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Ginger Bill
2017-06-08 12:03:40 +01:00
parent 333924cce1
commit 9b61adb97d
27 changed files with 216 additions and 243 deletions
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src/exact_value.cpp
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#include <math.h>
// TODO(bill): Big numbers
// IMPORTANT TODO(bill): This needs to be completely fixed!!!!!!!!
typedef struct AstNode AstNode;
typedef struct Complex128 {
f64 real, imag;
} Complex128;
typedef enum ExactValueKind {
ExactValue_Invalid,
ExactValue_Bool,
ExactValue_String,
ExactValue_Integer,
ExactValue_Float,
ExactValue_Complex,
ExactValue_Pointer,
ExactValue_Compound, // TODO(bill): Is this good enough?
ExactValue_Count,
} ExactValueKind;
typedef struct ExactValue {
ExactValueKind kind;
union {
bool value_bool;
String value_string;
i128 value_integer; // NOTE(bill): This must be an integer and not a pointer
f64 value_float;
i64 value_pointer;
Complex128 value_complex;
AstNode * value_compound;
};
} ExactValue;
HashKey hash_exact_value(ExactValue v) {
return hashing_proc(&v, gb_size_of(ExactValue));
}
ExactValue exact_value_compound(AstNode *node) {
ExactValue result = {ExactValue_Compound};
result.value_compound = node;
return result;
}
ExactValue exact_value_bool(bool b) {
ExactValue result = {ExactValue_Bool};
result.value_bool = (b != 0);
return result;
}
ExactValue exact_value_string(String string) {
// TODO(bill): Allow for numbers with underscores in them
ExactValue result = {ExactValue_String};
result.value_string = string;
return result;
}
ExactValue exact_value_i64(i64 i) {
ExactValue result = {ExactValue_Integer};
result.value_integer = i128_from_i64(i);
return result;
}
ExactValue exact_value_i128(i128 i) {
ExactValue result = {ExactValue_Integer};
result.value_integer = i;
return result;
}
ExactValue exact_value_u128(u128 i) {
ExactValue result = {ExactValue_Integer};
result.value_integer = *cast(i128 *)&i;
return result;
}
ExactValue exact_value_float(f64 f) {
ExactValue result = {ExactValue_Float};
result.value_float = f;
return result;
}
ExactValue exact_value_complex(f64 real, f64 imag) {
ExactValue result = {ExactValue_Complex};
result.value_complex.real = real;
result.value_complex.imag = imag;
return result;
}
ExactValue exact_value_pointer(i64 ptr) {
ExactValue result = {ExactValue_Pointer};
result.value_pointer = ptr;
return result;
}
ExactValue exact_value_integer_from_string(String string) {
return exact_value_i128(i128_from_string(string));
}
f64 float_from_string(String string) {
isize i = 0;
u8 *str = string.text;
isize len = string.len;
f64 sign = 1.0;
if (str[i] == '-') {
sign = -1.0;
i++;
} else if (*str == '+') {
i++;
}
f64 value = 0.0;
for (; i < len; i++) {
Rune r = cast(Rune)str[i];
if (r == '_') {
continue;
}
i64 v = digit_value(r);
if (v >= 10) {
break;
}
value *= 10.0;
value += v;
}
if (str[i] == '.') {
f64 pow10 = 10.0;
i++;
for (; i < string.len; i++) {
Rune r = cast(Rune)str[i];
if (r == '_') {
continue;
}
i64 v = digit_value(r);
if (v >= 10) {
break;
}
value += v/pow10;
pow10 *= 10.0;
}
}
bool frac = false;
f64 scale = 1.0;
if ((str[i] == 'e') || (str[i] == 'E')) {
i++;
if (str[i] == '-') {
frac = true;
i++;
} else if (str[i] == '+') {
i++;
}
u32 exp = 0;
for (; i < len; i++) {
Rune r = cast(Rune)str[i];
if (r == '_') {
continue;
}
u32 d = cast(u32)digit_value(r);
if (d >= 10) {
break;
}
exp = exp * 10 + d;
}
if (exp > 308) exp = 308;
while (exp >= 50) { scale *= 1e50; exp -= 50; }
while (exp >= 8) { scale *= 1e8; exp -= 8; }
while (exp > 0) { scale *= 10.0; exp -= 1; }
}
return sign * (frac ? (value / scale) : (value * scale));
}
ExactValue exact_value_float_from_string(String string) {
return exact_value_float(float_from_string(string));
}
ExactValue exact_value_from_basic_literal(Token token) {
switch (token.kind) {
case Token_String: return exact_value_string(token.string);
case Token_Integer: return exact_value_integer_from_string(token.string);
case Token_Float: return exact_value_float_from_string(token.string);
case Token_Imag: {
String str = token.string;
Rune last_rune = cast(Rune)str.text[str.len-1];
str.len--; // Ignore the `i|j|k`
f64 imag = float_from_string(str);
if (last_rune == 'i') {
return exact_value_complex(0, imag);
}
}
case Token_Rune: {
Rune r = GB_RUNE_INVALID;
gb_utf8_decode(token.string.text, token.string.len, &r);
// gb_printf("%.*s rune: %d\n", LIT(token.string), r);
return exact_value_i64(r);
}
default:
GB_PANIC("Invalid token for basic literal");
break;
}
ExactValue result = {ExactValue_Invalid};
return result;
}
ExactValue exact_value_to_integer(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
return v;
case ExactValue_Float: {
i128 i = i128_from_f64(v.value_float);
f64 f = i128_to_f64(i);
if (f == v.value_float) {
return exact_value_i128(i);
}
} break;
case ExactValue_Pointer:
return exact_value_i64(cast(i64)cast(intptr)v.value_pointer);
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_value_to_float(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
return exact_value_float(i128_to_f64(v.value_integer));
case ExactValue_Float:
return v;
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_value_to_complex(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
return exact_value_complex(i128_to_f64(v.value_integer), 0);
case ExactValue_Float:
return exact_value_complex(v.value_float, 0);
case ExactValue_Complex:
return v;
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_value_real(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
case ExactValue_Float:
return v;
case ExactValue_Complex:
return exact_value_float(v.value_complex.real);
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_value_imag(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
case ExactValue_Float:
return exact_value_i64(0);
case ExactValue_Complex:
return exact_value_float(v.value_complex.imag);
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_value_make_imag(ExactValue v) {
switch (v.kind) {
case ExactValue_Integer:
return exact_value_complex(0, exact_value_to_float(v).value_float);
case ExactValue_Float:
return exact_value_complex(0, v.value_float);
default:
GB_PANIC("Expected an integer or float type for `exact_value_make_imag`");
}
ExactValue r = {ExactValue_Invalid};
return r;
}
ExactValue exact_unary_operator_value(TokenKind op, ExactValue v, i32 precision) {
switch (op) {
case Token_Add: {
switch (v.kind) {
case ExactValue_Invalid:
case ExactValue_Integer:
case ExactValue_Float:
case ExactValue_Complex:
return v;
}
} break;
case Token_Sub: {
switch (v.kind) {
case ExactValue_Invalid:
return v;
case ExactValue_Integer: {
ExactValue i = v;
i.value_integer = i128_neg(i.value_integer);
return i;
}
case ExactValue_Float: {
ExactValue i = v;
i.value_float = -i.value_float;
return i;
}
case ExactValue_Complex: {
f64 real = v.value_complex.real;
f64 imag = v.value_complex.imag;
return exact_value_complex(-real, -imag);
}
}
} break;
case Token_Xor: {
i128 i = I128_ZERO;
switch (v.kind) {
case ExactValue_Invalid:
return v;
case ExactValue_Integer:
i = i128_not(v.value_integer);
break;
default:
goto failure;
}
// NOTE(bill): unsigned integers will be negative and will need to be
// limited to the types precision
// IMPORTANT NOTE(bill): Max precision is 64 bits as that's how integers are stored
if (0 < precision && precision < 128) {
i = i128_and(i, i128_not(i128_shl(I128_NEG_ONE, precision)));
}
return exact_value_i128(i);
} break;
case Token_Not: {
switch (v.kind) {
case ExactValue_Invalid: return v;
case ExactValue_Bool:
return exact_value_bool(!v.value_bool);
}
} break;
}
failure:
GB_PANIC("Invalid unary operation, %.*s", LIT(token_strings[op]));
ExactValue error_value = {};
return error_value;
}
// NOTE(bill): Make sure things are evaluated in correct order
i32 exact_value_order(ExactValue v) {
switch (v.kind) {
case ExactValue_Invalid:
return 0;
case ExactValue_Bool:
case ExactValue_String:
return 1;
case ExactValue_Integer:
return 2;
case ExactValue_Float:
return 3;
case ExactValue_Complex:
return 4;
case ExactValue_Pointer:
return 5;
default:
GB_PANIC("How'd you get here? Invalid Value.kind");
return -1;
}
}
void match_exact_values(ExactValue *x, ExactValue *y) {
if (exact_value_order(*y) < exact_value_order(*x)) {
match_exact_values(y, x);
return;
}
switch (x->kind) {
case ExactValue_Invalid:
*y = *x;
return;
case ExactValue_Bool:
case ExactValue_String:
case ExactValue_Complex:
return;
case ExactValue_Integer:
switch (y->kind) {
case ExactValue_Integer:
return;
case ExactValue_Float:
// TODO(bill): Is this good enough?
*x = exact_value_float(i128_to_f64(x->value_integer));
return;
case ExactValue_Complex:
*x = exact_value_complex(i128_to_f64(x->value_integer), 0);
return;
}
break;
case ExactValue_Float:
switch (y->kind) {
case ExactValue_Float:
return;
case ExactValue_Complex:
*x = exact_value_to_complex(*x);
return;
}
break;
}
compiler_error("match_exact_values: How'd you get here? Invalid ExactValueKind %d", x->kind);
}
// TODO(bill): Allow for pointer arithmetic? Or are pointer slices good enough?
ExactValue exact_binary_operator_value(TokenKind op, ExactValue x, ExactValue y) {
match_exact_values(&x, &y);
switch (x.kind) {
case ExactValue_Invalid:
return x;
case ExactValue_Bool:
switch (op) {
case Token_CmpAnd: return exact_value_bool(x.value_bool && y.value_bool);
case Token_CmpOr: return exact_value_bool(x.value_bool || y.value_bool);
case Token_And: return exact_value_bool(x.value_bool & y.value_bool);
case Token_Or: return exact_value_bool(x.value_bool | y.value_bool);
default: goto error;
}
break;
case ExactValue_Integer: {
i128 a = x.value_integer;
i128 b = y.value_integer;
i128 c = I128_ZERO;
switch (op) {
case Token_Add: c = i128_add(a, b); break;
case Token_Sub: c = i128_sub(a, b); break;
case Token_Mul: c = i128_mul(a, b); break;
case Token_Quo: return exact_value_float(fmod(i128_to_f64(a), i128_to_f64(b)));
case Token_QuoEq: c = i128_quo(a, b); break; // NOTE(bill): Integer division
case Token_Mod: c = i128_mod(a, b); break;
case Token_ModMod: c = i128_mod(i128_add(i128_mod(a, b), b), b); break;
case Token_And: c = i128_and (a, b); break;
case Token_Or: c = i128_or (a, b); break;
case Token_Xor: c = i128_xor (a, b); break;
case Token_AndNot: c = i128_and_not(a, b); break;
case Token_Shl: c = i128_shl (a, i128_to_u64(b)); break;
case Token_Shr: c = i128_shr (a, i128_to_u64(b)); break;
default: goto error;
}
return exact_value_i128(c);
} break;
case ExactValue_Float: {
f64 a = x.value_float;
f64 b = y.value_float;
switch (op) {
case Token_Add: return exact_value_float(a + b);
case Token_Sub: return exact_value_float(a - b);
case Token_Mul: return exact_value_float(a * b);
case Token_Quo: return exact_value_float(a / b);
default: goto error;
}
} break;
case ExactValue_Complex: {
y = exact_value_to_complex(y);
f64 a = x.value_complex.real;
f64 b = x.value_complex.imag;
f64 c = y.value_complex.real;
f64 d = y.value_complex.imag;
f64 real = 0;
f64 imag = 0;
switch (op) {
case Token_Add:
real = a + c;
imag = b + d;
break;
case Token_Sub:
real = a - c;
imag = b - d;
break;
case Token_Mul:
real = (a*c - b*d);
imag = (b*c + a*d);
break;
case Token_Quo: {
f64 s = c*c + d*d;
real = (a*c + b*d)/s;
imag = (b*c - a*d)/s;
} break;
default: goto error;
}
return exact_value_complex(real, imag);
} break;
}
error:
; // MSVC accepts this??? apparently you cannot declare variables immediately after labels...
ExactValue error_value = {};
// gb_printf_err("Invalid binary operation: %s\n", token_kind_to_string(op));
return error_value;
}
gb_inline ExactValue exact_value_add(ExactValue x, ExactValue y) { return exact_binary_operator_value(Token_Add, x, y); }
gb_inline ExactValue exact_value_sub(ExactValue x, ExactValue y) { return exact_binary_operator_value(Token_Sub, x, y); }
gb_inline ExactValue exact_value_mul(ExactValue x, ExactValue y) { return exact_binary_operator_value(Token_Mul, x, y); }
gb_inline ExactValue exact_value_quo(ExactValue x, ExactValue y) { return exact_binary_operator_value(Token_Quo, x, y); }
gb_inline ExactValue exact_value_shift(TokenKind op, ExactValue x, ExactValue y) { return exact_binary_operator_value(op, x, y); }
i32 cmp_f64(f64 a, f64 b) {
return (a > b) - (a < b);
}
bool compare_exact_values(TokenKind op, ExactValue x, ExactValue y) {
match_exact_values(&x, &y);
switch (x.kind) {
case ExactValue_Invalid:
return false;
case ExactValue_Bool:
switch (op) {
case Token_CmpEq: return x.value_bool == y.value_bool;
case Token_NotEq: return x.value_bool != y.value_bool;
}
break;
case ExactValue_Integer: {
i128 a = x.value_integer;
i128 b = y.value_integer;
switch (op) {
case Token_CmpEq: return i128_eq(a, b);
case Token_NotEq: return i128_ne(a, b);
case Token_Lt: return i128_lt(a, b);
case Token_LtEq: return i128_le(a, b);
case Token_Gt: return i128_gt(a, b);
case Token_GtEq: return i128_ge(a, b);
}
} break;
case ExactValue_Float: {
f64 a = x.value_float;
f64 b = y.value_float;
switch (op) {
case Token_CmpEq: return cmp_f64(a, b) == 0;
case Token_NotEq: return cmp_f64(a, b) != 0;
case Token_Lt: return cmp_f64(a, b) < 0;
case Token_LtEq: return cmp_f64(a, b) <= 0;
case Token_Gt: return cmp_f64(a, b) > 0;
case Token_GtEq: return cmp_f64(a, b) >= 0;
}
} break;
case ExactValue_Complex: {
f64 a = x.value_complex.real;
f64 b = x.value_complex.imag;
f64 c = y.value_complex.real;
f64 d = y.value_complex.imag;
switch (op) {
case Token_CmpEq: return cmp_f64(a, c) == 0 && cmp_f64(b, d) == 0;
case Token_NotEq: return cmp_f64(a, c) != 0 || cmp_f64(b, d) != 0;
}
} break;
case ExactValue_String: {
String a = x.value_string;
String b = y.value_string;
isize len = gb_min(a.len, b.len);
// TODO(bill): gb_memcompare is used because the strings are UTF-8
switch (op) {
case Token_CmpEq: return gb_memcompare(a.text, b.text, len) == 0;
case Token_NotEq: return gb_memcompare(a.text, b.text, len) != 0;
case Token_Lt: return gb_memcompare(a.text, b.text, len) < 0;
case Token_LtEq: return gb_memcompare(a.text, b.text, len) <= 0;
case Token_Gt: return gb_memcompare(a.text, b.text, len) > 0;
case Token_GtEq: return gb_memcompare(a.text, b.text, len) >= 0;
}
} break;
}
GB_PANIC("Invalid comparison");
return false;
}