Backed out changeset ae16e5919d19 (tree was closed for talos maintenance).

This commit is contained in:
Nicholas Nethercote 2009-07-01 11:33:54 +10:00
Родитель e78e9f8afd
Коммит bcbe52b5f0
9 изменённых файлов: 518 добавлений и 759 удалений

Просмотреть файл

@ -643,9 +643,9 @@ assemble(istream &in,
map<string,LIns*> labels;
map<string,pair<LOpcode,size_t> > op_map;
#define OPDEF(op, number, args, repkind) \
#define OPDEF(op, number, args) \
op_map[#op] = make_pair(LIR_##op, args);
#define OPDEF64(op, number, args, repkind) \
#define OPDEF64(op, number, args) \
op_map[#op] = make_pair(LIR_##op, args);
#include "nanojit/LIRopcode.tbl"
#undef OPDEF

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@ -1565,7 +1565,7 @@ namespace nanojit
for (int i=0, n = NumSavedRegs; i < n; i++) {
LIns *p = b->savedRegs[i];
if (p)
findSpecificRegFor(p, savedRegs[p->paramArg()]);
findSpecificRegFor(p, savedRegs[p->imm8()]);
}
}
@ -1584,10 +1584,10 @@ namespace nanojit
{
LInsp state = _thisfrag->lirbuf->state;
if (state)
findSpecificRegFor(state, argRegs[state->paramArg()]);
findSpecificRegFor(state, argRegs[state->imm8()]);
LInsp param1 = _thisfrag->lirbuf->param1;
if (param1)
findSpecificRegFor(param1, argRegs[param1->paramArg()]);
findSpecificRegFor(param1, argRegs[param1->imm8()]);
}
void Assembler::handleLoopCarriedExprs()

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@ -84,13 +84,12 @@ namespace nanojit
/* Opcodes must be strictly increasing without holes. */
uint32_t count = 0;
#define OPDEF(op, number, operands, repkind) \
NanoAssertMsg(LIR_##op == count++, "misnumbered opcode");
#define OPDEF64(op, number, operands, repkind) \
OPDEF(op, number, operands, repkind)
#include "LIRopcode.tbl"
#undef OPDEF
#undef OPDEF64
#define OPDEF(op, number, operands) \
NanoAssertMsg(LIR_##op == count++, "misnumbered opcode");
#define OPDEF64(op, number, operands) OPDEF(op, number, operands)
#include "LIRopcode.tbl"
#undef OPDEF
#undef OPDEF64
}
#endif

Просмотреть файл

@ -51,9 +51,9 @@ namespace nanojit
#ifdef FEATURE_NANOJIT
const uint8_t operandCount[] = {
#define OPDEF(op, number, operands, repkind) \
#define OPDEF(op, number, operands) \
operands,
#define OPDEF64(op, number, operands, repkind) \
#define OPDEF64(op, number, operands) \
operands,
#include "LIRopcode.tbl"
#undef OPDEF
@ -61,35 +61,13 @@ namespace nanojit
0
};
const uint8_t repKinds[] = {
#define OPDEF(op, number, operands, repkind) \
LRK_##repkind,
#define OPDEF64(op, number, operands, repkind) \
OPDEF(op, number, operands, repkind)
#include "LIRopcode.tbl"
#undef OPDEF
#undef OPDEF64
0
};
const uint8_t insSizes[] = {
#define OPDEF(op, number, operands, repkind) \
sizeof(LIns##repkind),
#define OPDEF64(op, number, operands, repkind) \
OPDEF(op, number, operands, repkind)
#include "LIRopcode.tbl"
#undef OPDEF
#undef OPDEF64
0
};
// LIR verbose specific
#ifdef NJ_VERBOSE
const char* lirNames[] = {
#define OPDEF(op, number, operands, repkind) \
#define OPDEF(op, number, operands) \
#op,
#define OPDEF64(op, number, operands, repkind) \
#define OPDEF64(op, number, operands) \
#op,
#include "LIRopcode.tbl"
#undef OPDEF
@ -153,8 +131,7 @@ namespace nanojit
int32_t LirBuffer::insCount()
{
// A LIR_skip payload is considered part of the LIR_skip, and LIR_call
// arg slots are considered part of the LIR_call.
// Doesn't include LIR_skip payload or LIR_call arg slots.
return _stats.lir;
}
@ -188,10 +165,10 @@ namespace nanojit
// Unlike all the ins*() functions, we don't call makeRoom() here
// because we know we have enough space, having just started a new
// page.
LInsSk* insSk = (LInsSk*)_unused;
LIns* ins = insSk->getLIns();
ins->initLInsSk((LInsp)addrOfLastLInsOnCurrentPage);
_unused += sizeof(LInsSk);
LInsp l = (LInsp)_unused;
l->setIns1(LIR_skip, (LInsp)addrOfLastLInsOnCurrentPage);
l->resv()->clear();
_unused += sizeof(LIns);
_stats.lir++;
}
@ -231,42 +208,40 @@ namespace nanojit
moveToNewPage(addrOfLastLInsOnPage);
}
// Make sure it's word-aligned.
NanoAssert(0 == startOfRoom % sizeof(void*));
return startOfRoom;
}
LInsp LirBufWriter::insStorei(LInsp val, LInsp base, int32_t d)
{
LOpcode op = val->isQuad() ? LIR_stqi : LIR_sti;
LInsSti* insSti = (LInsSti*)_buf->makeRoom(sizeof(LInsSti));
LIns* ins = insSti->getLIns();
ins->initLInsSti(op, val, base, d);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setStorei(op, val, base, d);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::ins0(LOpcode op)
{
LInsOp0* insOp0 = (LInsOp0*)_buf->makeRoom(sizeof(LInsOp0));
LIns* ins = insOp0->getLIns();
ins->initLInsOp0(op);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setIns0(op);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::ins1(LOpcode op, LInsp o1)
{
LInsOp1* insOp1 = (LInsOp1*)_buf->makeRoom(sizeof(LInsOp1));
LIns* ins = insOp1->getLIns();
ins->initLInsOp1(op, o1);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setIns1(op, o1);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::ins2(LOpcode op, LInsp o1, LInsp o2)
{
LInsOp2* insOp2 = (LInsOp2*)_buf->makeRoom(sizeof(LInsOp2));
LIns* ins = insOp2->getLIns();
ins->initLInsOp2(op, o1, o2);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setIns2(op, o1, o2);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::insLoad(LOpcode op, LInsp base, LInsp d)
@ -288,39 +263,39 @@ namespace nanojit
LInsp LirBufWriter::insAlloc(int32_t size)
{
size = (size+3)>>2; // # of required 32bit words
LInsI* insI = (LInsI*)_buf->makeRoom(sizeof(LInsI));
LIns* ins = insI->getLIns();
ins->initLInsI(LIR_alloc, size);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setAlloc(LIR_alloc, size);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::insParam(int32_t arg, int32_t kind)
{
LInsP* insP = (LInsP*)_buf->makeRoom(sizeof(LInsP));
LIns* ins = insP->getLIns();
ins->initLInsP(arg, kind);
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setParam(LIR_param, arg, kind);
l->resv()->clear();
if (kind) {
NanoAssert(arg < NumSavedRegs);
_buf->savedRegs[arg] = ins;
_buf->savedRegs[arg] = l;
_buf->explicitSavedRegs = true;
}
return ins;
return l;
}
LInsp LirBufWriter::insImm(int32_t imm)
{
LInsI* insI = (LInsI*)_buf->makeRoom(sizeof(LInsI));
LIns* ins = insI->getLIns();
ins->initLInsI(LIR_int, imm);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setImm(LIR_int, imm);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::insImmq(uint64_t imm)
{
LInsI64* insI64 = (LInsI64*)_buf->makeRoom(sizeof(LInsI64));
LIns* ins = insI64->getLIns();
ins->initLInsI64(LIR_quad, imm);
return ins;
LInsp l = (LInsp)_buf->makeRoom(sizeof(LIns));
l->setImmq(LIR_quad, imm);
l->resv()->clear();
return l;
}
LInsp LirBufWriter::insSkip(size_t payload_szB)
@ -333,14 +308,14 @@ namespace nanojit
NanoAssert(0 == NJ_MAX_SKIP_PAYLOAD_SZB % sizeof(void*));
NanoAssert(sizeof(void*) <= payload_szB && payload_szB <= NJ_MAX_SKIP_PAYLOAD_SZB);
uintptr_t payload = _buf->makeRoom(payload_szB + sizeof(LInsSk));
uintptr_t payload = _buf->makeRoom(payload_szB + sizeof(LIns)); // payload + skip
uintptr_t prevLInsAddr = payload - sizeof(LIns);
LInsSk* insSk = (LInsSk*)(payload + payload_szB);
LIns* ins = insSk->getLIns();
LInsp l = (LInsp)(payload + payload_szB);
NanoAssert(prevLInsAddr >= pageDataStart(prevLInsAddr));
NanoAssert(samepage(prevLInsAddr, insSk));
ins->initLInsSk((LInsp)prevLInsAddr);
return ins;
NanoAssert(samepage(prevLInsAddr, l));
l->setIns1(LIR_skip, (LInsp)prevLInsAddr);
l->resv()->clear();
return l;
}
// Reads the next non-skip instruction.
@ -366,38 +341,33 @@ namespace nanojit
do
{
// Nb: this switch is table-driven (because sizeof_LInsXYZ() is
// table-driven) in most cases to avoid branch mispredictions --
// if we do a vanilla switch on the iop or LInsRepKind the extra
// branch mispredictions cause a small but noticeable slowdown.
switch (iop)
{
default:
i -= insSizes[((LInsp)i)->opcode()];
break;
switch (iop)
{
default:
i -= sizeof(LIns);
break;
#if defined NANOJIT_64BIT
case LIR_callh:
case LIR_callh:
#endif
case LIR_call:
case LIR_fcall: {
case LIR_call:
case LIR_fcall: {
int argc = ((LInsp)i)->argc();
i -= sizeof(LInsC); // step over the instruction
i -= argc*sizeof(LInsp); // step over the arguments
NanoAssert( samepage(i, _i) );
uintptr_t prev = i - sizeof(LIns) - argc*sizeof(LInsp);
NanoAssert( samepage(i, prev) );
i = prev;
break;
}
case LIR_skip:
// Ignore the skip, move onto its predecessor.
NanoAssert(((LInsp)i)->prevLIns() != (LInsp)i);
i = uintptr_t(((LInsp)i)->prevLIns());
break;
case LIR_skip:
NanoAssert(((LInsp)i)->oprnd1() != (LInsp)i);
i = uintptr_t(((LInsp)i)->oprnd1());
break;
case LIR_start:
_i = 0; // this means the next call to this method will return 0
return cur;
}
case LIR_start:
_i = 0; // start of trace
return cur;
}
iop = ((LInsp)i)->opcode();
}
while (iop==LIR_skip || iop==LIR_2);
@ -406,7 +376,7 @@ namespace nanojit
}
bool LIns::isFloat() const {
switch (opcode()) {
switch (firstWord.code) {
default:
return false;
case LIR_fadd:
@ -422,69 +392,107 @@ namespace nanojit
}
#if defined(_DEBUG)
bool LIns::isLInsOp0() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_Op0 == repKinds[opcode()];
bool LIns::isOp1() const {
switch (firstWord.code) {
case LIR_skip:
case LIR_ret:
case LIR_live:
case LIR_neg:
#if !defined NANOJIT_64BIT
case LIR_callh:
#endif
case LIR_not:
case LIR_qlo:
case LIR_qhi:
case LIR_ov:
case LIR_cs:
case LIR_file:
case LIR_line:
case LIR_fret:
case LIR_fneg:
case LIR_i2f:
case LIR_u2f:
case LIR_mod:
return true;
default:
return false;
}
}
bool LIns::isLInsOp1() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_Op1 == repKinds[opcode()];
}
// Nb: this excludes loads and stores, which are covered by isLoad() and
// isStore().
bool LIns::isOp2() const {
switch (firstWord.code) {
case LIR_loop:
case LIR_x:
case LIR_jt:
case LIR_jf:
case LIR_feq:
case LIR_flt:
case LIR_fgt:
case LIR_fle:
case LIR_fge:
case LIR_cmov:
case LIR_add:
case LIR_sub:
case LIR_mul:
case LIR_div:
case LIR_and:
case LIR_or:
case LIR_xor:
case LIR_lsh:
case LIR_rsh:
case LIR_ush:
case LIR_xt:
case LIR_xf:
case LIR_eq:
case LIR_lt:
case LIR_gt:
case LIR_le:
case LIR_ge:
case LIR_ult:
case LIR_ugt:
case LIR_ule:
case LIR_uge:
case LIR_2:
case LIR_xbarrier:
case LIR_xtbl:
case LIR_qiand:
case LIR_qiadd:
case LIR_qjoin:
case LIR_qcmov:
case LIR_fadd:
case LIR_fsub:
case LIR_fmul:
case LIR_fdiv:
case LIR_qior:
case LIR_qilsh:
return true;
bool LIns::isLInsOp2() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_Op2 == repKinds[opcode()];
}
bool LIns::isLInsSti() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_Sti == repKinds[opcode()];
}
bool LIns::isLInsSk() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_Sk == repKinds[opcode()];
}
bool LIns::isLInsC() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_C == repKinds[opcode()];
}
bool LIns::isLInsP() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_P == repKinds[opcode()];
}
bool LIns::isLInsI() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_I == repKinds[opcode()];
}
bool LIns::isLInsI64() const {
NanoAssert(LRK_None != repKinds[opcode()]);
return LRK_I64 == repKinds[opcode()];
default:
return false;
}
}
#endif // defined(_DEBUG)
bool LIns::isCmp() const {
LOpcode op = opcode();
LOpcode op = firstWord.code;
return (op >= LIR_eq && op <= LIR_uge) || (op >= LIR_feq && op <= LIR_fge);
}
bool LIns::isCond() const {
LOpcode op = opcode();
LOpcode op = firstWord.code;
return (op == LIR_ov) || (op == LIR_cs) || isCmp();
}
bool LIns::isQuad() const {
#ifdef AVMPLUS_64BIT
// callh in 64bit cpu's means a call that returns an int64 in a single register
return (opcode() & LIR64) != 0 || opcode() == LIR_callh;
return (firstWord.code & LIR64) != 0 || firstWord.code == LIR_callh;
#else
// callh in 32bit cpu's means the 32bit MSW of an int64 result in 2 registers
return (opcode() & LIR64) != 0;
return (firstWord.code & LIR64) != 0;
#endif
}
@ -495,7 +503,7 @@ namespace nanojit
bool LIns::isconstq() const
{
return opcode() == LIR_quad;
return firstWord.code == LIR_quad;
}
bool LIns::isconstp() const
@ -509,14 +517,14 @@ namespace nanojit
bool LIns::isCse() const
{
return nanojit::isCseOpcode(opcode()) || (isCall() && callInfo()->_cse);
return nanojit::isCseOpcode(firstWord.code) || (isCall() && callInfo()->_cse);
}
void LIns::setTarget(LInsp label)
{
NanoAssert(label && label->isop(LIR_label));
NanoAssert(isBranch());
toLInsOp2()->oprnd_2 = label;
u.oprnd_2 = label;
}
LInsp LIns::getTarget()
@ -528,15 +536,15 @@ namespace nanojit
void *LIns::payload() const
{
NanoAssert(isop(LIR_skip));
// Operand 1 points to the previous LIns; we move past it to get to
// the payload.
return (void*) (uintptr_t(prevLIns()) + sizeof(LIns));
// Operand 1 points to the previous instruction; we move one
// instruction past it to get to the payload.
return (void*) (intptr_t(oprnd1()) + sizeof(LIns));
}
uint64_t LIns::imm64() const
{
NanoAssert(isconstq());
return (uint64_t(toLInsI64()->imm64_1) << 32) | uint32_t(toLInsI64()->imm64_0);
return (uint64_t(i64.imm64_1) << 32) | uint32_t(i64.imm64_0);
}
double LIns::imm64f() const
@ -552,7 +560,7 @@ namespace nanojit
const CallInfo* LIns::callInfo() const
{
NanoAssert(isCall());
return toLInsC()->ci;
return c.ci;
}
// Index args in r-l order. arg(0) is rightmost arg.
@ -561,9 +569,8 @@ namespace nanojit
{
NanoAssert(isCall());
NanoAssert(i < argc());
// Move to the start of the LInsC, then move back one word per argument.
LInsp* argSlot = (LInsp*)(uintptr_t(toLInsC()) - (i+1)*sizeof(void*));
return *argSlot;
LInsp* offs = (LInsp*)this - (i+1);
return *offs;
}
LIns* LirWriter::ins2i(LOpcode v, LIns* oprnd1, int32_t imm)
@ -1004,23 +1011,38 @@ namespace nanojit
op = LIR_callh;
}
// An example of what we're trying to serialize (for a 32-bit machine):
//
// byte
// ----
// N+0 [ arg operand #2 ----------------------
// N+4 arg operand #1 ----------------------
// N+8 arg operand #0 ---------------------- ]
// N+12 [ resv + code=LIR_call
// N+16 imm8a | imm8b | (pad16) -------------
// N+20 ci ----------------------------------
// N+24 (pad32) ----------------------------- ]
//
// In this example:
// 'argc' = 3
NanoAssert(argc <= (int)MAXARGS);
// Lay the call parameters out (in reverse order).
// Nb: this must be kept in sync with arg().
LInsp* newargs = (LInsp*)_buf->makeRoom(argc*sizeof(LInsp) + sizeof(LInsC)); // args + call
LInsp* newargs = (LInsp*)_buf->makeRoom(argc*sizeof(LInsp) + sizeof(LIns)); // args + call
for (int32_t i = 0; i < argc; i++)
newargs[argc - i - 1] = args[i];
// Write the call instruction itself.
LInsC* insC = (LInsC*)(uintptr_t(newargs) + argc*sizeof(LInsp));
LIns* ins = insC->getLIns();
LInsp l = (LInsp)(uintptr_t(newargs) + argc*sizeof(LInsp));
#ifndef NANOJIT_64BIT
ins->initLInsC(op==LIR_callh ? LIR_call : op, argc, ci);
l->setCall(op==LIR_callh ? LIR_call : op, argc, ci);
#else
ins->initLInsC(op, argc, ci);
l->setCall(op, argc, ci);
#endif
return ins;
l->resv()->clear();
return l;
}
using namespace avmplus;
@ -1436,9 +1458,9 @@ namespace nanojit
RetiredEntry *e = NJ_NEW(gc, RetiredEntry)(gc);
e->i = i;
for (int j=0, n=live.size(); j < n; j++) {
LInsp ins = live.keyAt(j);
if (!ins->isStore() && !ins->isGuard())
e->live.add(ins);
LInsp l = live.keyAt(j);
if (!l->isStore() && !l->isGuard())
e->live.add(l);
}
int size=0;
if ((size = e->live.size()) > maxlive)
@ -1685,8 +1707,8 @@ namespace nanojit
}
case LIR_param: {
uint32_t arg = i->paramArg();
if (!i->paramKind()) {
uint32_t arg = i->imm8();
if (!i->imm8b()) {
if (arg < sizeof(Assembler::argRegs)/sizeof(Assembler::argRegs[0])) {
sprintf(s, "%s = %s %d %s", formatRef(i), lirNames[op],
arg, gpn(Assembler::argRegs[arg]));

Просмотреть файл

@ -58,9 +58,9 @@ namespace nanojit
// flags; upper bits reserved
LIR64 = 0x40, // result is double or quad
#define OPDEF(op, number, args, repkind) \
#define OPDEF(op, number, args) \
LIR_##op = (number),
#define OPDEF64(op, number, args, repkind) \
#define OPDEF64(op, number, args) \
LIR_##op = ((number) | LIR64),
#include "LIRopcode.tbl"
LIR_sentinel
@ -70,6 +70,7 @@ namespace nanojit
#if defined NANOJIT_64BIT
#define LIR_ldp LIR_ldq
#define LIR_stp LIR_stq
#define LIR_piadd LIR_qiadd
#define LIR_piand LIR_qiand
#define LIR_pilsh LIR_qilsh
@ -77,6 +78,7 @@ namespace nanojit
#define LIR_pior LIR_qior
#else
#define LIR_ldp LIR_ld
#define LIR_stp LIR_st
#define LIR_piadd LIR_add
#define LIR_piand LIR_and
#define LIR_pilsh LIR_lsh
@ -146,6 +148,13 @@ namespace nanojit
return (op & ~LIR64) == LIR_ret;
}
// Sun Studio requires explicitly declaring signed int bit-field
#if defined(__SUNPRO_C) || defined(__SUNPRO_CC)
#define _sign_int signed int
#else
#define _sign_int int32_t
#endif
// The opcode is not logically part of the Reservation, but we include it
// in this struct to ensure that opcode plus the Reservation fits in a
// single word. Yuk.
@ -154,7 +163,7 @@ namespace nanojit
uint32_t arIndex:16; // index into stack frame. displ is -4*arIndex
Register reg:7; // register UnknownReg implies not in register
uint32_t used:1; // when set, the reservation is active
LOpcode opcode:8;
LOpcode code:8;
inline void init() {
reg = UnknownReg;
@ -162,425 +171,107 @@ namespace nanojit
used = 1;
}
inline void clear() {
inline void clear()
{
used = 0;
}
};
//-----------------------------------------------------------------------
// Low-level instructions. This is a bit complicated, because we have a
// variable-width representation to minimise space usage.
//
// - Instruction size is always an integral multiple of word size.
//
// - Every instruction has at least one word, holding the opcode and the
// reservation info. That word is in class LIns.
//
// - Beyond that, most instructions have 1, 2 or 3 extra words. These
// extra words are in classes LInsOp1, LInsOp2, etc (collectively called
// "LInsXYZ" in what follows). Each LInsXYZ class also contains a word,
// accessible by the 'ins' member, which holds the LIns data; its type
// is void* (which is the same size as LIns) rather than LIns to avoid a
// recursive dependency between LIns and LInsXYZ.
//
// - LIR is written forward, but read backwards. When reading backwards,
// in order to find the opcode, it must be in a predictable place in the
// LInsXYZ isn't affected by instruction width. Therefore, the LIns
// word (which contains the opcode) is always the *last* word in an
// instruction.
//
// - Each instruction is created by casting pre-allocated bytes from a
// LirBuffer to the LInsXYZ type. Therefore there are no constructors
// for LIns or LInsXYZ.
//
// - The standard handle for an instruction is a LIns*. This actually
// points to the LIns word, ie. to the final word in the instruction.
// This is a bit odd, but it allows the instruction's opcode to be
// easily accessed. Once you've looked at the opcode and know what kind
// of instruction it is, if you want to access any of the other words,
// you need to use toLInsXYZ(), which takes the LIns* and gives you an
// LInsXYZ*, ie. the pointer to the actual start of the instruction's
// bytes. From there you can access the instruction-specific extra
// words.
//
// - However, from outside class LIns, LInsXYZ isn't visible, nor is
// toLInsXYZ() -- from outside LIns, all LIR instructions are handled
// via LIns pointers and get/set methods are used for all LIns/LInsXYZ
// accesses. In fact, all data members in LInsXYZ are private and can
// only be accessed by LIns, which is a friend class. The only thing
// anyone outside LIns can do with a LInsXYZ is call getLIns().
//
// - An example Op2 instruction and the likely pointers to it (each line
// represents a word, and pointers to a line point to the start of the
// word on that line):
//
// [ oprnd_2 <-- LInsOp2* insOp2 == toLInsOp2(ins)
// oprnd_1
// opcode + resv ] <-- LIns* ins
//
// - LIR_skip instructions are more complicated. They allow an arbitrary
// blob of data (the "payload") to be placed in the LIR stream. The
// size of the payload is always a multiple of the word size. A skip
// instruction's operand points to the previous instruction, which lets
// the payload be skipped over when reading backwards. Here's an
// example of a skip instruction with a 3-word payload preceded by an
// LInsOp1:
//
// [ oprnd_1
// +-> opcode + resv ]
// | [ data
// | data
// | data
// +---- prevLIns <-- LInsSk* insSk == toLInsSk(ins)
// opcode==LIR_skip + resv ] <-- LIns* ins
//
// Skips are also used to link code pages. If the first instruction on
// a page isn't a LIR_start, it will be a skip, and the skip's operand
// will point to the last LIns on the previous page. In this case there
// isn't a payload as such; in fact, the previous page might be at a
// higher address, ie. the operand might point forward rather than
// backward.
//
// LInsSk has the same layout as LInsOp1, but we represent it as a
// different class because there are some places where we treat
// skips specially and so having it separate seems like a good idea.
//
// - Call instructions (LIR_call, LIR_fcall, LIR_calli, LIR_fcalli) are
// also more complicated. They are preceded by the arguments to the
// call, which are laid out in reverse order. For example, a call with
// 3 args will look like this:
//
// [ arg #2
// arg #1
// arg #0
// argc <-- LInsC insC == toLInsC(ins)
// ci
// opcode + resv ] <-- LIns* ins
//
// - Various things about the size and layout of LIns and LInsXYZ are
// statically checked in staticSanityCheck(). In particular, this is
// worthwhile because there's nothing that guarantees that all the
// LInsXYZ classes have a size that is a multiple of word size (but in
// practice all sane compilers use a layout that results in this). We
// also check that every LInsXYZ is word-aligned in
// LirBuffer::makeRoom(); this seems sensible to avoid potential
// slowdowns due to misalignment. It relies on pages themselves being
// word-aligned, which is extremely likely.
//
// - There is an enum, LInsRepKind, with one member for each of the
// LInsXYZ kinds. Each opcode is categorised with its LInsRepKind value
// in LIRopcode.tbl, and this is used in various places.
//-----------------------------------------------------------------------
enum LInsRepKind {
// LRK_XYZ corresponds to class LInsXYZ.
LRK_Op0,
LRK_Op1,
LRK_Op2,
LRK_Sti,
LRK_Sk,
LRK_C,
LRK_P,
LRK_I,
LRK_I64,
LRK_None // this one is used for unused opcode numbers
};
// 0-operand form. Used for LIR_start and LIR_label.
class LInsOp0
{
private:
friend class LIns;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// 1-operand form. Used for LIR_ret, LIR_ov, unary arithmetic/logic ops,
// etc.
class LInsOp1
{
private:
friend class LIns;
// Nb: oprnd_1 position relative to 'ins' must match that in
// LIns{Op2,Sti}. Checked in LirBufWriter::LirBufWriter().
LIns* oprnd_1;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// 2-operand form. Used for loads, guards, branches, comparisons, binary
// arithmetic/logic ops, etc.
class LInsOp2
{
private:
friend class LIns;
// Nb: oprnd_{1,2} position relative to 'ins' must match that in
// LIns{Op1,Sti}. Checked in LirBufWriter::LirBufWriter().
LIns* oprnd_2;
LIns* oprnd_1;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for LIR_sti and LIR_stqi.
class LInsSti
{
private:
friend class LIns;
int32_t disp;
// Nb: oprnd_{1,2} position relative to 'ins' must match that in
// LIns{Op1,Op2}. Checked in LIns::staticSanityCheck().
LIns* oprnd_2;
LIns* oprnd_1;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for LIR_skip.
class LInsSk
{
private:
friend class LIns;
LIns* prevLIns;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for all variants of LIR_call.
class LInsC
{
private:
friend class LIns;
uintptr_t argc:8;
const CallInfo* ci;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for LIR_param.
class LInsP
{
private:
friend class LIns;
uintptr_t arg:8;
uintptr_t kind:8;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for LIR_int and LIR_alloc.
class LInsI
{
private:
friend class LIns;
int32_t imm32;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used for LIR_quad.
class LInsI64
{
private:
friend class LIns;
int32_t imm64_0;
int32_t imm64_1;
void* ins;
public:
LIns* getLIns() { return (LIns*)&ins; };
};
// Used only as a placeholder for OPDEF macros for unused opcodes in
// LIRopcode.tbl.
class LInsNone
{
};
// Low-level Instruction. 4 words per instruction -- it's important this
// doesn't change unintentionally, so it is checked in LIR.cpp by an
// assertion in initOpcodeAndClearResv().
// The first word is the same for all LIns kinds; the last three differ.
class LIns
{
private:
// Last word: fields shared by all LIns kinds. The reservation fields
// are read/written during assembly.
Reservation lastWord;
// 2-operand form. Used for most LIns kinds, including LIR_skip (for
// which oprnd_1 is the target).
struct u_type
{
// Nb: oprnd_1 and oprnd_2 layout must match that in sti_type
// because oprnd1() and oprnd2() are used for both.
LIns* oprnd_1;
// LIns-to-LInsXYZ converters.
LInsOp0* toLInsOp0() const { return (LInsOp0*)( uintptr_t(this+1) - sizeof(LInsOp0) ); }
LInsOp1* toLInsOp1() const { return (LInsOp1*)( uintptr_t(this+1) - sizeof(LInsOp1) ); }
LInsOp2* toLInsOp2() const { return (LInsOp2*)( uintptr_t(this+1) - sizeof(LInsOp2) ); }
LInsSti* toLInsSti() const { return (LInsSti*)( uintptr_t(this+1) - sizeof(LInsSti) ); }
LInsSk* toLInsSk() const { return (LInsSk* )( uintptr_t(this+1) - sizeof(LInsSk ) ); }
LInsC* toLInsC() const { return (LInsC* )( uintptr_t(this+1) - sizeof(LInsC ) ); }
LInsP* toLInsP() const { return (LInsP* )( uintptr_t(this+1) - sizeof(LInsP ) ); }
LInsI* toLInsI() const { return (LInsI* )( uintptr_t(this+1) - sizeof(LInsI ) ); }
LInsI64* toLInsI64() const { return (LInsI64*)( uintptr_t(this+1) - sizeof(LInsI64) ); }
LIns* oprnd_2;
};
// This is never called, but that's ok because it contains only static
// assertions.
void staticSanityCheck()
// Used for LIR_sti and LIR_stqi.
struct sti_type
{
// LIns must be word-sized.
NanoStaticAssert(sizeof(LIns) == 1*sizeof(void*));
// Nb: oprnd_1 and oprnd_2 layout must match that in u_type
// because oprnd1() and oprnd2() are used for both.
LIns* oprnd_1;
// LInsXYZ have expected sizes too.
NanoStaticAssert(sizeof(LInsOp0) == 1*sizeof(void*));
NanoStaticAssert(sizeof(LInsOp1) == 2*sizeof(void*));
NanoStaticAssert(sizeof(LInsOp2) == 3*sizeof(void*));
NanoStaticAssert(sizeof(LInsSti) == 4*sizeof(void*));
NanoStaticAssert(sizeof(LInsSk) == 2*sizeof(void*));
NanoStaticAssert(sizeof(LInsC) == 3*sizeof(void*));
NanoStaticAssert(sizeof(LInsP) == 2*sizeof(void*));
NanoStaticAssert(sizeof(LInsI) == 2*sizeof(void*));
#if defined NANOJIT_64BIT
NanoStaticAssert(sizeof(LInsI64) == 2*sizeof(void*));
#else
NanoStaticAssert(sizeof(LInsI64) == 3*sizeof(void*));
#endif
LIns* oprnd_2;
// oprnd_1 must be in the same position in LIns{Op1,Op2,Sti}
// because oprnd1() is used for all of them.
NanoStaticAssert( (offsetof(LInsOp1, ins) - offsetof(LInsOp1, oprnd_1)) ==
(offsetof(LInsOp2, ins) - offsetof(LInsOp2, oprnd_1)) );
NanoStaticAssert( (offsetof(LInsOp2, ins) - offsetof(LInsOp2, oprnd_1)) ==
(offsetof(LInsSti, ins) - offsetof(LInsSti, oprnd_1)) );
int32_t disp;
};
// oprnd_2 must be in the same position in LIns{Op2,Sti}
// because oprnd2() is used for both of them.
NanoStaticAssert( (offsetof(LInsOp2, ins) - offsetof(LInsOp2, oprnd_2)) ==
(offsetof(LInsSti, ins) - offsetof(LInsSti, oprnd_2)) );
}
// Used for LIR_call and LIR_param.
struct c_type
{
uintptr_t imm8a:8; // call: 0 (not used); param: arg
uintptr_t imm8b:8; // call: argc; param: kind
public:
void initLInsOp0(LOpcode opcode) {
lastWord.clear();
lastWord.opcode = opcode;
NanoAssert(isLInsOp0());
}
void initLInsOp1(LOpcode opcode, LIns* oprnd1) {
lastWord.clear();
lastWord.opcode = opcode;
toLInsOp1()->oprnd_1 = oprnd1;
NanoAssert(isLInsOp1());
}
void initLInsOp2(LOpcode opcode, LIns* oprnd1, LIns* oprnd2) {
lastWord.clear();
lastWord.opcode = opcode;
toLInsOp2()->oprnd_1 = oprnd1;
toLInsOp2()->oprnd_2 = oprnd2;
NanoAssert(isLInsOp2());
}
void initLInsSti(LOpcode opcode, LIns* val, LIns* base, int32_t d) {
lastWord.clear();
lastWord.opcode = opcode;
toLInsSti()->oprnd_1 = val;
toLInsSti()->oprnd_2 = base;
toLInsSti()->disp = d;
NanoAssert(isLInsSti());
}
void initLInsSk(LIns* prevLIns) {
lastWord.clear();
lastWord.opcode = LIR_skip;
toLInsSk()->prevLIns = prevLIns;
NanoAssert(isLInsSk());
}
// Nb: this does NOT initialise the arguments. That must be done
// separately.
void initLInsC(LOpcode opcode, int32_t argc, const CallInfo* ci) {
NanoAssert(isU8(argc));
lastWord.clear();
lastWord.opcode = opcode;
toLInsC()->argc = argc;
toLInsC()->ci = ci;
NanoAssert(isLInsC());
}
void initLInsP(int32_t arg, int32_t kind) {
lastWord.clear();
lastWord.opcode = LIR_param;
NanoAssert(isU8(arg) && isU8(kind));
toLInsP()->arg = arg;
toLInsP()->kind = kind;
NanoAssert(isLInsP());
}
void initLInsI(LOpcode opcode, int32_t imm32) {
lastWord.clear();
lastWord.opcode = opcode;
toLInsI()->imm32 = imm32;
NanoAssert(isLInsI());
}
void initLInsI64(LOpcode opcode, int64_t imm64) {
lastWord.clear();
lastWord.opcode = opcode;
toLInsI64()->imm64_0 = int32_t(imm64);
toLInsI64()->imm64_1 = int32_t(imm64 >> 32);
NanoAssert(isLInsI64());
}
const CallInfo* ci; // call: callInfo; param: NULL (not used)
};
// Used for LIR_int.
struct i_type
{
int32_t imm32;
};
// Used for LIR_quad.
struct i64_type
{
int32_t imm64_0;
int32_t imm64_1;
};
#undef _sign_int
// 1st word: fields shared by all LIns kinds. The reservation fields
// are read/written during assembly.
Reservation firstWord;
// 2nd, 3rd and 4th words: differ depending on the LIns kind.
union
{
u_type u;
c_type c;
i_type i;
i64_type i64;
sti_type sti;
};
public:
LIns* oprnd1() const {
NanoAssert(isLInsOp1() || isLInsOp2() || isStore());
return toLInsOp2()->oprnd_1;
NanoAssert(isOp1() || isOp2() || isLoad() || isStore());
return u.oprnd_1;
}
LIns* oprnd2() const {
NanoAssert(isLInsOp2() || isStore());
return toLInsOp2()->oprnd_2;
NanoAssert(isOp2() || isLoad() || isStore());
return u.oprnd_2;
}
LIns* prevLIns() const {
NanoAssert(isop(LIR_skip));
return toLInsSk()->prevLIns;
}
inline LOpcode opcode() const { return lastWord.opcode; }
inline uint8_t paramArg() const { NanoAssert(isop(LIR_param)); return toLInsP()->arg; }
inline uint8_t paramKind() const { NanoAssert(isop(LIR_param)); return toLInsP()->kind; }
inline int32_t imm32() const { NanoAssert(isconst()); return toLInsI()->imm32; }
inline int32_t imm64_0() const { NanoAssert(isconstq()); return toLInsI64()->imm64_0; }
inline int32_t imm64_1() const { NanoAssert(isconstq()); return toLInsI64()->imm64_1; }
uint64_t imm64() const;
double imm64f() const;
Reservation* resv() { return &lastWord; }
void* payload() const;
inline Page* page() { return (Page*) alignTo(this,NJ_PAGE_SIZE); }
inline int32_t size() const {
inline LOpcode opcode() const { return firstWord.code; }
inline uint8_t imm8() const { NanoAssert(isop(LIR_param)); return c.imm8a; }
inline uint8_t imm8b() const { NanoAssert(isop(LIR_param)); return c.imm8b; }
inline int32_t imm32() const { NanoAssert(isconst()); return i.imm32; }
inline int32_t imm64_0() const { NanoAssert(isconstq()); return i64.imm64_0; }
inline int32_t imm64_1() const { NanoAssert(isconstq()); return i64.imm64_1; }
uint64_t imm64() const;
double imm64f() const;
Reservation* resv() { return &firstWord; }
void* payload() const;
inline Page* page() { return (Page*) alignTo(this,NJ_PAGE_SIZE); }
inline int32_t size() const {
NanoAssert(isop(LIR_alloc));
return toLInsI()->imm32 << 2;
return i.imm32<<2;
}
inline void setSize(int32_t bytes) {
NanoAssert(isop(LIR_alloc) && (bytes&3)==0 && isU16(bytes>>2));
i.imm32 = bytes>>2;
}
LIns* arg(uint32_t i);
@ -588,7 +279,7 @@ namespace nanojit
inline int32_t immdisp() const
{
NanoAssert(isStore());
return toLInsSti()->disp;
return sti.disp;
}
inline void* constvalp() const
@ -601,49 +292,36 @@ namespace nanojit
}
bool isCse() const;
bool isRet() const { return nanojit::isRetOpcode(opcode()); }
bool isop(LOpcode o) const { return opcode() == o; }
bool isRet() const { return nanojit::isRetOpcode(firstWord.code); }
bool isop(LOpcode o) const { return firstWord.code == o; }
#if defined(_DEBUG)
// isLInsXYZ() returns true if the instruction has the LInsXYZ form.
// Note that there is some overlap with other predicates, eg.
// isStore()==isLInsSti(), isCall()==isLInsC(), but that's ok; these
// ones are used only to check that opcodes are appropriate for
// instruction layouts, the others are used for non-debugging
// purposes.
bool isLInsOp0() const;
bool isLInsOp1() const;
bool isLInsOp2() const;
bool isLInsSti() const;
bool isLInsSk() const;
bool isLInsC() const;
bool isLInsP() const;
bool isLInsI() const;
bool isLInsI64() const;
bool isOp1() const; // true for unary ops
bool isOp2() const; // true for binary ops
#endif
bool isQuad() const;
bool isCond() const;
bool isFloat() const;
bool isCmp() const;
bool isCall() const {
LOpcode op = LOpcode(opcode() & ~LIR64);
LOpcode op = LOpcode(firstWord.code & ~LIR64);
return op == LIR_call;
}
bool isStore() const {
LOpcode op = LOpcode(opcode() & ~LIR64);
LOpcode op = LOpcode(firstWord.code & ~LIR64);
return op == LIR_sti;
}
bool isLoad() const {
LOpcode op = opcode();
LOpcode op = firstWord.code;
return op == LIR_ldq || op == LIR_ld || op == LIR_ldc ||
op == LIR_ldqc || op == LIR_ldcs || op == LIR_ldcb;
}
bool isGuard() const {
LOpcode op = opcode();
LOpcode op = firstWord.code;
return op == LIR_x || op == LIR_xf || op == LIR_xt ||
op == LIR_loop || op == LIR_xbarrier || op == LIR_xtbl;
}
// True if the instruction is a 32-bit or smaller constant integer.
bool isconst() const { return opcode() == LIR_int; }
bool isconst() const { return firstWord.code == LIR_int; }
// True if the instruction is a 32-bit or smaller constant integer and
// has the value val when treated as a 32-bit signed integer.
bool isconstval(int32_t val) const;
@ -655,6 +333,69 @@ namespace nanojit
return isop(LIR_jt) || isop(LIR_jf) || isop(LIR_j);
}
void setIns0(LOpcode op) {
firstWord.code = op;
}
void setIns1(LOpcode op, LIns* oprnd1) {
firstWord.code = op;
u.oprnd_1 = oprnd1;
NanoAssert(isOp1());
}
void setIns2(LOpcode op, LIns* oprnd1, LIns* oprnd2) {
firstWord.code = op;
u.oprnd_1 = oprnd1;
u.oprnd_2 = oprnd2;
NanoAssert(isOp2() || isLoad() || isGuard() || isBranch());
}
void setLoad(LOpcode op, LIns* base, LIns* d) {
setIns2(op, base, d);
}
void setGuard(LOpcode op, LIns* cond, LIns* data) {
setIns2(op, cond, data);
}
void setBranch(LOpcode op, LIns* cond, LIns* target) {
setIns2(op, cond, target);
}
void setStorei(LOpcode op, LIns* val, LIns* base, int32_t d) {
firstWord.code = op;
u.oprnd_1 = val;
u.oprnd_2 = base;
sti.disp = d;
NanoAssert(isStore());
}
void setImm(LOpcode op, int32_t imm32) {
firstWord.code = op;
i.imm32 = imm32;
NanoAssert(op == LIR_alloc || op == LIR_int);
}
void setAlloc(LOpcode op, int32_t size) {
setImm(op, size);
}
void setParam(LOpcode op, int32_t arg, int32_t kind)
{
firstWord.code = op;
NanoAssert(isU8(arg) && isU8(kind));
c.imm8a = arg;
c.imm8b = kind;
c.ci = NULL;
NanoAssert(op == LIR_param);
}
void setCall(LOpcode op, int32_t argc, const CallInfo* ci)
{
firstWord.code = op;
NanoAssert(isU8(argc));
c.imm8a = 0;
c.imm8b = argc;
c.ci = ci;
NanoAssert(op == LIR_call || op == LIR_fcall);
}
void setImmq(LOpcode op, int64_t imm64) {
firstWord.code = op;
i64.imm64_0 = int32_t(imm64);
i64.imm64_1 = int32_t(imm64>>32);
NanoAssert(op == LIR_quad);
}
void setTarget(LIns* t);
LIns* getTarget();
@ -662,17 +403,17 @@ namespace nanojit
inline uint32_t argc() const {
NanoAssert(isCall());
return toLInsC()->argc;
return c.imm8b;
}
const CallInfo *callInfo() const;
};
typedef LIns* LInsp;
typedef LIns* LInsp;
LIns* FASTCALL callArgN(LInsp i, uint32_t n);
extern const uint8_t operandCount[];
class Fragmento; // @todo remove this ; needed for minbuild for some reason?!? Should not be compiling this code at all
class LirFilter;
// make it a GCObject so we can explicitly delete it early
class LirWriter : public avmplus::GCObject
@ -749,12 +490,12 @@ namespace nanojit
// The first instruction on a page is always a start instruction, or a
// payload-less skip instruction linking to the previous page. The
// biggest possible instruction would take up the entire rest of the page.
#define NJ_MAX_LINS_SZB (NJ_PAGE_CODE_AREA_SZB - sizeof(LInsSk))
#define NJ_MAX_LINS_SZB (NJ_PAGE_CODE_AREA_SZB - sizeof(LIns))
// The maximum skip payload size is determined by the maximum instruction
// size. We require that a skip's payload be adjacent to the skip LIns
// itself.
#define NJ_MAX_SKIP_PAYLOAD_SZB (NJ_MAX_LINS_SZB - sizeof(LInsSk))
#define NJ_MAX_SKIP_PAYLOAD_SZB (NJ_MAX_LINS_SZB - sizeof(LIns))
#ifdef NJ_VERBOSE

Просмотреть файл

@ -44,22 +44,15 @@
*
* Includers must define OPDEF and OPDEF64 macros of the following forms:
*
* #define OPDEF(op,val,operands,repkind) ...
* #define OPDEF64(op,val,operands,repkind) ...
* #define OPDEF(op,val,operands) ...
* #define OPDEF64(op,val,operands) ...
*
* Selected arguments can then be used within the macro expansions.
*
* Field Description
* op Bytecode name, token-pasted after "LIR_" to form an LOpcode.
* val Bytecode value, which is the LOpcode enumerator value.
* operands Number of operands for this instruction, where an "operand" is
* a LIns* argument. Eg. LIR_sti has 3 fields, but the last is an
* immediate, so it only has two operands. Call instructions are
* considered to have 0 operands -- the call args aren't counted.
* The value is set to -1 for unused opcodes to make it obvious
* that it needs changing if the opcode becomes used.
* repkind Indicates how the instruction is represented in memory; XYZ
* corresponds to LInsXYZ and LRK_XYZ.
* op Bytecode name, token-pasted after "LIR_" to form an LOpcode
* val Bytecode value, which is the LOpcode enumerator value
* operands Number of operands for this instruction
*
* This file is best viewed with 128 columns:
12345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678901234567890123456789012345678
@ -68,36 +61,37 @@
/* op val name operands */
/* special operations (must be 0..N) */
OPDEF(start, 0, 0, Op0) // start of a fragment
OPDEF(unused1, 1,-1, None)
OPDEF(skip, 2, 1, Sk) // holds blobs ("payloads") of data; also links pages
OPDEF(unused3, 3,-1, None)
OPDEF(unused4, 4,-1, None)
OPDEF(unused5, 5,-1, None)
OPDEF(unused6, 6,-1, None)
OPDEF(start, 0, 0)
OPDEF(unused1, 1, 0)
OPDEF(skip, 2, 0)
OPDEF(unused3, 3, 0)
OPDEF(unused4, 4, 0)
OPDEF(unused5, 5, 2)
OPDEF(unused6, 6, 2)
/* non-pure operations */
OPDEF(addp, 7, 2, Op2) // integer addition for temporary pointer calculations
OPDEF(param, 8, 0, P) // load a parameter
OPDEF(unused9, 9,-1, None)
OPDEF(ld, 10, 2, Op2) // 32-bit load
OPDEF(alloc, 11, 0, I) // alloca some stack space
OPDEF(sti, 12, 2, Sti) // 32-bit store
OPDEF(ret, 13, 1, Op1) // return a word-sized value
OPDEF(live, 14, 1, Op1) // extend live range of reference
OPDEF(unused15, 15, 0, C)
OPDEF(call, 16, 0, C) // subroutine call returning a 32-bit value
OPDEF(addp, 7, 2)
OPDEF(param, 8, 0)
OPDEF(unused9, 9, 2)
OPDEF(ld, 10, 2) // 32-bit load
OPDEF(alloc, 11, 0) // alloca some stack space
OPDEF(sti, 12, 2) // 32-bit store
OPDEF(ret, 13, 1)
OPDEF(live, 14, 1) // extend live range of reference
OPDEF(unused15, 15, 0) // indirect call
OPDEF(call, 16, 0) // subroutine call returning a 32-bit value
/* guards */
OPDEF(loop, 17, 0, Op2) // loop fragment
OPDEF(x, 18, 0, Op2) // exit always
OPDEF(loop, 17, 0) // loop fragment
OPDEF(x, 18, 0) // exit always
/* branches */
OPDEF(j, 19, 0, Op2) // jump always
OPDEF(jt, 20, 1, Op2) // jump if true
OPDEF(jf, 21, 1, Op2) // jump if false
OPDEF(label, 22, 0, Op0) // a jump target (no machine code is emitted for this)
OPDEF(ji, 23,-1, None) // indirect jump (currently not implemented)
OPDEF(j, 19, 0) // jump always
OPDEF(jt, 20, 1) // jump true
OPDEF(jf, 21, 1) // jump false
OPDEF(label, 22, 0) // a jump target
OPDEF(ji, 23, 2) // jump indirect
/* operators */
@ -106,12 +100,12 @@ OPDEF(ji, 23,-1, None) // indirect jump (currently not implemented)
* common-subexpression-elimination detection code.
*/
OPDEF(int, 24, 0, I) // constant 32-bit integer
OPDEF(cmov, 25, 2, Op2) // conditional move (op1=cond, op2=LIR_2(iftrue,iffalse))
OPDEF(int, 24, 0) // constant 32-bit integer
OPDEF(cmov, 25, 2) // conditional move (op1=cond, op2=cond(iftrue,iffalse))
#if defined(NANOJIT_64BIT)
OPDEF(callh, 26,-1, None) // unused on 64-bit machines
OPDEF(callh, 26, 0)
#else
OPDEF(callh, 26, 1, Op1) // get the high 32 bits of a call returning a 64-bit value
OPDEF(callh, 26, 1)
#endif
/*
@ -123,43 +117,46 @@ OPDEF(callh, 26, 1, Op1) // get the high 32 bits of a call returning a 64
* with 3. NB: These opcodes must remain continuous so that comparison-opcode
* detection works correctly.
*/
OPDEF(feq, 27, 2, Op2) // floating-point equality
OPDEF(flt, 28, 2, Op2) // floating-point less-than
OPDEF(fgt, 29, 2, Op2) // floating-point greater-than
OPDEF(fle, 30, 2, Op2) // floating-point less-than-or-equal
OPDEF(fge, 31, 2, Op2) // floating-point greater-than-or-equal
OPDEF(feq, 27, 2) // floating-point equality [2 float inputs]
OPDEF(flt, 28, 2) // floating-point less than: arg1 < arg2
OPDEF(fgt, 29, 2) // floating-point greater than: arg1 > arg2
OPDEF(fle, 30, 2) // arg1 <= arg2, both floating-point
OPDEF(fge, 31, 2) // arg1 >= arg2, both floating-point
OPDEF(ldcb, 32, 2, Op2) // non-volatile 8-bit load
OPDEF(ldcs, 33, 2, Op2) // non-volatile 16-bit load
OPDEF(ldc, 34, 2, Op2) // non-volatile 32-bit load
OPDEF(ldcb, 32, 2) // non-volatile 8-bit load
OPDEF(ldcs, 33, 2) // non-volatile 16-bit load
OPDEF(ldc, 34, 2) // non-volatile 32-bit load
OPDEF(neg, 35, 1, Op1) // integer negation
OPDEF(add, 36, 2, Op2) // integer addition
OPDEF(sub, 37, 2, Op2) // integer subtraction
OPDEF(mul, 38, 2, Op2) // integer multiplication
OPDEF(div, 39, 2, Op2) // integer division
OPDEF(mod, 40, 1, Op1) // hack: get the modulus from a LIR_div result, for x86 only
// neg through ush are all integer operations
OPDEF(neg, 35, 1) // numeric negation [ 1 integer input / integer output ]
OPDEF(add, 36, 2) // integer addition [ 2 operand integer intputs / integer output ]
OPDEF(sub, 37, 2) // integer subtraction
OPDEF(mul, 38, 2) // integer multiplication
OPDEF(div, 39, 2)
OPDEF(mod, 40, 1)
OPDEF(and, 41, 2, Op2) // 32-bit bitwise AND
OPDEF(or, 42, 2, Op2) // 32-bit bitwise OR
OPDEF(xor, 43, 2, Op2) // 32-bit bitwise XOR
OPDEF(not, 44, 1, Op1) // 32-bit bitwise NOT
OPDEF(lsh, 45, 2, Op2) // 32-bit left shift
OPDEF(rsh, 46, 2, Op2) // 32-bit right shift with sign-extend (>>)
OPDEF(ush, 47, 2, Op2) // 32-bit unsigned right shift (>>>)
OPDEF(and, 41, 2)
OPDEF(or, 42, 2)
OPDEF(xor, 43, 2)
OPDEF(not, 44, 1)
OPDEF(lsh, 45, 2)
OPDEF(rsh, 46, 2) // >>
OPDEF(ush, 47, 2) // >>>
// conditional guards, op^1 to complement. Only things that are
// isCond() can be passed to these.
OPDEF(xt, 48, 1, Op2) // exit if true (0x30 0011 0000)
OPDEF(xf, 49, 1, Op2) // exit if false (0x31 0011 0001)
OPDEF(xt, 48, 1) // exit if true 0x30 0011 0000
OPDEF(xf, 49, 1) // exit if false 0x31 0011 0001
OPDEF(qlo, 50, 1, Op1) // get the low 32 bits of a 64-bit value
OPDEF(qhi, 51, 1, Op1) // get the high 32 bits of a 64-bit value
// qlo and qhi take a single quad argument and return its low and high
// 32 bits respectively as 32-bit integers.
OPDEF(qlo, 50, 1)
OPDEF(qhi, 51, 1)
OPDEF(unused52, 52,-1, None)
OPDEF(unused52, 52, 0)
OPDEF(ov, 53, 1, Op1) // test for overflow; value must have just been computed
OPDEF(cs, 54, 1, Op1) // test for carry; value must have just been computed
OPDEF(ov, 53, 1)
OPDEF(cs, 54, 1)
// Integer (all sizes) relational operators. (op ^ 1) is the op which flips the
// left and right sides of the comparison, so (lt ^ 1) == gt, or the operator
@ -168,96 +165,96 @@ OPDEF(cs, 54, 1, Op1) // test for carry; value must have just been
// with 3. 'u' prefix indicates the unsigned integer variant.
// NB: These opcodes must remain continuous so that comparison-opcode detection
// works correctly.
OPDEF(eq, 55, 2, Op2) // integer equality
OPDEF(lt, 56, 2, Op2) // signed integer less-than (0x38 0011 1000)
OPDEF(gt, 57, 2, Op2) // signed integer greater-than (0x39 0011 1001)
OPDEF(le, 58, 2, Op2) // signed integer less-than-or-equal (0x3A 0011 1010)
OPDEF(ge, 59, 2, Op2) // signed integer greater-than-or-equal (0x3B 0011 1011)
OPDEF(ult, 60, 2, Op2) // unsigned integer less-than (0x3C 0011 1100)
OPDEF(ugt, 61, 2, Op2) // unsigned integer greater-than (0x3D 0011 1101)
OPDEF(ule, 62, 2, Op2) // unsigned integer less-than-or-equal (0x3E 0011 1110)
OPDEF(uge, 63, 2, Op2) // unsigned integer greater-than-or-equal (0x3F 0011 1111)
OPDEF(eq, 55, 2) // integer equality
OPDEF(lt, 56, 2) // 0x38 0011 1000
OPDEF(gt, 57, 2) // 0x39 0011 1001
OPDEF(le, 58, 2) // 0x3A 0011 1010
OPDEF(ge, 59, 2) // 0x3B 0011 1011
OPDEF(ult, 60, 2) // 0x3C 0011 1100
OPDEF(ugt, 61, 2) // 0x3D 0011 1101
OPDEF(ule, 62, 2) // 0x3E 0011 1110
OPDEF(uge, 63, 2) // 0x3F 0011 1111
OPDEF64(2, 0, 2, Op2) // wraps a pair of refs, for LIR_cmov or LIR_qcmov
OPDEF64(file, 1, 2, Op1) // source filename for debug symbols
OPDEF64(line, 2, 2, Op1) // source line number for debug symbols
OPDEF64(xbarrier, 3, 1, Op2) // memory barrier; doesn't exit, but flushes all values to the stack
OPDEF64(xtbl, 4, 1, Op2) // exit via indirect jump
OPDEF64(2, 0, 2) // wraps a pair of refs
OPDEF64(file, 1, 2)
OPDEF64(line, 2, 2)
OPDEF64(xbarrier, 3, 1) // memory barrier (dummy guard)
OPDEF64(xtbl, 4, 1) // exit via indirect jump
OPDEF64(unused5_64, 5,-1, None)
OPDEF64(unused6_64, 6,-1, None)
OPDEF64(unused7_64, 7,-1, None)
OPDEF64(unused8_64, 8,-1, None)
OPDEF64(unused9_64, 9,-1, None)
OPDEF64(unused5_64, 5, 2)
OPDEF64(unused6_64, 6, 2)
OPDEF64(unused7_64, 7, 2)
OPDEF64(unused8_64, 8, 2)
OPDEF64(ldq, LIR_ld, 2, Op2) // 64-bit (quad) load
OPDEF64(unused9_64, 9, 2)
OPDEF64(ldq, LIR_ld, 2) // quad load
OPDEF64(unused11_64, 11,-1, None)
OPDEF64(unused11_64, 11, 2)
OPDEF64(stqi, LIR_sti, 2, Sti) // 64-bit (quad) store
OPDEF64(fret, LIR_ret, 1, Op1)
OPDEF64(stqi, LIR_sti, 2) // quad store
OPDEF64(fret, LIR_ret, 1)
OPDEF64(unused14_64, 14,-1, None)
OPDEF64(unused15_64, 15,-1, None)
OPDEF64(unused14_64, 14, 2)
OPDEF64(unused15_64, 15, 2)
OPDEF64(fcall, LIR_call, 0, C) // subroutine call returning 64-bit (quad) value
OPDEF64(fcall, LIR_call, 0) // subroutine call returning quad
OPDEF64(unused17_64, 17,-1, None)
OPDEF64(unused18_64, 18,-1, None)
OPDEF64(unused19_64, 19,-1, None)
OPDEF64(unused20_64, 20,-1, None)
OPDEF64(unused21_64, 21,-1, None)
OPDEF64(unused22_64, 22,-1, None)
OPDEF64(unused23_64, 23,-1, None)
OPDEF64(unused17_64, 17, 2)
OPDEF64(unused18_64, 18, 2)
OPDEF64(unused19_64, 19, 2)
OPDEF64(unused20_64, 20, 2)
OPDEF64(unused21_64, 21, 2)
OPDEF64(unused22_64, 22, 2)
OPDEF64(unused23_64, 23, 2)
// We strip off the 64 bit flag and compare that the opcode is between LIR_int
// We strip of the 64bit flag and compare that the opcode is between LIR_int
// and LIR_uge to decide whether we can CSE the opcode. All opcodes below
// this marker are subject to CSE.
OPDEF64(quad, LIR_int, 0, I64) // 64-bit (quad) constant value
OPDEF64(qcmov, LIR_cmov, 2, Op2) // 64-bit conditional move
OPDEF64(quad, LIR_int, 0) // quad constant value
OPDEF64(qcmov, LIR_cmov, 2)
OPDEF64(unused26_64, 26, 2)
OPDEF64(unused26_64, 26,-1, None)
OPDEF64(unused27_64, 27,-1, None)
OPDEF64(unused28_64, 28,-1, None)
OPDEF64(unused29_64, 29,-1, None)
OPDEF64(unused30_64, 30,-1, None)
OPDEF64(unused31_64, 31,-1, None)
OPDEF64(unused32_64, 32,-1, None)
OPDEF64(unused33_64, 33,-1, None)
OPDEF64(unused27_64, 27, 2)
OPDEF64(unused28_64, 28, 2)
OPDEF64(unused29_64, 29, 2)
OPDEF64(unused30_64, 30, 2)
OPDEF64(unused31_64, 31, 2)
OPDEF64(unused32_64, 32, 2)
OPDEF64(unused33_64, 33, 2)
OPDEF64(ldqc, LIR_ldc, 2, Op2) // non-volatile 64-bit load
OPDEF64(ldqc, LIR_ldc, 2)
OPDEF64(fneg, LIR_neg, 1, Op1) // floating-point negation
OPDEF64(fadd, LIR_add, 2, Op2) // floating-point addition
OPDEF64(fsub, LIR_sub, 2, Op2) // floating-point subtraction
OPDEF64(fmul, LIR_mul, 2, Op2) // floating-point multiplication
OPDEF64(fdiv, LIR_div, 2, Op2) // floating-point division
OPDEF64(fmod, LIR_mod, 2, Op2) // floating-point modulus(?)
/* floating-point arithmetic operations */
OPDEF64(fneg, LIR_neg, 1)
OPDEF64(fadd, LIR_add, 2)
OPDEF64(fsub, LIR_sub, 2)
OPDEF64(fmul, LIR_mul, 2)
OPDEF64(fdiv, LIR_div, 2)
OPDEF64(fmod, LIR_mod, 2)
OPDEF64(qiand, 41, 2, Op2) // 64-bit bitwise AND
OPDEF64(qiadd, 42, 2, Op2) // 64-bit bitwise ADD
OPDEF64(qior, 43, 2, Op2) // 64-bit bitwise OR
OPDEF64(qiand, 41, 2)
OPDEF64(qiadd, 42, 2)
OPDEF64(qior, 43, 2)
OPDEF64(qilsh, 44, 2)
OPDEF64(qjoin, 45, 2) // 1st arg is low 32 bits, 2nd arg is high 32 bits
OPDEF64(qilsh, 44, 2, Op2) // 64-bit left shift
OPDEF64(qjoin, 45, 2, Op2) // join two 32-bit values (1st arg is low bits, 2nd is high)
OPDEF64(i2f, 46, 1) // convert an integer to a float
OPDEF64(u2f, 47, 1) // convert an unsigned integer to a float
OPDEF64(i2f, 46, 1, Op1) // convert a signed 32-bit integer to a float
OPDEF64(u2f, 47, 1, Op1) // convert an unsigned 32-bit integer to a float
OPDEF64(unused48_64, 48,-1, None)
OPDEF64(unused49_64, 49,-1, None)
OPDEF64(unused50_64, 50,-1, None)
OPDEF64(unused51_64, 51,-1, None)
OPDEF64(unused52_64, 52,-1, None)
OPDEF64(unused53_64, 53,-1, None)
OPDEF64(unused54_64, 54,-1, None)
OPDEF64(unused55_64, 55,-1, None)
OPDEF64(unused56_64, 56,-1, None)
OPDEF64(unused57_64, 57,-1, None)
OPDEF64(unused58_64, 58,-1, None)
OPDEF64(unused59_64, 59,-1, None)
OPDEF64(unused60_64, 60,-1, None)
OPDEF64(unused61_64, 61,-1, None)
OPDEF64(unused62_64, 62,-1, None)
OPDEF64(unused63_64, 63,-1, None)
OPDEF64(unused48_64, 48, 2)
OPDEF64(unused49_64, 49, 2)
OPDEF64(unused50_64, 50, 2)
OPDEF64(unused51_64, 51, 2)
OPDEF64(unused52_64, 52, 2)
OPDEF64(unused53_64, 53, 2)
OPDEF64(unused54_64, 54, 2)
OPDEF64(unused55_64, 55, 2)
OPDEF64(unused56_64, 56, 2)
OPDEF64(unused57_64, 57, 2)
OPDEF64(unused58_64, 58, 2)
OPDEF64(unused59_64, 59, 2)
OPDEF64(unused60_64, 60, 2)
OPDEF64(unused61_64, 61, 2)
OPDEF64(unused62_64, 62, 2)
OPDEF64(unused63_64, 63, 2)

Просмотреть файл

@ -615,7 +615,7 @@ Assembler::hint(LIns* i, RegisterMask allow /* = ~0 */)
else if (op == LIR_callh)
prefer = rmask(R1);
else if (op == LIR_param)
prefer = rmask(imm2register(i->paramArg()));
prefer = rmask(imm2register(i->imm8()));
if (_allocator.free & allow & prefer)
allow &= prefer;
@ -1918,8 +1918,8 @@ Assembler::asm_qlo(LInsp ins)
void
Assembler::asm_param(LInsp ins)
{
uint32_t a = ins->paramArg();
uint32_t kind = ins->paramKind();
uint32_t a = ins->imm8();
uint32_t kind = ins->imm8b();
if (kind == 0) {
// ordinary param
AbiKind abi = _thisfrag->lirbuf->abi;

Просмотреть файл

@ -591,7 +591,7 @@ namespace nanojit
// restore first parameter, the only one we use
LInsp state = _thisfrag->lirbuf->state;
findSpecificRegFor(state, argRegs[state->paramArg()]);
findSpecificRegFor(state, argRegs[state->imm8()]);
}
void Assembler::asm_fcond(LInsp ins)
@ -817,8 +817,8 @@ namespace nanojit
void Assembler::asm_param(LInsp ins)
{
uint32_t a = ins->paramArg();
uint32_t kind = ins->paramKind();
uint32_t a = ins->imm8();
uint32_t kind = ins->imm8b();
// prepResultReg(ins, rmask(argRegs[a]));
if (kind == 0) {
prepResultReg(ins, rmask(argRegs[a]));

Просмотреть файл

@ -343,8 +343,8 @@ namespace nanojit
}
else if (op == LIR_param) {
uint32_t max_regs = max_abi_regs[_thisfrag->lirbuf->abi];
if (i->paramArg() < max_regs)
prefer &= rmask(Register(i->paramArg()));
if (i->imm8() < max_regs)
prefer &= rmask(Register(i->imm8()));
}
else if (op == LIR_callh || (op == LIR_rsh && i->oprnd1()->opcode()==LIR_callh)) {
prefer &= rmask(retRegs[1]);
@ -1114,8 +1114,8 @@ namespace nanojit
void Assembler::asm_param(LInsp ins)
{
uint32_t a = ins->paramArg();
uint32_t kind = ins->paramKind();
uint32_t a = ins->imm8();
uint32_t kind = ins->imm8b();
if (kind == 0) {
// ordinary param
AbiKind abi = _thisfrag->lirbuf->abi;