptr) || LLVMIsAAllocaInst(addr_ptr) || LLVMIsALoadInst(addr_ptr)) {
return LLVMGetAlignment(addr_ptr);
}
return default_alignment;
}
bool lb_try_update_alignment(LLVMValueRef addr_ptr, unsigned alignment) {
if (LLVMIsAGlobalValue(addr_ptr) || LLVMIsAAllocaInst(addr_ptr) || LLVMIsALoadInst(addr_ptr)) {
if (LLVMGetAlignment(addr_ptr) < alignment) {
@@ -546,6 +591,9 @@ bool lb_try_update_alignment(lbValue ptr, unsigned alignment) {
return lb_try_update_alignment(ptr.value, alignment);
}
bool lb_can_try_to_inline_array_arith(Type *t) {
return type_size_of(t) <= build_context.max_simd_align;
}
bool lb_try_vector_cast(lbModule *m, lbValue ptr, LLVMTypeRef *vector_type_) {
Type *array_type = base_type(type_deref(ptr.type));
@@ -554,7 +602,7 @@ bool lb_try_vector_cast(lbModule *m, lbValue ptr, LLVMTypeRef *vector_type_) {
Type *elem_type = base_array_type(array_type);
// TODO(bill): Determine what is the correct limit for doing vector arithmetic
if (type_size_of(array_type) <= build_context.max_align &&
if (lb_can_try_to_inline_array_arith(array_type) &&
is_type_valid_vector_elem(elem_type)) {
// Try to treat it like a vector if possible
bool possible = false;
@@ -854,8 +902,12 @@ void lb_emit_store(lbProcedure *p, lbValue ptr, lbValue value) {
Type *a = type_deref(ptr.type);
if (LLVMIsNull(value.value)) {
LLVMTypeRef src_t = LLVMGetElementType(LLVMTypeOf(ptr.value));
if (lb_sizeof(src_t) <= lb_max_zero_init_size()) {
LLVMTypeRef src_t = llvm_addr_type(p->module, ptr);
if (is_type_proc(a)) {
LLVMTypeRef rawptr_type = lb_type(p->module, t_rawptr);
LLVMTypeRef rawptr_ptr_type = LLVMPointerType(rawptr_type, 0);
LLVMBuildStore(p->builder, LLVMConstNull(rawptr_type), LLVMBuildBitCast(p->builder, ptr.value, rawptr_ptr_type, ""));
} else if (lb_sizeof(src_t) <= lb_max_zero_init_size()) {
LLVMBuildStore(p->builder, LLVMConstNull(src_t), ptr.value);
} else {
lb_mem_zero_ptr(p, ptr.value, a, 1);
@@ -873,25 +925,46 @@ void lb_emit_store(lbProcedure *p, lbValue ptr, lbValue value) {
enum {MAX_STORE_SIZE = 64};
if (LLVMIsALoadInst(value.value) && lb_sizeof(LLVMTypeOf(value.value)) > MAX_STORE_SIZE) {
LLVMValueRef dst_ptr = ptr.value;
LLVMValueRef src_ptr = LLVMGetOperand(value.value, 0);
src_ptr = LLVMBuildPointerCast(p->builder, src_ptr, LLVMTypeOf(dst_ptr), "");
if (lb_sizeof(LLVMTypeOf(value.value)) > MAX_STORE_SIZE) {
if (LLVMIsALoadInst(value.value)) {
LLVMValueRef dst_ptr = ptr.value;
LLVMValueRef src_ptr_original = LLVMGetOperand(value.value, 0);
LLVMValueRef src_ptr = LLVMBuildPointerCast(p->builder, src_ptr_original, LLVMTypeOf(dst_ptr), "");
LLVMBuildMemMove(p->builder,
dst_ptr, 1,
src_ptr, 1,
LLVMConstInt(LLVMInt64TypeInContext(p->module->ctx), lb_sizeof(LLVMTypeOf(value.value)), false));
return;
LLVMBuildMemMove(p->builder,
dst_ptr, lb_try_get_alignment(dst_ptr, 1),
src_ptr, lb_try_get_alignment(src_ptr_original, 1),
LLVMConstInt(LLVMInt64TypeInContext(p->module->ctx), lb_sizeof(LLVMTypeOf(value.value)), false));
return;
} else if (LLVMIsConstant(value.value)) {
lbAddr addr = lb_add_global_generated(p->module, value.type, value, nullptr);
LLVMValueRef global_data = addr.addr.value;
// make it truly private data
LLVMSetLinkage(global_data, LLVMPrivateLinkage);
LLVMSetUnnamedAddress(global_data, LLVMGlobalUnnamedAddr);
LLVMSetGlobalConstant(global_data, true);
LLVMValueRef dst_ptr = ptr.value;
LLVMValueRef src_ptr = global_data;
src_ptr = LLVMBuildPointerCast(p->builder, src_ptr, LLVMTypeOf(dst_ptr), "");
LLVMBuildMemMove(p->builder,
dst_ptr, lb_try_get_alignment(dst_ptr, 1),
src_ptr, lb_try_get_alignment(global_data, 1),
LLVMConstInt(LLVMInt64TypeInContext(p->module->ctx), lb_sizeof(LLVMTypeOf(value.value)), false));
return;
}
}
if (lb_is_type_proc_recursive(a)) {
// NOTE(bill, 2020-11-11): Because of certain LLVM rules, a procedure value may be
// stored as regular pointer with no procedure information
LLVMTypeRef src_t = LLVMGetElementType(LLVMTypeOf(ptr.value));
LLVMValueRef v = LLVMBuildPointerCast(p->builder, value.value, src_t, "");
LLVMBuildStore(p->builder, v, ptr.value);
LLVMTypeRef rawptr_type = lb_type(p->module, t_rawptr);
LLVMTypeRef rawptr_ptr_type = LLVMPointerType(rawptr_type, 0);
LLVMBuildStore(p->builder,
LLVMBuildPointerCast(p->builder, value.value, rawptr_type, ""),
LLVMBuildPointerCast(p->builder, ptr.value, rawptr_ptr_type, ""));
} else {
Type *ca = core_type(a);
if (ca->kind == Type_Basic || ca->kind == Type_Proc) {
@@ -904,8 +977,8 @@ void lb_emit_store(lbProcedure *p, lbValue ptr, lbValue value) {
}
}
LLVMTypeRef llvm_addr_type(lbValue addr_val) {
return LLVMGetElementType(LLVMTypeOf(addr_val.value));
LLVMTypeRef llvm_addr_type(lbModule *module, lbValue addr_val) {
return lb_type(module, type_deref(addr_val.type));
}
lbValue lb_emit_load(lbProcedure *p, lbValue value) {
@@ -914,12 +987,18 @@ lbValue lb_emit_load(lbProcedure *p, lbValue value) {
Type *vt = base_type(value.type);
GB_ASSERT(vt->kind == Type_MultiPointer);
Type *t = vt->MultiPointer.elem;
LLVMValueRef v = LLVMBuildLoad2(p->builder, llvm_addr_type(value), value.value, "");
LLVMValueRef v = LLVMBuildLoad2(p->builder, lb_type(p->module, t), value.value, "");
return lbValue{v, t};
} else if (is_type_soa_pointer(value.type)) {
lbValue ptr = lb_emit_struct_ev(p, value, 0);
lbValue idx = lb_emit_struct_ev(p, value, 1);
lbAddr addr = lb_addr_soa_variable(ptr, idx, nullptr);
return lb_addr_load(p, addr);
}
GB_ASSERT(is_type_pointer(value.type));
Type *t = type_deref(value.type);
LLVMValueRef v = LLVMBuildLoad2(p->builder, llvm_addr_type(value), value.value, "");
LLVMValueRef v = LLVMBuildLoad2(p->builder, lb_type(p->module, t), value.value, "");
return lbValue{v, t};
}
@@ -1184,12 +1263,12 @@ lbValue lb_emit_union_tag_ptr(lbProcedure *p, lbValue u) {
Type *tag_type = union_tag_type(ut);
LLVMTypeRef uvt = LLVMGetElementType(LLVMTypeOf(u.value));
LLVMTypeRef uvt = llvm_addr_type(p->module, u);
unsigned element_count = LLVMCountStructElementTypes(uvt);
GB_ASSERT_MSG(element_count >= 2, "element_count=%u (%s) != (%s)", element_count, type_to_string(ut), LLVMPrintTypeToString(uvt));
lbValue tag_ptr = {};
tag_ptr.value = LLVMBuildStructGEP(p->builder, u.value, 1, "");
tag_ptr.value = LLVMBuildStructGEP2(p->builder, uvt, u.value, 1, "");
tag_ptr.type = alloc_type_pointer(tag_type);
return tag_ptr;
}
@@ -1413,6 +1492,116 @@ String lb_get_entity_name(lbModule *m, Entity *e, String default_name) {
}
LLVMTypeRef lb_type_internal_for_procedures_raw(lbModule *m, Type *type) {
Type *original_type = type;
type = base_type(original_type);
GB_ASSERT(type->kind == Type_Proc);
LLVMTypeRef *found = map_get(&m->func_raw_types, type);
if (found) {
return *found;
}
unsigned param_count = 0;
if (type->Proc.calling_convention == ProcCC_Odin) {
param_count += 1;
}
if (type->Proc.param_count != 0) {
GB_ASSERT(type->Proc.params->kind == Type_Tuple);
for_array(i, type->Proc.params->Tuple.variables) {
Entity *e = type->Proc.params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
continue;
}
if (e->flags & EntityFlag_CVarArg) {
continue;
}
param_count += 1;
}
}
m->internal_type_level += 1;
defer (m->internal_type_level -= 1);
LLVMTypeRef ret = nullptr;
LLVMTypeRef *params = gb_alloc_array(permanent_allocator(), LLVMTypeRef, param_count);
if (type->Proc.result_count != 0) {
Type *single_ret = reduce_tuple_to_single_type(type->Proc.results);
ret = lb_type(m, single_ret);
if (ret != nullptr) {
if (is_type_boolean(single_ret) &&
is_calling_convention_none(type->Proc.calling_convention) &&
type_size_of(single_ret) <= 1) {
ret = LLVMInt1TypeInContext(m->ctx);
}
}
}
unsigned param_index = 0;
if (type->Proc.param_count != 0) {
GB_ASSERT(type->Proc.params->kind == Type_Tuple);
for_array(i, type->Proc.params->Tuple.variables) {
Entity *e = type->Proc.params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
continue;
}
if (e->flags & EntityFlag_CVarArg) {
continue;
}
Type *e_type = reduce_tuple_to_single_type(e->type);
LLVMTypeRef param_type = nullptr;
if (e->flags & EntityFlag_ByPtr) {
param_type = lb_type(m, alloc_type_pointer(e_type));
} else if (is_type_boolean(e_type) &&
type_size_of(e_type) <= 1) {
param_type = LLVMInt1TypeInContext(m->ctx);
} else {
if (is_type_proc(e_type)) {
param_type = lb_type(m, t_rawptr);
} else {
param_type = lb_type(m, e_type);
}
}
params[param_index++] = param_type;
}
}
if (param_index < param_count) {
params[param_index++] = lb_type(m, t_rawptr);
}
GB_ASSERT(param_index == param_count);
lbFunctionType *ft = lb_get_abi_info(m->ctx, params, param_count, ret, ret != nullptr, type->Proc.calling_convention);
{
for_array(j, ft->args) {
auto arg = ft->args[j];
GB_ASSERT_MSG(LLVMGetTypeContext(arg.type) == ft->ctx,
"\n\t%s %td/%td"
"\n\tArgTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMPrintTypeToString(arg.type),
j, ft->args.count,
LLVMGetTypeContext(arg.type), ft->ctx, LLVMGetGlobalContext());
}
GB_ASSERT_MSG(LLVMGetTypeContext(ft->ret.type) == ft->ctx,
"\n\t%s"
"\n\tRetTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMPrintTypeToString(ft->ret.type),
LLVMGetTypeContext(ft->ret.type), ft->ctx, LLVMGetGlobalContext());
}
map_set(&m->function_type_map, type, ft);
LLVMTypeRef new_abi_fn_type = lb_function_type_to_llvm_raw(ft, type->Proc.c_vararg);
GB_ASSERT_MSG(LLVMGetTypeContext(new_abi_fn_type) == m->ctx,
"\n\tFuncTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMGetTypeContext(new_abi_fn_type), m->ctx, LLVMGetGlobalContext());
map_set(&m->func_raw_types, type, new_abi_fn_type);
return new_abi_fn_type;
}
LLVMTypeRef lb_type_internal(lbModule *m, Type *type) {
LLVMContextRef ctx = m->ctx;
i64 size = type_size_of(type); // Check size
@@ -1916,103 +2105,8 @@ LLVMTypeRef lb_type_internal(lbModule *m, Type *type) {
if (m->internal_type_level > 1) { // TODO HACK(bill): is this really enough?
return LLVMPointerType(LLVMIntTypeInContext(m->ctx, 8), 0);
} else {
unsigned param_count = 0;
if (type->Proc.calling_convention == ProcCC_Odin) {
param_count += 1;
}
if (type->Proc.param_count != 0) {
GB_ASSERT(type->Proc.params->kind == Type_Tuple);
for_array(i, type->Proc.params->Tuple.variables) {
Entity *e = type->Proc.params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
continue;
}
if (e->flags & EntityFlag_CVarArg) {
continue;
}
param_count += 1;
}
}
m->internal_type_level += 1;
defer (m->internal_type_level -= 1);
LLVMTypeRef ret = nullptr;
LLVMTypeRef *params = gb_alloc_array(permanent_allocator(), LLVMTypeRef, param_count);
if (type->Proc.result_count != 0) {
Type *single_ret = reduce_tuple_to_single_type(type->Proc.results);
ret = lb_type(m, single_ret);
if (ret != nullptr) {
if (is_type_boolean(single_ret) &&
is_calling_convention_none(type->Proc.calling_convention) &&
type_size_of(single_ret) <= 1) {
ret = LLVMInt1TypeInContext(m->ctx);
}
}
}
unsigned param_index = 0;
if (type->Proc.param_count != 0) {
GB_ASSERT(type->Proc.params->kind == Type_Tuple);
for_array(i, type->Proc.params->Tuple.variables) {
Entity *e = type->Proc.params->Tuple.variables[i];
if (e->kind != Entity_Variable) {
continue;
}
if (e->flags & EntityFlag_CVarArg) {
continue;
}
Type *e_type = reduce_tuple_to_single_type(e->type);
LLVMTypeRef param_type = nullptr;
if (e->flags & EntityFlag_ByPtr) {
param_type = lb_type(m, alloc_type_pointer(e_type));
} else if (is_type_boolean(e_type) &&
type_size_of(e_type) <= 1) {
param_type = LLVMInt1TypeInContext(m->ctx);
} else {
if (is_type_proc(e_type)) {
param_type = lb_type(m, t_rawptr);
} else {
param_type = lb_type(m, e_type);
}
}
params[param_index++] = param_type;
}
}
if (param_index < param_count) {
params[param_index++] = lb_type(m, t_rawptr);
}
GB_ASSERT(param_index == param_count);
lbFunctionType *ft = lb_get_abi_info(m->ctx, params, param_count, ret, ret != nullptr, type->Proc.calling_convention);
{
for_array(j, ft->args) {
auto arg = ft->args[j];
GB_ASSERT_MSG(LLVMGetTypeContext(arg.type) == ft->ctx,
"\n\t%s %td/%td"
"\n\tArgTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMPrintTypeToString(arg.type),
j, ft->args.count,
LLVMGetTypeContext(arg.type), ft->ctx, LLVMGetGlobalContext());
}
GB_ASSERT_MSG(LLVMGetTypeContext(ft->ret.type) == ft->ctx,
"\n\t%s"
"\n\tRetTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMPrintTypeToString(ft->ret.type),
LLVMGetTypeContext(ft->ret.type), ft->ctx, LLVMGetGlobalContext());
}
map_set(&m->function_type_map, type, ft);
LLVMTypeRef new_abi_fn_ptr_type = lb_function_type_to_llvm_ptr(ft, type->Proc.c_vararg);
LLVMTypeRef new_abi_fn_type = LLVMGetElementType(new_abi_fn_ptr_type);
GB_ASSERT_MSG(LLVMGetTypeContext(new_abi_fn_type) == m->ctx,
"\n\tFuncTypeCtx: %p\n\tCurrentCtx: %p\n\tGlobalCtx: %p",
LLVMGetTypeContext(new_abi_fn_type), m->ctx, LLVMGetGlobalContext());
return new_abi_fn_ptr_type;
LLVMTypeRef proc_raw_type = lb_type_internal_for_procedures_raw(m, type);
return LLVMPointerType(proc_raw_type, 0);
}
break;
@@ -2055,6 +2149,15 @@ LLVMTypeRef lb_type_internal(lbModule *m, Type *type) {
m->internal_type_level += 1;
return t;
}
case Type_SoaPointer:
{
unsigned field_count = 2;
LLVMTypeRef *fields = gb_alloc_array(permanent_allocator(), LLVMTypeRef, field_count);
fields[0] = LLVMPointerType(lb_type(m, type->Pointer.elem), 0);
fields[1] = LLVMIntTypeInContext(ctx, 8*cast(unsigned)build_context.word_size);
return LLVMStructTypeInContext(ctx, fields, field_count, false);
}
}
@@ -2259,6 +2362,17 @@ void lb_emit_if(lbProcedure *p, lbValue cond, lbBlock *true_block, lbBlock *fals
}
gb_inline LLVMTypeRef OdinLLVMGetInternalElementType(LLVMTypeRef type) {
return LLVMGetElementType(type);
}
LLVMTypeRef OdinLLVMGetArrayElementType(LLVMTypeRef type) {
GB_ASSERT(lb_is_type_kind(type, LLVMArrayTypeKind));
return OdinLLVMGetInternalElementType(type);
}
LLVMTypeRef OdinLLVMGetVectorElementType(LLVMTypeRef type) {
GB_ASSERT(lb_is_type_kind(type, LLVMVectorTypeKind));
return OdinLLVMGetInternalElementType(type);
}
LLVMValueRef OdinLLVMBuildTransmute(lbProcedure *p, LLVMValueRef val, LLVMTypeRef dst_type) {
@@ -2329,7 +2443,7 @@ general_end:;
if (LLVMIsALoadInst(val) && (src_size >= dst_size && src_align >= dst_align)) {
LLVMValueRef val_ptr = LLVMGetOperand(val, 0);
val_ptr = LLVMBuildPointerCast(p->builder, val_ptr, LLVMPointerType(dst_type, 0), "");
LLVMValueRef loaded_val = LLVMBuildLoad(p->builder, val_ptr, "");
LLVMValueRef loaded_val = LLVMBuildLoad2(p->builder, dst_type, val_ptr, "");
// LLVMSetAlignment(loaded_val, gb_min(src_align, dst_align));
@@ -2345,7 +2459,7 @@ general_end:;
LLVMValueRef nptr = LLVMBuildPointerCast(p->builder, ptr, LLVMPointerType(src_type, 0), "");
LLVMBuildStore(p->builder, val, nptr);
return LLVMBuildLoad(p->builder, ptr, "");
return LLVMBuildLoad2(p->builder, dst_type, ptr, "");
}
}
@@ -2371,14 +2485,15 @@ LLVMValueRef lb_find_or_add_entity_string_ptr(lbModule *m, String const &str) {
isize len = gb_snprintf(name, max_len, "csbs$%x", id);
len -= 1;
LLVMValueRef global_data = LLVMAddGlobal(m->mod, LLVMTypeOf(data), name);
LLVMTypeRef type = LLVMTypeOf(data);
LLVMValueRef global_data = LLVMAddGlobal(m->mod, type, name);
LLVMSetInitializer(global_data, data);
LLVMSetLinkage(global_data, LLVMPrivateLinkage);
LLVMSetUnnamedAddress(global_data, LLVMGlobalUnnamedAddr);
LLVMSetAlignment(global_data, 1);
LLVMSetGlobalConstant(global_data, true);
LLVMValueRef ptr = LLVMConstInBoundsGEP(global_data, indices, 2);
LLVMValueRef ptr = LLVMConstInBoundsGEP2(type, global_data, indices, 2);
string_map_set(&m->const_strings, key, ptr);
return ptr;
}
@@ -2416,7 +2531,8 @@ lbValue lb_find_or_add_entity_string_byte_slice(lbModule *m, String const &str)
isize len = gb_snprintf(name, max_len, "csbs$%x", id);
len -= 1;
}
LLVMValueRef global_data = LLVMAddGlobal(m->mod, LLVMTypeOf(data), name);
LLVMTypeRef type = LLVMTypeOf(data);
LLVMValueRef global_data = LLVMAddGlobal(m->mod, type, name);
LLVMSetInitializer(global_data, data);
LLVMSetLinkage(global_data, LLVMPrivateLinkage);
LLVMSetUnnamedAddress(global_data, LLVMGlobalUnnamedAddr);
@@ -2425,7 +2541,7 @@ lbValue lb_find_or_add_entity_string_byte_slice(lbModule *m, String const &str)
LLVMValueRef ptr = nullptr;
if (str.len != 0) {
ptr = LLVMConstInBoundsGEP(global_data, indices, 2);
ptr = LLVMConstInBoundsGEP2(type, global_data, indices, 2);
} else {
ptr = LLVMConstNull(lb_type(m, t_u8_ptr));
}
@@ -2437,8 +2553,56 @@ lbValue lb_find_or_add_entity_string_byte_slice(lbModule *m, String const &str)
res.type = t_u8_slice;
return res;
}
lbValue lb_find_or_add_entity_string_byte_slice_with_type(lbModule *m, String const &str, Type *slice_type) {
GB_ASSERT(is_type_slice(slice_type));
LLVMValueRef indices[2] = {llvm_zero(m), llvm_zero(m)};
LLVMValueRef data = LLVMConstStringInContext(m->ctx,
cast(char const *)str.text,
cast(unsigned)str.len,
false);
char *name = nullptr;
{
isize max_len = 7+8+1;
name = gb_alloc_array(permanent_allocator(), char, max_len);
u32 id = m->gen->global_array_index.fetch_add(1);
isize len = gb_snprintf(name, max_len, "csbs$%x", id);
len -= 1;
}
LLVMTypeRef type = LLVMTypeOf(data);
LLVMValueRef global_data = LLVMAddGlobal(m->mod, type, name);
LLVMSetInitializer(global_data, data);
LLVMSetLinkage(global_data, LLVMPrivateLinkage);
LLVMSetUnnamedAddress(global_data, LLVMGlobalUnnamedAddr);
LLVMSetAlignment(global_data, 1);
LLVMSetGlobalConstant(global_data, true);
i64 data_len = str.len;
LLVMValueRef ptr = nullptr;
if (data_len != 0) {
ptr = LLVMConstInBoundsGEP2(type, global_data, indices, 2);
} else {
ptr = LLVMConstNull(lb_type(m, t_u8_ptr));
}
if (!is_type_u8_slice(slice_type)) {
Type *bt = base_type(slice_type);
Type *elem = bt->Slice.elem;
i64 sz = type_size_of(elem);
GB_ASSERT(sz > 0);
ptr = LLVMConstPointerCast(ptr, lb_type(m, alloc_type_pointer(elem)));
data_len /= sz;
}
LLVMValueRef len = LLVMConstInt(lb_type(m, t_int), data_len, true);
LLVMValueRef values[2] = {ptr, len};
lbValue res = {};
res.value = llvm_const_named_struct(m, slice_type, values, 2);
res.type = slice_type;
return res;
}
lbValue lb_find_ident(lbProcedure *p, lbModule *m, Entity *e, Ast *expr) {
src/llvm_backend_opt.cpp
+3 -1
View File
@@ -62,7 +62,9 @@ void lb_basic_populate_function_pass_manager(LLVMPassManagerRef fpm, i32 optimiz
LLVMAddPromoteMemoryToRegisterPass(fpm);
LLVMAddMergedLoadStoreMotionPass(fpm);
LLVM_ADD_CONSTANT_VALUE_PASS(fpm);
LLVMAddEarlyCSEPass(fpm);
if (!build_context.ODIN_DEBUG) {
LLVMAddEarlyCSEPass(fpm);
}
}
}
src/llvm_backend_proc.cpp
+148 -167
View File
@@ -1,3 +1,13 @@
LLVMValueRef lb_call_intrinsic(lbProcedure *p, const char *name, LLVMValueRef* args, unsigned arg_count, LLVMTypeRef* types, unsigned type_count)
{
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, type_count);
LLVMTypeRef call_type = LLVMIntrinsicGetType(p->module->ctx, id, types, type_count);
return LLVMBuildCall2(p->builder, call_type, ip, args, arg_count, "");
}
void lb_mem_copy_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile) {
dst = lb_emit_conv(p, dst, t_rawptr);
src = lb_emit_conv(p, src, t_rawptr);
@@ -10,23 +20,23 @@ void lb_mem_copy_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue l
name = "llvm.memmove.inline";
}
}
LLVMTypeRef types[3] = {
lb_type(p->module, t_rawptr),
lb_type(p->module, t_rawptr),
lb_type(p->module, t_int)
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s.%s.%s", name, LLVMPrintTypeToString(types[0]), LLVMPrintTypeToString(types[1]), LLVMPrintTypeToString(types[2]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[4] = {
dst.value,
src.value,
len.value,
LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile)
};
LLVMValueRef args[4] = {};
args[0] = dst.value;
args[1] = src.value;
args[2] = len.value;
args[3] = LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile);
LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
}
void lb_mem_copy_non_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbValue len, bool is_volatile) {
dst = lb_emit_conv(p, dst, t_rawptr);
src = lb_emit_conv(p, src, t_rawptr);
@@ -45,16 +55,14 @@ void lb_mem_copy_non_overlapping(lbProcedure *p, lbValue dst, lbValue src, lbVal
lb_type(p->module, t_rawptr),
lb_type(p->module, t_int)
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s.%s.%s", name, LLVMPrintTypeToString(types[0]), LLVMPrintTypeToString(types[1]), LLVMPrintTypeToString(types[2]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[4] = {};
args[0] = dst.value;
args[1] = src.value;
args[2] = len.value;
args[3] = LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile);
LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
LLVMValueRef args[4] = {
dst.value,
src.value,
len.value,
LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), 0, is_volatile) };
lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
}
@@ -121,8 +129,7 @@ lbProcedure *lb_create_procedure(lbModule *m, Entity *entity, bool ignore_body)
}
char *c_link_name = alloc_cstring(permanent_allocator(), p->name);
LLVMTypeRef func_ptr_type = lb_type(m, p->type);
LLVMTypeRef func_type = LLVMGetElementType(func_ptr_type);
LLVMTypeRef func_type = lb_get_procedure_raw_type(m, p->type);
p->value = LLVMAddFunction(m->mod, c_link_name, func_type);
@@ -141,34 +148,30 @@ lbProcedure *lb_create_procedure(lbModule *m, Entity *entity, bool ignore_body)
lb_add_attribute_to_proc(m, p->value, "noredzone");
}
if (build_context.optimization_level == 0 && build_context.ODIN_DEBUG) {
lb_add_attribute_to_proc(m, p->value, "noinline");
lb_add_attribute_to_proc(m, p->value, "optnone");
} else {
switch (p->inlining) {
case ProcInlining_inline:
lb_add_attribute_to_proc(m, p->value, "alwaysinline");
break;
case ProcInlining_no_inline:
lb_add_attribute_to_proc(m, p->value, "noinline");
break;
}
switch (entity->Procedure.optimization_mode) {
case ProcedureOptimizationMode_None:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Minimal:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Size:
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
case ProcedureOptimizationMode_Speed:
// TODO(bill): handle this correctly
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
}
switch (p->inlining) {
case ProcInlining_inline:
lb_add_attribute_to_proc(m, p->value, "alwaysinline");
break;
case ProcInlining_no_inline:
lb_add_attribute_to_proc(m, p->value, "noinline");
break;
}
switch (entity->Procedure.optimization_mode) {
case ProcedureOptimizationMode_None:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Minimal:
lb_add_attribute_to_proc(m, p->value, "optnone");
break;
case ProcedureOptimizationMode_Size:
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
case ProcedureOptimizationMode_Speed:
// TODO(bill): handle this correctly
lb_add_attribute_to_proc(m, p->value, "optsize");
break;
}
if (!entity->Procedure.target_feature_disabled &&
@@ -346,8 +349,7 @@ lbProcedure *lb_create_dummy_procedure(lbModule *m, String link_name, Type *type
char *c_link_name = alloc_cstring(permanent_allocator(), p->name);
LLVMTypeRef func_ptr_type = lb_type(m, p->type);
LLVMTypeRef func_type = LLVMGetElementType(func_ptr_type);
LLVMTypeRef func_type = lb_get_procedure_raw_type(m, p->type);
p->value = LLVMAddFunction(m->mod, c_link_name, func_type);
@@ -745,12 +747,12 @@ lbValue lb_emit_call_internal(lbProcedure *p, lbValue value, lbValue return_ptr,
GB_ASSERT(curr_block != p->decl_block->block);
{
LLVMTypeRef ftp = lb_type(p->module, value.type);
LLVMTypeRef fnp = lb_type_internal_for_procedures_raw(p->module, value.type);
LLVMTypeRef ftp = LLVMPointerType(fnp, 0);
LLVMValueRef fn = value.value;
if (!lb_is_type_kind(LLVMTypeOf(value.value), LLVMFunctionTypeKind)) {
fn = LLVMBuildPointerCast(p->builder, fn, ftp, "");
}
LLVMTypeRef fnp = LLVMGetElementType(LLVMTypeOf(fn));
GB_ASSERT_MSG(lb_is_type_kind(fnp, LLVMFunctionTypeKind), "%s", LLVMPrintTypeToString(fnp));
{
@@ -1264,13 +1266,8 @@ lbValue lb_build_builtin_simd_proc(lbProcedure *p, Ast *expr, TypeAndValue const
}
args[args_count++] = arg0.value;
LLVMTypeRef types[1] = {lb_type(p->module, arg0.type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
res.value = LLVMBuildCall(p->builder, ip, args, cast(unsigned)args_count, "");
res.value = lb_call_intrinsic(p, name, args, cast(unsigned)args_count, types, gb_count_of(types));
return res;
}
case BuiltinProc_simd_reduce_min:
@@ -1303,15 +1300,11 @@ lbValue lb_build_builtin_simd_proc(lbProcedure *p, Ast *expr, TypeAndValue const
case BuiltinProc_simd_reduce_or: name = "llvm.vector.reduce.or"; break;
case BuiltinProc_simd_reduce_xor: name = "llvm.vector.reduce.xor"; break;
}
LLVMTypeRef types[1] = {lb_type(p->module, arg0.type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = arg0.value;
LLVMTypeRef types[1] = { lb_type(p->module, arg0.type) };
LLVMValueRef args[1] = { arg0.value };
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -1360,15 +1353,10 @@ lbValue lb_build_builtin_simd_proc(lbProcedure *p, Ast *expr, TypeAndValue const
case BuiltinProc_simd_nearest: name = "llvm.nearbyint"; break;
}
LLVMTypeRef types[1] = {lb_type(p->module, arg0.type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMTypeRef types[1] = { lb_type(p->module, arg0.type) };
LLVMValueRef args[1] = { arg0.value };
LLVMValueRef args[1] = {};
args[0] = arg0.value;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -1432,15 +1420,10 @@ lbValue lb_build_builtin_simd_proc(lbProcedure *p, Ast *expr, TypeAndValue const
}
LLVMTypeRef types[1] = {lb_type(p->module, arg0.type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = arg0.value;
args[1] = arg1.value;
LLVMValueRef args[2] = { arg0.value, arg1.value };
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -1851,6 +1834,11 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
return lb_emit_matrix_flatten(p, m, tv.type);
}
case BuiltinProc_unreachable:
lb_emit_unreachable(p);
return {};
// "Intrinsics"
case BuiltinProc_alloca:
@@ -1898,11 +1886,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
case BuiltinProc_trap: name = "llvm.trap"; break;
}
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0);
LLVMBuildCall(p->builder, ip, nullptr, 0, "");
lb_call_intrinsic(p, name, nullptr, 0, nullptr, 0);
if (id == BuiltinProc_trap) {
LLVMBuildUnreachable(p->builder);
}
@@ -1922,11 +1906,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
res.value = LLVMBuildCall2(p->builder, func_type, the_asm, nullptr, 0, "");
} else {
char const *name = "llvm.readcyclecounter";
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0);
res.value = LLVMBuildCall(p->builder, ip, nullptr, 0, "");
res.value = lb_call_intrinsic(p, name, nullptr, 0, nullptr, 0);
}
return res;
}
@@ -1981,16 +1961,11 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
}
}
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = y.value;
LLVMValueRef args[2] = { x.value, y.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
if (is_type_tuple(main_type)) {
Type *res_type = nullptr;
@@ -2017,15 +1992,11 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
char const *name = "llvm.sqrt";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = x.value;
LLVMValueRef args[1] = { x.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -2040,17 +2011,11 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
char const *name = "llvm.fma";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[3] = {};
args[0] = x.value;
args[1] = y.value;
args[2] = z.value;
LLVMValueRef args[3] = { x.value, y.value, z.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -2102,15 +2067,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
lbValue ptr = lb_build_expr(p, ce->args[0]);
lbValue len = lb_build_expr(p, ce->args[1]);
len = lb_emit_conv(p, len, t_int);
LLVMValueRef indices[1] = {
len.value,
};
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildGEP(p->builder, ptr.value, indices, gb_count_of(indices), "");
return res;
return lb_emit_ptr_offset(p, ptr, len);
}
case BuiltinProc_ptr_sub:
{
@@ -2118,7 +2075,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
lbValue ptr1 = lb_build_expr(p, ce->args[1]);
LLVMTypeRef type_int = lb_type(p->module, t_int);
LLVMValueRef diff = LLVMBuildPtrDiff(p->builder, ptr0.value, ptr1.value, "");
LLVMValueRef diff = LLVMBuildPtrDiff2(p->builder, lb_type(p->module, ptr0.type), ptr0.value, ptr1.value, "");
diff = LLVMBuildIntCast2(p->builder, diff, type_int, /*signed*/true, "");
lbValue res = {};
@@ -2169,7 +2126,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
case BuiltinProc_atomic_load_explicit: {
lbValue dst = lb_build_expr(p, ce->args[0]);
LLVMValueRef instr = LLVMBuildLoad(p->builder, dst.value, "");
LLVMValueRef instr = LLVMBuildLoad2(p->builder, lb_type(p->module, type_deref(dst.type)), dst.value, "");
switch (id) {
case BuiltinProc_non_temporal_load:
{
@@ -2343,18 +2300,14 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
GB_ASSERT(name != nullptr);
LLVMTypeRef types[1] = {lb_type(p->module, platform_type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
lbValue res = {};
LLVMValueRef args[3] = {};
args[0] = x.value;
args[1] = y.value;
args[2] = scale.value;
LLVMValueRef args[3] = {
x.value,
y.value,
scale.value };
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = platform_type;
return lb_emit_conv(p, res, tv.type);
}
@@ -2368,17 +2321,10 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
char const *name = "llvm.expect";
LLVMTypeRef types[1] = {lb_type(p->module, t)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
lbValue res = {};
LLVMValueRef args[2] = { x.value, y.value };
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = y.value;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = t;
return lb_emit_conv(p, res, t);
}
@@ -2414,9 +2360,6 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
char const *name = "llvm.prefetch";
LLVMTypeRef types[1] = {lb_type(p->module, t_rawptr)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMTypeRef llvm_i32 = lb_type(p->module, t_i32);
LLVMValueRef args[4] = {};
@@ -2426,7 +2369,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
args[3] = LLVMConstInt(llvm_i32, cache, false);
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = nullptr;
return res;
}
@@ -2672,7 +2615,8 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
isize len = gb_snprintf(name, max_len, "csbs$%x", id);
len -= 1;
}
LLVMValueRef global_data = LLVMAddGlobal(m->mod, LLVMTypeOf(array), name);
LLVMTypeRef type = LLVMTypeOf(array);
LLVMValueRef global_data = LLVMAddGlobal(m->mod, type, name);
LLVMSetInitializer(global_data, array);
LLVMSetLinkage(global_data, LLVMInternalLinkage);
@@ -2684,7 +2628,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
};
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildInBoundsGEP(p->builder, global_data, indices, gb_count_of(indices), "");
res.value = LLVMBuildInBoundsGEP2(p->builder, type, global_data, indices, gb_count_of(indices), "");
return res;
}
@@ -2695,9 +2639,6 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
LLVMTypeRef types[1] = {
lb_type(p->module, t_uintptr),
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t_uintptr).value;
@@ -2705,7 +2646,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
case BuiltinProc_wasm_memory_size:
@@ -2714,16 +2655,13 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
LLVMTypeRef types[1] = {
lb_type(p->module, t_uintptr),
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t_uintptr).value;
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -2733,9 +2671,6 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
LLVMTypeRef types[1] = {
lb_type(p->module, t_u32),
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0); // types, gb_count_of(types));
Type *t_u32_ptr = alloc_type_pointer(t_u32);
@@ -2746,7 +2681,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -2756,19 +2691,16 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
LLVMTypeRef types[1] = {
lb_type(p->module, t_u32),
};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, nullptr, 0); // types, gb_count_of(types));
Type *t_u32_ptr = alloc_type_pointer(t_u32);
LLVMValueRef args[2] = {};
args[0] = lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t_u32_ptr).value;
args[1] = lb_emit_conv(p, lb_build_expr(p, ce->args[1]), t_u32).value;
LLVMValueRef args[2] = {
lb_emit_conv(p, lb_build_expr(p, ce->args[0]), t_u32_ptr).value,
lb_emit_conv(p, lb_build_expr(p, ce->args[1]), t_u32).value };
lbValue res = {};
res.type = tv.type;
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
return res;
}
@@ -2777,7 +2709,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
{
Type *param_types[2] = {t_u32, t_u32};
Type *type = alloc_type_proc_from_types(param_types, gb_count_of(param_types), tv.type, false, ProcCC_None);
LLVMTypeRef func_type = LLVMGetElementType(lb_type(p->module, type));
LLVMTypeRef func_type = lb_get_procedure_raw_type(p->module, type);
LLVMValueRef the_asm = llvm_get_inline_asm(
func_type,
str_lit("cpuid"),
@@ -2797,7 +2729,7 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
case BuiltinProc_x86_xgetbv:
{
Type *type = alloc_type_proc_from_types(&t_u32, 1, tv.type, false, ProcCC_None);
LLVMTypeRef func_type = LLVMGetElementType(lb_type(p->module, type));
LLVMTypeRef func_type = lb_get_procedure_raw_type(p->module, type);
LLVMValueRef the_asm = llvm_get_inline_asm(
func_type,
str_lit("xgetbv"),
@@ -2813,6 +2745,55 @@ lbValue lb_build_builtin_proc(lbProcedure *p, Ast *expr, TypeAndValue const &tv,
res.value = LLVMBuildCall2(p->builder, func_type, the_asm, args, gb_count_of(args), "");
return res;
}
case BuiltinProc_valgrind_client_request:
{
lbValue args[7] = {};
for (isize i = 0; i < 7; i++) {
args[i] = lb_emit_conv(p, lb_build_expr(p, ce->args[i]), t_uintptr);
}
if (!build_context.ODIN_VALGRIND_SUPPORT) {
return args[0];
}
lbValue array = lb_generate_local_array(p, t_uintptr, 6, false);
for (isize i = 0; i < 6; i++) {
lbValue gep = lb_emit_array_epi(p, array, i);
lb_emit_store(p, gep, args[i+1]);
}
switch (build_context.metrics.arch) {
case TargetArch_amd64:
{
Type *param_types[2] = {};
param_types[0] = t_uintptr;
param_types[1] = array.type;
Type *type = alloc_type_proc_from_types(param_types, gb_count_of(param_types), t_uintptr, false, ProcCC_None);
LLVMTypeRef func_type = lb_get_procedure_raw_type(p->module, type);
LLVMValueRef the_asm = llvm_get_inline_asm(
func_type,
str_lit("rolq $3, %rdi; rolq $13, %rdi\n rolq $61, %rdi; rolq $51, %rdi\n xchgq %rbx, %rbx"),
str_lit("={rdx},{rdx},{rax},cc,memory"),
true
);
LLVMValueRef asm_args[2] = {};
asm_args[0] = args[0].value;
asm_args[1] = array.value;
lbValue res = {};
res.type = t_uintptr;
res.value = LLVMBuildCall2(p->builder, func_type, the_asm, asm_args, gb_count_of(asm_args), "");
return res;
}
break;
default:
GB_PANIC("Unsupported architecture: %.*s", LIT(target_arch_names[build_context.metrics.arch]));
break;
}
}
}
GB_PANIC("Unhandled built-in procedure %.*s", LIT(builtin_procs[id].name));
src/llvm_backend_stmt.cpp
+15 -12
View File
@@ -458,15 +458,6 @@ void lb_build_range_interval(lbProcedure *p, AstBinaryExpr *node,
val1_type = type_of_expr(rs->vals[1]);
}
if (val0_type != nullptr) {
Entity *e = entity_of_node(rs->vals[0]);
lb_add_local(p, e->type, e, true);
}
if (val1_type != nullptr) {
Entity *e = entity_of_node(rs->vals[1]);
lb_add_local(p, e->type, e, true);
}
TokenKind op = Token_Lt;
switch (node->op.kind) {
case Token_Ellipsis: op = Token_LtEq; break;
@@ -478,10 +469,22 @@ void lb_build_range_interval(lbProcedure *p, AstBinaryExpr *node,
lbValue lower = lb_build_expr(p, node->left);
lbValue upper = {}; // initialized each time in the loop
lbAddr value = lb_add_local_generated(p, val0_type ? val0_type : lower.type, false);
lbAddr value;
if (val0_type != nullptr) {
Entity *e = entity_of_node(rs->vals[0]);
value = lb_add_local(p, val0_type, e, false);
} else {
value = lb_add_local_generated(p, lower.type, false);
}
lb_addr_store(p, value, lower);
lbAddr index = lb_add_local_generated(p, t_int, false);
lbAddr index;
if (val1_type != nullptr) {
Entity *e = entity_of_node(rs->vals[1]);
index = lb_add_local(p, val1_type, e, false);
} else {
index = lb_add_local_generated(p, t_int, false);
}
lb_addr_store(p, index, lb_const_int(m, t_int, 0));
lbBlock *loop = lb_create_block(p, "for.interval.loop");
@@ -1793,7 +1796,7 @@ void lb_build_assign_stmt_array(lbProcedure *p, TokenKind op, lbAddr const &lhs,
lbValue rhs = lb_emit_conv(p, value, lhs_type);
bool inline_array_arith = type_size_of(array_type) <= build_context.max_align;
bool inline_array_arith = lb_can_try_to_inline_array_arith(array_type);
if (lhs.kind == lbAddr_Swizzle) {
src/llvm_backend_type.cpp
+44 -51
View File
@@ -57,6 +57,7 @@ lbValue lb_typeid(lbModule *m, Type *type) {
case Type_SimdVector: kind = Typeid_Simd_Vector; break;
case Type_RelativePointer: kind = Typeid_Relative_Pointer; break;
case Type_RelativeSlice: kind = Typeid_Relative_Slice; break;
case Type_SoaPointer: kind = Typeid_SoaPointer; break;
}
if (is_type_cstring(type)) {
@@ -97,34 +98,12 @@ lbValue lb_type_info(lbModule *m, Type *type) {
isize index = lb_type_info_index(m->info, type);
GB_ASSERT(index >= 0);
LLVMTypeRef it = lb_type(m, t_int);
LLVMValueRef indices[2] = {
LLVMConstInt(it, 0, false),
LLVMConstInt(it, index, true),
};
lbValue value = {};
value.value = LLVMConstGEP(lb_global_type_info_data_ptr(m).value, indices, gb_count_of(indices));
value.type = t_type_info_ptr;
return value;
lbValue data = lb_global_type_info_data_ptr(m);
return lb_emit_array_epi(m, data, index);
}
lbValue lb_get_type_info_ptr(lbModule *m, Type *type) {
GB_ASSERT(!build_context.disallow_rtti);
i32 index = cast(i32)lb_type_info_index(m->info, type);
GB_ASSERT(index >= 0);
// gb_printf_err("%d %s\n", index, type_to_string(type));
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(m, t_int), 0, false),
LLVMConstInt(lb_type(m, t_int), index, false),
};
lbValue res = {};
res.type = t_type_info_ptr;
res.value = LLVMConstGEP(lb_global_type_info_data_ptr(m).value, indices, cast(unsigned)gb_count_of(indices));
return res;
LLVMTypeRef lb_get_procedure_raw_type(lbModule *m, Type *type) {
return lb_type_internal_for_procedures_raw(m, type);
}
@@ -178,10 +157,10 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
LLVMValueRef indices[2] = {llvm_zero(m), llvm_zero(m)};
LLVMValueRef values[2] = {
LLVMConstInBoundsGEP(lb_global_type_info_data_ptr(m).value, indices, gb_count_of(indices)),
LLVMConstInBoundsGEP2(lb_type(m, lb_global_type_info_data_entity->type), lb_global_type_info_data_ptr(m).value, indices, gb_count_of(indices)),
LLVMConstInt(lb_type(m, t_int), type->Array.count, true),
};
LLVMValueRef slice = llvm_const_named_struct_internal(llvm_addr_type(global_type_table), values, gb_count_of(values));
LLVMValueRef slice = llvm_const_named_struct_internal(lb_type(m, type_deref(global_type_table.type)), values, gb_count_of(values));
LLVMSetInitializer(global_type_table.value, slice);
}
@@ -260,7 +239,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
LLVMValueRef vals[4] = {
lb_const_string(p->module, t->Named.type_name->token.string).value,
lb_get_type_info_ptr(m, t->Named.base).value,
lb_type_info(m, t->Named.base).value,
pkg_name,
loc.value
};
@@ -419,7 +398,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
case Type_Pointer: {
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_pointer_ptr);
lbValue gep = lb_get_type_info_ptr(m, t->Pointer.elem);
lbValue gep = lb_type_info(m, t->Pointer.elem);
LLVMValueRef vals[1] = {
gep.value,
@@ -433,7 +412,21 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
}
case Type_MultiPointer: {
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_multi_pointer_ptr);
lbValue gep = lb_get_type_info_ptr(m, t->MultiPointer.elem);
lbValue gep = lb_type_info(m, t->MultiPointer.elem);
LLVMValueRef vals[1] = {
gep.value,
};
lbValue res = {};
res.type = type_deref(tag.type);
res.value = llvm_const_named_struct(m, res.type, vals, gb_count_of(vals));
lb_emit_store(p, tag, res);
break;
}
case Type_SoaPointer: {
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_soa_pointer_ptr);
lbValue gep = lb_type_info(m, t->SoaPointer.elem);
LLVMValueRef vals[1] = {
gep.value,
@@ -450,7 +443,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
i64 ez = type_size_of(t->Array.elem);
LLVMValueRef vals[3] = {
lb_get_type_info_ptr(m, t->Array.elem).value,
lb_type_info(m, t->Array.elem).value,
lb_const_int(m, t_int, ez).value,
lb_const_int(m, t_int, t->Array.count).value,
};
@@ -465,8 +458,8 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_enumerated_array_ptr);
LLVMValueRef vals[7] = {
lb_get_type_info_ptr(m, t->EnumeratedArray.elem).value,
lb_get_type_info_ptr(m, t->EnumeratedArray.index).value,
lb_type_info(m, t->EnumeratedArray.elem).value,
lb_type_info(m, t->EnumeratedArray.index).value,
lb_const_int(m, t_int, type_size_of(t->EnumeratedArray.elem)).value,
lb_const_int(m, t_int, t->EnumeratedArray.count).value,
@@ -497,7 +490,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_dynamic_array_ptr);
LLVMValueRef vals[2] = {
lb_get_type_info_ptr(m, t->DynamicArray.elem).value,
lb_type_info(m, t->DynamicArray.elem).value,
lb_const_int(m, t_int, type_size_of(t->DynamicArray.elem)).value,
};
@@ -511,7 +504,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_slice_ptr);
LLVMValueRef vals[2] = {
lb_get_type_info_ptr(m, t->Slice.elem).value,
lb_type_info(m, t->Slice.elem).value,
lb_const_int(m, t_int, type_size_of(t->Slice.elem)).value,
};
@@ -527,10 +520,10 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
LLVMValueRef params = LLVMConstNull(lb_type(m, t_type_info_ptr));
LLVMValueRef results = LLVMConstNull(lb_type(m, t_type_info_ptr));
if (t->Proc.params != nullptr) {
params = lb_get_type_info_ptr(m, t->Proc.params).value;
params = lb_type_info(m, t->Proc.params).value;
}
if (t->Proc.results != nullptr) {
results = lb_get_type_info_ptr(m, t->Proc.results).value;
results = lb_type_info(m, t->Proc.results).value;
}
LLVMValueRef vals[4] = {
@@ -649,7 +642,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
// NOTE(bill): Zeroth is nil so ignore it
for (isize variant_index = 0; variant_index < variant_count; variant_index++) {
Type *vt = t->Union.variants[variant_index];
lbValue tip = lb_get_type_info_ptr(m, vt);
lbValue tip = lb_type_info(m, vt);
lbValue index = lb_const_int(m, t_int, variant_index);
lbValue type_info = lb_emit_ptr_offset(p, memory_types, index);
@@ -737,7 +730,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
for (isize source_index = 0; source_index < count; source_index++) {
// TODO(bill): Order fields in source order not layout order
Entity *f = t->Struct.fields[source_index];
lbValue tip = lb_get_type_info_ptr(m, f->type);
lbValue tip = lb_type_info(m, f->type);
i64 foffset = 0;
if (!t->Struct.is_raw_union) {
GB_ASSERT(t->Struct.offsets != nullptr);
@@ -794,11 +787,11 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_map_ptr);
init_map_internal_types(t);
lbValue gst = lb_get_type_info_ptr(m, t->Map.generated_struct_type);
lbValue gst = lb_type_info(m, t->Map.generated_struct_type);
LLVMValueRef vals[5] = {
lb_get_type_info_ptr(m, t->Map.key).value,
lb_get_type_info_ptr(m, t->Map.value).value,
lb_type_info(m, t->Map.key).value,
lb_type_info(m, t->Map.value).value,
gst.value,
lb_get_equal_proc_for_type(m, t->Map.key).value,
lb_get_hasher_proc_for_type(m, t->Map.key).value
@@ -819,13 +812,13 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
LLVMValueRef vals[4] = {
lb_get_type_info_ptr(m, t->BitSet.elem).value,
lb_type_info(m, t->BitSet.elem).value,
LLVMConstNull(lb_type(m, t_type_info_ptr)),
lb_const_int(m, t_i64, t->BitSet.lower).value,
lb_const_int(m, t_i64, t->BitSet.upper).value,
};
if (t->BitSet.underlying != nullptr) {
vals[1] =lb_get_type_info_ptr(m, t->BitSet.underlying).value;
vals[1] =lb_type_info(m, t->BitSet.underlying).value;
}
lbValue res = {};
@@ -841,7 +834,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
LLVMValueRef vals[3] = {};
vals[0] = lb_get_type_info_ptr(m, t->SimdVector.elem).value;
vals[0] = lb_type_info(m, t->SimdVector.elem).value;
vals[1] = lb_const_int(m, t_int, type_size_of(t->SimdVector.elem)).value;
vals[2] = lb_const_int(m, t_int, t->SimdVector.count).value;
@@ -856,8 +849,8 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
{
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_relative_pointer_ptr);
LLVMValueRef vals[2] = {
lb_get_type_info_ptr(m, t->RelativePointer.pointer_type).value,
lb_get_type_info_ptr(m, t->RelativePointer.base_integer).value,
lb_type_info(m, t->RelativePointer.pointer_type).value,
lb_type_info(m, t->RelativePointer.base_integer).value,
};
lbValue res = {};
@@ -870,8 +863,8 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
{
tag = lb_const_ptr_cast(m, variant_ptr, t_type_info_relative_slice_ptr);
LLVMValueRef vals[2] = {
lb_get_type_info_ptr(m, t->RelativeSlice.slice_type).value,
lb_get_type_info_ptr(m, t->RelativeSlice.base_integer).value,
lb_type_info(m, t->RelativeSlice.slice_type).value,
lb_type_info(m, t->RelativeSlice.base_integer).value,
};
lbValue res = {};
@@ -886,7 +879,7 @@ void lb_setup_type_info_data(lbProcedure *p) { // NOTE(bill): Setup type_info da
i64 ez = type_size_of(t->Matrix.elem);
LLVMValueRef vals[5] = {
lb_get_type_info_ptr(m, t->Matrix.elem).value,
lb_type_info(m, t->Matrix.elem).value,
lb_const_int(m, t_int, ez).value,
lb_const_int(m, t_int, matrix_type_stride_in_elems(t)).value,
lb_const_int(m, t_int, t->Matrix.row_count).value,
src/llvm_backend_utility.cpp
+150 -176
View File
@@ -39,6 +39,13 @@ bool lb_is_type_aggregate(Type *t) {
return false;
}
void lb_emit_unreachable(lbProcedure *p) {
LLVMValueRef instr = LLVMGetLastInstruction(p->curr_block->block);
if (instr == nullptr || !lb_is_instr_terminating(instr)) {
lb_call_intrinsic(p, "llvm.trap", nullptr, 0, nullptr, 0);
LLVMBuildUnreachable(p->builder);
}
}
lbValue lb_correct_endianness(lbProcedure *p, lbValue value) {
Type *src = core_type(value.type);
@@ -73,9 +80,6 @@ LLVMValueRef lb_mem_zero_ptr_internal(lbProcedure *p, LLVMValueRef ptr, LLVMValu
lb_type(p->module, t_int)
};
if (true || is_inlinable) {
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s.%s", name, LLVMPrintTypeToString(types[0]), LLVMPrintTypeToString(types[1]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[4] = {};
args[0] = LLVMBuildPointerCast(p->builder, ptr, types[0], "");
@@ -83,16 +87,18 @@ LLVMValueRef lb_mem_zero_ptr_internal(lbProcedure *p, LLVMValueRef ptr, LLVMValu
args[2] = LLVMBuildIntCast2(p->builder, len, types[1], /*signed*/false, "");
args[3] = LLVMConstInt(LLVMInt1TypeInContext(p->module->ctx), is_volatile, false);
return LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
return lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
} else {
LLVMValueRef ip = lb_lookup_runtime_procedure(p->module, str_lit("memset")).value;
lbValue pr = lb_lookup_runtime_procedure(p->module, str_lit("memset"));
LLVMValueRef args[3] = {};
args[0] = LLVMBuildPointerCast(p->builder, ptr, types[0], "");
args[1] = LLVMConstInt(LLVMInt32TypeInContext(p->module->ctx), 0, false);
args[2] = LLVMBuildIntCast2(p->builder, len, types[1], /*signed*/false, "");
return LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
// We always get the function pointer type rather than the function and there is apparently no way around that?
LLVMTypeRef type = lb_type_internal_for_procedures_raw(p->module, pr.type);
return LLVMBuildCall2(p->builder, type, pr.value, args, gb_count_of(args), "");
}
}
@@ -346,44 +352,65 @@ lbValue lb_emit_try_has_value(lbProcedure *p, lbValue rhs) {
lbValue lb_emit_or_else(lbProcedure *p, Ast *arg, Ast *else_expr, TypeAndValue const &tv) {
if (arg->state_flags & StateFlag_DirectiveWasFalse) {
return lb_build_expr(p, else_expr);
}
lbValue lhs = {};
lbValue rhs = {};
lb_emit_try_lhs_rhs(p, arg, tv, &lhs, &rhs);
LLVMValueRef incoming_values[2] = {};
LLVMBasicBlockRef incoming_blocks[2] = {};
GB_ASSERT(else_expr != nullptr);
lbBlock *then = lb_create_block(p, "or_else.then");
lbBlock *done = lb_create_block(p, "or_else.done"); // NOTE(bill): Append later
lbBlock *else_ = lb_create_block(p, "or_else.else");
lb_emit_if(p, lb_emit_try_has_value(p, rhs), then, else_);
lb_start_block(p, then);
Type *type = default_type(tv.type);
incoming_values[0] = lb_emit_conv(p, lhs, type).value;
if (is_diverging_expr(else_expr)) {
lbBlock *then = lb_create_block(p, "or_else.then");
lbBlock *else_ = lb_create_block(p, "or_else.else");
lb_emit_jump(p, done);
lb_start_block(p, else_);
lb_emit_if(p, lb_emit_try_has_value(p, rhs), then, else_);
// NOTE(bill): else block needs to be straight afterwards to make sure that the actual value is used
// from the then block
lb_start_block(p, else_);
incoming_values[1] = lb_emit_conv(p, lb_build_expr(p, else_expr), type).value;
lb_build_expr(p, else_expr);
lb_emit_unreachable(p); // add just in case
lb_emit_jump(p, done);
lb_start_block(p, done);
lb_start_block(p, then);
return lb_emit_conv(p, lhs, type);
} else {
LLVMValueRef incoming_values[2] = {};
LLVMBasicBlockRef incoming_blocks[2] = {};
lbValue res = {};
res.value = LLVMBuildPhi(p->builder, lb_type(p->module, type), "");
res.type = type;
lbBlock *then = lb_create_block(p, "or_else.then");
lbBlock *done = lb_create_block(p, "or_else.done"); // NOTE(bill): Append later
lbBlock *else_ = lb_create_block(p, "or_else.else");
GB_ASSERT(p->curr_block->preds.count >= 2);
incoming_blocks[0] = p->curr_block->preds[0]->block;
incoming_blocks[1] = p->curr_block->preds[1]->block;
lb_emit_if(p, lb_emit_try_has_value(p, rhs), then, else_);
lb_start_block(p, then);
LLVMAddIncoming(res.value, incoming_values, incoming_blocks, 2);
incoming_values[0] = lb_emit_conv(p, lhs, type).value;
return res;
lb_emit_jump(p, done);
lb_start_block(p, else_);
incoming_values[1] = lb_emit_conv(p, lb_build_expr(p, else_expr), type).value;
lb_emit_jump(p, done);
lb_start_block(p, done);
lbValue res = {};
res.value = LLVMBuildPhi(p->builder, lb_type(p->module, type), "");
res.type = type;
GB_ASSERT(p->curr_block->preds.count >= 2);
incoming_blocks[0] = p->curr_block->preds[0]->block;
incoming_blocks[1] = p->curr_block->preds[1]->block;
LLVMAddIncoming(res.value, incoming_values, incoming_blocks, 2);
return res;
}
}
void lb_build_return_stmt(lbProcedure *p, Slice<Ast *> const &return_results);
@@ -460,15 +487,11 @@ lbValue lb_emit_byte_swap(lbProcedure *p, lbValue value, Type *end_type) {
char const *name = "llvm.bswap";
LLVMTypeRef types[1] = {lb_type(p->module, value.type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = value.value;
LLVMValueRef args[1] = { value.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = value.type;
if (is_type_float(original_type)) {
@@ -486,15 +509,10 @@ lbValue lb_emit_count_ones(lbProcedure *p, lbValue x, Type *type) {
char const *name = "llvm.ctpop";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = x.value;
LLVMValueRef args[1] = { x.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -515,16 +533,13 @@ lbValue lb_emit_count_trailing_zeros(lbProcedure *p, lbValue x, Type *type) {
char const *name = "llvm.cttz";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = LLVMConstNull(LLVMInt1TypeInContext(p->module->ctx));
LLVMValueRef args[2] = {
x.value,
LLVMConstNull(LLVMInt1TypeInContext(p->module->ctx)) };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -534,16 +549,13 @@ lbValue lb_emit_count_leading_zeros(lbProcedure *p, lbValue x, Type *type) {
char const *name = "llvm.ctlz";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[2] = {};
args[0] = x.value;
args[1] = LLVMConstNull(LLVMInt1TypeInContext(p->module->ctx));
LLVMValueRef args[2] = {
x.value,
LLVMConstNull(LLVMInt1TypeInContext(p->module->ctx)) };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -555,15 +567,11 @@ lbValue lb_emit_reverse_bits(lbProcedure *p, lbValue x, Type *type) {
char const *name = "llvm.bitreverse";
LLVMTypeRef types[1] = {lb_type(p->module, type)};
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s.%s", name, LLVMPrintTypeToString(types[0]));
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef args[1] = {};
args[0] = x.value;
LLVMValueRef args[1] = { x.value };
lbValue res = {};
res.value = LLVMBuildCall(p->builder, ip, args, gb_count_of(args), "");
res.value = lb_call_intrinsic(p, name, args, gb_count_of(args), types, gb_count_of(types));
res.type = type;
return res;
}
@@ -984,6 +992,11 @@ lbValue lb_emit_struct_ep(lbProcedure *p, lbValue s, i32 index) {
case 0: result_type = t->RelativeSlice.base_integer; break;
case 1: result_type = t->RelativeSlice.base_integer; break;
}
} else if (is_type_soa_pointer(t)) {
switch (index) {
case 0: result_type = alloc_type_pointer(t->SoaPointer.elem); break;
case 1: result_type = t_int; break;
}
} else {
GB_PANIC("TODO(bill): struct_gep type: %s, %d", type_to_string(s.type), index);
}
@@ -994,15 +1007,16 @@ lbValue lb_emit_struct_ep(lbProcedure *p, lbValue s, i32 index) {
index = lb_convert_struct_index(p->module, t, index);
if (lb_is_const(s)) {
// NOTE(bill): this cannot be replaced with lb_emit_epi
lbModule *m = p->module;
lbValue res = {};
LLVMValueRef indices[2] = {llvm_zero(m), LLVMConstInt(lb_type(m, t_i32), index, false)};
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
res.value = LLVMConstGEP2(lb_type(m, type_deref(s.type)), s.value, indices, gb_count_of(indices));
res.type = alloc_type_pointer(result_type);
return res;
} else {
lbValue res = {};
LLVMTypeRef st = LLVMGetElementType(LLVMTypeOf(s.value));
LLVMTypeRef st = lb_type(p->module, type_deref(s.type));
// gb_printf_err("%s\n", type_to_string(s.type));
// gb_printf_err("%s\n", LLVMPrintTypeToString(LLVMTypeOf(s.value)));
// gb_printf_err("%d\n", index);
@@ -1010,7 +1024,7 @@ lbValue lb_emit_struct_ep(lbProcedure *p, lbValue s, i32 index) {
unsigned count = LLVMCountStructElementTypes(st);
GB_ASSERT_MSG(count >= cast(unsigned)index, "%u %d %d", count, index, original_index);
res.value = LLVMBuildStructGEP(p->builder, s.value, cast(unsigned)index, "");
res.value = LLVMBuildStructGEP2(p->builder, st, s.value, cast(unsigned)index, "");
res.type = alloc_type_pointer(result_type);
return res;
}
@@ -1114,6 +1128,13 @@ lbValue lb_emit_struct_ev(lbProcedure *p, lbValue s, i32 index) {
result_type = t->Array.elem;
break;
case Type_SoaPointer:
switch (index) {
case 0: result_type = alloc_type_pointer(t->SoaPointer.elem); break;
case 1: result_type = t_int; break;
}
break;
default:
GB_PANIC("TODO(bill): struct_ev type: %s, %d", type_to_string(s.type), index);
break;
@@ -1141,7 +1162,28 @@ lbValue lb_emit_deep_field_gep(lbProcedure *p, lbValue e, Selection sel) {
}
type = core_type(type);
if (is_type_quaternion(type)) {
if (type->kind == Type_SoaPointer) {
lbValue addr = lb_emit_struct_ep(p, e, 0);
lbValue index = lb_emit_struct_ep(p, e, 1);
addr = lb_emit_load(p, addr);
index = lb_emit_load(p, index);
i32 first_index = sel.index[0];
Selection sub_sel = sel;
sub_sel.index.data += 1;
sub_sel.index.count -= 1;
lbValue arr = lb_emit_struct_ep(p, addr, first_index);
Type *t = base_type(type_deref(addr.type));
GB_ASSERT(is_type_soa_struct(t));
if (t->Struct.soa_kind == StructSoa_Fixed) {
e = lb_emit_array_ep(p, arr, index);
} else {
e = lb_emit_ptr_offset(p, lb_emit_load(p, arr), index);
}
} else if (is_type_quaternion(type)) {
e = lb_emit_struct_ep(p, e, index);
} else if (is_type_raw_union(type)) {
type = get_struct_field_type(type, index);
@@ -1216,7 +1258,12 @@ lbValue lb_emit_array_ep(lbProcedure *p, lbValue s, lbValue index) {
Type *ptr = base_array_type(st);
lbValue res = {};
res.value = LLVMBuildGEP(p->builder, s.value, indices, 2, "");
if (LLVMIsConstant(s.value) && LLVMIsConstant(index.value)) {
res.value = LLVMConstGEP2(lb_type(p->module, st), s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP2(p->builder, lb_type(p->module, st), s.value, indices, gb_count_of(indices), "");
}
res.type = alloc_type_pointer(ptr);
return res;
}
@@ -1226,24 +1273,16 @@ lbValue lb_emit_array_epi(lbProcedure *p, lbValue s, isize index) {
GB_ASSERT(is_type_pointer(t));
Type *st = base_type(type_deref(t));
GB_ASSERT_MSG(is_type_array(st) || is_type_enumerated_array(st) || is_type_matrix(st), "%s", type_to_string(st));
GB_ASSERT(0 <= index);
Type *ptr = base_array_type(st);
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(p->module, t_int), 0, false),
LLVMConstInt(lb_type(p->module, t_int), cast(unsigned)index, false),
};
lbValue res = {};
if (lb_is_const(s)) {
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP(p->builder, s.value, indices, gb_count_of(indices), "");
}
res.type = alloc_type_pointer(ptr);
return res;
return lb_emit_epi(p, s, index);
}
lbValue lb_emit_array_epi(lbModule *m, lbValue s, isize index) {
Type *t = s.type;
GB_ASSERT(is_type_pointer(t));
Type *st = base_type(type_deref(t));
GB_ASSERT_MSG(is_type_array(st) || is_type_enumerated_array(st) || is_type_matrix(st), "%s", type_to_string(st));
GB_ASSERT(0 <= index);
return lb_emit_epi(m, s, index);
}
lbValue lb_emit_ptr_offset(lbProcedure *p, lbValue ptr, lbValue index) {
@@ -1251,11 +1290,12 @@ lbValue lb_emit_ptr_offset(lbProcedure *p, lbValue ptr, lbValue index) {
LLVMValueRef indices[1] = {index.value};
lbValue res = {};
res.type = ptr.type;
LLVMTypeRef type = lb_type(p->module, type_deref(res.type, true));
if (lb_is_const(ptr) && lb_is_const(index)) {
res.value = LLVMConstGEP(ptr.value, indices, 1);
res.value = LLVMConstGEP2(type, ptr.value, indices, 1);
} else {
res.value = LLVMBuildGEP(p->builder, ptr.value, indices, 1, "");
res.value = LLVMBuildGEP2(p->builder, type, ptr.value, indices, 1, "");
}
return res;
}
@@ -1264,63 +1304,18 @@ lbValue lb_emit_matrix_epi(lbProcedure *p, lbValue s, isize row, isize column) {
Type *t = s.type;
GB_ASSERT(is_type_pointer(t));
Type *mt = base_type(type_deref(t));
Type *ptr = base_array_type(mt);
if (column == 0) {
GB_ASSERT_MSG(is_type_matrix(mt) || is_type_array_like(mt), "%s", type_to_string(mt));
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(p->module, t_int), 0, false),
LLVMConstInt(lb_type(p->module, t_int), cast(unsigned)row, false),
};
lbValue res = {};
if (lb_is_const(s)) {
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP(p->builder, s.value, indices, gb_count_of(indices), "");
}
Type *ptr = base_array_type(mt);
res.type = alloc_type_pointer(ptr);
return res;
return lb_emit_epi(p, s, row);
} else if (row == 0 && is_type_array_like(mt)) {
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(p->module, t_int), 0, false),
LLVMConstInt(lb_type(p->module, t_int), cast(unsigned)column, false),
};
lbValue res = {};
if (lb_is_const(s)) {
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP(p->builder, s.value, indices, gb_count_of(indices), "");
}
Type *ptr = base_array_type(mt);
res.type = alloc_type_pointer(ptr);
return res;
return lb_emit_epi(p, s, column);
}
GB_ASSERT_MSG(is_type_matrix(mt), "%s", type_to_string(mt));
isize offset = matrix_indices_to_offset(mt, row, column);
LLVMValueRef indices[2] = {
LLVMConstInt(lb_type(p->module, t_int), 0, false),
LLVMConstInt(lb_type(p->module, t_int), cast(unsigned)offset, false),
};
lbValue res = {};
if (lb_is_const(s)) {
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP(p->builder, s.value, indices, gb_count_of(indices), "");
}
res.type = alloc_type_pointer(ptr);
return res;
return lb_emit_epi(p, s, offset);
}
lbValue lb_emit_matrix_ep(lbProcedure *p, lbValue s, lbValue row, lbValue column) {
@@ -1343,11 +1338,12 @@ lbValue lb_emit_matrix_ep(lbProcedure *p, lbValue s, lbValue row, lbValue column
index,
};
LLVMTypeRef type = lb_type(p->module, mt);
lbValue res = {};
if (lb_is_const(s)) {
res.value = LLVMConstGEP(s.value, indices, gb_count_of(indices));
res.value = LLVMConstGEP2(type, s.value, indices, gb_count_of(indices));
} else {
res.value = LLVMBuildGEP(p->builder, s.value, indices, gb_count_of(indices), "");
res.value = LLVMBuildGEP2(p->builder, type, s.value, indices, gb_count_of(indices), "");
}
res.type = alloc_type_pointer(ptr);
return res;
@@ -1551,18 +1547,12 @@ lbValue lb_emit_mul_add(lbProcedure *p, lbValue a, lbValue b, lbValue c, Type *t
if (is_possible) {
char const *name = "llvm.fma";
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMTypeRef types[1] = {};
types[0] = lb_type(m, t);
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(m->mod, id, types, gb_count_of(types));
LLVMValueRef values[3] = {};
values[0] = a.value;
values[1] = b.value;
values[2] = c.value;
LLVMValueRef call = LLVMBuildCall(p->builder, ip, values, gb_count_of(values), "");
LLVMTypeRef types[1] = { lb_type(m, t) };
LLVMValueRef values[3] = {
a.value,
b.value,
c.value };
LLVMValueRef call = lb_call_intrinsic(p, name, values, gb_count_of(values), types, gb_count_of(types));
return {call, t};
} else {
lbValue x = lb_emit_arith(p, Token_Mul, a, b, t);
@@ -1661,7 +1651,7 @@ LLVMValueRef llvm_vector_expand_to_power_of_two(lbProcedure *p, LLVMValueRef val
LLVMValueRef llvm_vector_reduce_add(lbProcedure *p, LLVMValueRef value) {
LLVMTypeRef type = LLVMTypeOf(value);
GB_ASSERT(LLVMGetTypeKind(type) == LLVMVectorTypeKind);
LLVMTypeRef elem = LLVMGetElementType(type);
LLVMTypeRef elem = OdinLLVMGetVectorElementType(type);
unsigned len = LLVMGetVectorSize(type);
if (len == 0) {
return LLVMConstNull(type);
@@ -1691,15 +1681,9 @@ LLVMValueRef llvm_vector_reduce_add(lbProcedure *p, LLVMValueRef value) {
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
if (id != 0 && false) {
LLVMTypeRef types[1] = {};
types[0] = type;
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(p->module->mod, id, types, gb_count_of(types));
LLVMValueRef values[2] = {};
values[0] = LLVMConstNull(elem);
values[1] = value;
LLVMValueRef call = LLVMBuildCall(p->builder, ip, values+value_offset, value_count, "");
return call;
LLVMTypeRef types[1] = { type };
LLVMValueRef values[2] = { LLVMConstNull(elem), value };
return lb_call_intrinsic(p, name, values + value_offset, value_count, types, gb_count_of(types));
}
// Manual reduce
@@ -1743,7 +1727,7 @@ LLVMValueRef llvm_vector_reduce_add(lbProcedure *p, LLVMValueRef value) {
LLVMValueRef llvm_vector_add(lbProcedure *p, LLVMValueRef a, LLVMValueRef b) {
GB_ASSERT(LLVMTypeOf(a) == LLVMTypeOf(b));
LLVMTypeRef elem = LLVMGetElementType(LLVMTypeOf(a));
LLVMTypeRef elem = OdinLLVMGetVectorElementType(LLVMTypeOf(a));
if (LLVMGetTypeKind(elem) == LLVMIntegerTypeKind) {
return LLVMBuildAdd(p->builder, a, b, "");
@@ -1754,7 +1738,7 @@ LLVMValueRef llvm_vector_add(lbProcedure *p, LLVMValueRef a, LLVMValueRef b) {
LLVMValueRef llvm_vector_mul(lbProcedure *p, LLVMValueRef a, LLVMValueRef b) {
GB_ASSERT(LLVMTypeOf(a) == LLVMTypeOf(b));
LLVMTypeRef elem = LLVMGetElementType(LLVMTypeOf(a));
LLVMTypeRef elem = OdinLLVMGetVectorElementType(LLVMTypeOf(a));
if (LLVMGetTypeKind(elem) == LLVMIntegerTypeKind) {
return LLVMBuildMul(p->builder, a, b, "");
@@ -1768,14 +1752,13 @@ LLVMValueRef llvm_vector_dot(lbProcedure *p, LLVMValueRef a, LLVMValueRef b) {
}
LLVMValueRef llvm_vector_mul_add(lbProcedure *p, LLVMValueRef a, LLVMValueRef b, LLVMValueRef c) {
lbModule *m = p->module;
LLVMTypeRef t = LLVMTypeOf(a);
GB_ASSERT(t == LLVMTypeOf(b));
GB_ASSERT(t == LLVMTypeOf(c));
GB_ASSERT(LLVMGetTypeKind(t) == LLVMVectorTypeKind);
LLVMTypeRef elem = LLVMGetElementType(t);
LLVMTypeRef elem = OdinLLVMGetVectorElementType(t);
bool is_possible = false;
@@ -1791,18 +1774,9 @@ LLVMValueRef llvm_vector_mul_add(lbProcedure *p, LLVMValueRef a, LLVMValueRef b,
if (is_possible) {
char const *name = "llvm.fmuladd";
unsigned id = LLVMLookupIntrinsicID(name, gb_strlen(name));
GB_ASSERT_MSG(id != 0, "Unable to find %s", name);
LLVMTypeRef types[1] = {};
types[0] = t;
LLVMValueRef ip = LLVMGetIntrinsicDeclaration(m->mod, id, types, gb_count_of(types));
LLVMValueRef values[3] = {};
values[0] = a;
values[1] = b;
values[2] = c;
LLVMValueRef call = LLVMBuildCall(p->builder, ip, values, gb_count_of(values), "");
LLVMTypeRef types[1] = { t };
LLVMValueRef values[3] = { a, b, c};
LLVMValueRef call = lb_call_intrinsic(p, name, values, gb_count_of(values), types, gb_count_of(types));
return call;
} else {
LLVMValueRef x = llvm_vector_mul(p, a, b);
@@ -1817,7 +1791,7 @@ LLVMValueRef llvm_get_inline_asm(LLVMTypeRef func_type, String const &str, Strin
cast(char *)clobbers.text, cast(size_t)clobbers.len,
has_side_effects, is_align_stack,
dialect
#if LLVM_VERSION_MAJOR >= 13
#if LLVM_VERSION_MAJOR >= 13
, /*CanThrow*/false
#endif
);
src/main.cpp
+6 -2
View File
@@ -283,6 +283,9 @@ i32 linker_stage(lbGenerator *gen) {
String vs_exe_path = path_to_string(heap_allocator(), build_context.build_paths[BuildPath_VS_EXE]);
defer (gb_free(heap_allocator(), vs_exe_path.text));
String windows_sdk_bin_path = path_to_string(heap_allocator(), build_context.build_paths[BuildPath_Win_SDK_Bin_Path]);
defer (gb_free(heap_allocator(), windows_sdk_bin_path.text));
char const *subsystem_str = build_context.use_subsystem_windows ? "WINDOWS" : "CONSOLE";
if (!build_context.use_lld) { // msvc
if (build_context.has_resource) {
@@ -292,7 +295,8 @@ i32 linker_stage(lbGenerator *gen) {
defer (gb_free(heap_allocator(), res_path.text));
result = system_exec_command_line_app("msvc-link",
"\"rc.exe\" /nologo /fo \"%.*s\" \"%.*s\"",
"\"%.*src.exe\" /nologo /fo \"%.*s\" \"%.*s\"",
LIT(windows_sdk_bin_path),
LIT(res_path),
LIT(rc_path)
);
@@ -1558,7 +1562,7 @@ bool parse_build_flags(Array<String> args) {
bad_flags = true;
break;
}
build_context.resource_filepath = substring(path, 0, string_extension_position(path));
build_context.resource_filepath = path;
build_context.has_resource = true;
} else {
gb_printf_err("Invalid -resource path, got %.*s\n", LIT(path));
src/microsoft_craziness.h
+181 -172
View File
@@ -50,18 +50,7 @@ gb_global gbAllocator mc_allocator = heap_allocator();
struct Find_Result {
int windows_sdk_version; // Zero if no Windows SDK found.
wchar_t const *windows_sdk_root;
wchar_t const *windows_sdk_um_library_path;
wchar_t const *windows_sdk_ucrt_library_path;
wchar_t const *vs_exe_path;
wchar_t const *vs_library_path;
};
struct Find_Result_Utf8 {
int windows_sdk_version; // Zero if no Windows SDK found.
String windows_sdk_root;
String windows_sdk_bin_path;
String windows_sdk_um_library_path;
String windows_sdk_ucrt_library_path;
@@ -69,8 +58,6 @@ struct Find_Result_Utf8 {
String vs_library_path;
};
Find_Result_Utf8 find_visual_studio_and_windows_sdk_utf8();
String mc_wstring_to_string(wchar_t const *str) {
return string16_to_string(mc_allocator, make_string16_c(str));
}
@@ -87,6 +74,10 @@ String mc_concat(String a, String b, String c) {
return concatenate3_strings(mc_allocator, a, b, c);
}
String mc_concat(String a, String b, String c, String d) {
return concatenate4_strings(mc_allocator, a, b, c, d);
}
String mc_get_env(String key) {
char const * value = gb_get_env((char const *)key.text, mc_allocator);
return make_string_c(value);
@@ -219,19 +210,19 @@ struct DECLSPEC_UUID("42843719-DB4C-46C2-8E7C-64F1816EFD5B") DECLSPEC_NOVTABLE I
// The beginning of the actual code that does things.
struct Version_Data_Utf8 {
i32 best_version[4]; // For Windows 8 versions, only two of these numbers are used.
struct Version_Data {
i32 best_version[4];
String best_name;
};
typedef void (*MC_Visit_Proc)(String short_name, String full_name, Version_Data_Utf8 *data);
bool mc_visit_files(String dir_name, Version_Data_Utf8 *data, MC_Visit_Proc proc) {
typedef void (*MC_Visit_Proc)(String short_name, String full_name, Version_Data *data);
bool mc_visit_files(String dir_name, Version_Data *data, MC_Visit_Proc proc) {
// Visit everything in one folder (non-recursively). If it's a directory
// that doesn't start with ".", call the visit proc on it. The visit proc
// will see if the filename conforms to the expected versioning pattern.
String wildcard_name = mc_concat(dir_name, str_lit("\\*"));
String wildcard_name = mc_concat(dir_name, str_lit("*"));
defer (mc_free(wildcard_name));
MC_Find_Data find_data;
@@ -242,7 +233,7 @@ bool mc_visit_files(String dir_name, Version_Data_Utf8 *data, MC_Visit_Proc proc
bool success = true;
while (success) {
if ((find_data.file_attributes & FILE_ATTRIBUTE_DIRECTORY) && (find_data.filename[0] != '.')) {
String full_name = mc_concat(dir_name, str_lit("\\"), find_data.filename);
String full_name = mc_concat(dir_name, find_data.filename);
defer (mc_free(full_name));
proc(find_data.filename, full_name, data);
@@ -284,7 +275,7 @@ String find_windows_kit_root(HKEY key, String const version) {
return value;
}
void win10_best(String short_name, String full_name, Version_Data_Utf8 *data) {
void win10_best(String short_name, String full_name, Version_Data *data) {
// Find the Windows 10 subdirectory with the highest version number.
int i0, i1, i2, i3;
@@ -304,11 +295,11 @@ void win10_best(String short_name, String full_name, Version_Data_Utf8 *data) {
// we have to copy_string and free here because visit_files free's the full_name string
// after we execute this function, so Win*_Data would contain an invalid pointer.
if (data->best_name.len > 0) mc_free(data->best_name);
if (data->best_name.len) mc_free(data->best_name);
data->best_name = copy_string(mc_allocator, full_name);
if (data->best_name.len > 0) {
if (data->best_name.len) {
data->best_version[0] = i0;
data->best_version[1] = i1;
data->best_version[2] = i2;
@@ -316,34 +307,8 @@ void win10_best(String short_name, String full_name, Version_Data_Utf8 *data) {
}
}
void win8_best(String short_name, String full_name, Version_Data_Utf8 *data) {
// Find the Windows 8 subdirectory with the highest version number.
int i0, i1;
auto success = sscanf_s((const char *const)short_name.text, "winv%d.%d", &i0, &i1);
if (success < 2) return;
if (i0 < data->best_version[0]) return;
else if (i0 == data->best_version[0]) {
if (i1 < data->best_version[1]) return;
}
// we have to copy_string and free here because visit_files free's the full_name string
// after we execute this function, so Win*_Data would contain an invalid pointer.
if (data->best_name.len > 0) mc_free(data->best_name);
data->best_name = copy_string(mc_allocator, full_name);
if (data->best_name.len > 0) {
data->best_version[0] = i0;
data->best_version[1] = i1;
}
}
void find_windows_kit_root(Find_Result_Utf8 *result) {
// Information about the Windows 10 and Windows 8 development kits
// is stored in the same place in the registry. We open a key
// to that place, first checking preferntially for a Windows 10 kit,
// then, if that's not found, a Windows 8 kit.
void find_windows_kit_paths(Find_Result *result) {
bool sdk_found = false;
HKEY main_key;
@@ -355,44 +320,42 @@ void find_windows_kit_root(Find_Result_Utf8 *result) {
// Look for a Windows 10 entry.
String windows10_root = find_windows_kit_root(main_key, str_lit("KitsRoot10"));
if (windows10_root.len > 0) {
if (windows10_root.len) {
defer (mc_free(windows10_root));
String windows10_lib = mc_concat(windows10_root, str_lit("Lib"));
String windows10_lib = mc_concat(windows10_root, str_lit("Lib\\"));
Version_Data data_lib = {0};
mc_visit_files(windows10_lib, &data_lib, win10_best);
defer (mc_free(windows10_lib));
defer (mc_free(data_lib.best_name));
Version_Data_Utf8 data = {0};
mc_visit_files(windows10_lib, &data, win10_best);
if (data.best_name.len > 0) {
result->windows_sdk_version = 10;
result->windows_sdk_root = mc_concat(data.best_name, str_lit("\\"));
return;
String windows10_bin = mc_concat(windows10_root, str_lit("bin\\"));
Version_Data data_bin = {0};
mc_visit_files(windows10_bin, &data_bin, win10_best);
defer (mc_free(windows10_bin));
defer (mc_free(data_bin.best_name));
if (data_lib.best_name.len && data_bin.best_name.len) {
if (build_context.metrics.arch == TargetArch_amd64) {
result->windows_sdk_um_library_path = mc_concat(data_lib.best_name, str_lit("\\um\\x64\\"));
result->windows_sdk_ucrt_library_path = mc_concat(data_lib.best_name, str_lit("\\ucrt\\x64\\"));
result->windows_sdk_bin_path = mc_concat(data_bin.best_name, str_lit("\\x64\\"));
sdk_found = true;
} else if (build_context.metrics.arch == TargetArch_i386) {
result->windows_sdk_um_library_path = mc_concat(data_lib.best_name, str_lit("\\um\\x86\\"));
result->windows_sdk_ucrt_library_path = mc_concat(data_lib.best_name, str_lit("\\ucrt\\x86\\"));
result->windows_sdk_bin_path = mc_concat(data_bin.best_name, str_lit("\\x86\\"));
sdk_found = true;
}
}
mc_free(data.best_name);
}
// Look for a Windows 8 entry.
String windows8_root = find_windows_kit_root(main_key, str_lit("KitsRoot81"));
if (windows8_root.len > 0) {
defer (mc_free(windows8_root));
String windows8_lib = mc_concat(windows8_root, str_lit("Lib"));
defer (mc_free(windows8_lib));
Version_Data_Utf8 data = {0};
mc_visit_files(windows8_lib, &data, win8_best);
if (data.best_name.len > 0) {
result->windows_sdk_version = 8;
result->windows_sdk_root = mc_concat(data.best_name, str_lit("\\"));
return;
}
mc_free(data.best_name);
if (sdk_found) {
result->windows_sdk_version = 10;
}
// If we get here, we failed to find anything.
}
bool find_visual_studio_by_fighting_through_microsoft_craziness(Find_Result_Utf8 *result) {
bool find_visual_studio_by_fighting_through_microsoft_craziness(Find_Result *result) {
// The name of this procedure is kind of cryptic. Its purpose is
// to fight through Microsoft craziness. The things that the fine
// Visual Studio team want you to do, JUST TO FIND A SINGLE FOLDER
@@ -555,54 +518,97 @@ bool find_visual_studio_by_fighting_through_microsoft_craziness(Find_Result_Utf8
}
// NOTE(WalterPlinge): Environment variables can help to find Visual C++ and WinSDK paths for both
// official and portable installations (like mmozeiko's portable msvc script). This will only use
// the first paths it finds, and won't overwrite any values that `result` already has.
bool find_msvc_install_from_env_vars(Find_Result_Utf8 *result) {
// official and portable installations (like mmozeiko's portable msvc script).
void find_windows_kit_paths_from_env_vars(Find_Result *result) {
if (build_context.metrics.arch != TargetArch_amd64 && build_context.metrics.arch != TargetArch_i386) {
return false;
return;
}
// We can find windows sdk using the following combination of env vars:
// (UniversalCRTSdkDir or WindowsSdkDir) and (WindowsSDKLibVersion or WindowsSDKVersion)
bool sdk_found = false;
// We can find windows sdk lib dir using the following combination of env vars:
// (WindowsSdkDir or UniversalCRTSdkDir) and (WindowsSDKVersion or WindowsSDKLibVersion)
bool sdk_lib_found = false;
// We can find windows sdk bin dir using the following combination of env vars:
// (WindowsSdkVerBinPath) or ((WindowsSdkBinPath or WindowsSdkDir or UniversalCRTSdkDir) and (WindowsSDKVersion || WindowsSDKLibVersion))
bool sdk_bin_found = false;
// These appear to be suitable env vars used by Visual Studio
String win_sdk_ver_env = mc_get_env(str_lit("WindowsSDKVersion"));
String win_sdk_lib_env = mc_get_env(str_lit("WindowsSDKLibVersion"));
String win_sdk_lib_ver_env = mc_get_env(str_lit("WindowsSDKLibVersion"));
String win_sdk_dir_env = mc_get_env(str_lit("WindowsSdkDir"));
String crt_sdk_dir_env = mc_get_env(str_lit("UniversalCRTSdkDir"));
String win_sdk_bin_path_env = mc_get_env(str_lit("WindowsSdkBinPath"));
String win_sdk_ver_bin_path_env = mc_get_env(str_lit("WindowsSdkVerBinPath"));
defer ({
mc_free(win_sdk_ver_env);
mc_free(win_sdk_lib_env);
mc_free(win_sdk_lib_ver_env);
mc_free(win_sdk_dir_env);
mc_free(crt_sdk_dir_env);
mc_free(win_sdk_bin_path_env);
mc_free(win_sdk_ver_bin_path_env);
});
if (win_sdk_ver_bin_path_env.len || ((win_sdk_bin_path_env.len || win_sdk_dir_env.len || crt_sdk_dir_env.len) && (win_sdk_ver_env.len || win_sdk_lib_ver_env.len))) {
String bin;
defer (mc_free(bin));
if (win_sdk_ver_bin_path_env.len) {
String dir = win_sdk_ver_bin_path_env;
// Add trailing '\' in case it was missing
bin = mc_concat(dir, dir[dir.len - 1] != '\\' ? str_lit("\\") : str_lit(""));
} else {
String dir = win_sdk_bin_path_env.len ? win_sdk_bin_path_env : win_sdk_dir_env.len ? win_sdk_dir_env : crt_sdk_dir_env;
String ver = win_sdk_ver_env.len ? win_sdk_ver_env : win_sdk_lib_ver_env;
// Add trailing '\' in case it was missing
dir = mc_concat(dir, dir[dir.len - 1] != '\\' ? str_lit("\\") : str_lit(""));
ver = mc_concat(ver, ver[ver.len - 1] != '\\' ? str_lit("\\") : str_lit(""));
defer (mc_free(dir));
defer (mc_free(ver));
// Append "bin" for win_sdk_dir_env and crt_sdk_dir_env
String dir_bin = mc_concat(dir, win_sdk_bin_path_env.len ? str_lit("") : str_lit("bin\\"));
defer (mc_free(dir_bin));
bin = mc_concat(dir_bin, ver);
}
if (build_context.metrics.arch == TargetArch_amd64) {
result->windows_sdk_bin_path = mc_concat(bin, str_lit("x64\\"));
sdk_bin_found = true;
} else if (build_context.metrics.arch == TargetArch_i386) {
result->windows_sdk_bin_path = mc_concat(bin, str_lit("x86\\"));
sdk_bin_found = true;
}
}
// NOTE(WalterPlinge): If any combination is found, let's just assume they are correct
if ((win_sdk_ver_env.len || win_sdk_lib_env.len) && (win_sdk_dir_env.len || crt_sdk_dir_env.len)) {
//? Maybe we need to handle missing '\' at end of strings, so far it doesn't seem an issue
if ((win_sdk_ver_env.len || win_sdk_lib_ver_env.len) && (win_sdk_dir_env.len || crt_sdk_dir_env.len)) {
String dir = win_sdk_dir_env.len ? win_sdk_dir_env : crt_sdk_dir_env;
String ver = win_sdk_ver_env.len ? win_sdk_ver_env : win_sdk_lib_env;
String ver = win_sdk_ver_env.len ? win_sdk_ver_env : win_sdk_lib_ver_env;
// These have trailing '\' as we are just composing the path
String um_dir = build_context.metrics.arch == TargetArch_amd64
? str_lit("um\\x64\\")
: str_lit("um\\x86\\");
String ucrt_dir = build_context.metrics.arch == TargetArch_amd64
? str_lit("ucrt\\x64\\")
: str_lit("ucrt\\x86\\");
// Add trailing '\' in case it was missing
dir = mc_concat(dir, dir[dir.len - 1] != '\\' ? str_lit("\\") : str_lit(""));
ver = mc_concat(ver, ver[ver.len - 1] != '\\' ? str_lit("\\") : str_lit(""));
defer (mc_free(dir));
defer (mc_free(ver));
result->windows_sdk_root = mc_concat(dir, str_lit("Lib\\"), ver);
result->windows_sdk_um_library_path = mc_concat(result->windows_sdk_root, um_dir);
result->windows_sdk_ucrt_library_path = mc_concat(result->windows_sdk_root, ucrt_dir);
sdk_found = true;
if (build_context.metrics.arch == TargetArch_amd64) {
result->windows_sdk_um_library_path = mc_concat(dir, str_lit("Lib\\"), ver, str_lit("um\\x64\\"));
result->windows_sdk_ucrt_library_path = mc_concat(dir, str_lit("Lib\\"), ver, str_lit("ucrt\\x64\\"));
sdk_lib_found = true;
} else if (build_context.metrics.arch == TargetArch_i386) {
result->windows_sdk_um_library_path = mc_concat(dir, str_lit("Lib\\"), ver, str_lit("um\\x86\\"));
result->windows_sdk_ucrt_library_path = mc_concat(dir, str_lit("Lib\\"), ver, str_lit("ucrt\\x86\\"));
sdk_lib_found = true;
}
}
// If we haven't found it yet, we can loop through LIB for specific folders
//? This may not be robust enough using `um\x64` and `ucrt\x64`
if (!sdk_found) {
if (!sdk_lib_found) {
String lib = mc_get_env(str_lit("LIB"));
defer (mc_free(lib));
@@ -624,72 +630,67 @@ bool find_msvc_install_from_env_vars(Find_Result_Utf8 *result) {
continue;
}
hi = c;
String dir = substring(lib, lo, hi);
defer (lo = hi + 1);
// Skip when there are two ;; in a row
if (lo == hi) {
continue;
}
String dir = substring(lib, lo, hi);
// Remove the last slash so we can match with the strings above
String end = dir[dir.len - 1] == '\\'
? substring(dir, 0, dir.len - 1)
: substring(dir, 0, dir.len);
// Find one and we can make the other
if (string_ends_with(end, um_dir)) {
result->windows_sdk_um_library_path = mc_concat(end, str_lit("\\"));
break;
result->windows_sdk_um_library_path = mc_concat(end, str_lit("\\"));
} else if (string_ends_with(end, ucrt_dir)) {
result->windows_sdk_ucrt_library_path = mc_concat(end, str_lit("\\"));
}
if (result->windows_sdk_um_library_path.len && result->windows_sdk_ucrt_library_path.len) {
sdk_lib_found = true;
break;
}
}
// Get the root from the one we found, and make the other
// NOTE(WalterPlinge): we need to copy the string so that we don't risk a double free
if (result->windows_sdk_um_library_path.len > 0) {
String root = substring(result->windows_sdk_um_library_path, 0, result->windows_sdk_um_library_path.len - 1 - um_dir.len);
result->windows_sdk_root = copy_string(mc_allocator, root);
result->windows_sdk_ucrt_library_path = mc_concat(result->windows_sdk_root, ucrt_dir, str_lit("\\"));
} else if (result->windows_sdk_ucrt_library_path.len > 0) {
String root = substring(result->windows_sdk_ucrt_library_path, 0, result->windows_sdk_ucrt_library_path.len - 1 - ucrt_dir.len);
result->windows_sdk_root = copy_string(mc_allocator, root);
result->windows_sdk_um_library_path = mc_concat(result->windows_sdk_root, um_dir, str_lit("\\"));
}
if (result->windows_sdk_root.len > 0) {
sdk_found = true;
}
}
}
// NOTE(WalterPlinge): So far this function assumes it will only be called if MSVC was
// installed using mmozeiko's portable msvc script, which uses the windows 10 sdk.
// This may need to be changed later if it ends up causing problems.
if (sdk_found && result->windows_sdk_version == 0) {
if (sdk_bin_found && sdk_lib_found) {
result->windows_sdk_version = 10;
}
}
// NOTE(WalterPlinge): Environment variables can help to find Visual C++ and WinSDK paths for both
// official and portable installations (like mmozeiko's portable msvc script). This will only use
// the first paths it finds, and won't overwrite any values that `result` already has.
void find_visual_studio_paths_from_env_vars(Find_Result *result) {
if (build_context.metrics.arch != TargetArch_amd64 && build_context.metrics.arch != TargetArch_i386) {
return;
}
bool vs_found = false;
if (result->vs_exe_path.len > 0 && result->vs_library_path.len > 0) {
vs_found = true;
}
// We can find visual studio using VCToolsInstallDir
if (!vs_found) {
String vctid = mc_get_env(str_lit("VCToolsInstallDir"));
defer (mc_free(vctid));
String vctid = mc_get_env(str_lit("VCToolsInstallDir"));
defer (mc_free(vctid));
if (vctid.len) {
String exe = build_context.metrics.arch == TargetArch_amd64
? str_lit("bin\\Hostx64\\x64\\")
: str_lit("bin\\Hostx86\\x86\\");
String lib = build_context.metrics.arch == TargetArch_amd64
? str_lit("lib\\x64\\")
: str_lit("lib\\x86\\");
if (vctid.len) {
String exe = build_context.metrics.arch == TargetArch_amd64
? str_lit("bin\\Hostx64\\x64\\")
: str_lit("bin\\Hostx86\\x86\\");
String lib = build_context.metrics.arch == TargetArch_amd64
? str_lit("lib\\x64\\")
: str_lit("lib\\x86\\");
result->vs_exe_path = mc_concat(vctid, exe);
result->vs_library_path = mc_concat(vctid, lib);
vs_found = true;
}
result->vs_exe_path = mc_concat(vctid, exe);
result->vs_library_path = mc_concat(vctid, lib);
vs_found = true;
}
// If we haven't found it yet, we can loop through Path for specific folders
@@ -701,21 +702,32 @@ bool find_msvc_install_from_env_vars(Find_Result_Utf8 *result) {
String exe = build_context.metrics.arch == TargetArch_amd64
? str_lit("bin\\Hostx64\\x64")
: str_lit("bin\\Hostx86\\x86");
// The environment variable may have an uppercase X even though the folder is lowercase
String exe2 = build_context.metrics.arch == TargetArch_amd64
? str_lit("bin\\HostX64\\x64")
: str_lit("bin\\HostX86\\x86");
String lib = build_context.metrics.arch == TargetArch_amd64
? str_lit("lib\\x64")
: str_lit("lib\\x86");
isize lo = {0};
isize hi = {0};
for (isize c = 0; c < path.len; c += 1) {
if (path[c] != ';') {
for (isize c = 0; c <= path.len; c += 1) {
if (c != path.len && path[c] != ';') {
continue;
}
hi = c;
String dir = substring(path, lo, hi);
defer (lo = hi + 1);
// Skip when there are two ;; in a row
if (lo == hi) {
continue;
}
String dir = substring(path, lo, hi);
// Remove the last slash so we can match with the strings above
String end = dir[dir.len - 1] == '\\'
? substring(dir, 0, dir.len - 1)
: substring(dir, 0, dir.len);
@@ -726,7 +738,10 @@ bool find_msvc_install_from_env_vars(Find_Result_Utf8 *result) {
defer (mc_free(cl));
defer (mc_free(link));
if (!string_ends_with(end, exe) || !gb_file_exists((char *)cl.text) || !gb_file_exists((char *)link.text)) {
if (!string_ends_with(end, exe) && !string_ends_with(end, exe2)) {
continue;
}
if (!gb_file_exists((char *)cl.text) || !gb_file_exists((char *)link.text)) {
continue;
}
@@ -735,42 +750,36 @@ bool find_msvc_install_from_env_vars(Find_Result_Utf8 *result) {
result->vs_library_path = mc_concat(root, lib, str_lit("\\"));
vs_found = true;
break;
}
}
}
return sdk_found && vs_found;
}
Find_Result_Utf8 find_visual_studio_and_windows_sdk_utf8() {
Find_Result_Utf8 r = {};
find_windows_kit_root(&r);
if (r.windows_sdk_root.len > 0) {
if (build_context.metrics.arch == TargetArch_amd64) {
r.windows_sdk_um_library_path = mc_concat(r.windows_sdk_root, str_lit("um\\x64\\"));
r.windows_sdk_ucrt_library_path = mc_concat(r.windows_sdk_root, str_lit("ucrt\\x64\\"));
} else if (build_context.metrics.arch == TargetArch_i386) {
r.windows_sdk_um_library_path = mc_concat(r.windows_sdk_root, str_lit("um\\x86\\"));
r.windows_sdk_ucrt_library_path = mc_concat(r.windows_sdk_root, str_lit("ucrt\\x86\\"));
}
}
Find_Result find_visual_studio_and_windows_sdk() {
Find_Result r = {};
find_windows_kit_paths(&r);
find_visual_studio_by_fighting_through_microsoft_craziness(&r);
bool all_found =
r.windows_sdk_root.len > 0 &&
r.windows_sdk_um_library_path.len > 0 &&
r.windows_sdk_ucrt_library_path.len > 0 &&
r.vs_exe_path.len > 0 &&
r.vs_library_path.len > 0;
bool sdk_found =
r.windows_sdk_bin_path.len &&
r.windows_sdk_um_library_path.len &&
r.windows_sdk_ucrt_library_path.len ;
if (!all_found) {
find_msvc_install_from_env_vars(&r);
bool vs_found =
r.vs_exe_path.len &&
r.vs_library_path.len ;
if (!sdk_found) {
find_windows_kit_paths_from_env_vars(&r);
}
if (!vs_found) {
find_visual_studio_paths_from_env_vars(&r);
}
#if 0
printf("windows_sdk_root: %.*s\n", LIT(r.windows_sdk_root));
printf("windows_sdk_bin_path: %.*s\n", LIT(r.windows_sdk_bin_path));
printf("windows_sdk_um_library_path: %.*s\n", LIT(r.windows_sdk_um_library_path));
printf("windows_sdk_ucrt_library_path: %.*s\n", LIT(r.windows_sdk_ucrt_library_path));
printf("vs_exe_path: %.*s\n", LIT(r.vs_exe_path));
src/parser.cpp
+29 -47
View File
@@ -356,6 +356,7 @@ Ast *clone_ast(Ast *node) {
break;
case Ast_PointerType:
n->PointerType.type = clone_ast(n->PointerType.type);
n->PointerType.tag = clone_ast(n->PointerType.tag);
break;
case Ast_MultiPointerType:
n->MultiPointerType.type = clone_ast(n->MultiPointerType.type);
@@ -2167,10 +2168,11 @@ Ast *parse_operand(AstFile *f, bool lhs) {
Ast *original_type = parse_type(f);
Ast *type = unparen_expr(original_type);
switch (type->kind) {
case Ast_ArrayType: type->ArrayType.tag = tag; break;
case Ast_ArrayType: type->ArrayType.tag = tag; break;
case Ast_DynamicArrayType: type->DynamicArrayType.tag = tag; break;
case Ast_PointerType: type->PointerType.tag = tag; break;
default:
syntax_error(type, "Expected an array type after #%.*s, got %.*s", LIT(name.string), LIT(ast_strings[type->kind]));
syntax_error(type, "Expected an array or pointer type after #%.*s, got %.*s", LIT(name.string), LIT(ast_strings[type->kind]));
break;
}
return original_type;
@@ -2548,21 +2550,15 @@ Ast *parse_operand(AstFile *f, bool lhs) {
syntax_error(tag, "Invalid union tag '#%.*s'", LIT(tag.string));
}
}
if (no_nil && maybe) {
syntax_error(f->curr_token, "#maybe and #no_nil cannot be applied together");
}
if (no_nil && shared_nil) {
syntax_error(f->curr_token, "#shared_nil and #no_nil cannot be applied together");
}
if (shared_nil && maybe) {
syntax_error(f->curr_token, "#maybe and #shared_nil cannot be applied together");
}
if (maybe) {
union_kind = UnionType_maybe;
syntax_error(f->curr_token, "#maybe functionality has now been merged with standard 'union' functionality");
} else if (no_nil) {
}
if (no_nil) {
union_kind = UnionType_no_nil;
} else if (shared_nil) {
union_kind = UnionType_shared_nil;
@@ -3550,49 +3546,34 @@ Ast *parse_var_type(AstFile *f, bool allow_ellipsis, bool allow_typeid_token) {
}
enum FieldPrefixKind : i32 {
FieldPrefix_Unknown = -1,
FieldPrefix_Invalid = 0,
FieldPrefix_using, // implies #subtype
FieldPrefix_const,
FieldPrefix_no_alias,
FieldPrefix_c_vararg,
FieldPrefix_auto_cast,
FieldPrefix_any_int,
FieldPrefix_subtype, // does not imply `using` semantics
FieldPrefix_by_ptr,
};
struct ParseFieldPrefixMapping {
String name;
TokenKind token_kind;
FieldPrefixKind prefix;
FieldFlag flag;
};
gb_global ParseFieldPrefixMapping parse_field_prefix_mappings[] = {
{str_lit("using"), Token_using, FieldPrefix_using, FieldFlag_using},
{str_lit("auto_cast"), Token_auto_cast, FieldPrefix_auto_cast, FieldFlag_auto_cast},
{str_lit("no_alias"), Token_Hash, FieldPrefix_no_alias, FieldFlag_no_alias},
{str_lit("c_vararg"), Token_Hash, FieldPrefix_c_vararg, FieldFlag_c_vararg},
{str_lit("const"), Token_Hash, FieldPrefix_const, FieldFlag_const},
{str_lit("any_int"), Token_Hash, FieldPrefix_any_int, FieldFlag_any_int},
{str_lit("subtype"), Token_Hash, FieldPrefix_subtype, FieldFlag_subtype},
{str_lit("by_ptr"), Token_Hash, FieldPrefix_by_ptr, FieldFlag_by_ptr},
{str_lit("using"), Token_using, FieldFlag_using},
{str_lit("auto_cast"), Token_auto_cast, FieldFlag_auto_cast},
{str_lit("no_alias"), Token_Hash, FieldFlag_no_alias},
{str_lit("c_vararg"), Token_Hash, FieldFlag_c_vararg},
{str_lit("const"), Token_Hash, FieldFlag_const},
{str_lit("any_int"), Token_Hash, FieldFlag_any_int},
{str_lit("subtype"), Token_Hash, FieldFlag_subtype},
{str_lit("by_ptr"), Token_Hash, FieldFlag_by_ptr},
};
FieldPrefixKind is_token_field_prefix(AstFile *f) {
FieldFlag is_token_field_prefix(AstFile *f) {
switch (f->curr_token.kind) {
case Token_EOF:
return FieldPrefix_Invalid;
return FieldFlag_Invalid;
case Token_using:
return FieldPrefix_using;
return FieldFlag_using;
case Token_auto_cast:
return FieldPrefix_auto_cast;
return FieldFlag_auto_cast;
case Token_Hash:
advance_token(f);
@@ -3602,33 +3583,33 @@ FieldPrefixKind is_token_field_prefix(AstFile *f) {
auto const &mapping = parse_field_prefix_mappings[i];
if (mapping.token_kind == Token_Hash) {
if (f->curr_token.string == mapping.name) {
return mapping.prefix;
return mapping.flag;
}
}
}
break;
}
return FieldPrefix_Unknown;
return FieldFlag_Unknown;
}
return FieldPrefix_Invalid;
return FieldFlag_Invalid;
}
u32 parse_field_prefixes(AstFile *f) {
i32 counts[gb_count_of(parse_field_prefix_mappings)] = {};
for (;;) {
FieldPrefixKind kind = is_token_field_prefix(f);
if (kind == FieldPrefix_Invalid) {
FieldFlag flag = is_token_field_prefix(f);
if (flag & FieldFlag_Invalid) {
break;
}
if (kind == FieldPrefix_Unknown) {
if (flag & FieldFlag_Unknown) {
syntax_error(f->curr_token, "Unknown prefix kind '#%.*s'", LIT(f->curr_token.string));
advance_token(f);
continue;
}
for (i32 i = 0; i < gb_count_of(parse_field_prefix_mappings); i++) {
if (parse_field_prefix_mappings[i].prefix == kind) {
if (parse_field_prefix_mappings[i].flag == flag) {
counts[i] += 1;
advance_token(f);
break;
@@ -3894,7 +3875,8 @@ Ast *parse_field_list(AstFile *f, isize *name_count_, u32 allowed_flags, TokenKi
while (f->curr_token.kind != follow &&
f->curr_token.kind != Token_EOF) {
f->curr_token.kind != Token_EOF &&
f->curr_token.kind != Token_Semicolon) {
CommentGroup *docs = f->lead_comment;
u32 set_flags = parse_field_prefixes(f);
Token tag = {};
@@ -3922,7 +3904,7 @@ Ast *parse_field_list(AstFile *f, isize *name_count_, u32 allowed_flags, TokenKi
default_value = parse_expr(f, false);
if (!allow_default_parameters) {
syntax_error(f->curr_token, "Default parameters are only allowed for procedures");
default_value = nullptr;
default_value = nullptr;
}
}
src/parser.hpp
+8 -3
View File
@@ -282,7 +282,8 @@ enum StateFlag : u8 {
StateFlag_type_assert = 1<<2,
StateFlag_no_type_assert = 1<<3,
StateFlag_SelectorCallExpr = 1<<6,
StateFlag_SelectorCallExpr = 1<<5,
StateFlag_DirectiveWasFalse = 1<<6,
StateFlag_BeenHandled = 1<<7,
};
@@ -308,6 +309,10 @@ enum FieldFlag : u32 {
FieldFlag_Tags = 1<<10,
FieldFlag_Results = 1<<16,
FieldFlag_Unknown = 1u<<30,
FieldFlag_Invalid = 1u<<31,
// Parameter List Restrictions
FieldFlag_Signature = FieldFlag_ellipsis|FieldFlag_using|FieldFlag_no_alias|FieldFlag_c_vararg|FieldFlag_auto_cast|FieldFlag_const|FieldFlag_any_int|FieldFlag_by_ptr,
FieldFlag_Struct = FieldFlag_using|FieldFlag_subtype|FieldFlag_Tags,
@@ -335,7 +340,6 @@ char const *inline_asm_dialect_strings[InlineAsmDialect_COUNT] = {
enum UnionTypeKind : u8 {
UnionType_Normal = 0,
UnionType_maybe = 1, // removed
UnionType_no_nil = 2,
UnionType_shared_nil = 3,
};
@@ -647,7 +651,8 @@ AST_KIND(_TypeBegin, "", bool) \
}) \
AST_KIND(PointerType, "pointer type", struct { \
Token token; \
Ast *type; \
Ast *type; \
Ast *tag; \
}) \
AST_KIND(RelativeType, "relative type", struct { \
Ast *tag; \
src/string.cpp
+10
View File
@@ -324,6 +324,16 @@ String concatenate3_strings(gbAllocator a, String const &x, String const &y, Str
data[len] = 0;
return make_string(data, len);
}
String concatenate4_strings(gbAllocator a, String const &x, String const &y, String const &z, String const &w) {
isize len = x.len+y.len+z.len+w.len;
u8 *data = gb_alloc_array(a, u8, len+1);
gb_memmove(data, x.text, x.len);
gb_memmove(data+x.len, y.text, y.len);
gb_memmove(data+x.len+y.len, z.text, z.len);
gb_memmove(data+x.len+y.len+z.len, w.text, w.len);
data[len] = 0;
return make_string(data, len);
}
String string_join_and_quote(gbAllocator a, Array<String> strings) {
if (!strings.count) {
src/types.cpp
+111 -10
View File
@@ -278,7 +278,8 @@ struct TypeProc {
Type *generic_row_count; \
Type *generic_column_count; \
i64 stride_in_bytes; \
})
}) \
TYPE_KIND(SoaPointer, struct { Type *elem; })
enum TypeKind {
@@ -350,6 +351,7 @@ enum Typeid_Kind : u8 {
Typeid_Relative_Pointer,
Typeid_Relative_Slice,
Typeid_Matrix,
Typeid_SoaPointer,
};
// IMPORTANT NOTE(bill): This must match the same as the in core.odin
@@ -644,6 +646,7 @@ gb_global Type *t_type_info_simd_vector = nullptr;
gb_global Type *t_type_info_relative_pointer = nullptr;
gb_global Type *t_type_info_relative_slice = nullptr;
gb_global Type *t_type_info_matrix = nullptr;
gb_global Type *t_type_info_soa_pointer = nullptr;
gb_global Type *t_type_info_named_ptr = nullptr;
gb_global Type *t_type_info_integer_ptr = nullptr;
@@ -672,6 +675,7 @@ gb_global Type *t_type_info_simd_vector_ptr = nullptr;
gb_global Type *t_type_info_relative_pointer_ptr = nullptr;
gb_global Type *t_type_info_relative_slice_ptr = nullptr;
gb_global Type *t_type_info_matrix_ptr = nullptr;
gb_global Type *t_type_info_soa_pointer_ptr = nullptr;
gb_global Type *t_allocator = nullptr;
gb_global Type *t_allocator_ptr = nullptr;
@@ -735,6 +739,7 @@ Type * bit_set_to_int(Type *t);
bool are_types_identical(Type *x, Type *y);
bool is_type_pointer(Type *t);
bool is_type_soa_pointer(Type *t);
bool is_type_proc(Type *t);
bool is_type_slice(Type *t);
bool is_type_integer(Type *t);
@@ -917,6 +922,13 @@ Type *alloc_type_multi_pointer(Type *elem) {
return t;
}
Type *alloc_type_soa_pointer(Type *elem) {
Type *t = alloc_type(Type_SoaPointer);
t->SoaPointer.elem = elem;
return t;
}
Type *alloc_type_array(Type *elem, i64 count, Type *generic_count = nullptr) {
if (generic_count != nullptr) {
Type *t = alloc_type(Type_Array);
@@ -1103,17 +1115,28 @@ Type *alloc_type_simd_vector(i64 count, Type *elem, Type *generic_count=nullptr)
////////////////////////////////////////////////////////////////
Type *type_deref(Type *t) {
Type *type_deref(Type *t, bool allow_multi_pointer=false) {
if (t != nullptr) {
Type *bt = base_type(t);
if (bt == nullptr) {
return nullptr;
}
if (bt->kind == Type_Pointer) {
switch (bt->kind) {
case Type_Pointer:
return bt->Pointer.elem;
}
if (bt->kind == Type_RelativePointer) {
case Type_RelativePointer:
return type_deref(bt->RelativePointer.pointer_type);
case Type_SoaPointer:
{
Type *elem = base_type(bt->SoaPointer.elem);
GB_ASSERT(elem->kind == Type_Struct && elem->Struct.soa_kind != StructSoa_None);
return elem->Struct.soa_elem;
}
case Type_MultiPointer:
if (allow_multi_pointer) {
return bt->MultiPointer.elem;
}
break;
}
}
return t;
@@ -1327,6 +1350,10 @@ bool is_type_pointer(Type *t) {
}
return t->kind == Type_Pointer;
}
bool is_type_soa_pointer(Type *t) {
t = base_type(t);
return t->kind == Type_SoaPointer;
}
bool is_type_multi_pointer(Type *t) {
t = base_type(t);
return t->kind == Type_MultiPointer;
@@ -1401,7 +1428,7 @@ i64 matrix_align_of(Type *t, struct TypePath *tp) {
}
GB_ASSERT(min_alignment >= elem_align);
i64 align = gb_min(min_alignment, build_context.max_align);
i64 align = gb_min(min_alignment, build_context.max_simd_align);
return align;
}
@@ -1804,7 +1831,7 @@ bool is_type_dereferenceable(Type *t) {
if (is_type_rawptr(t)) {
return false;
}
return is_type_pointer(t);
return is_type_pointer(t) || is_type_soa_pointer(t);
}
@@ -2079,6 +2106,9 @@ bool is_type_polymorphic(Type *t, bool or_specialized=false) {
case Type_Pointer:
return is_type_polymorphic(t->Pointer.elem, or_specialized);
case Type_SoaPointer:
return is_type_polymorphic(t->SoaPointer.elem, or_specialized);
case Type_EnumeratedArray:
if (is_type_polymorphic(t->EnumeratedArray.index, or_specialized)) {
return true;
@@ -2196,6 +2226,7 @@ bool type_has_nil(Type *t) {
case Type_Slice:
case Type_Proc:
case Type_Pointer:
case Type_SoaPointer:
case Type_MultiPointer:
case Type_DynamicArray:
case Type_Map:
@@ -2262,6 +2293,8 @@ bool is_type_comparable(Type *t) {
return true;
case Type_Pointer:
return true;
case Type_SoaPointer:
return true;
case Type_MultiPointer:
return true;
case Type_Enum:
@@ -2335,6 +2368,7 @@ bool is_type_simple_compare(Type *t) {
case Type_Pointer:
case Type_MultiPointer:
case Type_SoaPointer:
case Type_Proc:
case Type_BitSet:
return true;
@@ -2369,6 +2403,57 @@ bool is_type_simple_compare(Type *t) {
return false;
}
bool is_type_load_safe(Type *type) {
GB_ASSERT(type != nullptr);
type = core_type(core_array_type(type));
switch (type->kind) {
case Type_Basic:
return (type->Basic.flags & (BasicFlag_Boolean|BasicFlag_Numeric|BasicFlag_Rune)) != 0;
case Type_BitSet:
if (type->BitSet.underlying) {
return is_type_load_safe(type->BitSet.underlying);
}
return true;
case Type_RelativePointer:
case Type_RelativeSlice:
return true;
case Type_Pointer:
case Type_MultiPointer:
case Type_Slice:
case Type_DynamicArray:
case Type_Proc:
case Type_SoaPointer:
return false;
case Type_Enum:
case Type_EnumeratedArray:
case Type_Array:
case Type_SimdVector:
case Type_Matrix:
GB_PANIC("should never be hit");
return false;
case Type_Struct:
for_array(i, type->Struct.fields) {
if (!is_type_load_safe(type->Struct.fields[i]->type)) {
return false;
}
}
return type_size_of(type) > 0;
case Type_Union:
for_array(i, type->Union.variants) {
if (!is_type_load_safe(type->Union.variants[i])) {
return false;
}
}
return type_size_of(type) > 0;
}
return false;
}
String lookup_subtype_polymorphic_field(Type *dst, Type *src) {
Type *prev_src = src;
// Type *prev_dst = dst;
@@ -2558,6 +2643,12 @@ bool are_types_identical_internal(Type *x, Type *y, bool check_tuple_names) {
}
break;
case Type_SoaPointer:
if (y->kind == Type_SoaPointer) {
return are_types_identical(x->SoaPointer.elem, y->SoaPointer.elem);
}
break;
case Type_Named:
if (y->kind == Type_Named) {
return x->Named.type_name == y->Named.type_name;
@@ -3465,7 +3556,7 @@ i64 type_align_of_internal(Type *t, TypePath *path) {
case Type_SimdVector: {
// IMPORTANT TODO(bill): Figure out the alignment of vector types
return gb_clamp(next_pow2(type_size_of_internal(t, path)), 1, build_context.max_align*2);
return gb_clamp(next_pow2(type_size_of_internal(t, path)), 1, build_context.max_simd_align*2);
}
case Type_Matrix:
@@ -3475,12 +3566,14 @@ i64 type_align_of_internal(Type *t, TypePath *path) {
return type_align_of_internal(t->RelativePointer.base_integer, path);
case Type_RelativeSlice:
return type_align_of_internal(t->RelativeSlice.base_integer, path);
case Type_SoaPointer:
return build_context.word_size;
}
// return gb_clamp(next_pow2(type_size_of(t)), 1, build_context.max_align);
// NOTE(bill): Things that are bigger than build_context.word_size, are actually comprised of smaller types
// TODO(bill): Is this correct for 128-bit types (integers)?
return gb_clamp(next_pow2(type_size_of_internal(t, path)), 1, build_context.word_size);
return gb_clamp(next_pow2(type_size_of_internal(t, path)), 1, build_context.max_align);
}
i64 *type_set_offsets_of(Slice<Entity *> const &fields, bool is_packed, bool is_raw_union) {
@@ -3580,6 +3673,9 @@ i64 type_size_of_internal(Type *t, TypePath *path) {
case Type_MultiPointer:
return build_context.word_size;
case Type_SoaPointer:
return build_context.word_size*2;
case Type_Array: {
i64 count, align, size, alignment;
count = t->Array.count;
@@ -4017,6 +4113,11 @@ gbString write_type_to_string(gbString str, Type *type, bool shorthand=false) {
str = write_type_to_string(str, type->Pointer.elem);
break;
case Type_SoaPointer:
str = gb_string_appendc(str, "#soa ^");
str = write_type_to_string(str, type->SoaPointer.elem);
break;
case Type_MultiPointer:
str = gb_string_appendc(str, "[^]");
str = write_type_to_string(str, type->Pointer.elem);
vendor/directx/d3d11/d3d11.odin
Vendored
+33
View File
@@ -3625,3 +3625,36 @@ IFunctionLinkingGraph_VTable :: struct {
GetLastError: proc "stdcall" (this: ^IFunctionLinkingGraph, ppErrorBuffer: ^^IBlob) -> HRESULT,
GenerateHlsl: proc "stdcall" (this: ^IFunctionLinkingGraph, uFlags: u32, ppBuffer: ^^IBlob) -> HRESULT,
}
IDebug_UUID_STRING :: "79CF2233-7536-4948-9D36-1E4692DC5760"
IDebug_UUID := &IID{0x79CF2233, 0x7536, 0x4948, {0x9D, 0x36, 0x1E, 0x46, 0x92, 0xDC, 0x57, 0x60}}
IDebug :: struct #raw_union {
#subtype iunknown: IUnknown,
using id3d11debug_vtable: ^IDebug_VTable,
}
RLDO_FLAGS :: enum u32 { // TODO: make bit_set
SUMMARY = 0x1,
DETAIL = 0x2,
IGNORE_INTERNAL = 0x4,
}
DEBUG_FEATURE :: enum u32 { // TODO: make bit_set
FLUSH_PER_RENDER_OP = 0x1,
FINISH_PER_RENDER_OP = 0x2,
FEATURE_PRESENT_PER_RENDER_OP = 0x4,
}
IDebug_VTable :: struct {
using iunkown_vtable: IUnknown_VTable,
SetFeatureMask: proc "stdcall" (this: ^IDebug, mask: DEBUG_FEATURE) -> HRESULT,
GetFeatureMask: proc "stdcall" (this: ^IDebug) -> DEBUG_FEATURE,
SetPresentPerRenderOpDelay: proc "stdcall" (this: ^IDebug, Milliseconds: u32) -> HRESULT,
GetPresentPerRenderOpDelay: proc "stdcall" (this: ^IDebug) -> u32,
SetSwapChain: proc "stdcall" (this: ^IDebug, pSwapChain: ^dxgi.ISwapChain) -> HRESULT,
GetSwapChain: proc "stdcall" (this: ^IDebug, ppSwapChain: ^^dxgi.ISwapChain) -> HRESULT,
ValidateContext: proc "stdcall" (this: ^IDebug, pContext: ^IDeviceContext) -> HRESULT,
ReportLiveDeviceObjects: proc "stdcall" (this: ^IDebug, Flags: RLDO_FLAGS) -> HRESULT,
ValidateContextForDispatch: proc "stdcall" (this: ^IDebug, pContext: ^IDeviceContext) -> HRESULT,
}
vendor/directx/dxgi/dxgi.odin
Vendored
+4 -4
View File
@@ -38,10 +38,10 @@ IUnknown_VTable :: struct {
@(default_calling_convention="stdcall")
foreign dxgi {
CreateDXGIFactory :: proc(riid: ^IID, ppFactory: rawptr) -> HRESULT ---
CreateDXGIFactory1 :: proc(riid: ^IID, ppFactory: rawptr) -> HRESULT ---
CreateDXGIFactory2 :: proc(Flags: u32, riid: ^IID, ppFactory: rawptr) -> HRESULT ---
DXGIGetDebugInterface1 :: proc(Flags: u32, riid: ^IID, pDebug: rawptr) -> HRESULT ---
CreateDXGIFactory :: proc(riid: ^IID, ppFactory: ^rawptr) -> HRESULT ---
CreateDXGIFactory1 :: proc(riid: ^IID, ppFactory: ^rawptr) -> HRESULT ---
CreateDXGIFactory2 :: proc(Flags: u32, riid: ^IID, ppFactory: ^rawptr) -> HRESULT ---
DXGIGetDebugInterface1 :: proc(Flags: u32, riid: ^IID, pDebug: ^rawptr) -> HRESULT ---
}
STANDARD_MULTISAMPLE_QUALITY_PATTERN :: 0xffffffff
vendor/glfw/bindings/bindings.odin
Vendored
+7
View File
@@ -13,6 +13,13 @@ when ODIN_OS == .Windows {
} else when ODIN_OS == .Linux {
// TODO: Add the billion-or-so static libs to link to in linux
foreign import glfw "system:glfw"
} else when ODIN_OS == .Darwin {
foreign import glfw {
"../lib/darwin/libglfw3.a",
"system:Cocoa.framework",
"system:IOKit.framework",
"system:OpenGL.framework",
}
} else {
foreign import glfw "system:glfw"
}
vendor/glfw/constants.odin
Vendored
+1 -1
View File
@@ -4,7 +4,7 @@ package glfw
/* Versions */
VERSION_MAJOR :: 3
VERSION_MINOR :: 3
VERSION_REVISION :: 4
VERSION_REVISION :: 8
/* Booleans */
TRUE :: true
vendor/glfw/lib/darwin/libglfw3.a
Vendored
BIN
View File
Binary file not shown.
vendor/glfw/lib/glfw3.dll
Vendored
BIN
View File
Binary file not shown.
vendor/glfw/lib/glfw3.lib
Vendored
BIN
View File
Binary file not shown.
vendor/glfw/lib/glfw3_mt.lib
Vendored
BIN
View File
Binary file not shown.
vendor/glfw/lib/glfw3dll.lib
Vendored
BIN
View File
Binary file not shown.

Some files were not shown because too many files have changed in this diff Show More