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orca/ext/wasm3/source/m3_exec.h

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//
// m3_exec.h
//
// Created by Steven Massey on 4/17/19.
// Copyright © 2019 Steven Massey. All rights reserved.
#ifndef m3_exec_h
#define m3_exec_h
// TODO: all these functions could move over to the .c at some point. normally, I'd say screw it,
// but it might prove useful to be able to compile m3_exec alone w/ optimizations while the remaining
// code is at debug O0
// About the naming convention of these operations/macros (_rs, _sr_, _ss, _srs, etc.)
//------------------------------------------------------------------------------------------------------
// - 'r' means register and 's' means slot
// - the first letter is the top of the stack
//
// so, for example, _rs means the first operand (the first thing pushed to the stack) is in a slot
// and the second operand (the top of the stack) is in a register
//------------------------------------------------------------------------------------------------------
#ifndef M3_COMPILE_OPCODES
# error "Opcodes should only be included in one compilation unit"
#endif
#include "m3_math_utils.h"
#include "m3_compile.h"
#include "m3_env.h"
#include "m3_info.h"
#include "m3_exec_defs.h"
#include <limits.h>
d_m3BeginExternC
# define rewrite_op(OP) * ((void **) (_pc-1)) = (void*)(OP)
# define immediate(TYPE) * ((TYPE *) _pc++)
# define skip_immediate(TYPE) (_pc++)
# define slot(TYPE) * (TYPE *) (_sp + immediate (i32))
# define slot_ptr(TYPE) (TYPE *) (_sp + immediate (i32))
# if d_m3EnableOpProfiling
d_m3RetSig profileOp (d_m3OpSig, cstr_t i_operationName);
# define nextOp() return profileOp (d_m3OpAllArgs, __FUNCTION__)
# elif d_m3EnableOpTracing
d_m3RetSig debugOp (d_m3OpSig, cstr_t i_operationName);
# define nextOp() return debugOp (d_m3OpAllArgs, __FUNCTION__)
# else
# define nextOp() nextOpDirect()
# endif
#define jumpOp(PC) jumpOpDirect(PC)
#if d_m3RecordBacktraces
#define pushBacktraceFrame() (PushBacktraceFrame (_mem->runtime, _pc - 1))
#define fillBacktraceFrame(FUNCTION) (FillBacktraceFunctionInfo (_mem->runtime, function))
#define newTrap(err) return (pushBacktraceFrame (), err)
#define forwardTrap(err) return err
#else
#define pushBacktraceFrame() do {} while (0)
#define fillBacktraceFrame(FUNCTION) do {} while (0)
#define newTrap(err) return err
#define forwardTrap(err) return err
#endif
#if d_m3EnableStrace == 1
// Flat trace
#define d_m3TracePrepare
#define d_m3TracePrint(fmt, ...) fprintf(stderr, fmt "\n", ##__VA_ARGS__)
#elif d_m3EnableStrace >= 2
// Structured trace
#define d_m3TracePrepare const IM3Runtime trace_rt = m3MemRuntime(_mem);
#define d_m3TracePrint(fmt, ...) fprintf(stderr, "%*s" fmt "\n", (trace_rt->callDepth)*2, "", ##__VA_ARGS__)
#else
#define d_m3TracePrepare
#define d_m3TracePrint(fmt, ...)
#endif
#if d_m3EnableStrace >= 3
#define d_m3TraceLoad(TYPE,offset,val) d_m3TracePrint("load." #TYPE " 0x%x = %" PRI##TYPE, offset, val)
#define d_m3TraceStore(TYPE,offset,val) d_m3TracePrint("store." #TYPE " 0x%x , %" PRI##TYPE, offset, val)
#else
#define d_m3TraceLoad(TYPE,offset,val)
#define d_m3TraceStore(TYPE,offset,val)
#endif
#ifdef DEBUG
#define d_outOfBounds newTrap (ErrorRuntime (m3Err_trapOutOfBoundsMemoryAccess, \
_mem->runtime, "memory size: %zu; access offset: %zu", \
_mem->length, operand))
# define d_outOfBoundsMemOp(OFFSET, SIZE) newTrap (ErrorRuntime (m3Err_trapOutOfBoundsMemoryAccess, \
_mem->runtime, "memory size: %zu; access offset: %zu; size: %u", \
_mem->length, OFFSET, SIZE))
#else
#define d_outOfBounds newTrap (m3Err_trapOutOfBoundsMemoryAccess)
# define d_outOfBoundsMemOp(OFFSET, SIZE) newTrap (m3Err_trapOutOfBoundsMemoryAccess)
#endif
d_m3RetSig Call (d_m3OpSig)
{
m3ret_t possible_trap = m3_Yield ();
if (M3_UNLIKELY(possible_trap)) return possible_trap;
nextOpDirect();
}
// TODO: OK, this needs some explanation here ;0
#define d_m3CommutativeOpMacro(RES, REG, TYPE, NAME, OP, ...) \
d_m3Op(TYPE##_##NAME##_rs) \
{ \
TYPE operand = slot (TYPE); \
OP((RES), operand, ((TYPE) REG), ##__VA_ARGS__); \
nextOp (); \
} \
d_m3Op(TYPE##_##NAME##_ss) \
{ \
TYPE operand2 = slot (TYPE); \
TYPE operand1 = slot (TYPE); \
OP((RES), operand1, operand2, ##__VA_ARGS__); \
nextOp (); \
}
#define d_m3OpMacro(RES, REG, TYPE, NAME, OP, ...) \
d_m3Op(TYPE##_##NAME##_sr) \
{ \
TYPE operand = slot (TYPE); \
OP((RES), ((TYPE) REG), operand, ##__VA_ARGS__); \
nextOp (); \
} \
d_m3CommutativeOpMacro(RES, REG, TYPE,NAME, OP, ##__VA_ARGS__)
// Accept macros
#define d_m3CommutativeOpMacro_i(TYPE, NAME, MACRO, ...) d_m3CommutativeOpMacro ( _r0, _r0, TYPE, NAME, MACRO, ##__VA_ARGS__)
#define d_m3OpMacro_i(TYPE, NAME, MACRO, ...) d_m3OpMacro ( _r0, _r0, TYPE, NAME, MACRO, ##__VA_ARGS__)
#define d_m3CommutativeOpMacro_f(TYPE, NAME, MACRO, ...) d_m3CommutativeOpMacro (_fp0, _fp0, TYPE, NAME, MACRO, ##__VA_ARGS__)
#define d_m3OpMacro_f(TYPE, NAME, MACRO, ...) d_m3OpMacro (_fp0, _fp0, TYPE, NAME, MACRO, ##__VA_ARGS__)
#define M3_FUNC(RES, A, B, OP) (RES) = OP((A), (B)) // Accept functions: res = OP(a,b)
#define M3_OPER(RES, A, B, OP) (RES) = ((A) OP (B)) // Accept operators: res = a OP b
#define d_m3CommutativeOpFunc_i(TYPE, NAME, OP) d_m3CommutativeOpMacro_i (TYPE, NAME, M3_FUNC, OP)
#define d_m3OpFunc_i(TYPE, NAME, OP) d_m3OpMacro_i (TYPE, NAME, M3_FUNC, OP)
#define d_m3CommutativeOpFunc_f(TYPE, NAME, OP) d_m3CommutativeOpMacro_f (TYPE, NAME, M3_FUNC, OP)
#define d_m3OpFunc_f(TYPE, NAME, OP) d_m3OpMacro_f (TYPE, NAME, M3_FUNC, OP)
#define d_m3CommutativeOp_i(TYPE, NAME, OP) d_m3CommutativeOpMacro_i (TYPE, NAME, M3_OPER, OP)
#define d_m3Op_i(TYPE, NAME, OP) d_m3OpMacro_i (TYPE, NAME, M3_OPER, OP)
#define d_m3CommutativeOp_f(TYPE, NAME, OP) d_m3CommutativeOpMacro_f (TYPE, NAME, M3_OPER, OP)
#define d_m3Op_f(TYPE, NAME, OP) d_m3OpMacro_f (TYPE, NAME, M3_OPER, OP)
// compare needs to be distinct for fp 'cause the result must be _r0
#define d_m3CompareOp_f(TYPE, NAME, OP) d_m3OpMacro (_r0, _fp0, TYPE, NAME, M3_OPER, OP)
#define d_m3CommutativeCmpOp_f(TYPE, NAME, OP) d_m3CommutativeOpMacro (_r0, _fp0, TYPE, NAME, M3_OPER, OP)
//-----------------------
// signed
d_m3CommutativeOp_i (i32, Equal, ==) d_m3CommutativeOp_i (i64, Equal, ==)
d_m3CommutativeOp_i (i32, NotEqual, !=) d_m3CommutativeOp_i (i64, NotEqual, !=)
d_m3Op_i (i32, LessThan, < ) d_m3Op_i (i64, LessThan, < )
d_m3Op_i (i32, GreaterThan, > ) d_m3Op_i (i64, GreaterThan, > )
d_m3Op_i (i32, LessThanOrEqual, <=) d_m3Op_i (i64, LessThanOrEqual, <=)
d_m3Op_i (i32, GreaterThanOrEqual, >=) d_m3Op_i (i64, GreaterThanOrEqual, >=)
// unsigned
d_m3Op_i (u32, LessThan, < ) d_m3Op_i (u64, LessThan, < )
d_m3Op_i (u32, GreaterThan, > ) d_m3Op_i (u64, GreaterThan, > )
d_m3Op_i (u32, LessThanOrEqual, <=) d_m3Op_i (u64, LessThanOrEqual, <=)
d_m3Op_i (u32, GreaterThanOrEqual, >=) d_m3Op_i (u64, GreaterThanOrEqual, >=)
#if d_m3HasFloat
d_m3CommutativeCmpOp_f (f32, Equal, ==) d_m3CommutativeCmpOp_f (f64, Equal, ==)
d_m3CommutativeCmpOp_f (f32, NotEqual, !=) d_m3CommutativeCmpOp_f (f64, NotEqual, !=)
d_m3CompareOp_f (f32, LessThan, < ) d_m3CompareOp_f (f64, LessThan, < )
d_m3CompareOp_f (f32, GreaterThan, > ) d_m3CompareOp_f (f64, GreaterThan, > )
d_m3CompareOp_f (f32, LessThanOrEqual, <=) d_m3CompareOp_f (f64, LessThanOrEqual, <=)
d_m3CompareOp_f (f32, GreaterThanOrEqual, >=) d_m3CompareOp_f (f64, GreaterThanOrEqual, >=)
#endif
d_m3CommutativeOp_i (i32, Add, +) d_m3CommutativeOp_i (i64, Add, +)
d_m3CommutativeOp_i (i32, Multiply, *) d_m3CommutativeOp_i (i64, Multiply, *)
d_m3Op_i (i32, Subtract, -) d_m3Op_i (i64, Subtract, -)
#define OP_SHL_32(X,N) ((X) << ((u32)(N) % 32))
#define OP_SHL_64(X,N) ((X) << ((u64)(N) % 64))
#define OP_SHR_32(X,N) ((X) >> ((u32)(N) % 32))
#define OP_SHR_64(X,N) ((X) >> ((u64)(N) % 64))
d_m3OpFunc_i (u32, ShiftLeft, OP_SHL_32) d_m3OpFunc_i (u64, ShiftLeft, OP_SHL_64)
d_m3OpFunc_i (i32, ShiftRight, OP_SHR_32) d_m3OpFunc_i (i64, ShiftRight, OP_SHR_64)
d_m3OpFunc_i (u32, ShiftRight, OP_SHR_32) d_m3OpFunc_i (u64, ShiftRight, OP_SHR_64)
d_m3CommutativeOp_i (u32, And, &)
d_m3CommutativeOp_i (u32, Or, |)
d_m3CommutativeOp_i (u32, Xor, ^)
d_m3CommutativeOp_i (u64, And, &)
d_m3CommutativeOp_i (u64, Or, |)
d_m3CommutativeOp_i (u64, Xor, ^)
#if d_m3HasFloat
d_m3CommutativeOp_f (f32, Add, +) d_m3CommutativeOp_f (f64, Add, +)
d_m3CommutativeOp_f (f32, Multiply, *) d_m3CommutativeOp_f (f64, Multiply, *)
d_m3Op_f (f32, Subtract, -) d_m3Op_f (f64, Subtract, -)
d_m3Op_f (f32, Divide, /) d_m3Op_f (f64, Divide, /)
#endif
d_m3OpFunc_i(u32, Rotl, rotl32)
d_m3OpFunc_i(u32, Rotr, rotr32)
d_m3OpFunc_i(u64, Rotl, rotl64)
d_m3OpFunc_i(u64, Rotr, rotr64)
d_m3OpMacro_i(u32, Divide, OP_DIV_U);
d_m3OpMacro_i(i32, Divide, OP_DIV_S, INT32_MIN);
d_m3OpMacro_i(u64, Divide, OP_DIV_U);
d_m3OpMacro_i(i64, Divide, OP_DIV_S, INT64_MIN);
d_m3OpMacro_i(u32, Remainder, OP_REM_U);
d_m3OpMacro_i(i32, Remainder, OP_REM_S, INT32_MIN);
d_m3OpMacro_i(u64, Remainder, OP_REM_U);
d_m3OpMacro_i(i64, Remainder, OP_REM_S, INT64_MIN);
#if d_m3HasFloat
d_m3OpFunc_f(f32, Min, min_f32);
d_m3OpFunc_f(f32, Max, max_f32);
d_m3OpFunc_f(f64, Min, min_f64);
d_m3OpFunc_f(f64, Max, max_f64);
d_m3OpFunc_f(f32, CopySign, copysignf);
d_m3OpFunc_f(f64, CopySign, copysign);
#endif
// Unary operations
// Note: This macro follows the principle of d_m3OpMacro
#define d_m3UnaryMacro(RES, REG, TYPE, NAME, OP, ...) \
d_m3Op(TYPE##_##NAME##_r) \
{ \
OP((RES), (TYPE) REG, ##__VA_ARGS__); \
nextOp (); \
} \
d_m3Op(TYPE##_##NAME##_s) \
{ \
TYPE operand = slot (TYPE); \
OP((RES), operand, ##__VA_ARGS__); \
nextOp (); \
}
#define M3_UNARY(RES, X, OP) (RES) = OP(X)
#define d_m3UnaryOp_i(TYPE, NAME, OPERATION) d_m3UnaryMacro( _r0, _r0, TYPE, NAME, M3_UNARY, OPERATION)
#define d_m3UnaryOp_f(TYPE, NAME, OPERATION) d_m3UnaryMacro(_fp0, _fp0, TYPE, NAME, M3_UNARY, OPERATION)
#if d_m3HasFloat
d_m3UnaryOp_f (f32, Abs, fabsf); d_m3UnaryOp_f (f64, Abs, fabs);
d_m3UnaryOp_f (f32, Ceil, ceilf); d_m3UnaryOp_f (f64, Ceil, ceil);
d_m3UnaryOp_f (f32, Floor, floorf); d_m3UnaryOp_f (f64, Floor, floor);
d_m3UnaryOp_f (f32, Trunc, truncf); d_m3UnaryOp_f (f64, Trunc, trunc);
d_m3UnaryOp_f (f32, Sqrt, sqrtf); d_m3UnaryOp_f (f64, Sqrt, sqrt);
d_m3UnaryOp_f (f32, Nearest, rintf); d_m3UnaryOp_f (f64, Nearest, rint);
d_m3UnaryOp_f (f32, Negate, -); d_m3UnaryOp_f (f64, Negate, -);
#endif
#define OP_EQZ(x) ((x) == 0)
d_m3UnaryOp_i (i32, EqualToZero, OP_EQZ)
d_m3UnaryOp_i (i64, EqualToZero, OP_EQZ)
// clz(0), ctz(0) results are undefined for rest platforms, fix it
#if (defined(__i386__) || defined(__x86_64__)) && !(defined(__AVX2__) || (defined(__ABM__) && defined(__BMI__)))
#define OP_CLZ_32(x) (M3_UNLIKELY((x) == 0) ? 32 : __builtin_clz(x))
#define OP_CTZ_32(x) (M3_UNLIKELY((x) == 0) ? 32 : __builtin_ctz(x))
// for 64-bit instructions branchless approach more preferable
#define OP_CLZ_64(x) (__builtin_clzll((x) | (1LL << 0)) + OP_EQZ(x))
#define OP_CTZ_64(x) (__builtin_ctzll((x) | (1LL << 63)) + OP_EQZ(x))
#elif defined(__ppc__) || defined(__ppc64__)
// PowerPC is defined for __builtin_clz(0) and __builtin_ctz(0).
// See (https://github.com/aquynh/capstone/blob/master/MathExtras.h#L99)
#define OP_CLZ_32(x) __builtin_clz(x)
#define OP_CTZ_32(x) __builtin_ctz(x)
#define OP_CLZ_64(x) __builtin_clzll(x)
#define OP_CTZ_64(x) __builtin_ctzll(x)
#else
#define OP_CLZ_32(x) (M3_UNLIKELY((x) == 0) ? 32 : __builtin_clz(x))
#define OP_CTZ_32(x) (M3_UNLIKELY((x) == 0) ? 32 : __builtin_ctz(x))
#define OP_CLZ_64(x) (M3_UNLIKELY((x) == 0) ? 64 : __builtin_clzll(x))
#define OP_CTZ_64(x) (M3_UNLIKELY((x) == 0) ? 64 : __builtin_ctzll(x))
#endif
d_m3UnaryOp_i (u32, Clz, OP_CLZ_32)
d_m3UnaryOp_i (u64, Clz, OP_CLZ_64)
d_m3UnaryOp_i (u32, Ctz, OP_CTZ_32)
d_m3UnaryOp_i (u64, Ctz, OP_CTZ_64)
d_m3UnaryOp_i (u32, Popcnt, __builtin_popcount)
d_m3UnaryOp_i (u64, Popcnt, __builtin_popcountll)
#define OP_WRAP_I64(X) ((X) & 0x00000000ffffffff)
d_m3Op(i32_Wrap_i64_r)
{
_r0 = OP_WRAP_I64((i64) _r0);
nextOp ();
}
d_m3Op(i32_Wrap_i64_s)
{
i64 operand = slot (i64);
_r0 = OP_WRAP_I64(operand);
nextOp ();
}
// Integer sign extension operations
#define OP_EXTEND8_S_I32(X) ((int32_t)(int8_t)(X))
#define OP_EXTEND16_S_I32(X) ((int32_t)(int16_t)(X))
#define OP_EXTEND8_S_I64(X) ((int64_t)(int8_t)(X))
#define OP_EXTEND16_S_I64(X) ((int64_t)(int16_t)(X))
#define OP_EXTEND32_S_I64(X) ((int64_t)(int32_t)(X))
d_m3UnaryOp_i (i32, Extend8_s, OP_EXTEND8_S_I32)
d_m3UnaryOp_i (i32, Extend16_s, OP_EXTEND16_S_I32)
d_m3UnaryOp_i (i64, Extend8_s, OP_EXTEND8_S_I64)
d_m3UnaryOp_i (i64, Extend16_s, OP_EXTEND16_S_I64)
d_m3UnaryOp_i (i64, Extend32_s, OP_EXTEND32_S_I64)
#define d_m3TruncMacro(DEST, SRC, TYPE, NAME, FROM, OP, ...) \
d_m3Op(TYPE##_##NAME##_##FROM##_r_r) \
{ \
OP((DEST), (FROM) SRC, ##__VA_ARGS__); \
nextOp (); \
} \
d_m3Op(TYPE##_##NAME##_##FROM##_r_s) \
{ \
FROM * stack = slot_ptr (FROM); \
OP((DEST), (* stack), ##__VA_ARGS__); \
nextOp (); \
} \
d_m3Op(TYPE##_##NAME##_##FROM##_s_r) \
{ \
TYPE * dest = slot_ptr (TYPE); \
OP((* dest), (FROM) SRC, ##__VA_ARGS__); \
nextOp (); \
} \
d_m3Op(TYPE##_##NAME##_##FROM##_s_s) \
{ \
FROM * stack = slot_ptr (FROM); \
TYPE * dest = slot_ptr (TYPE); \
OP((* dest), (* stack), ##__VA_ARGS__); \
nextOp (); \
}
#if d_m3HasFloat
d_m3TruncMacro(_r0, _fp0, i32, Trunc, f32, OP_I32_TRUNC_F32)
d_m3TruncMacro(_r0, _fp0, u32, Trunc, f32, OP_U32_TRUNC_F32)
d_m3TruncMacro(_r0, _fp0, i32, Trunc, f64, OP_I32_TRUNC_F64)
d_m3TruncMacro(_r0, _fp0, u32, Trunc, f64, OP_U32_TRUNC_F64)
d_m3TruncMacro(_r0, _fp0, i64, Trunc, f32, OP_I64_TRUNC_F32)
d_m3TruncMacro(_r0, _fp0, u64, Trunc, f32, OP_U64_TRUNC_F32)
d_m3TruncMacro(_r0, _fp0, i64, Trunc, f64, OP_I64_TRUNC_F64)
d_m3TruncMacro(_r0, _fp0, u64, Trunc, f64, OP_U64_TRUNC_F64)
d_m3TruncMacro(_r0, _fp0, i32, TruncSat, f32, OP_I32_TRUNC_SAT_F32)
d_m3TruncMacro(_r0, _fp0, u32, TruncSat, f32, OP_U32_TRUNC_SAT_F32)
d_m3TruncMacro(_r0, _fp0, i32, TruncSat, f64, OP_I32_TRUNC_SAT_F64)
d_m3TruncMacro(_r0, _fp0, u32, TruncSat, f64, OP_U32_TRUNC_SAT_F64)
d_m3TruncMacro(_r0, _fp0, i64, TruncSat, f32, OP_I64_TRUNC_SAT_F32)
d_m3TruncMacro(_r0, _fp0, u64, TruncSat, f32, OP_U64_TRUNC_SAT_F32)
d_m3TruncMacro(_r0, _fp0, i64, TruncSat, f64, OP_I64_TRUNC_SAT_F64)
d_m3TruncMacro(_r0, _fp0, u64, TruncSat, f64, OP_U64_TRUNC_SAT_F64)
#endif
#define d_m3TypeModifyOp(REG_TO, REG_FROM, TO, NAME, FROM) \
d_m3Op(TO##_##NAME##_##FROM##_r) \
{ \
REG_TO = (TO) ((FROM) REG_FROM); \
nextOp (); \
} \
\
d_m3Op(TO##_##NAME##_##FROM##_s) \
{ \
FROM from = slot (FROM); \
REG_TO = (TO) (from); \
nextOp (); \
}
// Int to int
d_m3TypeModifyOp (_r0, _r0, i64, Extend, i32);
d_m3TypeModifyOp (_r0, _r0, i64, Extend, u32);
// Float to float
#if d_m3HasFloat
d_m3TypeModifyOp (_fp0, _fp0, f32, Demote, f64);
d_m3TypeModifyOp (_fp0, _fp0, f64, Promote, f32);
#endif
#define d_m3TypeConvertOp(REG_TO, REG_FROM, TO, NAME, FROM) \
d_m3Op(TO##_##NAME##_##FROM##_r_r) \
{ \
REG_TO = (TO) ((FROM) REG_FROM); \
nextOp (); \
} \
\
d_m3Op(TO##_##NAME##_##FROM##_s_r) \
{ \
slot (TO) = (TO) ((FROM) REG_FROM); \
nextOp (); \
} \
\
d_m3Op(TO##_##NAME##_##FROM##_r_s) \
{ \
FROM from = slot (FROM); \
REG_TO = (TO) (from); \
nextOp (); \
} \
\
d_m3Op(TO##_##NAME##_##FROM##_s_s) \
{ \
FROM from = slot (FROM); \
slot (TO) = (TO) (from); \
nextOp (); \
}
// Int to float
#if d_m3HasFloat
d_m3TypeConvertOp (_fp0, _r0, f64, Convert, i32);
d_m3TypeConvertOp (_fp0, _r0, f64, Convert, u32);
d_m3TypeConvertOp (_fp0, _r0, f64, Convert, i64);
d_m3TypeConvertOp (_fp0, _r0, f64, Convert, u64);
d_m3TypeConvertOp (_fp0, _r0, f32, Convert, i32);
d_m3TypeConvertOp (_fp0, _r0, f32, Convert, u32);
d_m3TypeConvertOp (_fp0, _r0, f32, Convert, i64);
d_m3TypeConvertOp (_fp0, _r0, f32, Convert, u64);
#endif
#define d_m3ReinterpretOp(REG, TO, SRC, FROM) \
d_m3Op(TO##_Reinterpret_##FROM##_r_r) \
{ \
union { FROM c; TO t; } u; \
u.c = (FROM) SRC; \
REG = u.t; \
nextOp (); \
} \
\
d_m3Op(TO##_Reinterpret_##FROM##_r_s) \
{ \
union { FROM c; TO t; } u; \
u.c = slot (FROM); \
REG = u.t; \
nextOp (); \
} \
\
d_m3Op(TO##_Reinterpret_##FROM##_s_r) \
{ \
union { FROM c; TO t; } u; \
u.c = (FROM) SRC; \
slot (TO) = u.t; \
nextOp (); \
} \
\
d_m3Op(TO##_Reinterpret_##FROM##_s_s) \
{ \
union { FROM c; TO t; } u; \
u.c = slot (FROM); \
slot (TO) = u.t; \
nextOp (); \
}
#if d_m3HasFloat
d_m3ReinterpretOp (_r0, i32, _fp0, f32)
d_m3ReinterpretOp (_r0, i64, _fp0, f64)
d_m3ReinterpretOp (_fp0, f32, _r0, i32)
d_m3ReinterpretOp (_fp0, f64, _r0, i64)
#endif
d_m3Op (GetGlobal_s32)
{
u32 * global = immediate (u32 *);
slot (u32) = * global; // printf ("get global: %p %" PRIi64 "\n", global, *global);
nextOp ();
}
d_m3Op (GetGlobal_s64)
{
u64 * global = immediate (u64 *);
slot (u64) = * global; // printf ("get global: %p %" PRIi64 "\n", global, *global);
nextOp ();
}
d_m3Op (SetGlobal_i32)
{
u32 * global = immediate (u32 *);
* global = (u32) _r0; // printf ("set global: %p %" PRIi64 "\n", global, _r0);
nextOp ();
}
d_m3Op (SetGlobal_i64)
{
u64 * global = immediate (u64 *);
* global = (u64) _r0; // printf ("set global: %p %" PRIi64 "\n", global, _r0);
nextOp ();
}
d_m3Op (Call)
{
pc_t callPC = immediate (pc_t);
i32 stackOffset = immediate (i32);
IM3Memory memory = m3MemInfo (_mem);
m3stack_t sp = _sp + stackOffset;
m3ret_t r = Call (callPC, sp, _mem, d_m3OpDefaultArgs);
_mem = memory->mallocated;
if (M3_LIKELY(not r))
nextOp ();
else
{
pushBacktraceFrame ();
forwardTrap (r);
}
}
d_m3Op (CallIndirect)
{
u32 tableIndex = slot (u32);
IM3Module module = immediate (IM3Module);
IM3FuncType type = immediate (IM3FuncType);
i32 stackOffset = immediate (i32);
IM3Memory memory = m3MemInfo (_mem);
m3stack_t sp = _sp + stackOffset;
m3ret_t r = m3Err_none;
if (M3_LIKELY(tableIndex < module->table0Size))
{
IM3Function function = module->table0 [tableIndex];
if (M3_LIKELY(function))
{
if (M3_LIKELY(type == function->funcType))
{
if (M3_UNLIKELY(not function->compiled))
r = CompileFunction (function);
if (M3_LIKELY(not r))
{
r = Call (function->compiled, sp, _mem, d_m3OpDefaultArgs);
_mem = memory->mallocated;
if (M3_LIKELY(not r))
nextOpDirect ();
else
{
pushBacktraceFrame ();
forwardTrap (r);
}
}
}
else r = m3Err_trapIndirectCallTypeMismatch;
}
else r = m3Err_trapTableElementIsNull;
}
else r = m3Err_trapTableIndexOutOfRange;
if (M3_UNLIKELY(r))
newTrap (r);
else forwardTrap (r);
}
d_m3Op (CallRawFunction)
{
d_m3TracePrepare
M3ImportContext ctx;
M3RawCall call = (M3RawCall) (* _pc++);
ctx.function = immediate (IM3Function);
ctx.userdata = immediate (void *);
u64* const sp = ((u64*)_sp);
IM3Memory memory = m3MemInfo (_mem);
IM3Runtime runtime = m3MemRuntime(_mem);
#if d_m3EnableStrace
IM3FuncType ftype = ctx.function->funcType;
FILE* out = stderr;
char outbuff[1024];
char* outp = outbuff;
char* oute = outbuff+1024;
outp += snprintf(outp, oute-outp, "%s!%s(", ctx.function->import.moduleUtf8, ctx.function->import.fieldUtf8);
const int nArgs = ftype->numArgs;
const int nRets = ftype->numRets;
u64 * args = sp + nRets;
for (int i=0; i<nArgs; i++) {
const int type = ftype->types[nRets + i];
switch (type) {
case c_m3Type_i32: outp += snprintf(outp, oute-outp, "%" PRIi32, *(i32*)(args+i)); break;
case c_m3Type_i64: outp += snprintf(outp, oute-outp, "%" PRIi64, *(i64*)(args+i)); break;
case c_m3Type_f32: outp += snprintf(outp, oute-outp, "%" PRIf32, *(f32*)(args+i)); break;
case c_m3Type_f64: outp += snprintf(outp, oute-outp, "%" PRIf64, *(f64*)(args+i)); break;
default: outp += snprintf(outp, oute-outp, "<type %d>", type); break;
}
outp += snprintf(outp, oute-outp, (i < nArgs-1) ? ", " : ")");
}
# if d_m3EnableStrace >= 2
outp += snprintf(outp, oute-outp, " { <native> }");
# endif
#endif
// m3_Call uses runtime->stack to set-up initial exported function stack.
// Reconfigure the stack to enable recursive invocations of m3_Call.
// I.e. exported/table function can be called from an impoted function.
void* stack_backup = runtime->stack;
runtime->stack = sp;
m3ret_t possible_trap = call (runtime, &ctx, sp, m3MemData(_mem));
runtime->stack = stack_backup;
#if d_m3EnableStrace
if (M3_UNLIKELY(possible_trap)) {
d_m3TracePrint("%s -> %s", outbuff, (char*)possible_trap);
} else {
switch (GetSingleRetType(ftype)) {
case c_m3Type_none: d_m3TracePrint("%s", outbuff); break;
case c_m3Type_i32: d_m3TracePrint("%s = %" PRIi32, outbuff, *(i32*)sp); break;
case c_m3Type_i64: d_m3TracePrint("%s = %" PRIi64, outbuff, *(i64*)sp); break;
case c_m3Type_f32: d_m3TracePrint("%s = %" PRIf32, outbuff, *(f32*)sp); break;
case c_m3Type_f64: d_m3TracePrint("%s = %" PRIf64, outbuff, *(f64*)sp); break;
}
}
#endif
if (M3_UNLIKELY(possible_trap)) {
_mem = memory->mallocated;
pushBacktraceFrame ();
}
forwardTrap (possible_trap);
}
d_m3Op (MemSize)
{
IM3Memory memory = m3MemInfo (_mem);
_r0 = memory->numPages;
nextOp ();
}
d_m3Op (MemGrow)
{
IM3Runtime runtime = m3MemRuntime(_mem);
IM3Memory memory = & runtime->memory;
u32 numPagesToGrow = (u32) _r0;
_r0 = memory->numPages;
if (M3_LIKELY(numPagesToGrow))
{
u32 requiredPages = memory->numPages + numPagesToGrow;
M3Result r = ResizeMemory (runtime, requiredPages);
if (r)
_r0 = -1;
_mem = memory->mallocated;
}
nextOp ();
}
d_m3Op (MemCopy)
{
u32 size = (u32) _r0;
u64 source = slot (u32);
u64 destination = slot (u32);
if (M3_LIKELY(destination + size <= _mem->length))
{
if (M3_LIKELY(source + size <= _mem->length))
{
u8 * dst = m3MemData (_mem) + destination;
u8 * src = m3MemData (_mem) + source;
memmove (dst, src, size);
nextOp ();
}
else d_outOfBoundsMemOp (source, size);
}
else d_outOfBoundsMemOp (destination, size);
}
d_m3Op (MemFill)
{
u32 size = (u32) _r0;
u32 byte = slot (u32);
u64 destination = slot (u32);
if (M3_LIKELY(destination + size <= _mem->length))
{
u8 * mem8 = m3MemData (_mem) + destination;
memset (mem8, (u8) byte, size);
nextOp ();
}
else d_outOfBoundsMemOp (destination, size);
}
// it's a debate: should the compilation be trigger be the caller or callee page.
// it's a much easier to put it in the caller pager. if it's in the callee, either the entire page
// has be left dangling or it's just a stub that jumps to a newly acquired page. In Gestalt, I opted
// for the stub approach. Stubbing makes it easier to dynamically free the compilation. You can also
// do both.
d_m3Op (Compile)
{
rewrite_op (op_Call);
IM3Function function = immediate (IM3Function);
m3ret_t result = m3Err_none;
if (M3_UNLIKELY(not function->compiled)) // check to see if function was compiled since this operation was emitted.
result = CompileFunction (function);
if (not result)
{
// patch up compiled pc and call rewritten op_Call
* ((void**) --_pc) = (void*) (function->compiled);
--_pc;
nextOpDirect ();
}
newTrap (result);
}
d_m3Op (Entry)
{
d_m3ClearRegisters
d_m3TracePrepare
IM3Function function = immediate (IM3Function);
IM3Memory memory = m3MemInfo (_mem);
#if d_m3SkipStackCheck
if (true)
#else
if (M3_LIKELY ((void *) (_sp + function->maxStackSlots) < _mem->maxStack))
#endif
{
#if defined(DEBUG)
function->hits++;
#endif
u8 * stack = (u8 *) ((m3slot_t *) _sp + function->numRetAndArgSlots);
memset (stack, 0x0, function->numLocalBytes);
stack += function->numLocalBytes;
if (function->constants)
{
memcpy (stack, function->constants, function->numConstantBytes);
}
#if d_m3EnableStrace >= 2
d_m3TracePrint("%s %s {", m3_GetFunctionName(function), SPrintFunctionArgList (function, _sp + function->numRetSlots));
trace_rt->callDepth++;
#endif
m3ret_t r = nextOpImpl ();
#if d_m3EnableStrace >= 2
trace_rt->callDepth--;
if (r) {
d_m3TracePrint("} !trap = %s", (char*)r);
} else {
int rettype = GetSingleRetType(function->funcType);
if (rettype != c_m3Type_none) {
char str [128] = { 0 };
SPrintArg (str, 127, _sp, rettype);
d_m3TracePrint("} = %s", str);
} else {
d_m3TracePrint("}");
}
}
#endif
if (M3_UNLIKELY(r)) {
_mem = memory->mallocated;
fillBacktraceFrame ();
}
forwardTrap (r);
}
else newTrap (m3Err_trapStackOverflow);
}
d_m3Op (Loop)
{
d_m3TracePrepare
// regs are unused coming into a loop anyway
// this reduces code size & stack usage
d_m3ClearRegisters
m3ret_t r;
IM3Memory memory = m3MemInfo (_mem);
do
{
#if d_m3EnableStrace >= 3
d_m3TracePrint("iter {");
trace_rt->callDepth++;
#endif
r = nextOpImpl ();
#if d_m3EnableStrace >= 3
trace_rt->callDepth--;
d_m3TracePrint("}");
#endif
// linear memory pointer needs refreshed here because the block it's looping over
// can potentially invoke the grow operation.
_mem = memory->mallocated;
}
while (r == _pc);
forwardTrap (r);
}
d_m3Op (Branch)
{
jumpOp (* _pc);
}
d_m3Op (If_r)
{
i32 condition = (i32) _r0;
pc_t elsePC = immediate (pc_t);
if (condition)
nextOp ();
else
jumpOp (elsePC);
}
d_m3Op (If_s)
{
i32 condition = slot (i32);
pc_t elsePC = immediate (pc_t);
if (condition)
nextOp ();
else
jumpOp (elsePC);
}
d_m3Op (BranchTable)
{
u32 branchIndex = slot (u32); // branch index is always in a slot
u32 numTargets = immediate (u32);
pc_t * branches = (pc_t *) _pc;
if (branchIndex > numTargets)
branchIndex = numTargets; // the default index
jumpOp (branches [branchIndex]);
}
#define d_m3SetRegisterSetSlot(TYPE, REG) \
d_m3Op (SetRegister_##TYPE) \
{ \
REG = slot (TYPE); \
nextOp (); \
} \
\
d_m3Op (SetSlot_##TYPE) \
{ \
slot (TYPE) = (TYPE) REG; \
nextOp (); \
} \
\
d_m3Op (PreserveSetSlot_##TYPE) \
{ \
TYPE * stack = slot_ptr (TYPE); \
TYPE * preserve = slot_ptr (TYPE); \
\
* preserve = * stack; \
* stack = (TYPE) REG; \
\
nextOp (); \
}
d_m3SetRegisterSetSlot (i32, _r0)
d_m3SetRegisterSetSlot (i64, _r0)
#if d_m3HasFloat
d_m3SetRegisterSetSlot (f32, _fp0)
d_m3SetRegisterSetSlot (f64, _fp0)
#endif
d_m3Op (CopySlot_32)
{
u32 * dst = slot_ptr (u32);
u32 * src = slot_ptr (u32);
* dst = * src;
nextOp ();
}
d_m3Op (PreserveCopySlot_32)
{
u32 * dest = slot_ptr (u32);
u32 * src = slot_ptr (u32);
u32 * preserve = slot_ptr (u32);
* preserve = * dest;
* dest = * src;
nextOp ();
}
d_m3Op (CopySlot_64)
{
u64 * dst = slot_ptr (u64);
u64 * src = slot_ptr (u64);
* dst = * src; // printf ("copy: %p <- %" PRIi64 " <- %p\n", dst, * dst, src);
nextOp ();
}
d_m3Op (PreserveCopySlot_64)
{
u64 * dest = slot_ptr (u64);
u64 * src = slot_ptr (u64);
u64 * preserve = slot_ptr (u64);
* preserve = * dest;
* dest = * src;
nextOp ();
}
#if d_m3EnableOpTracing
//--------------------------------------------------------------------------------------------------------
d_m3Op (DumpStack)
{
u32 opcodeIndex = immediate (u32);
u32 stackHeight = immediate (u32);
IM3Function function = immediate (IM3Function);
cstr_t funcName = (function) ? m3_GetFunctionName(function) : "";
printf (" %4d ", opcodeIndex);
printf (" %-25s r0: 0x%016" PRIx64 " i:%" PRIi64 " u:%" PRIu64 "\n", funcName, _r0, _r0, _r0);
#if d_m3HasFloat
printf (" fp0: %" PRIf64 "\n", _fp0);
#endif
m3stack_t sp = _sp;
for (u32 i = 0; i < stackHeight; ++i)
{
cstr_t kind = "";
printf ("%p %5s %2d: 0x%" PRIx64 " i:%" PRIi64 "\n", sp, kind, i, (u64) *(sp), (i64) *(sp));
++sp;
}
printf ("---------------------------------------------------------------------------------------------------------\n");
nextOpDirect();
}
#endif
#define d_m3Select_i(TYPE, REG) \
d_m3Op (Select_##TYPE##_rss) \
{ \
i32 condition = (i32) _r0; \
\
TYPE operand2 = slot (TYPE); \
TYPE operand1 = slot (TYPE); \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
} \
\
d_m3Op (Select_##TYPE##_srs) \
{ \
i32 condition = slot (i32); \
\
TYPE operand2 = (TYPE) REG; \
TYPE operand1 = slot (TYPE); \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
} \
\
d_m3Op (Select_##TYPE##_ssr) \
{ \
i32 condition = slot (i32); \
\
TYPE operand2 = slot (TYPE); \
TYPE operand1 = (TYPE) REG; \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
} \
\
d_m3Op (Select_##TYPE##_sss) \
{ \
i32 condition = slot (i32); \
\
TYPE operand2 = slot (TYPE); \
TYPE operand1 = slot (TYPE); \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
}
d_m3Select_i (i32, _r0)
d_m3Select_i (i64, _r0)
#define d_m3Select_f(TYPE, REG, LABEL, SELECTOR) \
d_m3Op (Select_##TYPE##_##LABEL##ss) \
{ \
i32 condition = (i32) SELECTOR; \
\
TYPE operand2 = slot (TYPE); \
TYPE operand1 = slot (TYPE); \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
} \
\
d_m3Op (Select_##TYPE##_##LABEL##rs) \
{ \
i32 condition = (i32) SELECTOR; \
\
TYPE operand2 = (TYPE) REG; \
TYPE operand1 = slot (TYPE); \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
} \
\
d_m3Op (Select_##TYPE##_##LABEL##sr) \
{ \
i32 condition = (i32) SELECTOR; \
\
TYPE operand2 = slot (TYPE); \
TYPE operand1 = (TYPE) REG; \
\
REG = (condition) ? operand1 : operand2; \
\
nextOp (); \
}
#if d_m3HasFloat
d_m3Select_f (f32, _fp0, r, _r0)
d_m3Select_f (f32, _fp0, s, slot (i32))
d_m3Select_f (f64, _fp0, r, _r0)
d_m3Select_f (f64, _fp0, s, slot (i32))
#endif
d_m3Op (Return)
{
m3StackCheck();
return m3Err_none;
}
d_m3Op (BranchIf_r)
{
i32 condition = (i32) _r0;
pc_t branch = immediate (pc_t);
if (condition)
{
jumpOp (branch);
}
else nextOp ();
}
d_m3Op (BranchIf_s)
{
i32 condition = slot (i32);
pc_t branch = immediate (pc_t);
if (condition)
{
jumpOp (branch);
}
else nextOp ();
}
d_m3Op (BranchIfPrologue_r)
{
i32 condition = (i32) _r0;
pc_t branch = immediate (pc_t);
if (condition)
{
// this is the "prologue" that ends with
// a plain branch to the actual target
nextOp ();
}
else jumpOp (branch); // jump over the prologue
}
d_m3Op (BranchIfPrologue_s)
{
i32 condition = slot (i32);
pc_t branch = immediate (pc_t);
if (condition)
{
nextOp ();
}
else jumpOp (branch);
}
d_m3Op (ContinueLoop)
{
m3StackCheck();
// TODO: this is where execution can "escape" the M3 code and callback to the client / fiber switch
// OR it can go in the Loop operation. I think it's best to do here. adding code to the loop operation
// has the potential to increase its native-stack usage. (don't forget ContinueLoopIf too.)
void * loopId = immediate (void *);
return loopId;
}
d_m3Op (ContinueLoopIf)
{
i32 condition = (i32) _r0;
void * loopId = immediate (void *);
if (condition)
{
return loopId;
}
else nextOp ();
}
d_m3Op (Const32)
{
u32 value = * (u32 *)_pc++;
slot (u32) = value;
nextOp ();
}
d_m3Op (Const64)
{
u64 value = * (u64 *)_pc;
_pc += (M3_SIZEOF_PTR == 4) ? 2 : 1;
slot (u64) = value;
nextOp ();
}
d_m3Op (Unsupported)
{
newTrap ("unsupported instruction executed");
}
d_m3Op (Unreachable)
{
m3StackCheck();
newTrap (m3Err_trapUnreachable);
}
d_m3Op (End)
{
m3StackCheck();
return m3Err_none;
}
d_m3Op (SetGlobal_s32)
{
u32 * global = immediate (u32 *);
* global = slot (u32);
nextOp ();
}
d_m3Op (SetGlobal_s64)
{
u64 * global = immediate (u64 *);
* global = slot (u64);
nextOp ();
}
#if d_m3HasFloat
d_m3Op (SetGlobal_f32)
{
f32 * global = immediate (f32 *);
* global = _fp0;
nextOp ();
}
d_m3Op (SetGlobal_f64)
{
f64 * global = immediate (f64 *);
* global = _fp0;
nextOp ();
}
#endif
#if d_m3SkipMemoryBoundsCheck
# define m3MemCheck(x) true
#else
# define m3MemCheck(x) M3_LIKELY(x)
#endif
// memcpy here is to support non-aligned access on some platforms.
#define d_m3Load(REG,DEST_TYPE,SRC_TYPE) \
d_m3Op(DEST_TYPE##_Load_##SRC_TYPE##_r) \
{ \
d_m3TracePrepare \
u32 offset = immediate (u32); \
u64 operand = (u32) _r0; \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (SRC_TYPE) <= _mem->length \
)) { \
u8* src8 = m3MemData(_mem) + operand; \
SRC_TYPE value; \
memcpy(&value, src8, sizeof(value)); \
M3_BSWAP_##SRC_TYPE(value); \
REG = (DEST_TYPE)value; \
d_m3TraceLoad(DEST_TYPE, operand, REG); \
nextOp (); \
} else d_outOfBounds; \
} \
d_m3Op(DEST_TYPE##_Load_##SRC_TYPE##_s) \
{ \
d_m3TracePrepare \
u64 operand = slot (u32); \
u32 offset = immediate (u32); \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (SRC_TYPE) <= _mem->length \
)) { \
u8* src8 = m3MemData(_mem) + operand; \
SRC_TYPE value; \
memcpy(&value, src8, sizeof(value)); \
M3_BSWAP_##SRC_TYPE(value); \
REG = (DEST_TYPE)value; \
d_m3TraceLoad(DEST_TYPE, operand, REG); \
nextOp (); \
} else d_outOfBounds; \
}
// printf ("get: %d -> %d\n", operand + offset, (i64) REG);
#define d_m3Load_i(DEST_TYPE, SRC_TYPE) d_m3Load(_r0, DEST_TYPE, SRC_TYPE)
#define d_m3Load_f(DEST_TYPE, SRC_TYPE) d_m3Load(_fp0, DEST_TYPE, SRC_TYPE)
#if d_m3HasFloat
d_m3Load_f (f32, f32);
d_m3Load_f (f64, f64);
#endif
d_m3Load_i (i32, i8);
d_m3Load_i (i32, u8);
d_m3Load_i (i32, i16);
d_m3Load_i (i32, u16);
d_m3Load_i (i32, i32);
d_m3Load_i (i64, i8);
d_m3Load_i (i64, u8);
d_m3Load_i (i64, i16);
d_m3Load_i (i64, u16);
d_m3Load_i (i64, i32);
d_m3Load_i (i64, u32);
d_m3Load_i (i64, i64);
#define d_m3Store(REG, SRC_TYPE, DEST_TYPE) \
d_m3Op (SRC_TYPE##_Store_##DEST_TYPE##_rs) \
{ \
d_m3TracePrepare \
u64 operand = slot (u32); \
u32 offset = immediate (u32); \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (DEST_TYPE) <= _mem->length \
)) { \
d_m3TraceStore(SRC_TYPE, operand, REG); \
u8* mem8 = m3MemData(_mem) + operand; \
DEST_TYPE val = (DEST_TYPE) REG; \
M3_BSWAP_##DEST_TYPE(val); \
memcpy(mem8, &val, sizeof(val)); \
nextOp (); \
} else d_outOfBounds; \
} \
d_m3Op (SRC_TYPE##_Store_##DEST_TYPE##_sr) \
{ \
d_m3TracePrepare \
const SRC_TYPE value = slot (SRC_TYPE); \
u64 operand = (u32) _r0; \
u32 offset = immediate (u32); \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (DEST_TYPE) <= _mem->length \
)) { \
d_m3TraceStore(SRC_TYPE, operand, value); \
u8* mem8 = m3MemData(_mem) + operand; \
DEST_TYPE val = (DEST_TYPE) value; \
M3_BSWAP_##DEST_TYPE(val); \
memcpy(mem8, &val, sizeof(val)); \
nextOp (); \
} else d_outOfBounds; \
} \
d_m3Op (SRC_TYPE##_Store_##DEST_TYPE##_ss) \
{ \
d_m3TracePrepare \
const SRC_TYPE value = slot (SRC_TYPE); \
u64 operand = slot (u32); \
u32 offset = immediate (u32); \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (DEST_TYPE) <= _mem->length \
)) { \
d_m3TraceStore(SRC_TYPE, operand, value); \
u8* mem8 = m3MemData(_mem) + operand; \
DEST_TYPE val = (DEST_TYPE) value; \
M3_BSWAP_##DEST_TYPE(val); \
memcpy(mem8, &val, sizeof(val)); \
nextOp (); \
} else d_outOfBounds; \
}
// both operands can be in regs when storing a float
#define d_m3StoreFp(REG, TYPE) \
d_m3Op (TYPE##_Store_##TYPE##_rr) \
{ \
d_m3TracePrepare \
u64 operand = (u32) _r0; \
u32 offset = immediate (u32); \
operand += offset; \
\
if (m3MemCheck( \
operand + sizeof (TYPE) <= _mem->length \
)) { \
d_m3TraceStore(TYPE, operand, REG); \
u8* mem8 = m3MemData(_mem) + operand; \
TYPE val = (TYPE) REG; \
M3_BSWAP_##TYPE(val); \
memcpy(mem8, &val, sizeof(val)); \
nextOp (); \
} else d_outOfBounds; \
}
#define d_m3Store_i(SRC_TYPE, DEST_TYPE) d_m3Store(_r0, SRC_TYPE, DEST_TYPE)
#define d_m3Store_f(SRC_TYPE, DEST_TYPE) d_m3Store(_fp0, SRC_TYPE, DEST_TYPE) d_m3StoreFp (_fp0, SRC_TYPE);
#if d_m3HasFloat
d_m3Store_f (f32, f32)
d_m3Store_f (f64, f64)
#endif
d_m3Store_i (i32, u8)
d_m3Store_i (i32, i16)
d_m3Store_i (i32, i32)
d_m3Store_i (i64, u8)
d_m3Store_i (i64, i16)
d_m3Store_i (i64, i32)
d_m3Store_i (i64, i64)
#undef m3MemCheck
//---------------------------------------------------------------------------------------------------------------------
// debug/profiling
//---------------------------------------------------------------------------------------------------------------------
#if d_m3EnableOpTracing
d_m3RetSig debugOp (d_m3OpSig, cstr_t i_opcode)
{
char name [100];
strcpy (name, strstr (i_opcode, "op_") + 3);
char * bracket = strstr (name, "(");
if (bracket) {
*bracket = 0;
}
puts (name);
nextOpDirect();
}
# endif
# if d_m3EnableOpProfiling
d_m3RetSig profileOp (d_m3OpSig, cstr_t i_operationName)
{
ProfileHit (i_operationName);
nextOpDirect();
}
# endif
d_m3EndExternC
#endif // m3_exec_h
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