/*
** MIPS IR assembler (SSA IR -> machine code).
** Copyright (C) 2005-2017 Mike Pall. See Copyright Notice in luajit.h
*/
/* -- Register allocator extensions --------------------------------------- */
/* Allocate a register with a hint. */
static Reg ra_hintalloc(ASMState *as, IRRef ref, Reg hint, RegSet allow)
{
Reg r = IR(ref)->r;
if (ra_noreg(r)) {
if (!ra_hashint(r) && !iscrossref(as, ref))
ra_sethint(IR(ref)->r, hint); /* Propagate register hint. */
r = ra_allocref(as, ref, allow);
}
ra_noweak(as, r);
return r;
}
/* Allocate a register or RID_ZERO. */
static Reg ra_alloc1z(ASMState *as, IRRef ref, RegSet allow)
{
Reg r = IR(ref)->r;
if (ra_noreg(r)) {
if (!(allow & RSET_FPR) && irref_isk(ref) && get_kval(IR(ref)) == 0)
return RID_ZERO;
r = ra_allocref(as, ref, allow);
} else {
ra_noweak(as, r);
}
return r;
}
/* Allocate two source registers for three-operand instructions. */
static Reg ra_alloc2(ASMState *as, IRIns *ir, RegSet allow)
{
IRIns *irl = IR(ir->op1), *irr = IR(ir->op2);
Reg left = irl->r, right = irr->r;
if (ra_hasreg(left)) {
ra_noweak(as, left);
if (ra_noreg(right))
right = ra_alloc1z(as, ir->op2, rset_exclude(allow, left));
else
ra_noweak(as, right);
} else if (ra_hasreg(right)) {
ra_noweak(as, right);
left = ra_alloc1z(as, ir->op1, rset_exclude(allow, right));
} else if (ra_hashint(right)) {
right = ra_alloc1z(as, ir->op2, allow);
left = ra_alloc1z(as, ir->op1, rset_exclude(allow, right));
} else {
left = ra_alloc1z(as, ir->op1, allow);
right = ra_alloc1z(as, ir->op2, rset_exclude(allow, left));
}
return left | (right << 8);
}
/* -- Guard handling ------------------------------------------------------ */
/* Need some spare long-range jump slots, for out-of-range branches. */
#define MIPS_SPAREJUMP 4
/* Setup spare long-range jump slots per mcarea. */
static void asm_sparejump_setup(ASMState *as)
{
MCode *mxp = as->mcbot;
if (((uintptr_t)mxp & (LJ_PAGESIZE-1)) == sizeof(MCLink)) {
lua_assert(MIPSI_NOP == 0);
memset(mxp, 0, MIPS_SPAREJUMP*2*sizeof(MCode));
mxp += MIPS_SPAREJUMP*2;
lua_assert(mxp < as->mctop);
lj_mcode_sync(as->mcbot, mxp);
lj_mcode_commitbot(as->J, mxp);
as->mcbot = mxp;
as->mclim = as->mcbot + MCLIM_REDZONE;
}
}
/* Setup exit stub after the end of each trace. */
static void asm_exitstub_setup(ASMState *as)
{
MCode *mxp = as->mctop;
/* sw TMP, 0(sp); j ->vm_exit_handler; li TMP, traceno */
*--mxp = MIPSI_LI|MIPSF_T(RID_TMP)|as->T->traceno;
*--mxp = MIPSI_J|((((uintptr_t)(void *)lj_vm_exit_handler)>>2)&0x03ffffffu);
lua_assert(((uintptr_t)mxp ^ (uintptr_t)(void *)lj_vm_exit_handler)>>28 == 0);
*--mxp = MIPSI_SW|MIPSF_T(RID_TMP)|MIPSF_S(RID_SP)|0;
as->mctop = mxp;
}
/* Keep this in-sync with exitstub_trace_addr(). */
#define asm_exitstub_addr(as) ((as)->mctop)
/* Emit conditional branch to exit for guard. */
static void asm_guard(ASMState *as, MIPSIns mi, Reg rs, Reg rt)
{
MCode *target = asm_exitstub_addr(as);
MCode *p = as->mcp;
if (LJ_UNLIKELY(p == as->invmcp)) {
as->invmcp = NULL;
as->loopinv = 1;
as->mcp = p+1;
mi = mi ^ ((mi>>28) == 1 ? 0x04000000u : 0x00010000u); /* Invert cond. */
target = p; /* Patch target later in asm_loop_fixup. */
}
emit_ti(as, MIPSI_LI, RID_TMP, as->snapno);
emit_branch(as, mi, rs, rt, target);
}
/* -- Operand fusion ------------------------------------------------------ */
/* Limit linear search to this distance. Avoids O(n^2) behavior. */
#define CONFLICT_SEARCH_LIM 31
/* Check if there's no conflicting instruction between curins and ref. */
static int noconflict(ASMState *as, IRRef ref, IROp conflict)
{
IRIns *ir = as->ir;
IRRef i = as->curins;
if (i > ref + CONFLICT_SEARCH_LIM)
return 0; /* Give up, ref is too far away. */
while (--i > ref)
if (ir[i].o == conflict)
return 0; /* Conflict found. */
return 1; /* Ok, no conflict. */
}
/* Fuse the array base of colocated arrays. */
static int32_t asm_fuseabase(ASMState *as, IRRef ref)
{
IRIns *ir = IR(ref);
if (ir->o == IR_TNEW && ir->op1 <= LJ_MAX_COLOSIZE &&
!neverfuse(as) && noconflict(as, ref, IR_NEWREF))
return (int32_t)sizeof(GCtab);
return 0;
}
/* Fuse array/hash/upvalue reference into register+offset operand. */
static Reg asm_fuseahuref(ASMState *as, IRRef ref, int32_t *ofsp, RegSet allow)
{
IRIns *ir = IR(ref);
if (ra_noreg(ir->r)) {
if (ir->o == IR_AREF) {
if (mayfuse(as, ref)) {
if (irref_isk(ir->op2)) {
IRRef tab = IR(ir->op1)->op1;
int32_t ofs = asm_fuseabase(as, tab);
IRRef refa = ofs ? tab : ir->op1;
ofs += 8*IR(ir->op2)->i;
if (checki16(ofs)) {
*ofsp = ofs;
return ra_alloc1(as, refa, allow);
}
}
}
} else if (ir->o == IR_HREFK) {
if (mayfuse(as, ref)) {
int32_t ofs = (int32_t)(IR(ir->op2)->op2 * sizeof(Node));
if (checki16(ofs)) {
*ofsp = ofs;
return ra_alloc1(as, ir->op1, allow);
}
}
} else if (ir->o == IR_UREFC) {
if (irref_isk(ir->op1)) {
GCfunc *fn = ir_kfunc(IR(ir->op1));
intptr_t ofs = (intptr_t)&gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.tv;
intptr_t jgl = (intptr_t)J2G(as->J);
if ((uintptr_t)(ofs-jgl) < 65536) {
*ofsp = ofs-jgl-32768;
return RID_JGL;
} else {
*ofsp = (int16_t)ofs;
return ra_allock(as, ofs-(int16_t)ofs, allow);
}
}
}
}
*ofsp = 0;
return ra_alloc1(as, ref, allow);
}
/* Fuse XLOAD/XSTORE reference into load/store operand. */
static void asm_fusexref(ASMState *as, MIPSIns mi, Reg rt, IRRef ref,
RegSet allow, int32_t ofs)
{
IRIns *ir = IR(ref);
Reg base;
if (ra_noreg(ir->r) && canfuse(as, ir)) {
if (ir->o == IR_ADD) {
intptr_t ofs2;
if (irref_isk(ir->op2) && (ofs2 = ofs + get_kval(IR(ir->op2)),
checki16(ofs2))) {
ref = ir->op1;
ofs = (int32_t)ofs2;
}
} else if (ir->o == IR_STRREF) {
intptr_t ofs2 = 65536;
lua_assert(ofs == 0);
ofs = (int32_t)sizeof(GCstr);
if (irref_isk(ir->op2)) {
ofs2 = ofs + get_kval(IR(ir->op2));
ref = ir->op1;
} else if (irref_isk(ir->op1)) {
ofs2 = ofs + get_kval(IR(ir->op1));
ref = ir->op2;
}
if (!checki16(ofs2)) {
/* NYI: Fuse ADD with constant. */
Reg right, left = ra_alloc2(as, ir, allow);
right = (left >> 8); left &= 255;
emit_hsi(as, mi, rt, RID_TMP, ofs);
emit_dst(as, MIPSI_AADDU, RID_TMP, left, right);
return;
}
ofs = ofs2;
}
}
base = ra_alloc1(as, ref, allow);
emit_hsi(as, mi, rt, base, ofs);
}
/* -- Calls --------------------------------------------------------------- */
/* Generate a call to a C function. */
static void asm_gencall(ASMState *as, const CCallInfo *ci, IRRef *args)
{
uint32_t n, nargs = CCI_XNARGS(ci);
int32_t ofs = LJ_32 ? 16 : 0;
#if LJ_SOFTFP
Reg gpr = REGARG_FIRSTGPR;
#else
Reg gpr, fpr = REGARG_FIRSTFPR;
#endif
if ((void *)ci->func)
emit_call(as, (void *)ci->func, 1);
#if !LJ_SOFTFP
for (gpr = REGARG_FIRSTGPR; gpr <= REGARG_LASTGPR; gpr++)
as->cost[gpr] = REGCOST(~0u, ASMREF_L);
gpr = REGARG_FIRSTGPR;
#endif
for (n = 0; n < nargs; n++) { /* Setup args. */
IRRef ref = args[n];
if (ref) {
IRIns *ir = IR(ref);
#if !LJ_SOFTFP
if (irt_isfp(ir->t) && fpr <= REGARG_LASTFPR &&
!(ci->flags & CCI_VARARG)) {
lua_assert(rset_test(as->freeset, fpr)); /* Already evicted. */
ra_leftov(as, fpr, ref);
fpr += LJ_32 ? 2 : 1;
gpr += (LJ_32 && irt_isnum(ir->t)) ? 2 : 1;
} else
#endif
{
#if LJ_32 && !LJ_SOFTFP
fpr = REGARG_LASTFPR+1;
#endif
if (LJ_32 && irt_isnum(ir->t)) gpr = (gpr+1) & ~1;
if (gpr <= REGARG_LASTGPR) {
lua_assert(rset_test(as->freeset, gpr)); /* Already evicted. */
#if !LJ_SOFTFP
if (irt_isfp(ir->t)) {
RegSet of = as->freeset;
Reg r;
/* Workaround to protect argument GPRs from being used for remat. */
as->freeset &= ~RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1);
r = ra_alloc1(as, ref, RSET_FPR);
as->freeset |= (of & RSET_RANGE(REGARG_FIRSTGPR, REGARG_LASTGPR+1));
if (irt_isnum(ir->t)) {
#if LJ_32
emit_tg(as, MIPSI_MFC1, gpr+(LJ_BE?0:1), r+1);
emit_tg(as, MIPSI_MFC1, gpr+(LJ_BE?1:0), r);
lua_assert(rset_test(as->freeset, gpr+1)); /* Already evicted. */
gpr += 2;
#else
emit_tg(as, MIPSI_DMFC1, gpr, r);
gpr++; fpr++;
#endif
} else if (irt_isfloat(ir->t)) {
emit_tg(as, MIPSI_MFC1, gpr, r);
gpr++;
#if LJ_64
fpr++;
#endif
}
} else
#endif
{
ra_leftov(as, gpr, ref);
gpr++;
#if LJ_64 && !LJ_SOFTFP
fpr++;
#endif
}
} else {
Reg r = ra_alloc1z(as, ref, !LJ_SOFTFP && irt_isfp(ir->t) ? RSET_FPR : RSET_GPR);
#if LJ_32
if (irt_isnum(ir->t)) ofs = (ofs + 4) & ~4;
emit_spstore(as, ir, r, ofs);
ofs += irt_isnum(ir->t) ? 8 : 4;
#else
emit_spstore(as, ir, r, ofs + ((LJ_BE && !irt_isfp(ir->t) && !irt_is64(ir->t)) ? 4 : 0));
ofs += 8;
#endif
}
}
} else {
#if !LJ_SOFTFP
fpr = REGARG_LASTFPR+1;
#endif
if (gpr <= REGARG_LASTGPR) {
gpr++;
#if LJ_64 && !LJ_SOFTFP
fpr++;
#endif
} else {
ofs += LJ_32 ? 4 : 8;
}
}
checkmclim(as);
}
}
/* Setup result reg/sp for call. Evict scratch regs. */
static void asm_setupresult(ASMState *as, IRIns *ir, const CCallInfo *ci)
{
RegSet drop = RSET_SCRATCH;
#if LJ_32
int hiop = ((ir+1)->o == IR_HIOP && !irt_isnil((ir+1)->t));
#endif
#if !LJ_SOFTFP
if ((ci->flags & CCI_NOFPRCLOBBER))
drop &= ~RSET_FPR;
#endif
if (ra_hasreg(ir->r))
rset_clear(drop, ir->r); /* Dest reg handled below. */
#if LJ_32
if (hiop && ra_hasreg((ir+1)->r))
rset_clear(drop, (ir+1)->r); /* Dest reg handled below. */
#endif
ra_evictset(as, drop); /* Evictions must be performed first. */
if (ra_used(ir)) {
lua_assert(!irt_ispri(ir->t));
if (!LJ_SOFTFP && irt_isfp(ir->t)) {
if ((ci->flags & CCI_CASTU64)) {
int32_t ofs = sps_scale(ir->s);
Reg dest = ir->r;
if (ra_hasreg(dest)) {
ra_free(as, dest);
ra_modified(as, dest);
#if LJ_32
emit_tg(as, MIPSI_MTC1, RID_RETHI, dest+1);
emit_tg(as, MIPSI_MTC1, RID_RETLO, dest);
#else
emit_tg(as, MIPSI_DMTC1, RID_RET, dest);
#endif
}
if (ofs) {
#if LJ_32
emit_tsi(as, MIPSI_SW, RID_RETLO, RID_SP, ofs+(LJ_BE?4:0));
emit_tsi(as, MIPSI_SW, RID_RETHI, RID_SP, ofs+(LJ_BE?0:4));
#else
emit_tsi(as, MIPSI_SD, RID_RET, RID_SP, ofs);
#endif
}
} else {
ra_destreg(as, ir, RID_FPRET);
}
#if LJ_32
} else if (hiop) {
ra_destpair(as, ir);
#endif
} else {
ra_destreg(as, ir, RID_RET);
}
}
}
static void asm_callx(ASMState *as, IRIns *ir)
{
IRRef args[CCI_NARGS_MAX*2];
CCallInfo ci;
IRRef func;
IRIns *irf;
ci.flags = asm_callx_flags(as, ir);
asm_collectargs(as, ir, &ci, args);
asm_setupresult(as, ir, &ci);
func = ir->op2; irf = IR(func);
if (irf->o == IR_CARG) { func = irf->op1; irf = IR(func); }
if (irref_isk(func)) { /* Call to constant address. */
ci.func = (ASMFunction)(void *)get_kval(irf);
} else { /* Need specific register for indirect calls. */
Reg r = ra_alloc1(as, func, RID2RSET(RID_CFUNCADDR));
MCode *p = as->mcp;
if (r == RID_CFUNCADDR)
*--p = MIPSI_NOP;
else
*--p = MIPSI_MOVE | MIPSF_D(RID_CFUNCADDR) | MIPSF_S(r);
*--p = MIPSI_JALR | MIPSF_S(r);
as->mcp = p;
ci.func = (ASMFunction)(void *)0;
}
asm_gencall(as, &ci, args);
}
#if !LJ_SOFTFP
static void asm_callround(ASMState *as, IRIns *ir, IRCallID id)
{
/* The modified regs must match with the *.dasc implementation. */
RegSet drop = RID2RSET(RID_R1)|RID2RSET(RID_R12)|RID2RSET(RID_FPRET)|
RID2RSET(RID_F2)|RID2RSET(RID_F4)|RID2RSET(REGARG_FIRSTFPR);
if (ra_hasreg(ir->r)) rset_clear(drop, ir->r);
ra_evictset(as, drop);
ra_destreg(as, ir, RID_FPRET);
emit_call(as, (void *)lj_ir_callinfo[id].func, 0);
ra_leftov(as, REGARG_FIRSTFPR, ir->op1);
}
#endif
/* -- Returns ------------------------------------------------------------- */
/* Return to lower frame. Guard that it goes to the right spot. */
static void asm_retf(ASMState *as, IRIns *ir)
{
Reg base = ra_alloc1(as, REF_BASE, RSET_GPR);
void *pc = ir_kptr(IR(ir->op2));
int32_t delta = 1+LJ_FR2+bc_a(*((const BCIns *)pc - 1));
as->topslot -= (BCReg)delta;
if ((int32_t)as->topslot < 0) as->topslot = 0;
irt_setmark(IR(REF_BASE)->t); /* Children must not coalesce with BASE reg. */
emit_setgl(as, base, jit_base);
emit_addptr(as, base, -8*delta);
asm_guard(as, MIPSI_BNE, RID_TMP,
ra_allock(as, igcptr(pc), rset_exclude(RSET_GPR, base)));
emit_tsi(as, MIPSI_AL, RID_TMP, base, -8);
}
/* -- Type conversions ---------------------------------------------------- */
#if !LJ_SOFTFP
static void asm_tointg(ASMState *as, IRIns *ir, Reg left)
{
Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left));
Reg dest = ra_dest(as, ir, RSET_GPR);
asm_guard(as, MIPSI_BC1F, 0, 0);
emit_fgh(as, MIPSI_C_EQ_D, 0, tmp, left);
emit_fg(as, MIPSI_CVT_D_W, tmp, tmp);
emit_tg(as, MIPSI_MFC1, dest, tmp);
emit_fg(as, MIPSI_CVT_W_D, tmp, left);
}
static void asm_tobit(ASMState *as, IRIns *ir)
{
RegSet allow = RSET_FPR;
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_alloc1(as, ir->op1, allow);
Reg right = ra_alloc1(as, ir->op2, rset_clear(allow, left));
Reg tmp = ra_scratch(as, rset_clear(allow, right));
emit_tg(as, MIPSI_MFC1, dest, tmp);
emit_fgh(as, MIPSI_ADD_D, tmp, left, right);
}
#elif LJ_64 /* && LJ_SOFTFP */
static void asm_tointg(ASMState *as, IRIns *ir, Reg r)
{
/* The modified regs must match with the *.dasc implementation. */
RegSet drop = RID2RSET(REGARG_FIRSTGPR)|RID2RSET(RID_RET)|RID2RSET(RID_RET+1)|
RID2RSET(RID_R1)|RID2RSET(RID_R12);
if (ra_hasreg(ir->r)) rset_clear(drop, ir->r);
ra_evictset(as, drop);
/* Return values are in RID_RET (converted value) and RID_RET+1 (status). */
ra_destreg(as, ir, RID_RET);
asm_guard(as, MIPSI_BNE, RID_RET+1, RID_ZERO);
emit_call(as, (void *)lj_ir_callinfo[IRCALL_lj_vm_tointg].func, 0);
if (r == RID_NONE)
ra_leftov(as, REGARG_FIRSTGPR, ir->op1);
else if (r != REGARG_FIRSTGPR)
emit_move(as, REGARG_FIRSTGPR, r);
}
static void asm_tobit(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
emit_dta(as, MIPSI_SLL, dest, dest, 0);
asm_callid(as, ir, IRCALL_lj_vm_tobit);
}
#endif
static void asm_conv(ASMState *as, IRIns *ir)
{
IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK);
#if !LJ_SOFTFP32
int stfp = (st == IRT_NUM || st == IRT_FLOAT);
#endif
#if LJ_64
int st64 = (st == IRT_I64 || st == IRT_U64 || st == IRT_P64);
#endif
IRRef lref = ir->op1;
#if LJ_32
lua_assert(!(irt_isint64(ir->t) ||
(st == IRT_I64 || st == IRT_U64))); /* Handled by SPLIT. */
#endif
#if LJ_SOFTFP32
/* FP conversions are handled by SPLIT. */
lua_assert(!irt_isfp(ir->t) && !(st == IRT_NUM || st == IRT_FLOAT));
/* Can't check for same types: SPLIT uses CONV int.int + BXOR for sfp NEG. */
#else
lua_assert(irt_type(ir->t) != st);
#if !LJ_SOFTFP
if (irt_isfp(ir->t)) {
Reg dest = ra_dest(as, ir, RSET_FPR);
if (stfp) { /* FP to FP conversion. */
emit_fg(as, st == IRT_NUM ? MIPSI_CVT_S_D : MIPSI_CVT_D_S,
dest, ra_alloc1(as, lref, RSET_FPR));
} else if (st == IRT_U32) { /* U32 to FP conversion. */
/* y = (x ^ 0x8000000) + 2147483648.0 */
Reg left = ra_alloc1(as, lref, RSET_GPR);
Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, dest));
if (irt_isfloat(ir->t))
emit_fg(as, MIPSI_CVT_S_D, dest, dest);
/* Must perform arithmetic with doubles to keep the precision. */
emit_fgh(as, MIPSI_ADD_D, dest, dest, tmp);
emit_fg(as, MIPSI_CVT_D_W, dest, dest);
emit_lsptr(as, MIPSI_LDC1, (tmp & 31),
(void *)&as->J->k64[LJ_K64_2P31], RSET_GPR);
emit_tg(as, MIPSI_MTC1, RID_TMP, dest);
emit_dst(as, MIPSI_XOR, RID_TMP, RID_TMP, left);
emit_ti(as, MIPSI_LUI, RID_TMP, 0x8000);
#if LJ_64
} else if(st == IRT_U64) { /* U64 to FP conversion. */
/* if (x >= 1u<<63) y = (double)(int64_t)(x&(1u<<63)-1) + pow(2.0, 63) */
Reg left = ra_alloc1(as, lref, RSET_GPR);
Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, dest));
MCLabel l_end = emit_label(as);
if (irt_isfloat(ir->t)) {
emit_fgh(as, MIPSI_ADD_S, dest, dest, tmp);
emit_lsptr(as, MIPSI_LWC1, (tmp & 31), (void *)&as->J->k32[LJ_K32_2P63],
rset_exclude(RSET_GPR, left));
emit_fg(as, MIPSI_CVT_S_L, dest, dest);
} else {
emit_fgh(as, MIPSI_ADD_D, dest, dest, tmp);
emit_lsptr(as, MIPSI_LDC1, (tmp & 31), (void *)&as->J->k64[LJ_K64_2P63],
rset_exclude(RSET_GPR, left));
emit_fg(as, MIPSI_CVT_D_L, dest, dest);
}
emit_branch(as, MIPSI_BGEZ, left, RID_ZERO, l_end);
emit_tg(as, MIPSI_DMTC1, RID_TMP, dest);
emit_tsml(as, MIPSI_DEXTM, RID_TMP, left, 30, 0);
#endif
} else { /* Integer to FP conversion. */
Reg left = ra_alloc1(as, lref, RSET_GPR);
#if LJ_32
emit_fg(as, irt_isfloat(ir->t) ? MIPSI_CVT_S_W : MIPSI_CVT_D_W,
dest, dest);
emit_tg(as, MIPSI_MTC1, left, dest);
#else
MIPSIns mi = irt_isfloat(ir->t) ?
(st64 ? MIPSI_CVT_S_L : MIPSI_CVT_S_W) :
(st64 ? MIPSI_CVT_D_L : MIPSI_CVT_D_W);
emit_fg(as, mi, dest, dest);
emit_tg(as, st64 ? MIPSI_DMTC1 : MIPSI_MTC1, left, dest);
#endif
}
} else if (stfp) { /* FP to integer conversion. */
if (irt_isguard(ir->t)) {
/* Checked conversions are only supported from number to int. */
lua_assert(irt_isint(ir->t) && st == IRT_NUM);
asm_tointg(as, ir, ra_alloc1(as, lref, RSET_FPR));
} else {
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_alloc1(as, lref, RSET_FPR);
Reg tmp = ra_scratch(as, rset_exclude(RSET_FPR, left));
if (irt_isu32(ir->t)) { /* FP to U32 conversion. */
/* y = (int)floor(x - 2147483648.0) ^ 0x80000000 */
emit_dst(as, MIPSI_XOR, dest, dest, RID_TMP);
emit_ti(as, MIPSI_LUI, RID_TMP, 0x8000);
emit_tg(as, MIPSI_MFC1, dest, tmp);
emit_fg(as, st == IRT_FLOAT ? MIPSI_FLOOR_W_S : MIPSI_FLOOR_W_D,
tmp, tmp);
emit_fgh(as, st == IRT_FLOAT ? MIPSI_SUB_S : MIPSI_SUB_D,
tmp, left, tmp);
if (st == IRT_FLOAT)
emit_lsptr(as, MIPSI_LWC1, (tmp & 31),
(void *)&as->J->k32[LJ_K32_2P31], RSET_GPR);
else
emit_lsptr(as, MIPSI_LDC1, (tmp & 31),
(void *)&as->J->k64[LJ_K64_2P31], RSET_GPR);
#if LJ_64
} else if (irt_isu64(ir->t)) { /* FP to U64 conversion. */
MCLabel l_end;
emit_tg(as, MIPSI_DMFC1, dest, tmp);
l_end = emit_label(as);
/* For inputs >= 2^63 add -2^64 and convert again. */
if (st == IRT_NUM) {
emit_fg(as, MIPSI_TRUNC_L_D, tmp, tmp);
emit_fgh(as, MIPSI_ADD_D, tmp, left, tmp);
emit_lsptr(as, MIPSI_LDC1, (tmp & 31),
(void *)&as->J->k64[LJ_K64_M2P64],
rset_exclude(RSET_GPR, dest));
emit_fg(as, MIPSI_TRUNC_L_D, tmp, left); /* Delay slot. */
emit_branch(as, MIPSI_BC1T, 0, 0, l_end);
emit_fgh(as, MIPSI_C_OLT_D, 0, left, tmp);
emit_lsptr(as, MIPSI_LDC1, (tmp & 31),
(void *)&as->J->k64[LJ_K64_2P63],
rset_exclude(RSET_GPR, dest));
} else {
emit_fg(as, MIPSI_TRUNC_L_S, tmp, tmp);
emit_fgh(as, MIPSI_ADD_S, tmp, left, tmp);
emit_lsptr(as, MIPSI_LWC1, (tmp & 31),
(void *)&as->J->k32[LJ_K32_M2P64],
rset_exclude(RSET_GPR, dest));
emit_fg(as, MIPSI_TRUNC_L_S, tmp, left); /* Delay slot. */
emit_branch(as, MIPSI_BC1T, 0, 0, l_end);
emit_fgh(as, MIPSI_C_OLT_S, 0, left, tmp);
emit_lsptr(as, MIPSI_LWC1, (tmp & 31),
(void *)&as->J->k32[LJ_K32_2P63],
rset_exclude(RSET_GPR, dest));
}
#endif
} else {
#if LJ_32
emit_tg(as, MIPSI_MFC1, dest, tmp);
emit_fg(as, st == IRT_FLOAT ? MIPSI_TRUNC_W_S : MIPSI_TRUNC_W_D,
tmp, left);
#else
MIPSIns mi = irt_is64(ir->t) ?
(st == IRT_NUM ? MIPSI_TRUNC_L_D : MIPSI_TRUNC_L_S) :
(st == IRT_NUM ? MIPSI_TRUNC_W_D : MIPSI_TRUNC_W_S);
emit_tg(as, irt_is64(ir->t) ? MIPSI_DMFC1 : MIPSI_MFC1, dest, left);
emit_fg(as, mi, left, left);
#endif
}
}
} else
#else
if (irt_isfp(ir->t)) {
#if LJ_64 && LJ_HASFFI
if (stfp) { /* FP to FP conversion. */
asm_callid(as, ir, irt_isnum(ir->t) ? IRCALL_softfp_f2d :
IRCALL_softfp_d2f);
} else { /* Integer to FP conversion. */
IRCallID cid = ((IRT_IS64 >> st) & 1) ?
(irt_isnum(ir->t) ?
(st == IRT_I64 ? IRCALL_fp64_l2d : IRCALL_fp64_ul2d) :
(st == IRT_I64 ? IRCALL_fp64_l2f : IRCALL_fp64_ul2f)) :
(irt_isnum(ir->t) ?
(st == IRT_INT ? IRCALL_softfp_i2d : IRCALL_softfp_ui2d) :
(st == IRT_INT ? IRCALL_softfp_i2f : IRCALL_softfp_ui2f));
asm_callid(as, ir, cid);
}
#else
asm_callid(as, ir, IRCALL_softfp_i2d);
#endif
} else if (stfp) { /* FP to integer conversion. */
if (irt_isguard(ir->t)) {
/* Checked conversions are only supported from number to int. */
lua_assert(irt_isint(ir->t) && st == IRT_NUM);
asm_tointg(as, ir, RID_NONE);
} else {
IRCallID cid = irt_is64(ir->t) ?
((st == IRT_NUM) ?
(irt_isi64(ir->t) ? IRCALL_fp64_d2l : IRCALL_fp64_d2ul) :
(irt_isi64(ir->t) ? IRCALL_fp64_f2l : IRCALL_fp64_f2ul)) :
((st == IRT_NUM) ?
(irt_isint(ir->t) ? IRCALL_softfp_d2i : IRCALL_softfp_d2ui) :
(irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui));
asm_callid(as, ir, cid);
}
} else
#endif
#endif
{
Reg dest = ra_dest(as, ir, RSET_GPR);
if (st >= IRT_I8 && st <= IRT_U16) { /* Extend to 32 bit integer. */
Reg left = ra_alloc1(as, ir->op1, RSET_GPR);
lua_assert(irt_isint(ir->t) || irt_isu32(ir->t));
if ((ir->op2 & IRCONV_SEXT)) {
if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) {
emit_dst(as, st == IRT_I8 ? MIPSI_SEB : MIPSI_SEH, dest, 0, left);
} else {
uint32_t shift = st == IRT_I8 ? 24 : 16;
emit_dta(as, MIPSI_SRA, dest, dest, shift);
emit_dta(as, MIPSI_SLL, dest, left, shift);
}
} else {
emit_tsi(as, MIPSI_ANDI, dest, left,
(int32_t)(st == IRT_U8 ? 0xff : 0xffff));
}
} else { /* 32/64 bit integer conversions. */
#if LJ_32
/* Only need to handle 32/32 bit no-op (cast) on 32 bit archs. */
ra_leftov(as, dest, lref); /* Do nothing, but may need to move regs. */
#else
if (irt_is64(ir->t)) {
if (st64) {
/* 64/64 bit no-op (cast)*/
ra_leftov(as, dest, lref);
} else {
Reg left = ra_alloc1(as, lref, RSET_GPR);
if ((ir->op2 & IRCONV_SEXT)) { /* 32 to 64 bit sign extension. */
emit_dta(as, MIPSI_SLL, dest, left, 0);
} else { /* 32 to 64 bit zero extension. */
emit_tsml(as, MIPSI_DEXT, dest, left, 31, 0);
}
}
} else {
if (st64) {
/* This is either a 32 bit reg/reg mov which zeroes the hiword
** or a load of the loword from a 64 bit address.
*/
Reg left = ra_alloc1(as, lref, RSET_GPR);
emit_tsml(as, MIPSI_DEXT, dest, left, 31, 0);
} else { /* 32/32 bit no-op (cast). */
/* Do nothing, but may need to move regs. */
ra_leftov(as, dest, lref);
}
}
#endif
}
}
}
static void asm_strto(ASMState *as, IRIns *ir)
{
const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_strscan_num];
IRRef args[2];
int32_t ofs = 0;
#if LJ_SOFTFP32
ra_evictset(as, RSET_SCRATCH);
if (ra_used(ir)) {
if (ra_hasspill(ir->s) && ra_hasspill((ir+1)->s) &&
(ir->s & 1) == LJ_BE && (ir->s ^ 1) == (ir+1)->s) {
int i;
for (i = 0; i < 2; i++) {
Reg r = (ir+i)->r;
if (ra_hasreg(r)) {
ra_free(as, r);
ra_modified(as, r);
emit_spload(as, ir+i, r, sps_scale((ir+i)->s));
}
}
ofs = sps_scale(ir->s & ~1);
} else {
Reg rhi = ra_dest(as, ir+1, RSET_GPR);
Reg rlo = ra_dest(as, ir, rset_exclude(RSET_GPR, rhi));
emit_tsi(as, MIPSI_LW, rhi, RID_SP, ofs+(LJ_BE?0:4));
emit_tsi(as, MIPSI_LW, rlo, RID_SP, ofs+(LJ_BE?4:0));
}
}
#else
RegSet drop = RSET_SCRATCH;
if (ra_hasreg(ir->r)) rset_set(drop, ir->r); /* Spill dest reg (if any). */
ra_evictset(as, drop);
ofs = sps_scale(ir->s);
#endif
asm_guard(as, MIPSI_BEQ, RID_RET, RID_ZERO); /* Test return status. */
args[0] = ir->op1; /* GCstr *str */
args[1] = ASMREF_TMP1; /* TValue *n */
asm_gencall(as, ci, args);
/* Store the result to the spill slot or temp slots. */
emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1),
RID_SP, ofs);
}
/* -- Memory references --------------------------------------------------- */
#if LJ_64
/* Store tagged value for ref at base+ofs. */
static void asm_tvstore64(ASMState *as, Reg base, int32_t ofs, IRRef ref)
{
RegSet allow = rset_exclude(RSET_GPR, base);
IRIns *ir = IR(ref);
lua_assert(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t));
if (irref_isk(ref)) {
TValue k;
lj_ir_kvalue(as->J->L, &k, ir);
emit_tsi(as, MIPSI_SD, ra_allock(as, (int64_t)k.u64, allow), base, ofs);
} else {
Reg src = ra_alloc1(as, ref, allow);
Reg type = ra_allock(as, (int64_t)irt_toitype(ir->t) << 47,
rset_exclude(allow, src));
emit_tsi(as, MIPSI_SD, RID_TMP, base, ofs);
if (irt_isinteger(ir->t)) {
emit_dst(as, MIPSI_DADDU, RID_TMP, RID_TMP, type);
emit_tsml(as, MIPSI_DEXT, RID_TMP, src, 31, 0);
} else {
emit_dst(as, MIPSI_DADDU, RID_TMP, src, type);
}
}
}
#endif
/* Get pointer to TValue. */
static void asm_tvptr(ASMState *as, Reg dest, IRRef ref)
{
IRIns *ir = IR(ref);
if (irt_isnum(ir->t)) {
if (irref_isk(ref)) /* Use the number constant itself as a TValue. */
ra_allockreg(as, igcptr(ir_knum(ir)), dest);
else /* Otherwise force a spill and use the spill slot. */
emit_tsi(as, MIPSI_AADDIU, dest, RID_SP, ra_spill(as, ir));
} else {
/* Otherwise use g->tmptv to hold the TValue. */
#if LJ_32
RegSet allow = rset_exclude(RSET_GPR, dest);
Reg type;
emit_tsi(as, MIPSI_ADDIU, dest, RID_JGL, (int32_t)(offsetof(global_State, tmptv)-32768));
if (!irt_ispri(ir->t)) {
Reg src = ra_alloc1(as, ref, allow);
emit_setgl(as, src, tmptv.gcr);
}
if (LJ_SOFTFP && (ir+1)->o == IR_HIOP)
type = ra_alloc1(as, ref+1, allow);
else
type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow);
emit_setgl(as, type, tmptv.it);
#else
asm_tvstore64(as, dest, 0, ref);
emit_tsi(as, MIPSI_DADDIU, dest, RID_JGL,
(int32_t)(offsetof(global_State, tmptv)-32768));
#endif
}
}
static void asm_aref(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg idx, base;
if (irref_isk(ir->op2)) {
IRRef tab = IR(ir->op1)->op1;
int32_t ofs = asm_fuseabase(as, tab);
IRRef refa = ofs ? tab : ir->op1;
ofs += 8*IR(ir->op2)->i;
if (checki16(ofs)) {
base = ra_alloc1(as, refa, RSET_GPR);
emit_tsi(as, MIPSI_AADDIU, dest, base, ofs);
return;
}
}
base = ra_alloc1(as, ir->op1, RSET_GPR);
idx = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, base));
emit_dst(as, MIPSI_AADDU, dest, RID_TMP, base);
emit_dta(as, MIPSI_SLL, RID_TMP, idx, 3);
}
/* Inlined hash lookup. Specialized for key type and for const keys.
** The equivalent C code is:
** Node *n = hashkey(t, key);
** do {
** if (lj_obj_equal(&n->key, key)) return &n->val;
** } while ((n = nextnode(n)));
** return niltv(L);
*/
static void asm_href(ASMState *as, IRIns *ir, IROp merge)
{
RegSet allow = RSET_GPR;
int destused = ra_used(ir);
Reg dest = ra_dest(as, ir, allow);
Reg tab = ra_alloc1(as, ir->op1, rset_clear(allow, dest));
Reg key = RID_NONE, type = RID_NONE, tmpnum = RID_NONE, tmp1 = RID_TMP, tmp2;
#if LJ_64
Reg cmp64 = RID_NONE;
#endif
IRRef refkey = ir->op2;
IRIns *irkey = IR(refkey);
int isk = irref_isk(refkey);
IRType1 kt = irkey->t;
uint32_t khash;
MCLabel l_end, l_loop, l_next;
rset_clear(allow, tab);
#if LJ_SOFTFP32
if (!isk) {
key = ra_alloc1(as, refkey, allow);
rset_clear(allow, key);
if (irkey[1].o == IR_HIOP) {
if (ra_hasreg((irkey+1)->r)) {
type = tmpnum = (irkey+1)->r;
tmp1 = ra_scratch(as, allow);
rset_clear(allow, tmp1);
ra_noweak(as, tmpnum);
} else {
type = tmpnum = ra_allocref(as, refkey+1, allow);
}
rset_clear(allow, tmpnum);
} else {
type = ra_allock(as, (int32_t)irt_toitype(irkey->t), allow);
rset_clear(allow, type);
}
}
#else
if (!LJ_SOFTFP && irt_isnum(kt)) {
key = ra_alloc1(as, refkey, RSET_FPR);
tmpnum = ra_scratch(as, rset_exclude(RSET_FPR, key));
} else if (!irt_ispri(kt)) {
key = ra_alloc1(as, refkey, allow);
rset_clear(allow, key);
#if LJ_32
type = ra_allock(as, (int32_t)irt_toitype(irkey->t), allow);
rset_clear(allow, type);
#endif
}
#endif
tmp2 = ra_scratch(as, allow);
rset_clear(allow, tmp2);
#if LJ_64
if (LJ_SOFTFP || !irt_isnum(kt)) {
/* Allocate cmp64 register used for 64-bit comparisons */
if (LJ_SOFTFP && irt_isnum(kt)) {
cmp64 = key;
} else if (!isk && irt_isaddr(kt)) {
cmp64 = tmp2;
} else {
int64_t k;
if (isk && irt_isaddr(kt)) {
k = ((int64_t)irt_toitype(irkey->t) << 47) | irkey[1].tv.u64;
} else {
lua_assert(irt_ispri(kt) && !irt_isnil(kt));
k = ~((int64_t)~irt_toitype(ir->t) << 47);
}
cmp64 = ra_allock(as, k, allow);
rset_clear(allow, cmp64);
}
}
#endif
/* Key not found in chain: jump to exit (if merged) or load niltv. */
l_end = emit_label(as);
as->invmcp = NULL;
if (merge == IR_NE)
asm_guard(as, MIPSI_B, RID_ZERO, RID_ZERO);
else if (destused)
emit_loada(as, dest, niltvg(J2G(as->J)));
/* Follow hash chain until the end. */
emit_move(as, dest, tmp1);
l_loop = --as->mcp;
emit_tsi(as, MIPSI_AL, tmp1, dest, (int32_t)offsetof(Node, next));
l_next = emit_label(as);
/* Type and value comparison. */
if (merge == IR_EQ) { /* Must match asm_guard(). */
emit_ti(as, MIPSI_LI, RID_TMP, as->snapno);
l_end = asm_exitstub_addr(as);
}
if (!LJ_SOFTFP && irt_isnum(kt)) {
emit_branch(as, MIPSI_BC1T, 0, 0, l_end);
emit_fgh(as, MIPSI_C_EQ_D, 0, tmpnum, key);
*--as->mcp = MIPSI_NOP; /* Avoid NaN comparison overhead. */
emit_branch(as, MIPSI_BEQ, tmp1, RID_ZERO, l_next);
emit_tsi(as, MIPSI_SLTIU, tmp1, tmp1, (int32_t)LJ_TISNUM);
#if LJ_32
emit_hsi(as, MIPSI_LDC1, tmpnum, dest, (int32_t)offsetof(Node, key.n));
} else {
if (irt_ispri(kt)) {
emit_branch(as, MIPSI_BEQ, tmp1, type, l_end);
} else {
emit_branch(as, MIPSI_BEQ, tmp2, key, l_end);
emit_tsi(as, MIPSI_LW, tmp2, dest, (int32_t)offsetof(Node, key.gcr));
emit_branch(as, MIPSI_BNE, tmp1, type, l_next);
}
}
emit_tsi(as, MIPSI_LW, tmp1, dest, (int32_t)offsetof(Node, key.it));
*l_loop = MIPSI_BNE | MIPSF_S(tmp1) | ((as->mcp-l_loop-1) & 0xffffu);
#else
emit_dta(as, MIPSI_DSRA32, tmp1, tmp1, 15);
emit_tg(as, MIPSI_DMTC1, tmp1, tmpnum);
emit_tsi(as, MIPSI_LD, tmp1, dest, (int32_t)offsetof(Node, key.u64));
} else {
emit_branch(as, MIPSI_BEQ, tmp1, cmp64, l_end);
emit_tsi(as, MIPSI_LD, tmp1, dest, (int32_t)offsetof(Node, key.u64));
}
*l_loop = MIPSI_BNE | MIPSF_S(tmp1) | ((as->mcp-l_loop-1) & 0xffffu);
if (!isk && irt_isaddr(kt)) {
type = ra_allock(as, (int64_t)irt_toitype(kt) << 47, allow);
emit_dst(as, MIPSI_DADDU, tmp2, key, type);
rset_clear(allow, type);
}
#endif
/* Load main position relative to tab->node into dest. */
khash = isk ? ir_khash(irkey) : 1;
if (khash == 0) {
emit_tsi(as, MIPSI_AL, dest, tab, (int32_t)offsetof(GCtab, node));
} else {
Reg tmphash = tmp1;
if (isk)
tmphash = ra_allock(as, khash, allow);
emit_dst(as, MIPSI_AADDU, dest, dest, tmp1);
lua_assert(sizeof(Node) == 24);
emit_dst(as, MIPSI_SUBU, tmp1, tmp2, tmp1);
emit_dta(as, MIPSI_SLL, tmp1, tmp1, 3);
emit_dta(as, MIPSI_SLL, tmp2, tmp1, 5);
emit_dst(as, MIPSI_AND, tmp1, tmp2, tmphash);
emit_tsi(as, MIPSI_AL, dest, tab, (int32_t)offsetof(GCtab, node));
emit_tsi(as, MIPSI_LW, tmp2, tab, (int32_t)offsetof(GCtab, hmask));
if (isk) {
/* Nothing to do. */
} else if (irt_isstr(kt)) {
emit_tsi(as, MIPSI_LW, tmp1, key, (int32_t)offsetof(GCstr, hash));
} else { /* Must match with hash*() in lj_tab.c. */
emit_dst(as, MIPSI_SUBU, tmp1, tmp1, tmp2);
emit_rotr(as, tmp2, tmp2, dest, (-HASH_ROT3)&31);
emit_dst(as, MIPSI_XOR, tmp1, tmp1, tmp2);
emit_rotr(as, tmp1, tmp1, dest, (-HASH_ROT2-HASH_ROT1)&31);
emit_dst(as, MIPSI_SUBU, tmp2, tmp2, dest);
#if LJ_32
if (LJ_SOFTFP ? (irkey[1].o == IR_HIOP) : irt_isnum(kt)) {
emit_dst(as, MIPSI_XOR, tmp2, tmp2, tmp1);
if ((as->flags & JIT_F_MIPSXXR2)) {
emit_dta(as, MIPSI_ROTR, dest, tmp1, (-HASH_ROT1)&31);
} else {
emit_dst(as, MIPSI_OR, dest, dest, tmp1);
emit_dta(as, MIPSI_SLL, tmp1, tmp1, HASH_ROT1);
emit_dta(as, MIPSI_SRL, dest, tmp1, (-HASH_ROT1)&31);
}
emit_dst(as, MIPSI_ADDU, tmp1, tmp1, tmp1);
#if LJ_SOFTFP
emit_ds(as, MIPSI_MOVE, tmp1, type);
emit_ds(as, MIPSI_MOVE, tmp2, key);
#else
emit_tg(as, MIPSI_MFC1, tmp2, key);
emit_tg(as, MIPSI_MFC1, tmp1, key+1);
#endif
} else {
emit_dst(as, MIPSI_XOR, tmp2, key, tmp1);
emit_rotr(as, dest, tmp1, tmp2, (-HASH_ROT1)&31);
emit_dst(as, MIPSI_ADDU, tmp1, key, ra_allock(as, HASH_BIAS, allow));
}
#else
emit_dst(as, MIPSI_XOR, tmp2, tmp2, tmp1);
emit_dta(as, MIPSI_ROTR, dest, tmp1, (-HASH_ROT1)&31);
if (irt_isnum(kt)) {
emit_dst(as, MIPSI_ADDU, tmp1, tmp1, tmp1);
emit_dta(as, MIPSI_DSRA32, tmp1, LJ_SOFTFP ? key : tmp1, 0);
emit_dta(as, MIPSI_SLL, tmp2, LJ_SOFTFP ? key : tmp1, 0);
#if !LJ_SOFTFP
emit_tg(as, MIPSI_DMFC1, tmp1, key);
#endif
} else {
checkmclim(as);
emit_dta(as, MIPSI_DSRA32, tmp1, tmp1, 0);
emit_dta(as, MIPSI_SLL, tmp2, key, 0);
emit_dst(as, MIPSI_DADDU, tmp1, key, type);
}
#endif
}
}
}
static void asm_hrefk(ASMState *as, IRIns *ir)
{
IRIns *kslot = IR(ir->op2);
IRIns *irkey = IR(kslot->op1);
int32_t ofs = (int32_t)(kslot->op2 * sizeof(Node));
int32_t kofs = ofs + (int32_t)offsetof(Node, key);
Reg dest = (ra_used(ir)||ofs > 32736) ? ra_dest(as, ir, RSET_GPR) : RID_NONE;
Reg node = ra_alloc1(as, ir->op1, RSET_GPR);
RegSet allow = rset_exclude(RSET_GPR, node);
Reg idx = node;
#if LJ_32
Reg key = RID_NONE, type = RID_TMP;
int32_t lo, hi;
#else
Reg key = ra_scratch(as, allow);
int64_t k;
#endif
lua_assert(ofs % sizeof(Node) == 0);
if (ofs > 32736) {
idx = dest;
rset_clear(allow, dest);
kofs = (int32_t)offsetof(Node, key);
} else if (ra_hasreg(dest)) {
emit_tsi(as, MIPSI_AADDIU, dest, node, ofs);
}
#if LJ_32
if (!irt_ispri(irkey->t)) {
key = ra_scratch(as, allow);
rset_clear(allow, key);
}
if (irt_isnum(irkey->t)) {
lo = (int32_t)ir_knum(irkey)->u32.lo;
hi = (int32_t)ir_knum(irkey)->u32.hi;
} else {
lo = irkey->i;
hi = irt_toitype(irkey->t);
if (!ra_hasreg(key))
goto nolo;
}
asm_guard(as, MIPSI_BNE, key, lo ? ra_allock(as, lo, allow) : RID_ZERO);
nolo:
asm_guard(as, MIPSI_BNE, type, hi ? ra_allock(as, hi, allow) : RID_ZERO);
if (ra_hasreg(key)) emit_tsi(as, MIPSI_LW, key, idx, kofs+(LJ_BE?4:0));
emit_tsi(as, MIPSI_LW, type, idx, kofs+(LJ_BE?0:4));
#else
if (irt_ispri(irkey->t)) {
lua_assert(!irt_isnil(irkey->t));
k = ~((int64_t)~irt_toitype(irkey->t) << 47);
} else if (irt_isnum(irkey->t)) {
k = (int64_t)ir_knum(irkey)->u64;
} else {
k = ((int64_t)irt_toitype(irkey->t) << 47) | (int64_t)ir_kgc(irkey);
}
asm_guard(as, MIPSI_BNE, key, ra_allock(as, k, allow));
emit_tsi(as, MIPSI_LD, key, idx, kofs);
#endif
if (ofs > 32736)
emit_tsi(as, MIPSI_AADDU, dest, node, ra_allock(as, ofs, allow));
}
static void asm_uref(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
if (irref_isk(ir->op1)) {
GCfunc *fn = ir_kfunc(IR(ir->op1));
MRef *v = &gcref(fn->l.uvptr[(ir->op2 >> 8)])->uv.v;
emit_lsptr(as, MIPSI_AL, dest, v, RSET_GPR);
} else {
Reg uv = ra_scratch(as, RSET_GPR);
Reg func = ra_alloc1(as, ir->op1, RSET_GPR);
if (ir->o == IR_UREFC) {
asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_tsi(as, MIPSI_AADDIU, dest, uv, (int32_t)offsetof(GCupval, tv));
emit_tsi(as, MIPSI_LBU, RID_TMP, uv, (int32_t)offsetof(GCupval, closed));
} else {
emit_tsi(as, MIPSI_AL, dest, uv, (int32_t)offsetof(GCupval, v));
}
emit_tsi(as, MIPSI_AL, uv, func, (int32_t)offsetof(GCfuncL, uvptr) +
(int32_t)sizeof(MRef) * (int32_t)(ir->op2 >> 8));
}
}
static void asm_fref(ASMState *as, IRIns *ir)
{
UNUSED(as); UNUSED(ir);
lua_assert(!ra_used(ir));
}
static void asm_strref(ASMState *as, IRIns *ir)
{
#if LJ_32
Reg dest = ra_dest(as, ir, RSET_GPR);
IRRef ref = ir->op2, refk = ir->op1;
int32_t ofs = (int32_t)sizeof(GCstr);
Reg r;
if (irref_isk(ref)) {
IRRef tmp = refk; refk = ref; ref = tmp;
} else if (!irref_isk(refk)) {
Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR);
IRIns *irr = IR(ir->op2);
if (ra_hasreg(irr->r)) {
ra_noweak(as, irr->r);
right = irr->r;
} else if (mayfuse(as, irr->op2) &&
irr->o == IR_ADD && irref_isk(irr->op2) &&
checki16(ofs + IR(irr->op2)->i)) {
ofs += IR(irr->op2)->i;
right = ra_alloc1(as, irr->op1, rset_exclude(RSET_GPR, left));
} else {
right = ra_allocref(as, ir->op2, rset_exclude(RSET_GPR, left));
}
emit_tsi(as, MIPSI_ADDIU, dest, dest, ofs);
emit_dst(as, MIPSI_ADDU, dest, left, right);
return;
}
r = ra_alloc1(as, ref, RSET_GPR);
ofs += IR(refk)->i;
if (checki16(ofs))
emit_tsi(as, MIPSI_ADDIU, dest, r, ofs);
else
emit_dst(as, MIPSI_ADDU, dest, r,
ra_allock(as, ofs, rset_exclude(RSET_GPR, r)));
#else
RegSet allow = RSET_GPR;
Reg dest = ra_dest(as, ir, allow);
Reg base = ra_alloc1(as, ir->op1, allow);
IRIns *irr = IR(ir->op2);
int32_t ofs = sizeof(GCstr);
rset_clear(allow, base);
if (irref_isk(ir->op2) && checki16(ofs + irr->i)) {
emit_tsi(as, MIPSI_DADDIU, dest, base, ofs + irr->i);
} else {
emit_tsi(as, MIPSI_DADDIU, dest, dest, ofs);
emit_dst(as, MIPSI_DADDU, dest, base, ra_alloc1(as, ir->op2, allow));
}
#endif
}
/* -- Loads and stores ---------------------------------------------------- */
static MIPSIns asm_fxloadins(IRIns *ir)
{
switch (irt_type(ir->t)) {
case IRT_I8: return MIPSI_LB;
case IRT_U8: return MIPSI_LBU;
case IRT_I16: return MIPSI_LH;
case IRT_U16: return MIPSI_LHU;
case IRT_NUM: lua_assert(!LJ_SOFTFP32); if (!LJ_SOFTFP) return MIPSI_LDC1;
case IRT_FLOAT: if (!LJ_SOFTFP) return MIPSI_LWC1;
default: return (LJ_64 && irt_is64(ir->t)) ? MIPSI_LD : MIPSI_LW;
}
}
static MIPSIns asm_fxstoreins(IRIns *ir)
{
switch (irt_type(ir->t)) {
case IRT_I8: case IRT_U8: return MIPSI_SB;
case IRT_I16: case IRT_U16: return MIPSI_SH;
case IRT_NUM: lua_assert(!LJ_SOFTFP32); if (!LJ_SOFTFP) return MIPSI_SDC1;
case IRT_FLOAT: if (!LJ_SOFTFP) return MIPSI_SWC1;
default: return (LJ_64 && irt_is64(ir->t)) ? MIPSI_SD : MIPSI_SW;
}
}
static void asm_fload(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
MIPSIns mi = asm_fxloadins(ir);
Reg idx;
int32_t ofs;
if (ir->op1 == REF_NIL) {
idx = RID_JGL;
ofs = (ir->op2 << 2) - 32768 - GG_OFS(g);
} else {
idx = ra_alloc1(as, ir->op1, RSET_GPR);
if (ir->op2 == IRFL_TAB_ARRAY) {
ofs = asm_fuseabase(as, ir->op1);
if (ofs) { /* Turn the t->array load into an add for colocated arrays. */
emit_tsi(as, MIPSI_AADDIU, dest, idx, ofs);
return;
}
}
ofs = field_ofs[ir->op2];
}
lua_assert(!irt_isfp(ir->t));
emit_tsi(as, mi, dest, idx, ofs);
}
static void asm_fstore(ASMState *as, IRIns *ir)
{
if (ir->r != RID_SINK) {
Reg src = ra_alloc1z(as, ir->op2, RSET_GPR);
IRIns *irf = IR(ir->op1);
Reg idx = ra_alloc1(as, irf->op1, rset_exclude(RSET_GPR, src));
int32_t ofs = field_ofs[irf->op2];
MIPSIns mi = asm_fxstoreins(ir);
lua_assert(!irt_isfp(ir->t));
emit_tsi(as, mi, src, idx, ofs);
}
}
static void asm_xload(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir,
(!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR);
lua_assert(!(ir->op2 & IRXLOAD_UNALIGNED));
asm_fusexref(as, asm_fxloadins(ir), dest, ir->op1, RSET_GPR, 0);
}
static void asm_xstore_(ASMState *as, IRIns *ir, int32_t ofs)
{
if (ir->r != RID_SINK) {
Reg src = ra_alloc1z(as, ir->op2,
(!LJ_SOFTFP && irt_isfp(ir->t)) ? RSET_FPR : RSET_GPR);
asm_fusexref(as, asm_fxstoreins(ir), src, ir->op1,
rset_exclude(RSET_GPR, src), ofs);
}
}
#define asm_xstore(as, ir) asm_xstore_(as, ir, 0)
static void asm_ahuvload(ASMState *as, IRIns *ir)
{
int hiop = (LJ_SOFTFP32 && (ir+1)->o == IR_HIOP);
Reg dest = RID_NONE, type = RID_TMP, idx;
RegSet allow = RSET_GPR;
int32_t ofs = 0;
IRType1 t = ir->t;
if (hiop) {
t.irt = IRT_NUM;
if (ra_used(ir+1)) {
type = ra_dest(as, ir+1, allow);
rset_clear(allow, type);
}
}
if (ra_used(ir)) {
lua_assert((LJ_SOFTFP32 ? 0 : irt_isnum(ir->t)) ||
irt_isint(ir->t) || irt_isaddr(ir->t));
dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow);
rset_clear(allow, dest);
#if LJ_64
if (irt_isaddr(t))
emit_tsml(as, MIPSI_DEXTM, dest, dest, 14, 0);
else if (irt_isint(t))
emit_dta(as, MIPSI_SLL, dest, dest, 0);
#endif
}
idx = asm_fuseahuref(as, ir->op1, &ofs, allow);
rset_clear(allow, idx);
if (irt_isnum(t)) {
asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_tsi(as, MIPSI_SLTIU, RID_TMP, type, (int32_t)LJ_TISNUM);
} else {
asm_guard(as, MIPSI_BNE, type,
ra_allock(as, (int32_t)irt_toitype(t), allow));
}
#if LJ_32
if (ra_hasreg(dest)) {
if (!LJ_SOFTFP && irt_isnum(t))
emit_hsi(as, MIPSI_LDC1, dest, idx, ofs);
else
emit_tsi(as, MIPSI_LW, dest, idx, ofs+(LJ_BE?4:0));
}
emit_tsi(as, MIPSI_LW, type, idx, ofs+(LJ_BE?0:4));
#else
if (ra_hasreg(dest)) {
if (!LJ_SOFTFP && irt_isnum(t)) {
emit_hsi(as, MIPSI_LDC1, dest, idx, ofs);
dest = type;
}
} else {
dest = type;
}
emit_dta(as, MIPSI_DSRA32, type, dest, 15);
emit_tsi(as, MIPSI_LD, dest, idx, ofs);
#endif
}
static void asm_ahustore(ASMState *as, IRIns *ir)
{
RegSet allow = RSET_GPR;
Reg idx, src = RID_NONE, type = RID_NONE;
int32_t ofs = 0;
if (ir->r == RID_SINK)
return;
if (!LJ_SOFTFP32 && irt_isnum(ir->t)) {
src = ra_alloc1(as, ir->op2, LJ_SOFTFP ? RSET_GPR : RSET_FPR);
idx = asm_fuseahuref(as, ir->op1, &ofs, allow);
emit_hsi(as, LJ_SOFTFP ? MIPSI_SD : MIPSI_SDC1, src, idx, ofs);
} else {
#if LJ_32
if (!irt_ispri(ir->t)) {
src = ra_alloc1(as, ir->op2, allow);
rset_clear(allow, src);
}
if (LJ_SOFTFP && (ir+1)->o == IR_HIOP)
type = ra_alloc1(as, (ir+1)->op2, allow);
else
type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow);
rset_clear(allow, type);
idx = asm_fuseahuref(as, ir->op1, &ofs, allow);
if (ra_hasreg(src))
emit_tsi(as, MIPSI_SW, src, idx, ofs+(LJ_BE?4:0));
emit_tsi(as, MIPSI_SW, type, idx, ofs+(LJ_BE?0:4));
#else
Reg tmp = RID_TMP;
if (irt_ispri(ir->t)) {
tmp = ra_allock(as, ~((int64_t)~irt_toitype(ir->t) << 47), allow);
rset_clear(allow, tmp);
} else {
src = ra_alloc1(as, ir->op2, allow);
rset_clear(allow, src);
type = ra_allock(as, (int64_t)irt_toitype(ir->t) << 47, allow);
rset_clear(allow, type);
}
idx = asm_fuseahuref(as, ir->op1, &ofs, allow);
emit_tsi(as, MIPSI_SD, tmp, idx, ofs);
if (ra_hasreg(src)) {
if (irt_isinteger(ir->t)) {
emit_dst(as, MIPSI_DADDU, tmp, tmp, type);
emit_tsml(as, MIPSI_DEXT, tmp, src, 31, 0);
} else {
emit_dst(as, MIPSI_DADDU, tmp, src, type);
}
}
#endif
}
}
static void asm_sload(ASMState *as, IRIns *ir)
{
Reg dest = RID_NONE, type = RID_NONE, base;
RegSet allow = RSET_GPR;
IRType1 t = ir->t;
#if LJ_32
int32_t ofs = 8*((int32_t)ir->op1-1) + ((ir->op2 & IRSLOAD_FRAME) ? 4 : 0);
int hiop = (LJ_SOFTFP32 && (ir+1)->o == IR_HIOP);
if (hiop)
t.irt = IRT_NUM;
#else
int32_t ofs = 8*((int32_t)ir->op1-2);
#endif
lua_assert(!(ir->op2 & IRSLOAD_PARENT)); /* Handled by asm_head_side(). */
lua_assert(irt_isguard(ir->t) || !(ir->op2 & IRSLOAD_TYPECHECK));
#if LJ_SOFTFP32
lua_assert(!(ir->op2 & IRSLOAD_CONVERT)); /* Handled by LJ_SOFTFP SPLIT. */
if (hiop && ra_used(ir+1)) {
type = ra_dest(as, ir+1, allow);
rset_clear(allow, type);
}
#else
if ((ir->op2 & IRSLOAD_CONVERT) && irt_isguard(t) && irt_isint(t)) {
dest = ra_scratch(as, LJ_SOFTFP ? allow : RSET_FPR);
asm_tointg(as, ir, dest);
t.irt = IRT_NUM; /* Continue with a regular number type check. */
} else
#endif
if (ra_used(ir)) {
lua_assert((LJ_SOFTFP32 ? 0 : irt_isnum(ir->t)) ||
irt_isint(ir->t) || irt_isaddr(ir->t));
dest = ra_dest(as, ir, (!LJ_SOFTFP && irt_isnum(t)) ? RSET_FPR : allow);
rset_clear(allow, dest);
base = ra_alloc1(as, REF_BASE, allow);
rset_clear(allow, base);
if (!LJ_SOFTFP32 && (ir->op2 & IRSLOAD_CONVERT)) {
if (irt_isint(t)) {
Reg tmp = ra_scratch(as, LJ_SOFTFP ? RSET_GPR : RSET_FPR);
#if LJ_SOFTFP
ra_evictset(as, rset_exclude(RSET_SCRATCH, dest));
ra_destreg(as, ir, RID_RET);
emit_call(as, (void *)lj_ir_callinfo[IRCALL_softfp_d2i].func, 0);
if (tmp != REGARG_FIRSTGPR)
emit_move(as, REGARG_FIRSTGPR, tmp);
#else
emit_tg(as, MIPSI_MFC1, dest, tmp);
emit_fg(as, MIPSI_TRUNC_W_D, tmp, tmp);
#endif
dest = tmp;
t.irt = IRT_NUM; /* Check for original type. */
} else {
Reg tmp = ra_scratch(as, RSET_GPR);
#if LJ_SOFTFP
ra_evictset(as, rset_exclude(RSET_SCRATCH, dest));
ra_destreg(as, ir, RID_RET);
emit_call(as, (void *)lj_ir_callinfo[IRCALL_softfp_i2d].func, 0);
emit_dta(as, MIPSI_SLL, REGARG_FIRSTGPR, tmp, 0);
#else
emit_fg(as, MIPSI_CVT_D_W, dest, dest);
emit_tg(as, MIPSI_MTC1, tmp, dest);
#endif
dest = tmp;
t.irt = IRT_INT; /* Check for original type. */
}
}
#if LJ_64
else if (irt_isaddr(t)) {
/* Clear type from pointers. */
emit_tsml(as, MIPSI_DEXTM, dest, dest, 14, 0);
} else if (irt_isint(t) && (ir->op2 & IRSLOAD_TYPECHECK)) {
/* Sign-extend integers. */
emit_dta(as, MIPSI_SLL, dest, dest, 0);
}
#endif
goto dotypecheck;
}
base = ra_alloc1(as, REF_BASE, allow);
rset_clear(allow, base);
dotypecheck:
#if LJ_32
if ((ir->op2 & IRSLOAD_TYPECHECK)) {
if (ra_noreg(type))
type = RID_TMP;
if (irt_isnum(t)) {
asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_tsi(as, MIPSI_SLTIU, RID_TMP, type, (int32_t)LJ_TISNUM);
} else {
Reg ktype = ra_allock(as, irt_toitype(t), allow);
asm_guard(as, MIPSI_BNE, type, ktype);
}
}
if (ra_hasreg(dest)) {
if (!LJ_SOFTFP && irt_isnum(t))
emit_hsi(as, MIPSI_LDC1, dest, base, ofs);
else
emit_tsi(as, MIPSI_LW, dest, base, ofs ^ (LJ_BE?4:0));
}
if (ra_hasreg(type))
emit_tsi(as, MIPSI_LW, type, base, ofs ^ (LJ_BE?0:4));
#else
if ((ir->op2 & IRSLOAD_TYPECHECK)) {
type = dest < RID_MAX_GPR ? dest : RID_TMP;
if (irt_ispri(t)) {
asm_guard(as, MIPSI_BNE, type,
ra_allock(as, ~((int64_t)~irt_toitype(t) << 47) , allow));
} else {
if (irt_isnum(t)) {
asm_guard(as, MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_tsi(as, MIPSI_SLTIU, RID_TMP, RID_TMP, (int32_t)LJ_TISNUM);
if (!LJ_SOFTFP && ra_hasreg(dest))
emit_hsi(as, MIPSI_LDC1, dest, base, ofs);
} else {
asm_guard(as, MIPSI_BNE, RID_TMP,
ra_allock(as, (int32_t)irt_toitype(t), allow));
}
emit_dta(as, MIPSI_DSRA32, RID_TMP, type, 15);
}
emit_tsi(as, MIPSI_LD, type, base, ofs);
} else if (ra_hasreg(dest)) {
if (!LJ_SOFTFP && irt_isnum(t))
emit_hsi(as, MIPSI_LDC1, dest, base, ofs);
else
emit_tsi(as, irt_isint(t) ? MIPSI_LW : MIPSI_LD, dest, base,
ofs ^ ((LJ_BE && irt_isint(t)) ? 4 : 0));
}
#endif
}
/* -- Allocations --------------------------------------------------------- */
#if LJ_HASFFI
static void asm_cnew(ASMState *as, IRIns *ir)
{
CTState *cts = ctype_ctsG(J2G(as->J));
CTypeID id = (CTypeID)IR(ir->op1)->i;
CTSize sz;
CTInfo info = lj_ctype_info(cts, id, &sz);
const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_mem_newgco];
IRRef args[4];
RegSet drop = RSET_SCRATCH;
lua_assert(sz != CTSIZE_INVALID || (ir->o == IR_CNEW && ir->op2 != REF_NIL));
as->gcsteps++;
if (ra_hasreg(ir->r))
rset_clear(drop, ir->r); /* Dest reg handled below. */
ra_evictset(as, drop);
if (ra_used(ir))
ra_destreg(as, ir, RID_RET); /* GCcdata * */
/* Initialize immutable cdata object. */
if (ir->o == IR_CNEWI) {
RegSet allow = (RSET_GPR & ~RSET_SCRATCH);
#if LJ_32
int32_t ofs = sizeof(GCcdata);
if (sz == 8) {
ofs += 4;
lua_assert((ir+1)->o == IR_HIOP);
if (LJ_LE) ir++;
}
for (;;) {
Reg r = ra_alloc1z(as, ir->op2, allow);
emit_tsi(as, MIPSI_SW, r, RID_RET, ofs);
rset_clear(allow, r);
if (ofs == sizeof(GCcdata)) break;
ofs -= 4; if (LJ_BE) ir++; else ir--;
}
#else
emit_tsi(as, MIPSI_SD, ra_alloc1(as, ir->op2, allow),
RID_RET, sizeof(GCcdata));
#endif
lua_assert(sz == 4 || sz == 8);
} else if (ir->op2 != REF_NIL) { /* Create VLA/VLS/aligned cdata. */
ci = &lj_ir_callinfo[IRCALL_lj_cdata_newv];
args[0] = ASMREF_L; /* lua_State *L */
args[1] = ir->op1; /* CTypeID id */
args[2] = ir->op2; /* CTSize sz */
args[3] = ASMREF_TMP1; /* CTSize align */
asm_gencall(as, ci, args);
emit_loadi(as, ra_releasetmp(as, ASMREF_TMP1), (int32_t)ctype_align(info));
return;
}
/* Initialize gct and ctypeid. lj_mem_newgco() already sets marked. */
emit_tsi(as, MIPSI_SB, RID_RET+1, RID_RET, offsetof(GCcdata, gct));
emit_tsi(as, MIPSI_SH, RID_TMP, RID_RET, offsetof(GCcdata, ctypeid));
emit_ti(as, MIPSI_LI, RID_RET+1, ~LJ_TCDATA);
emit_ti(as, MIPSI_LI, RID_TMP, id); /* Lower 16 bit used. Sign-ext ok. */
args[0] = ASMREF_L; /* lua_State *L */
args[1] = ASMREF_TMP1; /* MSize size */
asm_gencall(as, ci, args);
ra_allockreg(as, (int32_t)(sz+sizeof(GCcdata)),
ra_releasetmp(as, ASMREF_TMP1));
}
#else
#define asm_cnew(as, ir) ((void)0)
#endif
/* -- Write barriers ------------------------------------------------------ */
static void asm_tbar(ASMState *as, IRIns *ir)
{
Reg tab = ra_alloc1(as, ir->op1, RSET_GPR);
Reg mark = ra_scratch(as, rset_exclude(RSET_GPR, tab));
Reg link = RID_TMP;
MCLabel l_end = emit_label(as);
emit_tsi(as, MIPSI_AS, link, tab, (int32_t)offsetof(GCtab, gclist));
emit_tsi(as, MIPSI_SB, mark, tab, (int32_t)offsetof(GCtab, marked));
emit_setgl(as, tab, gc.grayagain);
emit_getgl(as, link, gc.grayagain);
emit_dst(as, MIPSI_XOR, mark, mark, RID_TMP); /* Clear black bit. */
emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end);
emit_tsi(as, MIPSI_ANDI, RID_TMP, mark, LJ_GC_BLACK);
emit_tsi(as, MIPSI_LBU, mark, tab, (int32_t)offsetof(GCtab, marked));
}
static void asm_obar(ASMState *as, IRIns *ir)
{
const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_barrieruv];
IRRef args[2];
MCLabel l_end;
Reg obj, val, tmp;
/* No need for other object barriers (yet). */
lua_assert(IR(ir->op1)->o == IR_UREFC);
ra_evictset(as, RSET_SCRATCH);
l_end = emit_label(as);
args[0] = ASMREF_TMP1; /* global_State *g */
args[1] = ir->op1; /* TValue *tv */
asm_gencall(as, ci, args);
emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768);
obj = IR(ir->op1)->r;
tmp = ra_scratch(as, rset_exclude(RSET_GPR, obj));
emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end);
emit_tsi(as, MIPSI_ANDI, tmp, tmp, LJ_GC_BLACK);
emit_branch(as, MIPSI_BEQ, RID_TMP, RID_ZERO, l_end);
emit_tsi(as, MIPSI_ANDI, RID_TMP, RID_TMP, LJ_GC_WHITES);
val = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, obj));
emit_tsi(as, MIPSI_LBU, tmp, obj,
(int32_t)offsetof(GCupval, marked)-(int32_t)offsetof(GCupval, tv));
emit_tsi(as, MIPSI_LBU, RID_TMP, val, (int32_t)offsetof(GChead, marked));
}
/* -- Arithmetic and logic operations ------------------------------------- */
#if !LJ_SOFTFP
static void asm_fparith(ASMState *as, IRIns *ir, MIPSIns mi)
{
Reg dest = ra_dest(as, ir, RSET_FPR);
Reg right, left = ra_alloc2(as, ir, RSET_FPR);
right = (left >> 8); left &= 255;
emit_fgh(as, mi, dest, left, right);
}
static void asm_fpunary(ASMState *as, IRIns *ir, MIPSIns mi)
{
Reg dest = ra_dest(as, ir, RSET_FPR);
Reg left = ra_hintalloc(as, ir->op1, dest, RSET_FPR);
emit_fg(as, mi, dest, left);
}
#endif
#if !LJ_SOFTFP32
static void asm_fpmath(ASMState *as, IRIns *ir)
{
if (ir->op2 == IRFPM_EXP2 && asm_fpjoin_pow(as, ir))
return;
#if !LJ_SOFTFP
if (ir->op2 <= IRFPM_TRUNC)
asm_callround(as, ir, IRCALL_lj_vm_floor + ir->op2);
else if (ir->op2 == IRFPM_SQRT)
asm_fpunary(as, ir, MIPSI_SQRT_D);
else
#endif
asm_callid(as, ir, IRCALL_lj_vm_floor + ir->op2);
}
#endif
#if !LJ_SOFTFP
#define asm_fpadd(as, ir) asm_fparith(as, ir, MIPSI_ADD_D)
#define asm_fpsub(as, ir) asm_fparith(as, ir, MIPSI_SUB_D)
#define asm_fpmul(as, ir) asm_fparith(as, ir, MIPSI_MUL_D)
#elif LJ_64 /* && LJ_SOFTFP */
#define asm_fpadd(as, ir) asm_callid(as, ir, IRCALL_softfp_add)
#define asm_fpsub(as, ir) asm_callid(as, ir, IRCALL_softfp_sub)
#define asm_fpmul(as, ir) asm_callid(as, ir, IRCALL_softfp_mul)
#endif
static void asm_add(ASMState *as, IRIns *ir)
{
IRType1 t = ir->t;
#if !LJ_SOFTFP32
if (irt_isnum(t)) {
asm_fpadd(as, ir);
} else
#endif
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
if (irref_isk(ir->op2)) {
intptr_t k = get_kval(IR(ir->op2));
if (checki16(k)) {
emit_tsi(as, (LJ_64 && irt_is64(t)) ? MIPSI_DADDIU : MIPSI_ADDIU, dest,
left, k);
return;
}
}
right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left));
emit_dst(as, (LJ_64 && irt_is64(t)) ? MIPSI_DADDU : MIPSI_ADDU, dest,
left, right);
}
}
static void asm_sub(ASMState *as, IRIns *ir)
{
#if !LJ_SOFTFP32
if (irt_isnum(ir->t)) {
asm_fpsub(as, ir);
} else
#endif
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
emit_dst(as, (LJ_64 && irt_is64(ir->t)) ? MIPSI_DSUBU : MIPSI_SUBU, dest,
left, right);
}
}
static void asm_mul(ASMState *as, IRIns *ir)
{
#if !LJ_SOFTFP32
if (irt_isnum(ir->t)) {
asm_fpmul(as, ir);
} else
#endif
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
if (LJ_64 && irt_is64(ir->t)) {
emit_dst(as, MIPSI_MFLO, dest, 0, 0);
emit_dst(as, MIPSI_DMULT, 0, left, right);
} else {
emit_dst(as, MIPSI_MUL, dest, left, right);
}
}
}
static void asm_mod(ASMState *as, IRIns *ir)
{
#if LJ_64 && LJ_HASFFI
if (!irt_isint(ir->t))
asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_modi64 :
IRCALL_lj_carith_modu64);
else
#endif
asm_callid(as, ir, IRCALL_lj_vm_modi);
}
#if !LJ_SOFTFP32
static void asm_pow(ASMState *as, IRIns *ir)
{
#if LJ_64 && LJ_HASFFI
if (!irt_isnum(ir->t))
asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_powi64 :
IRCALL_lj_carith_powu64);
else
#endif
asm_callid(as, ir, IRCALL_lj_vm_powi);
}
static void asm_div(ASMState *as, IRIns *ir)
{
#if LJ_64 && LJ_HASFFI
if (!irt_isnum(ir->t))
asm_callid(as, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_divi64 :
IRCALL_lj_carith_divu64);
else
#endif
#if !LJ_SOFTFP
asm_fparith(as, ir, MIPSI_DIV_D);
#else
asm_callid(as, ir, IRCALL_softfp_div);
#endif
}
#endif
static void asm_neg(ASMState *as, IRIns *ir)
{
#if !LJ_SOFTFP
if (irt_isnum(ir->t)) {
asm_fpunary(as, ir, MIPSI_NEG_D);
} else
#elif LJ_64 /* && LJ_SOFTFP */
if (irt_isnum(ir->t)) {
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
emit_dst(as, MIPSI_XOR, dest, left,
ra_allock(as, 0x8000000000000000ll, rset_exclude(RSET_GPR, dest)));
} else
#endif
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
emit_dst(as, (LJ_64 && irt_is64(ir->t)) ? MIPSI_DSUBU : MIPSI_SUBU, dest,
RID_ZERO, left);
}
}
#if !LJ_SOFTFP
#define asm_abs(as, ir) asm_fpunary(as, ir, MIPSI_ABS_D)
#elif LJ_64 /* && LJ_SOFTFP */
static void asm_abs(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_alloc1(as, ir->op1, RSET_GPR);
emit_tsml(as, MIPSI_DEXTM, dest, left, 30, 0);
}
#endif
#define asm_atan2(as, ir) asm_callid(as, ir, IRCALL_atan2)
#define asm_ldexp(as, ir) asm_callid(as, ir, IRCALL_ldexp)
static void asm_arithov(ASMState *as, IRIns *ir)
{
Reg right, left, tmp, dest = ra_dest(as, ir, RSET_GPR);
lua_assert(!irt_is64(ir->t));
if (irref_isk(ir->op2)) {
int k = IR(ir->op2)->i;
if (ir->o == IR_SUBOV) k = -k;
if (checki16(k)) { /* (dest < left) == (k >= 0 ? 1 : 0) */
left = ra_alloc1(as, ir->op1, RSET_GPR);
asm_guard(as, k >= 0 ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_dst(as, MIPSI_SLT, RID_TMP, dest, dest == left ? RID_TMP : left);
emit_tsi(as, MIPSI_ADDIU, dest, left, k);
if (dest == left) emit_move(as, RID_TMP, left);
return;
}
}
left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
tmp = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_GPR, left),
right), dest));
asm_guard(as, MIPSI_BLTZ, RID_TMP, 0);
emit_dst(as, MIPSI_AND, RID_TMP, RID_TMP, tmp);
if (ir->o == IR_ADDOV) { /* ((dest^left) & (dest^right)) < 0 */
emit_dst(as, MIPSI_XOR, RID_TMP, dest, dest == right ? RID_TMP : right);
} else { /* ((dest^left) & (dest^~right)) < 0 */
emit_dst(as, MIPSI_XOR, RID_TMP, RID_TMP, dest);
emit_dst(as, MIPSI_NOR, RID_TMP, dest == right ? RID_TMP : right, RID_ZERO);
}
emit_dst(as, MIPSI_XOR, tmp, dest, dest == left ? RID_TMP : left);
emit_dst(as, ir->o == IR_ADDOV ? MIPSI_ADDU : MIPSI_SUBU, dest, left, right);
if (dest == left || dest == right)
emit_move(as, RID_TMP, dest == left ? left : right);
}
#define asm_addov(as, ir) asm_arithov(as, ir)
#define asm_subov(as, ir) asm_arithov(as, ir)
static void asm_mulov(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg tmp, right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
tmp = ra_scratch(as, rset_exclude(rset_exclude(rset_exclude(RSET_GPR, left),
right), dest));
asm_guard(as, MIPSI_BNE, RID_TMP, tmp);
emit_dta(as, MIPSI_SRA, RID_TMP, dest, 31);
emit_dst(as, MIPSI_MFHI, tmp, 0, 0);
emit_dst(as, MIPSI_MFLO, dest, 0, 0);
emit_dst(as, MIPSI_MULT, 0, left, right);
}
#if LJ_32 && LJ_HASFFI
static void asm_add64(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR);
if (irref_isk(ir->op2)) {
int32_t k = IR(ir->op2)->i;
if (k == 0) {
emit_dst(as, MIPSI_ADDU, dest, left, RID_TMP);
goto loarith;
} else if (checki16(k)) {
emit_dst(as, MIPSI_ADDU, dest, dest, RID_TMP);
emit_tsi(as, MIPSI_ADDIU, dest, left, k);
goto loarith;
}
}
emit_dst(as, MIPSI_ADDU, dest, dest, RID_TMP);
right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left));
emit_dst(as, MIPSI_ADDU, dest, left, right);
loarith:
ir--;
dest = ra_dest(as, ir, RSET_GPR);
left = ra_alloc1(as, ir->op1, RSET_GPR);
if (irref_isk(ir->op2)) {
int32_t k = IR(ir->op2)->i;
if (k == 0) {
if (dest != left)
emit_move(as, dest, left);
return;
} else if (checki16(k)) {
if (dest == left) {
Reg tmp = ra_scratch(as, rset_exclude(RSET_GPR, left));
emit_move(as, dest, tmp);
dest = tmp;
}
emit_dst(as, MIPSI_SLTU, RID_TMP, dest, left);
emit_tsi(as, MIPSI_ADDIU, dest, left, k);
return;
}
}
right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left));
if (dest == left && dest == right) {
Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right));
emit_move(as, dest, tmp);
dest = tmp;
}
emit_dst(as, MIPSI_SLTU, RID_TMP, dest, dest == left ? right : left);
emit_dst(as, MIPSI_ADDU, dest, left, right);
}
static void asm_sub64(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
emit_dst(as, MIPSI_SUBU, dest, dest, RID_TMP);
emit_dst(as, MIPSI_SUBU, dest, left, right);
ir--;
dest = ra_dest(as, ir, RSET_GPR);
left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
if (dest == left) {
Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right));
emit_move(as, dest, tmp);
dest = tmp;
}
emit_dst(as, MIPSI_SLTU, RID_TMP, left, dest);
emit_dst(as, MIPSI_SUBU, dest, left, right);
}
static void asm_neg64(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_alloc1(as, ir->op1, RSET_GPR);
emit_dst(as, MIPSI_SUBU, dest, dest, RID_TMP);
emit_dst(as, MIPSI_SUBU, dest, RID_ZERO, left);
ir--;
dest = ra_dest(as, ir, RSET_GPR);
left = ra_alloc1(as, ir->op1, RSET_GPR);
emit_dst(as, MIPSI_SLTU, RID_TMP, RID_ZERO, dest);
emit_dst(as, MIPSI_SUBU, dest, RID_ZERO, left);
}
#endif
static void asm_bnot(ASMState *as, IRIns *ir)
{
Reg left, right, dest = ra_dest(as, ir, RSET_GPR);
IRIns *irl = IR(ir->op1);
if (mayfuse(as, ir->op1) && irl->o == IR_BOR) {
left = ra_alloc2(as, irl, RSET_GPR);
right = (left >> 8); left &= 255;
} else {
left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
right = RID_ZERO;
}
emit_dst(as, MIPSI_NOR, dest, left, right);
}
static void asm_bswap(ASMState *as, IRIns *ir)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg left = ra_alloc1(as, ir->op1, RSET_GPR);
#if LJ_32
if ((as->flags & JIT_F_MIPSXXR2)) {
emit_dta(as, MIPSI_ROTR, dest, RID_TMP, 16);
emit_dst(as, MIPSI_WSBH, RID_TMP, 0, left);
} else {
Reg tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), dest));
emit_dst(as, MIPSI_OR, dest, dest, tmp);
emit_dst(as, MIPSI_OR, dest, dest, RID_TMP);
emit_tsi(as, MIPSI_ANDI, dest, dest, 0xff00);
emit_dta(as, MIPSI_SLL, RID_TMP, RID_TMP, 8);
emit_dta(as, MIPSI_SRL, dest, left, 8);
emit_tsi(as, MIPSI_ANDI, RID_TMP, left, 0xff00);
emit_dst(as, MIPSI_OR, tmp, tmp, RID_TMP);
emit_dta(as, MIPSI_SRL, tmp, left, 24);
emit_dta(as, MIPSI_SLL, RID_TMP, left, 24);
}
#else
if (irt_is64(ir->t)) {
emit_dst(as, MIPSI_DSHD, dest, 0, RID_TMP);
emit_dst(as, MIPSI_DSBH, RID_TMP, 0, left);
} else {
emit_dta(as, MIPSI_ROTR, dest, RID_TMP, 16);
emit_dst(as, MIPSI_WSBH, RID_TMP, 0, left);
}
#endif
}
static void asm_bitop(ASMState *as, IRIns *ir, MIPSIns mi, MIPSIns mik)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
if (irref_isk(ir->op2)) {
intptr_t k = get_kval(IR(ir->op2));
if (checku16(k)) {
emit_tsi(as, mik, dest, left, k);
return;
}
}
right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left));
emit_dst(as, mi, dest, left, right);
}
#define asm_band(as, ir) asm_bitop(as, ir, MIPSI_AND, MIPSI_ANDI)
#define asm_bor(as, ir) asm_bitop(as, ir, MIPSI_OR, MIPSI_ORI)
#define asm_bxor(as, ir) asm_bitop(as, ir, MIPSI_XOR, MIPSI_XORI)
static void asm_bitshift(ASMState *as, IRIns *ir, MIPSIns mi, MIPSIns mik)
{
Reg dest = ra_dest(as, ir, RSET_GPR);
if (irref_isk(ir->op2)) { /* Constant shifts. */
uint32_t shift = (uint32_t)IR(ir->op2)->i;
if (LJ_64 && irt_is64(ir->t)) mik |= (shift & 32) ? MIPSI_D32 : MIPSI_D;
emit_dta(as, mik, dest, ra_hintalloc(as, ir->op1, dest, RSET_GPR),
(shift & 31));
} else {
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
if (LJ_64 && irt_is64(ir->t)) mi |= MIPSI_DV;
emit_dst(as, mi, dest, right, left); /* Shift amount is in rs. */
}
}
#define asm_bshl(as, ir) asm_bitshift(as, ir, MIPSI_SLLV, MIPSI_SLL)
#define asm_bshr(as, ir) asm_bitshift(as, ir, MIPSI_SRLV, MIPSI_SRL)
#define asm_bsar(as, ir) asm_bitshift(as, ir, MIPSI_SRAV, MIPSI_SRA)
#define asm_brol(as, ir) lua_assert(0)
static void asm_bror(ASMState *as, IRIns *ir)
{
if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) {
asm_bitshift(as, ir, MIPSI_ROTRV, MIPSI_ROTR);
} else {
Reg dest = ra_dest(as, ir, RSET_GPR);
if (irref_isk(ir->op2)) { /* Constant shifts. */
uint32_t shift = (uint32_t)(IR(ir->op2)->i & 31);
Reg left = ra_hintalloc(as, ir->op1, dest, RSET_GPR);
emit_rotr(as, dest, left, RID_TMP, shift);
} else {
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
emit_dst(as, MIPSI_OR, dest, dest, RID_TMP);
emit_dst(as, MIPSI_SRLV, dest, right, left);
emit_dst(as, MIPSI_SLLV, RID_TMP, RID_TMP, left);
emit_dst(as, MIPSI_SUBU, RID_TMP, ra_allock(as, 32, RSET_GPR), right);
}
}
}
#if LJ_SOFTFP
static void asm_sfpmin_max(ASMState *as, IRIns *ir)
{
CCallInfo ci = lj_ir_callinfo[(IROp)ir->o == IR_MIN ? IRCALL_lj_vm_sfmin : IRCALL_lj_vm_sfmax];
#if LJ_64
IRRef args[2];
args[0] = ir->op1;
args[1] = ir->op2;
#else
IRRef args[4];
args[0^LJ_BE] = ir->op1;
args[1^LJ_BE] = (ir+1)->op1;
args[2^LJ_BE] = ir->op2;
args[3^LJ_BE] = (ir+1)->op2;
#endif
asm_setupresult(as, ir, &ci);
emit_call(as, (void *)ci.func, 0);
ci.func = NULL;
asm_gencall(as, &ci, args);
}
#endif
static void asm_min_max(ASMState *as, IRIns *ir, int ismax)
{
if (!LJ_SOFTFP32 && irt_isnum(ir->t)) {
#if LJ_SOFTFP
asm_sfpmin_max(as, ir);
#else
Reg dest = ra_dest(as, ir, RSET_FPR);
Reg right, left = ra_alloc2(as, ir, RSET_FPR);
right = (left >> 8); left &= 255;
if (dest == left) {
emit_fg(as, MIPSI_MOVT_D, dest, right);
} else {
emit_fg(as, MIPSI_MOVF_D, dest, left);
if (dest != right) emit_fg(as, MIPSI_MOV_D, dest, right);
}
emit_fgh(as, MIPSI_C_OLT_D, 0, ismax ? left : right, ismax ? right : left);
#endif
} else {
Reg dest = ra_dest(as, ir, RSET_GPR);
Reg right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
if (dest == left) {
emit_dst(as, MIPSI_MOVN, dest, right, RID_TMP);
} else {
emit_dst(as, MIPSI_MOVZ, dest, left, RID_TMP);
if (dest != right) emit_move(as, dest, right);
}
emit_dst(as, MIPSI_SLT, RID_TMP,
ismax ? left : right, ismax ? right : left);
}
}
#define asm_min(as, ir) asm_min_max(as, ir, 0)
#define asm_max(as, ir) asm_min_max(as, ir, 1)
/* -- Comparisons --------------------------------------------------------- */
#if LJ_SOFTFP
/* SFP comparisons. */
static void asm_sfpcomp(ASMState *as, IRIns *ir)
{
const CCallInfo *ci = &lj_ir_callinfo[IRCALL_softfp_cmp];
RegSet drop = RSET_SCRATCH;
Reg r;
#if LJ_64
IRRef args[2];
args[0] = ir->op1;
args[1] = ir->op2;
#else
IRRef args[4];
args[LJ_LE ? 0 : 1] = ir->op1; args[LJ_LE ? 1 : 0] = (ir+1)->op1;
args[LJ_LE ? 2 : 3] = ir->op2; args[LJ_LE ? 3 : 2] = (ir+1)->op2;
#endif
for (r = REGARG_FIRSTGPR; r <= REGARG_FIRSTGPR+(LJ_64?1:3); r++) {
if (!rset_test(as->freeset, r) &&
regcost_ref(as->cost[r]) == args[r-REGARG_FIRSTGPR])
rset_clear(drop, r);
}
ra_evictset(as, drop);
asm_setupresult(as, ir, ci);
switch ((IROp)ir->o) {
case IR_LT:
asm_guard(as, MIPSI_BGEZ, RID_RET, 0);
break;
case IR_ULT:
asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP);
emit_loadi(as, RID_TMP, 1);
asm_guard(as, MIPSI_BEQ, RID_RET, RID_ZERO);
break;
case IR_GE:
asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP);
emit_loadi(as, RID_TMP, 2);
asm_guard(as, MIPSI_BLTZ, RID_RET, 0);
break;
case IR_LE:
asm_guard(as, MIPSI_BGTZ, RID_RET, 0);
break;
case IR_GT:
asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP);
emit_loadi(as, RID_TMP, 2);
asm_guard(as, MIPSI_BLEZ, RID_RET, 0);
break;
case IR_UGE:
asm_guard(as, MIPSI_BLTZ, RID_RET, 0);
break;
case IR_ULE:
asm_guard(as, MIPSI_BEQ, RID_RET, RID_TMP);
emit_loadi(as, RID_TMP, 1);
break;
case IR_UGT: case IR_ABC:
asm_guard(as, MIPSI_BLEZ, RID_RET, 0);
break;
case IR_EQ: case IR_NE:
asm_guard(as, (ir->o & 1) ? MIPSI_BEQ : MIPSI_BNE, RID_RET, RID_ZERO);
default:
break;
}
asm_gencall(as, ci, args);
}
#endif
static void asm_comp(ASMState *as, IRIns *ir)
{
/* ORDER IR: LT GE LE GT ULT UGE ULE UGT. */
IROp op = ir->o;
if (!LJ_SOFTFP32 && irt_isnum(ir->t)) {
#if LJ_SOFTFP
asm_sfpcomp(as, ir);
#else
Reg right, left = ra_alloc2(as, ir, RSET_FPR);
right = (left >> 8); left &= 255;
asm_guard(as, (op&1) ? MIPSI_BC1T : MIPSI_BC1F, 0, 0);
emit_fgh(as, MIPSI_C_OLT_D + ((op&3) ^ ((op>>2)&1)), 0, left, right);
#endif
} else {
Reg right, left = ra_alloc1(as, ir->op1, RSET_GPR);
if (op == IR_ABC) op = IR_UGT;
if ((op&4) == 0 && irref_isk(ir->op2) && get_kval(IR(ir->op2)) == 0) {
MIPSIns mi = (op&2) ? ((op&1) ? MIPSI_BLEZ : MIPSI_BGTZ) :
((op&1) ? MIPSI_BLTZ : MIPSI_BGEZ);
asm_guard(as, mi, left, 0);
} else {
if (irref_isk(ir->op2)) {
intptr_t k = get_kval(IR(ir->op2));
if ((op&2)) k++;
if (checki16(k)) {
asm_guard(as, (op&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_tsi(as, (op&4) ? MIPSI_SLTIU : MIPSI_SLTI,
RID_TMP, left, k);
return;
}
}
right = ra_alloc1(as, ir->op2, rset_exclude(RSET_GPR, left));
asm_guard(as, ((op^(op>>1))&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO);
emit_dst(as, (op&4) ? MIPSI_SLTU : MIPSI_SLT,
RID_TMP, (op&2) ? right : left, (op&2) ? left : right);
}
}
}
static void asm_equal(ASMState *as, IRIns *ir)
{
Reg right, left = ra_alloc2(as, ir, (!LJ_SOFTFP && irt_isnum(ir->t)) ?
RSET_FPR : RSET_GPR);
right = (left >> 8); left &= 255;
if (!LJ_SOFTFP32 && irt_isnum(ir->t)) {
#if LJ_SOFTFP
asm_sfpcomp(as, ir);
#else
asm_guard(as, (ir->o & 1) ? MIPSI_BC1T : MIPSI_BC1F, 0, 0);
emit_fgh(as, MIPSI_C_EQ_D, 0, left, right);
#endif
} else {
asm_guard(as, (ir->o & 1) ? MIPSI_BEQ : MIPSI_BNE, left, right);
}
}
#if LJ_32 && LJ_HASFFI
/* 64 bit integer comparisons. */
static void asm_comp64(ASMState *as, IRIns *ir)
{
/* ORDER IR: LT GE LE GT ULT UGE ULE UGT. */
IROp op = (ir-1)->o;
MCLabel l_end;
Reg rightlo, leftlo, righthi, lefthi = ra_alloc2(as, ir, RSET_GPR);
righthi = (lefthi >> 8); lefthi &= 255;
leftlo = ra_alloc2(as, ir-1,
rset_exclude(rset_exclude(RSET_GPR, lefthi), righthi));
rightlo = (leftlo >> 8); leftlo &= 255;
asm_guard(as, ((op^(op>>1))&1) ? MIPSI_BNE : MIPSI_BEQ, RID_TMP, RID_ZERO);
l_end = emit_label(as);
if (lefthi != righthi)
emit_dst(as, (op&4) ? MIPSI_SLTU : MIPSI_SLT, RID_TMP,
(op&2) ? righthi : lefthi, (op&2) ? lefthi : righthi);
emit_dst(as, MIPSI_SLTU, RID_TMP,
(op&2) ? rightlo : leftlo, (op&2) ? leftlo : rightlo);
if (lefthi != righthi)
emit_branch(as, MIPSI_BEQ, lefthi, righthi, l_end);
}
static void asm_comp64eq(ASMState *as, IRIns *ir)
{
Reg tmp, right, left = ra_alloc2(as, ir, RSET_GPR);
right = (left >> 8); left &= 255;
asm_guard(as, ((ir-1)->o & 1) ? MIPSI_BEQ : MIPSI_BNE, RID_TMP, RID_ZERO);
tmp = ra_scratch(as, rset_exclude(rset_exclude(RSET_GPR, left), right));
emit_dst(as, MIPSI_OR, RID_TMP, RID_TMP, tmp);
emit_dst(as, MIPSI_XOR, tmp, left, right);
left = ra_alloc2(as, ir-1, RSET_GPR);
right = (left >> 8); left &= 255;
emit_dst(as, MIPSI_XOR, RID_TMP, left, right);
}
#endif
/* -- Support for 64 bit ops in 32 bit mode ------------------------------- */
/* Hiword op of a split 64 bit op. Previous op must be the loword op. */
static void asm_hiop(ASMState *as, IRIns *ir)
{
#if LJ_32 && (LJ_HASFFI || LJ_SOFTFP)
/* HIOP is marked as a store because it needs its own DCE logic. */
int uselo = ra_used(ir-1), usehi = ra_used(ir); /* Loword/hiword used? */
if (LJ_UNLIKELY(!(as->flags & JIT_F_OPT_DCE))) uselo = usehi = 1;
if ((ir-1)->o == IR_CONV) { /* Conversions to/from 64 bit. */
as->curins--; /* Always skip the CONV. */
#if LJ_HASFFI && !LJ_SOFTFP
if (usehi || uselo)
asm_conv64(as, ir);
return;
#endif
} else if ((ir-1)->o < IR_EQ) { /* 64 bit integer comparisons. ORDER IR. */
as->curins--; /* Always skip the loword comparison. */
#if LJ_SOFTFP
if (!irt_isint(ir->t)) {
asm_sfpcomp(as, ir-1);
return;
}
#endif
#if LJ_HASFFI
asm_comp64(as, ir);
#endif
return;
} else if ((ir-1)->o <= IR_NE) { /* 64 bit integer comparisons. ORDER IR. */
as->curins--; /* Always skip the loword comparison. */
#if LJ_SOFTFP
if (!irt_isint(ir->t)) {
asm_sfpcomp(as, ir-1);
return;
}
#endif
#if LJ_HASFFI
asm_comp64eq(as, ir);
#endif
return;
#if LJ_SOFTFP
} else if ((ir-1)->o == IR_MIN || (ir-1)->o == IR_MAX) {
as->curins--; /* Always skip the loword min/max. */
if (uselo || usehi)
asm_sfpmin_max(as, ir-1);
return;
#endif
} else if ((ir-1)->o == IR_XSTORE) {
as->curins--; /* Handle both stores here. */
if ((ir-1)->r != RID_SINK) {
asm_xstore_(as, ir, LJ_LE ? 4 : 0);
asm_xstore_(as, ir-1, LJ_LE ? 0 : 4);
}
return;
}
if (!usehi) return; /* Skip unused hiword op for all remaining ops. */
switch ((ir-1)->o) {
#if LJ_HASFFI
case IR_ADD: as->curins--; asm_add64(as, ir); break;
case IR_SUB: as->curins--; asm_sub64(as, ir); break;
case IR_NEG: as->curins--; asm_neg64(as, ir); break;
#endif
#if LJ_SOFTFP
case IR_SLOAD: case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD:
case IR_STRTO:
if (!uselo)
ra_allocref(as, ir->op1, RSET_GPR); /* Mark lo op as used. */
break;
#endif
case IR_CALLN:
case IR_CALLS:
case IR_CALLXS:
if (!uselo)
ra_allocref(as, ir->op1, RID2RSET(RID_RETLO)); /* Mark lo op as used. */
break;
#if LJ_SOFTFP
case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_TOSTR:
#endif
case IR_CNEWI:
/* Nothing to do here. Handled by lo op itself. */
break;
default: lua_assert(0); break;
}
#else
UNUSED(as); UNUSED(ir); lua_assert(0); /* Unused without FFI. */
#endif
}
/* -- Profiling ----------------------------------------------------------- */
static void asm_prof(ASMState *as, IRIns *ir)
{
UNUSED(ir);
asm_guard(as, MIPSI_BNE, RID_TMP, RID_ZERO);
emit_tsi(as, MIPSI_ANDI, RID_TMP, RID_TMP, HOOK_PROFILE);
emit_lsglptr(as, MIPSI_LBU, RID_TMP,
(int32_t)offsetof(global_State, hookmask));
}
/* -- Stack handling ------------------------------------------------------ */
/* Check Lua stack size for overflow. Use exit handler as fallback. */
static void asm_stack_check(ASMState *as, BCReg topslot,
IRIns *irp, RegSet allow, ExitNo exitno)
{
/* Try to get an unused temp. register, otherwise spill/restore RID_RET*. */
Reg tmp, pbase = irp ? (ra_hasreg(irp->r) ? irp->r : RID_TMP) : RID_BASE;
ExitNo oldsnap = as->snapno;
rset_clear(allow, pbase);
#if LJ_32
tmp = allow ? rset_pickbot(allow) :
(pbase == RID_RETHI ? RID_RETLO : RID_RETHI);
#else
tmp = allow ? rset_pickbot(allow) : RID_RET;
#endif
as->snapno = exitno;
asm_guard(as, MIPSI_BNE, RID_TMP, RID_ZERO);
as->snapno = oldsnap;
if (allow == RSET_EMPTY) /* Restore temp. register. */
emit_tsi(as, MIPSI_AL, tmp, RID_SP, 0);
else
ra_modified(as, tmp);
emit_tsi(as, MIPSI_SLTIU, RID_TMP, RID_TMP, (int32_t)(8*topslot));
emit_dst(as, MIPSI_ASUBU, RID_TMP, tmp, pbase);
emit_tsi(as, MIPSI_AL, tmp, tmp, offsetof(lua_State, maxstack));
if (pbase == RID_TMP)
emit_getgl(as, RID_TMP, jit_base);
emit_getgl(as, tmp, cur_L);
if (allow == RSET_EMPTY) /* Spill temp. register. */
emit_tsi(as, MIPSI_AS, tmp, RID_SP, 0);
}
/* Restore Lua stack from on-trace state. */
static void asm_stack_restore(ASMState *as, SnapShot *snap)
{
SnapEntry *map = &as->T->snapmap[snap->mapofs];
#if LJ_32 || defined(LUA_USE_ASSERT)
SnapEntry *flinks = &as->T->snapmap[snap_nextofs(as->T, snap)-1-LJ_FR2];
#endif
MSize n, nent = snap->nent;
/* Store the value of all modified slots to the Lua stack. */
for (n = 0; n < nent; n++) {
SnapEntry sn = map[n];
BCReg s = snap_slot(sn);
int32_t ofs = 8*((int32_t)s-1-LJ_FR2);
IRRef ref = snap_ref(sn);
IRIns *ir = IR(ref);
if ((sn & SNAP_NORESTORE))
continue;
if (irt_isnum(ir->t)) {
#if LJ_SOFTFP32
Reg tmp;
RegSet allow = rset_exclude(RSET_GPR, RID_BASE);
lua_assert(irref_isk(ref)); /* LJ_SOFTFP: must be a number constant. */
tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.lo, allow);
emit_tsi(as, MIPSI_SW, tmp, RID_BASE, ofs+(LJ_BE?4:0));
if (rset_test(as->freeset, tmp+1)) allow = RID2RSET(tmp+1);
tmp = ra_allock(as, (int32_t)ir_knum(ir)->u32.hi, allow);
emit_tsi(as, MIPSI_SW, tmp, RID_BASE, ofs+(LJ_BE?0:4));
#elif LJ_SOFTFP /* && LJ_64 */
Reg src = ra_alloc1(as, ref, rset_exclude(RSET_GPR, RID_BASE));
emit_tsi(as, MIPSI_SD, src, RID_BASE, ofs);
#else
Reg src = ra_alloc1(as, ref, RSET_FPR);
emit_hsi(as, MIPSI_SDC1, src, RID_BASE, ofs);
#endif
} else {
#if LJ_32
RegSet allow = rset_exclude(RSET_GPR, RID_BASE);
Reg type;
lua_assert(irt_ispri(ir->t) || irt_isaddr(ir->t) || irt_isinteger(ir->t));
if (!irt_ispri(ir->t)) {
Reg src = ra_alloc1(as, ref, allow);
rset_clear(allow, src);
emit_tsi(as, MIPSI_SW, src, RID_BASE, ofs+(LJ_BE?4:0));
}
if ((sn & (SNAP_CONT|SNAP_FRAME))) {
if (s == 0) continue; /* Do not overwrite link to previous frame. */
type = ra_allock(as, (int32_t)(*flinks--), allow);
#if LJ_SOFTFP
} else if ((sn & SNAP_SOFTFPNUM)) {
type = ra_alloc1(as, ref+1, rset_exclude(RSET_GPR, RID_BASE));
#endif
} else {
type = ra_allock(as, (int32_t)irt_toitype(ir->t), allow);
}
emit_tsi(as, MIPSI_SW, type, RID_BASE, ofs+(LJ_BE?0:4));
#else
asm_tvstore64(as, RID_BASE, ofs, ref);
#endif
}
checkmclim(as);
}
lua_assert(map + nent == flinks);
}
/* -- GC handling --------------------------------------------------------- */
/* Check GC threshold and do one or more GC steps. */
static void asm_gc_check(ASMState *as)
{
const CCallInfo *ci = &lj_ir_callinfo[IRCALL_lj_gc_step_jit];
IRRef args[2];
MCLabel l_end;
Reg tmp;
ra_evictset(as, RSET_SCRATCH);
l_end = emit_label(as);
/* Exit trace if in GCSatomic or GCSfinalize. Avoids syncing GC objects. */
/* Assumes asm_snap_prep() already done. */
asm_guard(as, MIPSI_BNE, RID_RET, RID_ZERO);
args[0] = ASMREF_TMP1; /* global_State *g */
args[1] = ASMREF_TMP2; /* MSize steps */
asm_gencall(as, ci, args);
emit_tsi(as, MIPSI_AADDIU, ra_releasetmp(as, ASMREF_TMP1), RID_JGL, -32768);
tmp = ra_releasetmp(as, ASMREF_TMP2);
emit_loadi(as, tmp, as->gcsteps);
/* Jump around GC step if GC total < GC threshold. */
emit_branch(as, MIPSI_BNE, RID_TMP, RID_ZERO, l_end);
emit_dst(as, MIPSI_SLTU, RID_TMP, RID_TMP, tmp);
emit_getgl(as, tmp, gc.threshold);
emit_getgl(as, RID_TMP, gc.total);
as->gcsteps = 0;
checkmclim(as);
}
/* -- Loop handling ------------------------------------------------------- */
/* Fixup the loop branch. */
static void asm_loop_fixup(ASMState *as)
{
MCode *p = as->mctop;
MCode *target = as->mcp;
p[-1] = MIPSI_NOP;
if (as->loopinv) { /* Inverted loop branch? */
/* asm_guard already inverted the cond branch. Only patch the target. */
p[-3] |= ((target-p+2) & 0x0000ffffu);
} else {
p[-2] = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu);
}
}
/* -- Head of trace ------------------------------------------------------- */
/* Coalesce BASE register for a root trace. */
static void asm_head_root_base(ASMState *as)
{
IRIns *ir = IR(REF_BASE);
Reg r = ir->r;
if (as->loopinv) as->mctop--;
if (ra_hasreg(r)) {
ra_free(as, r);
if (rset_test(as->modset, r) || irt_ismarked(ir->t))
ir->r = RID_INIT; /* No inheritance for modified BASE register. */
if (r != RID_BASE)
emit_move(as, r, RID_BASE);
}
}
/* Coalesce BASE register for a side trace. */
static RegSet asm_head_side_base(ASMState *as, IRIns *irp, RegSet allow)
{
IRIns *ir = IR(REF_BASE);
Reg r = ir->r;
if (as->loopinv) as->mctop--;
if (ra_hasreg(r)) {
ra_free(as, r);
if (rset_test(as->modset, r) || irt_ismarked(ir->t))
ir->r = RID_INIT; /* No inheritance for modified BASE register. */
if (irp->r == r) {
rset_clear(allow, r); /* Mark same BASE register as coalesced. */
} else if (ra_hasreg(irp->r) && rset_test(as->freeset, irp->r)) {
rset_clear(allow, irp->r);
emit_move(as, r, irp->r); /* Move from coalesced parent reg. */
} else {
emit_getgl(as, r, jit_base); /* Otherwise reload BASE. */
}
}
return allow;
}
/* -- Tail of trace ------------------------------------------------------- */
/* Fixup the tail code. */
static void asm_tail_fixup(ASMState *as, TraceNo lnk)
{
MCode *target = lnk ? traceref(as->J,lnk)->mcode : (MCode *)lj_vm_exit_interp;
int32_t spadj = as->T->spadjust;
MCode *p = as->mctop-1;
*p = spadj ? (MIPSI_AADDIU|MIPSF_T(RID_SP)|MIPSF_S(RID_SP)|spadj) : MIPSI_NOP;
p[-1] = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu);
}
/* Prepare tail of code. */
static void asm_tail_prep(ASMState *as)
{
as->mcp = as->mctop-2; /* Leave room for branch plus nop or stack adj. */
as->invmcp = as->loopref ? as->mcp : NULL;
}
/* -- Trace setup --------------------------------------------------------- */
/* Ensure there are enough stack slots for call arguments. */
static Reg asm_setup_call_slots(ASMState *as, IRIns *ir, const CCallInfo *ci)
{
IRRef args[CCI_NARGS_MAX*2];
uint32_t i, nargs = CCI_XNARGS(ci);
#if LJ_32
int nslots = 4, ngpr = REGARG_NUMGPR, nfpr = REGARG_NUMFPR;
#else
int nslots = 0, ngpr = REGARG_NUMGPR;
#endif
asm_collectargs(as, ir, ci, args);
for (i = 0; i < nargs; i++) {
#if LJ_32
if (!LJ_SOFTFP && args[i] && irt_isfp(IR(args[i])->t) &&
nfpr > 0 && !(ci->flags & CCI_VARARG)) {
nfpr--;
ngpr -= irt_isnum(IR(args[i])->t) ? 2 : 1;
} else if (!LJ_SOFTFP && args[i] && irt_isnum(IR(args[i])->t)) {
nfpr = 0;
ngpr = ngpr & ~1;
if (ngpr > 0) ngpr -= 2; else nslots = (nslots+3) & ~1;
} else {
nfpr = 0;
if (ngpr > 0) ngpr--; else nslots++;
}
#else
if (ngpr > 0) ngpr--; else nslots += 2;
#endif
}
if (nslots > as->evenspill) /* Leave room for args in stack slots. */
as->evenspill = nslots;
return irt_isfp(ir->t) ? REGSP_HINT(RID_FPRET) : REGSP_HINT(RID_RET);
}
static void asm_setup_target(ASMState *as)
{
asm_sparejump_setup(as);
asm_exitstub_setup(as);
}
/* -- Trace patching ------------------------------------------------------ */
/* Patch exit jumps of existing machine code to a new target. */
void lj_asm_patchexit(jit_State *J, GCtrace *T, ExitNo exitno, MCode *target)
{
MCode *p = T->mcode;
MCode *pe = (MCode *)((char *)p + T->szmcode);
MCode *px = exitstub_trace_addr(T, exitno);
MCode *cstart = NULL, *cstop = NULL;
MCode *mcarea = lj_mcode_patch(J, p, 0);
MCode exitload = MIPSI_LI | MIPSF_T(RID_TMP) | exitno;
MCode tjump = MIPSI_J|(((uintptr_t)target>>2)&0x03ffffffu);
for (p++; p < pe; p++) {
if (*p == exitload) { /* Look for load of exit number. */
/* Look for exitstub branch. Yes, this covers all used branch variants. */
if (((p[-1] ^ (px-p)) & 0xffffu) == 0 &&
((p[-1] & 0xf0000000u) == MIPSI_BEQ ||
(p[-1] & 0xfc1e0000u) == MIPSI_BLTZ ||
(p[-1] & 0xffe00000u) == MIPSI_BC1F)) {
ptrdiff_t delta = target - p;
if (((delta + 0x8000) >> 16) == 0) { /* Patch in-range branch. */
patchbranch:
p[-1] = (p[-1] & 0xffff0000u) | (delta & 0xffffu);
*p = MIPSI_NOP; /* Replace the load of the exit number. */
cstop = p;
if (!cstart) cstart = p-1;
} else { /* Branch out of range. Use spare jump slot in mcarea. */
int i;
for (i = (int)(sizeof(MCLink)/sizeof(MCode));
i < (int)(sizeof(MCLink)/sizeof(MCode)+MIPS_SPAREJUMP*2);
i += 2) {
if (mcarea[i] == tjump) {
delta = mcarea+i - p;
goto patchbranch;
} else if (mcarea[i] == MIPSI_NOP) {
mcarea[i] = tjump;
cstart = mcarea+i;
delta = mcarea+i - p;
goto patchbranch;
}
}
/* Ignore jump slot overflow. Child trace is simply not attached. */
}
} else if (p+1 == pe) {
/* Patch NOP after code for inverted loop branch. Use of J is ok. */
lua_assert(p[1] == MIPSI_NOP);
p[1] = tjump;
*p = MIPSI_NOP; /* Replace the load of the exit number. */
cstop = p+2;
if (!cstart) cstart = p+1;
}
}
}
if (cstart) lj_mcode_sync(cstart, cstop);
lj_mcode_patch(J, mcarea, 1);
}