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|
|//
|// Common DynASM definitions and macros for x86 CPUs.
|// Copyright (C) 2005-2011 Mike Pall. See Copyright Notice in luajit.h
|//
|
|// Standard DynASM declarations.
|.arch x86
|.section code, deopt, tail, mfmap
|
|// Type definitions with (almost) global validity.
|.type L, lua_State, esi // L.
|.type BASE, TValue, ebx // L->base.
|.type TOP, TValue, edi // L->top (calls/open ops).
|.type CI, CallInfo, ecx // L->ci (calls, locally).
|.type LCL, LClosure, eax // func->value (calls).
|
|// Type definitions with local validity.
|.type GL, global_State
|.type TVALUE, TValue
|.type VALUE, Value
|.type CINFO, CallInfo
|.type GCOBJECT, GCObject
|.type TSTRING, TString
|.type TABLE, Table
|.type CCLOSURE, CClosure
|.type PROTO, Proto
|.type UPVAL, UpVal
|.type NODE, Node
|
|// Definitions copied to DynASM domain to avoid unnecessary constant args.
|// CHECK: must match with the definitions in lua.h!
|.define LUA_TNIL, 0
|.define LUA_TBOOLEAN, 1
|.define LUA_TLIGHTUSERDATA, 2
|.define LUA_TNUMBER, 3
|.define LUA_TSTRING, 4
|.define LUA_TTABLE, 5
|.define LUA_TFUNCTION, 6
|.define LUA_TUSERDATA, 7
|.define LUA_TTHREAD, 8
|
|.define LUA_TNUM_NUM, 0x33
|.define LUA_TNUM_NUM_NUM, 0x333
|.define LUA_TSTR_STR, 0x44
|.define LUA_TSTR_NUM, 0x43
|.define LUA_TSTR_NUM_NUM, 0x433
|.define LUA_TTABLE_NUM, 0x53
|.define LUA_TTABLE_STR, 0x54
|
|// Macros to test, set and copy stack slots.
|.macro istt, idx, tp; cmp dword BASE[idx].tt, tp; .endmacro
|.macro isnil, idx; istt idx, LUA_TNIL; .endmacro
|.macro isnumber, idx; istt idx, LUA_TNUMBER; .endmacro
|.macro isstring, idx; istt idx, LUA_TSTRING; .endmacro
|.macro istable, idx; istt idx, LUA_TTABLE; .endmacro
|.macro isfunction, idx; istt idx, LUA_TFUNCTION; .endmacro
|
|.macro isnumber2, idx1, idx2, reg
| mov reg, BASE[idx1].tt; shl reg, 4; or reg, BASE[idx2].tt
| cmp reg, LUA_TNUM_NUM
|.endmacro
|.macro isnumber2, idx1, idx2; isnumber2, idx1, idx2, eax; .endmacro
|
|.macro isnumber3, idx1, idx2, idx3, reg
| mov reg, BASE[idx1].tt; shl reg, 4; or reg, BASE[idx2].tt
| shl reg, 4; or reg, BASE[idx3].tt; cmp reg, LUA_TNUM_NUM_NUM
|.endmacro
|.macro isnumber3, idx1, idx2, idx3; isnumber3, idx1, idx2, idx3, eax; .endmacro
|
|.macro tvisnil, tv; cmp dword tv.tt, LUA_TNIL; .endmacro
|
|.macro settt, tv, tp; mov dword tv.tt, tp; .endmacro
|.macro setnilvalue, tv; settt tv, LUA_TNIL; .endmacro
|
|.macro setbvalue, tv, val // May use edx.
||if (val) { /* true */
| mov edx, LUA_TBOOLEAN
| mov dword tv.value, edx // Assumes: LUA_TBOOLEAN == 1
| settt tv, edx
||} else { /* false */
| mov dword tv.value, 0
| settt tv, LUA_TBOOLEAN
||}
|.endmacro
|
|.macro loadnvaluek, vptr
||if ((vptr)->n == (lua_Number)0) {
| fldz
||} else if ((vptr)->n == (lua_Number)1) {
| fld1
||} else {
| fld qword [vptr]
||}
|.endmacro
|
|.macro setnvaluek, tv, vptr // Pass a Value *! With permanent addr.
| // SSE2 does not pay off here (I tried).
| loadnvaluek vptr
| fstp qword tv.value
| settt tv, LUA_TNUMBER
|.endmacro
|
|.macro setnvalue, tv, vptr // Pass a Value *! Temporary ok.
| mov dword tv.value, (vptr)->na[0]
| mov dword tv.value.na[1], (vptr)->na[1]
| settt tv, LUA_TNUMBER
|.endmacro
|
|.macro setsvalue, tv, vptr
| mov aword tv.value, vptr
| settt tv, LUA_TSTRING
|.endmacro
|
|.macro sethvalue, tv, vptr
| mov aword tv.value, vptr
| settt tv, LUA_TTABLE
|.endmacro
|
|.macro copyslotSSE, D, S, R1 // May use xmm0.
| mov R1, S.tt; movq xmm0, qword S.value
| mov D.tt, R1; movq qword D.value, xmm0
|.endmacro
|
|.macro copyslot, D, S, R1, R2, R3
||if (J->flags & JIT_F_CPU_SSE2) {
| copyslotSSE D, S, R1
||} else {
| mov R1, S.value; mov R2, S.value.na[1]; mov R3, S.tt
| mov D.value, R1; mov D.value.na[1], R2; mov D.tt, R3
||}
|.endmacro
|
|.macro copyslot, D, S, R1, R2
||if (J->flags & JIT_F_CPU_SSE2) {
| copyslotSSE D, S, R1
||} else {
| mov R1, S.value; mov R2, S.value.na[1]; mov D.value, R1
| mov R1, S.tt; mov D.value.na[1], R2; mov D.tt, R1
||}
|.endmacro
|
|.macro copyslot, D, S
| copyslot D, S, ecx, edx, eax
|.endmacro
|
|.macro copyconst, tv, tvk // May use edx.
||switch (ttype(tvk)) {
||case LUA_TNIL:
| setnilvalue tv
|| break;
||case LUA_TBOOLEAN:
| setbvalue tv, bvalue(tvk) // May use edx.
|| break;
||case LUA_TNUMBER: {
| setnvaluek tv, &(tvk)->value
|| break;
||}
||case LUA_TSTRING:
| setsvalue tv, &gcvalue(tvk)
|| break;
||default: lua_assert(0); break;
||}
|.endmacro
|
|// Macros to get Lua structures.
|.macro getLCL, reg // May use CI and TOP (edi).
||if (!J->pt->is_vararg) {
| mov LCL:reg, BASE[-1].value
||} else {
| mov CI, L->ci
| mov TOP, CI->func
| mov LCL:reg, TOP->value
||}
|.endmacro
|.macro getLCL; getLCL eax; .endmacro
|
|// Macros to handle variants.
|.macro addidx, type, idx
||if (idx) {
| add type, idx*#type
||}
|.endmacro
|
|.macro subidx, type, idx
||if (idx) {
| sub type, idx*#type
||}
|.endmacro
|
|// Annoying x87 stuff: support for two compare variants.
|.macro fcomparepp // Compare and pop st0 >< st1.
||if (J->flags & JIT_F_CPU_CMOV) {
| fucomip st1
| fpop
||} else {
| fucompp
| fnstsw ax // eax modified!
| sahf
| // Sometimes test ah, imm8 would be faster.
| // But all following compares need to be changed then.
| // Don't bother since this is only compatibility stuff for old CPUs.
||}
|.endmacro
|
|// If you change LUA_TVALUE_ALIGN, be sure to change the Makefile, too:
|// DASMFLAGS= -D TVALUE_SIZE=...
|// Then rerun make. Or change the default below:
|.if not TVALUE_SIZE; .define TVALUE_SIZE, 16; .endif
|
|.if TVALUE_SIZE == 16
| .macro TValuemul, reg; sal reg, 4; .endmacro // *16
| .macro TValuediv, reg; sar reg, 4; .endmacro // /16
| .macro Nodemul, reg; sal reg, 5; .endmacro // *32
|.elif TVALUE_SIZE == 12
| .macro TValuemul, reg; sal reg, 2; lea reg, [reg+reg*2]; .endmacro // *12
| .macro TValuediv, reg; sal reg, 2; imul reg, 0xaaaaaaab; .endmacro // /12
| .macro Nodemul, reg; imul reg, 28; .endmacro // *28
|.else
| .fatal Unsupported TValue size `TVALUE_SIZE'.
|.endif
|
|//
|// x86 C calling conventions and stack frame layout during a JIT call:
|//
|// ebp+aword*4 CARG2 nresults
|// ebp+aword*3 CARG2 func (also used as SAVER3 for L)
|// ebp+aword*2 CARG1 L
|// ------------------------------- call to GATE_LJ
|// ebp+aword*1 retaddr
|// ebp+aword*0 frameptr ebp
|// ebp-aword*1 SAVER1 TOP edi
|// ebp-aword*2 SAVER2 BASE ebx
|// -------------------------------
|// GATE_LJ retaddr
|// esp+aword*2 ARG3
|// esp+aword*1 ARG2
|// esp+aword*0 ARG1 <-- esp for first JIT frame
|// -------------------------------
|// 1st JIT frame retaddr
|// esp+aword*2 ARG3
|// esp+aword*1 ARG2
|// esp+aword*0 ARG1 <-- esp for second JIT frame
|// -------------------------------
|// 2nd JIT frame retaddr
|//
|// We could omit the fixed frame pointer (ebp) and have one more register
|// available. But there is no pressing need (could use it for CI).
|// And it's easier for debugging (gdb is still confused -- why?).
|//
|// The stack is aligned to 4 awords (16 bytes). Calls to C functions
|// with up to 3 arguments do not need any stack pointer adjustment.
|//
|
|.define CARG3, [ebp+aword*4]
|.define CARG2, [ebp+aword*3]
|.define CARG1, [ebp+aword*2]
|.define SAVER1, [ebp-aword*1]
|.define SAVER2, [ebp-aword*2]
|.define ARG7, aword [esp+aword*6] // Requires large frame.
|.define ARG6, aword [esp+aword*5] // Requires large frame.
|.define ARG5, aword [esp+aword*4] // Requires large frame.
|.define ARG4, aword [esp+aword*3] // Requires large frame.
|.define ARG3, aword [esp+aword*2]
|.define ARG2, aword [esp+aword*1]
|.define ARG1, aword [esp]
|.define FRAME_RETADDR, aword [esp+aword*3]
|.define TMP3, [esp+aword*2]
|.define TMP2, [esp+aword*1]
|.define TMP1, [esp]
|.define FPARG2, qword [esp+qword*1] // Requires large frame.
|.define FPARG1, qword [esp]
|.define LJFRAME_OFFSET, aword*2 // 16 byte aligned with retaddr + ebp.
|.define FRAME_OFFSET, aword*3 // 16 byte aligned with retaddr.
|.define LFRAME_OFFSET, aword*7 // 16 byte aligned with retaddr.
|.define S2LFRAME_OFFSET, aword*4 // Delta to large frame.
|
|.macro call, target, a1
| mov ARG1, a1; call target; .endmacro
|.macro call, target, a1, a2
| mov ARG1, a1; mov ARG2, a2; call target; .endmacro
|.macro call, target, a1, a2, a3
| mov ARG1, a1; mov ARG2, a2; mov ARG3, a3; call target; .endmacro
|.macro call, target, a1, a2, a3, a4
| push a4; push a3; push a2; push a1
| call target; add esp, S2LFRAME_OFFSET; .endmacro
|.macro call, target, a1, a2, a3, a4, a5
| mov ARG1, a5; push a4; push a3; push a2; push a1
| call target; add esp, S2LFRAME_OFFSET; .endmacro
|
|// The following macros require a large frame.
|.macro call_LFRAME, target, a1, a2, a3, a4
| mov ARG1, a1; mov ARG2, a2; mov ARG3, a3; mov ARG4, a4
| call target; .endmacro
|.macro call_LFRAME, target, a1, a2, a3, a4, a5
| mov ARG1, a1; mov ARG2, a2; mov ARG3, a3; mov ARG4, a4; mov ARG5, a5
| call target; .endmacro
|
|
