File: //home/ubuntu/neovim/.deps/build/src/luajit/src/lj_emit_arm64.h
/*
** ARM64 instruction emitter.
** Copyright (C) 2005-2023 Mike Pall. See Copyright Notice in luajit.h
**
** Contributed by Djordje Kovacevic and Stefan Pejic from RT-RK.com.
** Sponsored by Cisco Systems, Inc.
*/
/* -- Constant encoding --------------------------------------------------- */
static uint64_t get_k64val(ASMState *as, IRRef ref)
{
IRIns *ir = IR(ref);
if (ir->o == IR_KINT64) {
return ir_kint64(ir)->u64;
} else if (ir->o == IR_KGC) {
return (uint64_t)ir_kgc(ir);
} else if (ir->o == IR_KPTR || ir->o == IR_KKPTR) {
return (uint64_t)ir_kptr(ir);
} else {
lj_assertA(ir->o == IR_KINT || ir->o == IR_KNULL,
"bad 64 bit const IR op %d", ir->o);
return (uint32_t)ir->i; /* Zero-extended. */
}
}
/* Encode constant in K12 format for data processing instructions. */
static uint32_t emit_isk12(int64_t n)
{
uint64_t k = n < 0 ? ~(uint64_t)n+1u : (uint64_t)n;
uint32_t m = n < 0 ? 0x40000000 : 0;
if (k < 0x1000) {
return (uint32_t)(A64I_K12|m|A64F_U12(k));
} else if ((k & 0xfff000) == k) {
return (uint32_t)(A64I_K12|m|0x400000|A64F_U12(k>>12));
}
return 0;
}
#define emit_clz64(n) (lj_fls64(n)^63)
#define emit_ctz64(n) lj_ffs64(n)
/* Encode constant in K13 format for logical data processing instructions. */
static uint32_t emit_isk13(uint64_t n, int is64)
{
/* Thanks to: https://dougallj.wordpress.com/2021/10/30/ */
int rot, ones, size, immr, imms;
if (!is64) n = ((uint64_t)n << 32) | (uint32_t)n;
if ((n+1u) <= 1u) return 0; /* Neither all-zero nor all-ones are allowed. */
rot = (n & (n+1u)) ? emit_ctz64(n & (n+1u)) : 64;
n = lj_ror(n, rot & 63);
ones = emit_ctz64(~n);
size = emit_clz64(n) + ones;
if (lj_ror(n, size & 63) != n) return 0; /* Non-repeating? */
immr = -rot & (size - 1);
imms = (-(size << 1) | (ones - 1)) & 63;
return A64I_K13 | A64F_IMMR(immr | (size & 64)) | A64F_IMMS(imms);
}
static uint32_t emit_isfpk64(uint64_t n)
{
uint64_t etop9 = ((n >> 54) & 0x1ff);
if ((n << 16) == 0 && (etop9 == 0x100 || etop9 == 0x0ff)) {
return (uint32_t)(((n >> 48) & 0x7f) | ((n >> 56) & 0x80));
}
return ~0u;
}
static uint32_t emit_isfpmovi(uint64_t n)
{
/* Is every byte either 0x00 or 0xff? */
if ((n & U64x(01010101,01010101)) * 0xff != n) return 0;
/* Form 8-bit value by taking one bit from each byte. */
n &= U64x(80402010,08040201);
n = (n * U64x(01010101,01010101)) >> 56;
/* Split into the format expected by movi. */
return ((n & 0xe0) << 6) | 0x700 | (n & 0x1f);
}
/* -- Emit basic instructions --------------------------------------------- */
static void emit_dnma(ASMState *as, A64Ins ai, Reg rd, Reg rn, Reg rm, Reg ra)
{
*--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_M(rm) | A64F_A(ra);
}
static void emit_dnm(ASMState *as, A64Ins ai, Reg rd, Reg rn, Reg rm)
{
*--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_M(rm);
}
static void emit_dm(ASMState *as, A64Ins ai, Reg rd, Reg rm)
{
*--as->mcp = ai | A64F_D(rd) | A64F_M(rm);
}
static void emit_dn(ASMState *as, A64Ins ai, Reg rd, Reg rn)
{
*--as->mcp = ai | A64F_D(rd) | A64F_N(rn);
}
static void emit_nm(ASMState *as, A64Ins ai, Reg rn, Reg rm)
{
*--as->mcp = ai | A64F_N(rn) | A64F_M(rm);
}
static void emit_d(ASMState *as, A64Ins ai, Reg rd)
{
*--as->mcp = ai | A64F_D(rd);
}
static void emit_dl(ASMState *as, A64Ins ai, Reg rd, uint32_t l)
{
*--as->mcp = ai | A64F_D(rd) | A64F_S19(l >> 2);
}
static void emit_n(ASMState *as, A64Ins ai, Reg rn)
{
*--as->mcp = ai | A64F_N(rn);
}
static int emit_checkofs(A64Ins ai, int64_t ofs)
{
int scale = (ai >> 30) & 3;
if (ofs < 0 || (ofs & ((1<<scale)-1))) {
return (ofs >= -256 && ofs <= 255) ? -1 : 0;
} else {
return (ofs < (4096<<scale)) ? 1 : 0;
}
}
static LJ_AINLINE uint32_t emit_lso_pair_candidate(A64Ins ai, int ofs, int sc)
{
if (ofs >= 0) {
return ai | A64F_U12(ofs>>sc); /* Subsequent lj_ror checks ofs. */
} else if (ofs >= -256) {
return (ai^A64I_LS_U) | A64F_S9(ofs & 0x1ff);
} else {
return A64F_D(31); /* Will mismatch prev. */
}
}
static void emit_lso(ASMState *as, A64Ins ai, Reg rd, Reg rn, int64_t ofs64)
{
int ot = emit_checkofs(ai, ofs64), sc = (ai >> 30) & 3, ofs = (int)ofs64;
lj_assertA(ot, "load/store offset %d out of range", ofs);
/* Combine LDR/STR pairs to LDP/STP. */
if ((sc == 2 || sc == 3) &&
(!(ai & 0x400000) || rd != rn) &&
as->mcp != as->mcloop) {
uint32_t prev = *as->mcp & ~A64F_D(31);
int ofsm = ofs - (1<<sc), ofsp = ofs + (1<<sc);
A64Ins aip;
if (prev == emit_lso_pair_candidate(ai | A64F_N(rn), ofsm, sc)) {
aip = (A64F_A(rd) | A64F_D(*as->mcp & 31));
} else if (prev == emit_lso_pair_candidate(ai | A64F_N(rn), ofsp, sc)) {
aip = (A64F_D(rd) | A64F_A(*as->mcp & 31));
ofsm = ofs;
} else {
goto nopair;
}
if (lj_ror((unsigned int)ofsm + (64u<<sc), sc) <= 127u) {
*as->mcp = aip | A64F_N(rn) | (((ofsm >> sc) & 0x7f) << 15) |
(ai ^ ((ai == A64I_LDRx || ai == A64I_STRx) ? 0x50000000 : 0x90000000));
return;
}
}
nopair:
if (ot == 1)
*--as->mcp = ai | A64F_D(rd) | A64F_N(rn) | A64F_U12(ofs >> sc);
else
*--as->mcp = (ai^A64I_LS_U) | A64F_D(rd) | A64F_N(rn) | A64F_S9(ofs & 0x1ff);
}
/* -- 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 other consts. */
static int emit_kdelta(ASMState *as, Reg rd, uint64_t k, int is64)
{
RegSet work = (~as->freeset & RSET_GPR) | RID2RSET(RID_GL);
while (work) {
Reg r = rset_picktop(work);
IRRef ref = regcost_ref(as->cost[r]);
lj_assertA(r != rd, "dest reg %d not free", rd);
if (ref < REF_TRUE) {
uint64_t kx = ra_iskref(ref) ? (uint64_t)ra_krefk(as, ref) :
get_k64val(as, ref);
int64_t delta = (int64_t)(k - kx);
if (!is64) delta = (int64_t)(int32_t)delta; /* Sign-extend. */
if (delta == 0) {
emit_dm(as, is64|A64I_MOVw, rd, r);
return 1;
} else {
uint32_t k12 = emit_isk12(delta < 0 ? (int64_t)(~(uint64_t)delta+1u) : delta);
if (k12) {
emit_dn(as, (delta < 0 ? A64I_SUBw : A64I_ADDw)^is64^k12, rd, r);
return 1;
}
/* Do other ops or multi-step deltas pay off? Probably not.
** E.g. XOR rarely helps with pointer consts.
*/
}
}
rset_clear(work, r);
}
return 0; /* Failed. */
}
#define glofs(as, k) \
((intptr_t)((uintptr_t)(k) - (uintptr_t)&J2GG(as->J)->g))
#define mcpofs(as, k) \
((intptr_t)((uintptr_t)(k) - (uintptr_t)(as->mcp - 1)))
#define checkmcpofs(as, k) \
(A64F_S_OK(mcpofs(as, k)>>2, 19))
/* Try to form a const as ADR or ADRP or ADRP + ADD. */
static int emit_kadrp(ASMState *as, Reg rd, uint64_t k)
{
A64Ins ai = A64I_ADR;
int64_t ofs = mcpofs(as, k);
if (!A64F_S_OK((uint64_t)ofs, 21)) {
uint64_t kpage = k & ~0xfffull;
MCode *adrp = as->mcp - 1 - (k != kpage);
ofs = (int64_t)(kpage - ((uint64_t)adrp & ~0xfffull)) >> 12;
if (!A64F_S_OK(ofs, 21))
return 0; /* Failed. */
if (k != kpage)
emit_dn(as, (A64I_ADDx^A64I_K12)|A64F_U12(k - kpage), rd, rd);
ai = A64I_ADRP;
}
emit_dl(as, ai|(((uint32_t)ofs&3)<<29), rd, ofs);
return 1;
}
static void emit_loadk(ASMState *as, Reg rd, uint64_t u64)
{
int zeros = 0, ones = 0, neg, lshift = 0;
int is64 = (u64 >> 32) ? A64I_X : 0, i = is64 ? 4 : 2;
/* Count non-homogeneous 16 bit fragments. */
while (--i >= 0) {
uint32_t frag = (u64 >> i*16) & 0xffff;
zeros += (frag != 0);
ones += (frag != 0xffff);
}
neg = ones < zeros; /* Use MOVN if it pays off. */
if ((neg ? ones : zeros) > 1) { /* Need 2+ ins. Try 1 ins encodings. */
uint32_t k13 = emit_isk13(u64, is64);
if (k13) {
emit_dn(as, (is64|A64I_ORRw)^k13, rd, RID_ZERO);
return;
}
if (emit_kdelta(as, rd, u64, is64)) {
return;
}
if (emit_kadrp(as, rd, u64)) { /* Either 1 or 2 ins. */
return;
}
}
if (neg) {
u64 = ~u64;
if (!is64) u64 = (uint32_t)u64;
}
if (u64) {
/* Find first/last fragment to be filled. */
int shift = (63-emit_clz64(u64)) & ~15;
lshift = emit_ctz64(u64) & ~15;
for (; shift > lshift; shift -= 16) {
uint32_t frag = (u64 >> shift) & 0xffff;
if (frag == 0) continue; /* Will be correctly filled by MOVN/MOVZ. */
if (neg) frag ^= 0xffff; /* MOVK requires the original value. */
emit_d(as, is64 | A64I_MOVKw | A64F_U16(frag) | A64F_LSL16(shift), rd);
}
}
/* But MOVN needs an inverted value. */
emit_d(as, is64 | (neg ? A64I_MOVNw : A64I_MOVZw) |
A64F_U16((u64 >> lshift) & 0xffff) | A64F_LSL16(lshift), rd);
}
/* Load a 32 bit constant into a GPR. */
#define emit_loadi(as, rd, i) emit_loadk(as, rd, (uint32_t)i)
/* Load a 64 bit constant into a GPR. */
#define emit_loadu64(as, rd, i) emit_loadk(as, rd, i)
static Reg ra_allock(ASMState *as, intptr_t k, RegSet allow);
/* Get/set from constant pointer. */
static void emit_lsptr(ASMState *as, A64Ins ai, Reg r, void *p)
{
Reg base = RID_GL;
int64_t ofs = glofs(as, p);
if (emit_checkofs(ai, ofs)) {
/* GL + offset, might subsequently fuse to LDP/STP. */
} else if (ai == A64I_LDRx && checkmcpofs(as, p)) {
/* IP + offset is cheaper than allock, but address must be in range. */
emit_dl(as, A64I_LDRLx, r, mcpofs(as, p));
return;
} else { /* Split up into base reg + offset. */
int64_t i64 = i64ptr(p);
base = ra_allock(as, (i64 & ~0x7fffull), rset_exclude(RSET_GPR, r));
ofs = i64 & 0x7fffull;
}
emit_lso(as, ai, r, base, ofs);
}
/* Load 64 bit IR constant into register. */
static void emit_loadk64(ASMState *as, Reg r, IRIns *ir)
{
const uint64_t *k = &ir_k64(ir)->u64;
int64_t ofs;
if (r >= RID_MAX_GPR) {
uint32_t fpk = emit_isfpk64(*k);
if (fpk != ~0u) {
emit_d(as, A64I_FMOV_DI | A64F_FP8(fpk), (r & 31));
return;
} else if ((fpk = emit_isfpmovi(*k))) {
emit_d(as, A64I_MOVI_DI | (fpk << 5), (r & 31));
return;
}
}
ofs = glofs(as, k);
if (emit_checkofs(A64I_LDRx, ofs)) {
emit_lso(as, r >= RID_MAX_GPR ? A64I_LDRd : A64I_LDRx,
(r & 31), RID_GL, ofs);
} else if (checkmcpofs(as, k)) {
emit_dl(as, r >= RID_MAX_GPR ? A64I_LDRLd : A64I_LDRLx,
(r & 31), mcpofs(as, k));
} else {
if (r >= RID_MAX_GPR) {
emit_dn(as, A64I_FMOV_D_R, (r & 31), RID_TMP);
r = RID_TMP;
}
emit_loadu64(as, r, *k);
}
}
/* Get/set global_State fields. */
#define emit_getgl(as, r, field) \
emit_lsptr(as, A64I_LDRx, (r), (void *)&J2G(as->J)->field)
#define emit_setgl(as, r, field) \
emit_lsptr(as, A64I_STRx, (r), (void *)&J2G(as->J)->field)
/* Trace number is determined from pc of exit instruction. */
#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_cond_branch(ASMState *as, A64CC cond, MCode *target)
{
MCode *p = --as->mcp;
ptrdiff_t delta = target - p;
lj_assertA(A64F_S_OK(delta, 19), "branch target out of range");
*p = A64I_BCC | A64F_S19(delta) | cond;
}
static void emit_branch(ASMState *as, A64Ins ai, MCode *target)
{
MCode *p = --as->mcp;
ptrdiff_t delta = target - p;
lj_assertA(A64F_S_OK(delta, 26), "branch target out of range");
*p = ai | A64F_S26(delta);
}
static void emit_tnb(ASMState *as, A64Ins ai, Reg r, uint32_t bit, MCode *target)
{
MCode *p = --as->mcp;
ptrdiff_t delta = target - p;
lj_assertA(bit < 63, "bit number out of range");
lj_assertA(A64F_S_OK(delta, 14), "branch target out of range");
if (bit > 31) ai |= A64I_X;
*p = ai | A64F_BIT(bit & 31) | A64F_S14(delta) | r;
}
static void emit_cnb(ASMState *as, A64Ins ai, Reg r, MCode *target)
{
MCode *p = --as->mcp;
ptrdiff_t delta = target - p;
lj_assertA(A64F_S_OK(delta, 19), "branch target out of range");
*p = ai | A64F_S19(delta) | r;
}
#define emit_jmp(as, target) emit_branch(as, A64I_B, (target))
static void emit_call(ASMState *as, ASMFunction target)
{
MCode *p = --as->mcp;
#if LJ_ABI_PAUTH
char *targetp = ptrauth_auth_data((char *)target,
ptrauth_key_function_pointer, 0);
#else
char *targetp = (char *)target;
#endif
ptrdiff_t delta = targetp - (char *)p;
if (A64F_S_OK(delta>>2, 26)) {
*p = A64I_BL | A64F_S26(delta>>2);
} else { /* Target out of range: need indirect call. But don't use R0-R7. */
Reg r = ra_allock(as, i64ptr(target),
RSET_RANGE(RID_X8, RID_MAX_GPR)-RSET_FIXED);
*p = A64I_BLR_AUTH | A64F_N(r);
}
}
/* -- Emit generic operations --------------------------------------------- */
/* Generic move between two regs. */
static void emit_movrr(ASMState *as, IRIns *ir, Reg dst, Reg src)
{
if (dst >= RID_MAX_GPR) {
emit_dn(as, irt_isnum(ir->t) ? A64I_FMOV_D : A64I_FMOV_S,
(dst & 31), (src & 31));
return;
}
if (as->mcp != as->mcloop) { /* Swap early registers for loads/stores. */
MCode ins = *as->mcp, swp = (src^dst);
if ((ins & 0xbf800000) == 0xb9000000) {
if (!((ins ^ (dst << 5)) & 0x000003e0))
*as->mcp = ins ^ (swp << 5); /* Swap N in load/store. */
if (!(ins & 0x00400000) && !((ins ^ dst) & 0x0000001f))
*as->mcp = ins ^ swp; /* Swap D in store. */
}
}
emit_dm(as, A64I_MOVx, 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_lso(as, irt_isnum(ir->t) ? A64I_LDRd : A64I_LDRs, (r & 31), base, ofs);
else
emit_lso(as, irt_is64(ir->t) ? A64I_LDRx : A64I_LDRw, r, 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_lso(as, irt_isnum(ir->t) ? A64I_STRd : A64I_STRs, (r & 31), base, ofs);
else
emit_lso(as, irt_is64(ir->t) ? A64I_STRx : A64I_STRw, r, base, ofs);
}
/* Emit an arithmetic operation with a constant operand. */
static void emit_opk(ASMState *as, A64Ins ai, Reg dest, Reg src,
int32_t i, RegSet allow)
{
uint32_t k = emit_isk12(i);
if (k)
emit_dn(as, ai^k, dest, src);
else
emit_dnm(as, ai, dest, src, ra_allock(as, i, allow));
}
/* Add offset to pointer. */
static void emit_addptr(ASMState *as, Reg r, int32_t ofs)
{
if (ofs)
emit_opk(as, ofs < 0 ? A64I_SUBx : A64I_ADDx, r, r,
ofs < 0 ? (int32_t)(~(uint32_t)ofs+1u) : ofs,
rset_exclude(RSET_GPR, r));
}
#define emit_spsub(as, ofs) emit_addptr(as, RID_SP, -(ofs))