/*
** MIPS instruction emitter.
** Copyright (C) 2005-2017 Mike Pall. See Copyright Notice in luajit.h
*/
#if LJ_64
static intptr_t get_k64val(IRIns *ir)
{
if (ir->o == IR_KINT64) {
return (intptr_t)ir_kint64(ir)->u64;
} else if (ir->o == IR_KGC) {
return (intptr_t)ir_kgc(ir);
} else if (ir->o == IR_KPTR || ir->o == IR_KKPTR) {
return (intptr_t)ir_kptr(ir);
} else if (LJ_SOFTFP && ir->o == IR_KNUM) {
return (intptr_t)ir_knum(ir)->u64;
} else {
lua_assert(ir->o == IR_KINT || ir->o == IR_KNULL);
return ir->i; /* Sign-extended. */
}
}
#endif
#if LJ_64
#define get_kval(ir) get_k64val(ir)
#else
#define get_kval(ir) ((ir)->i)
#endif
/* -- Emit basic instructions --------------------------------------------- */
static void emit_dst(ASMState *as, MIPSIns mi, Reg rd, Reg rs, Reg rt)
{
*--as->mcp = mi | MIPSF_D(rd) | MIPSF_S(rs) | MIPSF_T(rt);
}
static void emit_dta(ASMState *as, MIPSIns mi, Reg rd, Reg rt, uint32_t a)
{
*--as->mcp = mi | MIPSF_D(rd) | MIPSF_T(rt) | MIPSF_A(a);
}
#define emit_ds(as, mi, rd, rs) emit_dst(as, (mi), (rd), (rs), 0)
#define emit_tg(as, mi, rt, rg) emit_dst(as, (mi), (rg)&31, 0, (rt))
static void emit_tsi(ASMState *as, MIPSIns mi, Reg rt, Reg rs, int32_t i)
{
*--as->mcp = mi | MIPSF_T(rt) | MIPSF_S(rs) | (i & 0xffff);
}
#define emit_ti(as, mi, rt, i) emit_tsi(as, (mi), (rt), 0, (i))
#define emit_hsi(as, mi, rh, rs, i) emit_tsi(as, (mi), (rh) & 31, (rs), (i))
static void emit_fgh(ASMState *as, MIPSIns mi, Reg rf, Reg rg, Reg rh)
{
*--as->mcp = mi | MIPSF_F(rf&31) | MIPSF_G(rg&31) | MIPSF_H(rh&31);
}
#define emit_fg(as, mi, rf, rg) emit_fgh(as, (mi), (rf), (rg), 0)
static void emit_rotr(ASMState *as, Reg dest, Reg src, Reg tmp, uint32_t shift)
{
if (LJ_64 || (as->flags & JIT_F_MIPSXXR2)) {
emit_dta(as, MIPSI_ROTR, dest, src, shift);
} else {
emit_dst(as, MIPSI_OR, dest, dest, tmp);
emit_dta(as, MIPSI_SLL, dest, src, (-shift)&31);
emit_dta(as, MIPSI_SRL, tmp, src, shift);
}
}
#if LJ_64
static void emit_tsml(ASMState *as, MIPSIns mi, Reg rt, Reg rs, uint32_t msb,
uint32_t lsb)
{
*--as->mcp = mi | MIPSF_T(rt) | MIPSF_S(rs) | MIPSF_M(msb) | MIPSF_L(lsb);
}
#endif
/* -- Emit loads/stores --------------------------------------------------- */
/* Prefer rematerialization of BASE/L from global_State over spills. */
#define emit_canremat(ref) ((ref) <= REF_BASE)
/* Try to find a one step delta relative to another constant. */
static int emit_kdelta1(ASMState *as, Reg t, intptr_t i)
{
RegSet work = ~as->freeset & RSET_GPR;
while (work) {
Reg r = rset_picktop(work);
IRRef ref = regcost_ref(as->cost[r]);
lua_assert(r != t);
if (ref < ASMREF_L) {
intptr_t delta = (intptr_t)((uintptr_t)i -
(uintptr_t)(ra_iskref(ref) ? ra_krefk(as, ref) : get_kval(IR(ref))));
if (checki16(delta)) {
emit_tsi(as, MIPSI_AADDIU, t, r, delta);
return 1;
}
}
rset_clear(work, r);
}
return 0; /* Failed. */
}
/* Load a 32 bit constant into a GPR. */
static void emit_loadi(ASMState *as, Reg r, int32_t i)
{
if (checki16(i)) {
emit_ti(as, MIPSI_LI, r, i);
} else {
if ((i & 0xffff)) {
intptr_t jgl = (intptr_t)(void *)J2G(as->J);
if ((uintptr_t)(i-jgl) < 65536) {
emit_tsi(as, MIPSI_ADDIU, r, RID_JGL, i-jgl-32768);
return;
} else if (emit_kdelta1(as, r, i)) {
return;
} else if ((i >> 16) == 0) {
emit_tsi(as, MIPSI_ORI, r, RID_ZERO, i);
return;
}
emit_tsi(as, MIPSI_ORI, r, r, i);
}
emit_ti(as, MIPSI_LUI, r, (i >> 16));
}
}
#if LJ_64
/* Load a 64 bit constant into a GPR. */
static void emit_loadu64(ASMState *as, Reg r, uint64_t u64)
{
if (checki32((int64_t)u64)) {
emit_loadi(as, r, (int32_t)u64);
} else {
uint64_t delta = u64 - (uint64_t)(void *)J2G(as->J);
if (delta < 65536) {
emit_tsi(as, MIPSI_DADDIU, r, RID_JGL, (int32_t)(delta-32768));
} else if (emit_kdelta1(as, r, (intptr_t)u64)) {
return;
} else {
if ((u64 & 0xffff)) {
emit_tsi(as, MIPSI_ORI, r, r, u64 & 0xffff);
}
if (((u64 >> 16) & 0xffff)) {
emit_dta(as, MIPSI_DSLL, r, r, 16);
emit_tsi(as, MIPSI_ORI, r, r, (u64 >> 16) & 0xffff);
emit_dta(as, MIPSI_DSLL, r, r, 16);
} else {
emit_dta(as, MIPSI_DSLL32, r, r, 0);
}
emit_loadi(as, r, (int32_t)(u64 >> 32));
}
/* TODO: There are probably more optimization opportunities. */
}
}
#define emit_loada(as, r, addr) emit_loadu64(as, (r), u64ptr((addr)))
#else
#define emit_loada(as, r, addr) emit_loadi(as, (r), i32ptr((addr)))
#endif
static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow);
static void ra_allockreg(ASMState *as, intptr_t k, Reg r);
/* Get/set from constant pointer. */
static void emit_lsptr(ASMState *as, MIPSIns mi, Reg r, void *p, RegSet allow)
{
intptr_t jgl = (intptr_t)(J2G(as->J));
intptr_t i = (intptr_t)(p);
Reg base;
if ((uint32_t)(i-jgl) < 65536) {
i = i-jgl-32768;
base = RID_JGL;
} else {
base = ra_allock(as, i-(int16_t)i, allow);
}
emit_tsi(as, mi, r, base, i);
}
#if LJ_64
static void emit_loadk64(ASMState *as, Reg r, IRIns *ir)
{
const uint64_t *k = &ir_k64(ir)->u64;
Reg r64 = r;
if (rset_test(RSET_FPR, r)) {
r64 = RID_TMP;
emit_tg(as, MIPSI_DMTC1, r64, r);
}
if ((uint32_t)((intptr_t)k-(intptr_t)J2G(as->J)) < 65536)
emit_lsptr(as, MIPSI_LD, r64, (void *)k, 0);
else
emit_loadu64(as, r64, *k);
}
#else
#define emit_loadk64(as, r, ir) \
emit_lsptr(as, MIPSI_LDC1, ((r) & 31), (void *)&ir_knum((ir))->u64, RSET_GPR)
#endif
/* Get/set global_State fields. */
static void emit_lsglptr(ASMState *as, MIPSIns mi, Reg r, int32_t ofs)
{
emit_tsi(as, mi, r, RID_JGL, ofs-32768);
}
#define emit_getgl(as, r, field) \
emit_lsglptr(as, MIPSI_AL, (r), (int32_t)offsetof(global_State, field))
#define emit_setgl(as, r, field) \
emit_lsglptr(as, MIPSI_AS, (r), (int32_t)offsetof(global_State, field))
/* Trace number is determined from per-trace exit stubs. */
#define emit_setvmstate(as, i) UNUSED(i)
/* -- Emit control-flow instructions -------------------------------------- */
/* Label for internal jumps. */
typedef MCode *MCLabel;
/* Return label pointing to current PC. */
#define emit_label(as) ((as)->mcp)
static void emit_branch(ASMState *as, MIPSIns mi, Reg rs, Reg rt, MCode *target)
{
MCode *p = as->mcp;
ptrdiff_t delta = target - p;
lua_assert(((delta + 0x8000) >> 16) == 0);
*--p = mi | MIPSF_S(rs) | MIPSF_T(rt) | ((uint32_t)delta & 0xffffu);
as->mcp = p;
}
static void emit_jmp(ASMState *as, MCode *target)
{
*--as->mcp = MIPSI_NOP;
emit_branch(as, MIPSI_B, RID_ZERO, RID_ZERO, (target));
}
static void emit_call(ASMState *as, void *target, int needcfa)
{
MCode *p = as->mcp;
*--p = MIPSI_NOP;
if ((((uintptr_t)target ^ (uintptr_t)p) >> 28) == 0) {
*--p = (((uintptr_t)target & 1) ? MIPSI_JALX : MIPSI_JAL) |
(((uintptr_t)target >>2) & 0x03ffffffu);
} else { /* Target out of range: need indirect call. */
*--p = MIPSI_JALR | MIPSF_S(RID_CFUNCADDR);
needcfa = 1;
}
as->mcp = p;
if (needcfa) ra_allockreg(as, (intptr_t)target, RID_CFUNCADDR);
}
/* -- Emit generic operations --------------------------------------------- */
#define emit_move(as, dst, src) \
emit_ds(as, MIPSI_MOVE, (dst), (src))
/* Generic move between two regs. */
static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src)
{
if (dst < RID_MAX_GPR)
emit_move(as, dst, src);
else
emit_fg(as, irt_isnum(ir->t) ? MIPSI_MOV_D : MIPSI_MOV_S, dst, src);
}
/* Generic load of register with base and (small) offset address. */
static void emit_loadofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs)
{
if (r < RID_MAX_GPR)
emit_tsi(as, irt_is64(ir->t) ? MIPSI_LD : MIPSI_LW, r, base, ofs);
else
emit_tsi(as, irt_isnum(ir->t) ? MIPSI_LDC1 : MIPSI_LWC1,
(r & 31), base, ofs);
}
/* Generic store of register with base and (small) offset address. */
static void emit_storeofs(ASMState *as, IRIns *ir, Reg r, Reg base, int32_t ofs)
{
if (r < RID_MAX_GPR)
emit_tsi(as, irt_is64(ir->t) ? MIPSI_SD : MIPSI_SW, r, base, ofs);
else
emit_tsi(as, irt_isnum(ir->t) ? MIPSI_SDC1 : MIPSI_SWC1,
(r&31), base, ofs);
}
/* Add offset to pointer. */
static void emit_addptr(ASMState *as, Reg r, int32_t ofs)
{
if (ofs) {
lua_assert(checki16(ofs));
emit_tsi(as, MIPSI_AADDIU, r, r, ofs);
}
}
#define emit_spsub(as, ofs) emit_addptr(as, RID_SP, -(ofs))