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214 lines
3.9 KiB
214 lines
3.9 KiB
#include <assert.h>
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#include <math.h>
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#include <types.h>
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#define CHAR_BIT 8
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// TODO: Throughout here we use `assert` for error conditions, which isn't optimal
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// Instead we should use `unlikely` branches to a single trapping function (which should optimize better)
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// The below functions are for implementing WASM instructions
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// ROTL and ROTR helper functions
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INLINE uint32_t
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rotl_u32(uint32_t n, uint32_t c_u32)
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{
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// WASM requires a modulus here (usually a single bitwise op, but it means we need no assert)
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unsigned int c = c_u32 % (CHAR_BIT * sizeof(n));
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const unsigned int mask = (CHAR_BIT * sizeof(n) - 1); // assumes width is a power of 2.
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c &= mask;
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return (n << c) | (n >> ((-c) & mask));
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}
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INLINE uint32_t
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rotr_u32(uint32_t n, uint32_t c_u32)
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{
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// WASM requires a modulus here (usually a single bitwise op, but it means we need no assert)
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unsigned int c = c_u32 % (CHAR_BIT * sizeof(n));
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const unsigned int mask = (CHAR_BIT * sizeof(n) - 1);
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c &= mask;
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return (n >> c) | (n << ((-c) & mask));
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}
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INLINE uint64_t
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rotl_u64(uint64_t n, uint64_t c_u64)
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{
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// WASM requires a modulus here (usually a single bitwise op, but it means we need no assert)
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unsigned int c = c_u64 % (CHAR_BIT * sizeof(n));
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const unsigned int mask = (CHAR_BIT * sizeof(n) - 1); // assumes width is a power of 2.
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c &= mask;
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return (n << c) | (n >> ((-c) & mask));
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}
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INLINE uint64_t
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rotr_u64(uint64_t n, uint64_t c_u64)
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{
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// WASM requires a modulus here (usually a single bitwise op, but it means we need no assert)
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unsigned int c = c_u64 % (CHAR_BIT * sizeof(n));
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const unsigned int mask = (CHAR_BIT * sizeof(n) - 1);
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c &= mask;
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return (n >> c) | (n << ((-c) & mask));
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}
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// Now safe division and remainder
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INLINE uint32_t
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u32_div(uint32_t a, uint32_t b)
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{
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assert(b);
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return a / b;
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}
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INLINE uint32_t
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u32_rem(uint32_t a, uint32_t b)
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{
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assert(b);
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return a % b;
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}
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INLINE int32_t
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i32_div(int32_t a, int32_t b)
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{
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assert(b && (a != INT32_MIN || b != -1));
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return a / b;
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}
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INLINE int32_t
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i32_rem(int32_t a, int32_t b)
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{
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assert(b && (a != INT32_MIN || b != -1));
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return a % b;
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}
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INLINE uint64_t
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u64_div(uint64_t a, uint64_t b)
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{
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assert(b);
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return a / b;
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}
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INLINE uint64_t
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u64_rem(uint64_t a, uint64_t b)
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{
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assert(b);
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return a % b;
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}
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INLINE int64_t
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i64_div(int64_t a, int64_t b)
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{
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assert(b && (a != INT64_MIN || b != -1));
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return a / b;
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}
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INLINE int64_t
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i64_rem(int64_t a, int64_t b)
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{
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assert(b && (a != INT64_MIN || b != -1));
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return a % b;
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}
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// float to integer conversion methods
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// In C, float => int conversions always truncate
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// If a int2float(int::min_value) <= float <= int2float(int::max_value), it must always be safe to truncate it
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uint32_t
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u32_trunc_f32(float f)
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{
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assert(0 <= f && f <= UINT32_MAX);
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return (uint32_t)f;
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}
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int32_t
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i32_trunc_f32(float f)
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{
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assert(INT32_MIN <= f && f <= INT32_MAX);
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return (int32_t)f;
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}
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uint32_t
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u32_trunc_f64(double f)
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{
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assert(0 <= f && f <= UINT32_MAX);
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return (uint32_t)f;
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}
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int32_t
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i32_trunc_f64(double f)
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{
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assert(INT32_MIN <= f && f <= INT32_MAX);
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return (int32_t)f;
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}
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uint64_t
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u64_trunc_f32(float f)
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{
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assert(0 <= f && f <= UINT64_MAX);
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return (uint64_t)f;
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}
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int64_t
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i64_trunc_f32(float f)
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{
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assert(INT64_MIN <= f && f <= INT64_MAX);
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return (int64_t)f;
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}
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uint64_t
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u64_trunc_f64(double f)
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{
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assert(0 <= f && f <= UINT64_MAX);
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return (uint64_t)f;
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}
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int64_t
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i64_trunc_f64(double f)
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{
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assert(INT64_MIN <= f && f <= INT64_MAX);
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return (int64_t)f;
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}
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// Float => Float truncation functions
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INLINE float
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f32_trunc_f32(float f)
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{
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return trunc(f);
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}
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INLINE float
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f32_min(float a, float b)
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{
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return a < b ? a : b;
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}
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INLINE float
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f32_max(float a, float b)
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{
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return a > b ? a : b;
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}
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INLINE float
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f32_floor(float a)
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{
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return floor(a);
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}
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INLINE double
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f64_min(double a, double b)
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{
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return a < b ? a : b;
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}
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INLINE double
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f64_max(double a, double b)
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{
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return a > b ? a : b;
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}
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INLINE double
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f64_floor(double a)
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{
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return floor(a);
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}
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