/* ** SPLIT: Split 64 bit IR instructions into 32 bit IR instructions. ** Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h */ #define lj_opt_split_c #define LUA_CORE #include "lj_obj.h" #if LJ_HASJIT && (LJ_SOFTFP || (LJ_32 && LJ_HASFFI)) #include "lj_err.h" #include "lj_str.h" #include "lj_ir.h" #include "lj_jit.h" #include "lj_ircall.h" #include "lj_iropt.h" #include "lj_vm.h" /* SPLIT pass: ** ** This pass splits up 64 bit IR instructions into multiple 32 bit IR ** instructions. It's only active for soft-float targets or for 32 bit CPUs ** which lack native 64 bit integer operations (the FFI is currently the ** only emitter for 64 bit integer instructions). ** ** Splitting the IR in a separate pass keeps each 32 bit IR assembler ** backend simple. Only a small amount of extra functionality needs to be ** implemented. This is much easier than adding support for allocating ** register pairs to each backend (believe me, I tried). A few simple, but ** important optimizations can be performed by the SPLIT pass, which would ** be tedious to do in the backend. ** ** The basic idea is to replace each 64 bit IR instruction with its 32 bit ** equivalent plus an extra HIOP instruction. The splitted IR is not passed ** through FOLD or any other optimizations, so each HIOP is guaranteed to ** immediately follow it's counterpart. The actual functionality of HIOP is ** inferred from the previous instruction. ** ** The operands of HIOP hold the hiword input references. The output of HIOP ** is the hiword output reference, which is also used to hold the hiword ** register or spill slot information. The register allocator treats this ** instruction independently of any other instruction, which improves code ** quality compared to using fixed register pairs. ** ** It's easier to split up some instructions into two regular 32 bit ** instructions. E.g. XLOAD is split up into two XLOADs with two different ** addresses. Obviously 64 bit constants need to be split up into two 32 bit ** constants, too. Some hiword instructions can be entirely omitted, e.g. ** when zero-extending a 32 bit value to 64 bits. 64 bit arguments for calls ** are split up into two 32 bit arguments each. ** ** On soft-float targets, floating-point instructions are directly converted ** to soft-float calls by the SPLIT pass (except for comparisons and MIN/MAX). ** HIOP for number results has the type IRT_SOFTFP ("sfp" in -jdump). ** ** Here's the IR and x64 machine code for 'x.b = x.a + 1' for a struct with ** two int64_t fields: ** ** 0100 p32 ADD base +8 ** 0101 i64 XLOAD 0100 ** 0102 i64 ADD 0101 +1 ** 0103 p32 ADD base +16 ** 0104 i64 XSTORE 0103 0102 ** ** mov rax, [esi+0x8] ** add rax, +0x01 ** mov [esi+0x10], rax ** ** Here's the transformed IR and the x86 machine code after the SPLIT pass: ** ** 0100 p32 ADD base +8 ** 0101 int XLOAD 0100 ** 0102 p32 ADD base +12 ** 0103 int XLOAD 0102 ** 0104 int ADD 0101 +1 ** 0105 int HIOP 0103 +0 ** 0106 p32 ADD base +16 ** 0107 int XSTORE 0106 0104 ** 0108 int HIOP 0106 0105 ** ** mov eax, [esi+0x8] ** mov ecx, [esi+0xc] ** add eax, +0x01 ** adc ecx, +0x00 ** mov [esi+0x10], eax ** mov [esi+0x14], ecx ** ** You may notice the reassociated hiword address computation, which is ** later fused into the mov operands by the assembler. */ /* Some local macros to save typing. Undef'd at the end. */ #define IR(ref) (&J->cur.ir[(ref)]) /* Directly emit the transformed IR without updating chains etc. */ static IRRef split_emit(jit_State *J, uint16_t ot, IRRef1 op1, IRRef1 op2) { IRRef nref = lj_ir_nextins(J); IRIns *ir = IR(nref); ir->ot = ot; ir->op1 = op1; ir->op2 = op2; return nref; } #if LJ_SOFTFP /* Emit a (checked) number to integer conversion. */ static IRRef split_num2int(jit_State *J, IRRef lo, IRRef hi, int check) { IRRef tmp, res; #if LJ_LE tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), lo, hi); #else tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hi, lo); #endif res = split_emit(J, IRTI(IR_CALLN), tmp, IRCALL_softfp_d2i); if (check) { tmp = split_emit(J, IRTI(IR_CALLN), res, IRCALL_softfp_i2d); split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); split_emit(J, IRTGI(IR_EQ), tmp, lo); split_emit(J, IRTG(IR_HIOP, IRT_SOFTFP), tmp+1, hi); } return res; } /* Emit a CALLN with one split 64 bit argument. */ static IRRef split_call_l(jit_State *J, IRRef1 *hisubst, IRIns *oir, IRIns *ir, IRCallID id) { IRRef tmp, op1 = ir->op1; J->cur.nins--; #if LJ_LE tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); #else tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); #endif ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); return split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); } /* Emit a CALLN with one split 64 bit argument and a 32 bit argument. */ static IRRef split_call_li(jit_State *J, IRRef1 *hisubst, IRIns *oir, IRIns *ir, IRCallID id) { IRRef tmp, op1 = ir->op1, op2 = ir->op2; J->cur.nins--; #if LJ_LE tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); #else tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); #endif tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); return split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); } #endif /* Emit a CALLN with two split 64 bit arguments. */ static IRRef split_call_ll(jit_State *J, IRRef1 *hisubst, IRIns *oir, IRIns *ir, IRCallID id) { IRRef tmp, op1 = ir->op1, op2 = ir->op2; J->cur.nins--; #if LJ_LE tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, hisubst[op2]); #else tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, hisubst[op2]); tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, oir[op2].prev); #endif ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, id); return split_emit(J, IRT(IR_HIOP, (LJ_SOFTFP && irt_isnum(ir->t)) ? IRT_SOFTFP : IRT_INT), tmp, tmp); } /* Get a pointer to the other 32 bit word (LE: hiword, BE: loword). */ static IRRef split_ptr(jit_State *J, IRIns *oir, IRRef ref) { IRRef nref = oir[ref].prev; IRIns *ir = IR(nref); int32_t ofs = 4; if (ir->o == IR_KPTR) return lj_ir_kptr(J, (char *)ir_kptr(ir) + ofs); if (ir->o == IR_ADD && irref_isk(ir->op2) && !irt_isphi(oir[ref].t)) { /* Reassociate address. */ ofs += IR(ir->op2)->i; nref = ir->op1; if (ofs == 0) return nref; } return split_emit(J, IRTI(IR_ADD), nref, lj_ir_kint(J, ofs)); } /* Substitute references of a snapshot. */ static void split_subst_snap(jit_State *J, SnapShot *snap, IRIns *oir) { SnapEntry *map = &J->cur.snapmap[snap->mapofs]; MSize n, nent = snap->nent; for (n = 0; n < nent; n++) { SnapEntry sn = map[n]; IRIns *ir = &oir[snap_ref(sn)]; if (!(LJ_SOFTFP && (sn & SNAP_SOFTFPNUM) && irref_isk(snap_ref(sn)))) map[n] = ((sn & 0xffff0000) | ir->prev); } } /* Transform the old IR to the new IR. */ static void split_ir(jit_State *J) { IRRef nins = J->cur.nins, nk = J->cur.nk; MSize irlen = nins - nk; MSize need = (irlen+1)*(sizeof(IRIns) + sizeof(IRRef1)); IRIns *oir = (IRIns *)lj_str_needbuf(J->L, &G(J->L)->tmpbuf, need); IRRef1 *hisubst; IRRef ref, snref; SnapShot *snap; /* Copy old IR to buffer. */ memcpy(oir, IR(nk), irlen*sizeof(IRIns)); /* Bias hiword substitution table and old IR. Loword kept in field prev. */ hisubst = (IRRef1 *)&oir[irlen] - nk; oir -= nk; /* Remove all IR instructions, but retain IR constants. */ J->cur.nins = REF_FIRST; J->loopref = 0; /* Process constants and fixed references. */ for (ref = nk; ref <= REF_BASE; ref++) { IRIns *ir = &oir[ref]; if ((LJ_SOFTFP && ir->o == IR_KNUM) || ir->o == IR_KINT64) { /* Split up 64 bit constant. */ TValue tv = *ir_k64(ir); ir->prev = lj_ir_kint(J, (int32_t)tv.u32.lo); hisubst[ref] = lj_ir_kint(J, (int32_t)tv.u32.hi); } else { ir->prev = ref; /* Identity substitution for loword. */ hisubst[ref] = 0; } } /* Process old IR instructions. */ snap = J->cur.snap; snref = snap->ref; for (ref = REF_FIRST; ref < nins; ref++) { IRIns *ir = &oir[ref]; IRRef nref = lj_ir_nextins(J); IRIns *nir = IR(nref); IRRef hi = 0; if (ref >= snref) { snap->ref = nref; split_subst_snap(J, snap++, oir); snref = snap < &J->cur.snap[J->cur.nsnap] ? snap->ref : ~(IRRef)0; } /* Copy-substitute old instruction to new instruction. */ nir->op1 = ir->op1 < nk ? ir->op1 : oir[ir->op1].prev; nir->op2 = ir->op2 < nk ? ir->op2 : oir[ir->op2].prev; ir->prev = nref; /* Loword substitution. */ nir->o = ir->o; nir->t.irt = ir->t.irt & ~(IRT_MARK|IRT_ISPHI); hisubst[ref] = 0; /* Split 64 bit instructions. */ #if LJ_SOFTFP if (irt_isnum(ir->t)) { nir->t.irt = IRT_INT | (nir->t.irt & IRT_GUARD); /* Turn into INT op. */ /* Note: hi ref = lo ref + 1! Required for SNAP_SOFTFPNUM logic. */ switch (ir->o) { case IR_ADD: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_add); break; case IR_SUB: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_sub); break; case IR_MUL: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_mul); break; case IR_DIV: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_softfp_div); break; case IR_POW: hi = split_call_li(J, hisubst, oir, ir, IRCALL_lj_vm_powi); break; case IR_FPMATH: /* Try to rejoin pow from EXP2, MUL and LOG2. */ if (nir->op2 == IRFPM_EXP2 && nir->op1 > J->loopref) { IRIns *irp = IR(nir->op1); if (irp->o == IR_CALLN && irp->op2 == IRCALL_softfp_mul) { IRIns *irm4 = IR(irp->op1); IRIns *irm3 = IR(irm4->op1); IRIns *irm12 = IR(irm3->op1); IRIns *irl1 = IR(irm12->op1); if (irm12->op1 > J->loopref && irl1->o == IR_CALLN && irl1->op2 == IRCALL_lj_vm_log2) { IRRef tmp = irl1->op1; /* Recycle first two args from LOG2. */ IRRef arg3 = irm3->op2, arg4 = irm4->op2; J->cur.nins--; tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, arg3); tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), tmp, arg4); ir->prev = tmp = split_emit(J, IRTI(IR_CALLN), tmp, IRCALL_pow); hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), tmp, tmp); break; } } } hi = split_call_l(J, hisubst, oir, ir, IRCALL_lj_vm_floor + ir->op2); break; case IR_ATAN2: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_atan2); break; case IR_LDEXP: hi = split_call_li(J, hisubst, oir, ir, IRCALL_ldexp); break; case IR_NEG: case IR_ABS: nir->o = IR_CONV; /* Pass through loword. */ nir->op2 = (IRT_INT << 5) | IRT_INT; hi = split_emit(J, IRT(ir->o == IR_NEG ? IR_BXOR : IR_BAND, IRT_SOFTFP), hisubst[ir->op1], hisubst[ir->op2]); break; case IR_SLOAD: if ((nir->op2 & IRSLOAD_CONVERT)) { /* Convert from int to number. */ nir->op2 &= ~IRSLOAD_CONVERT; ir->prev = nref = split_emit(J, IRTI(IR_CALLN), nref, IRCALL_softfp_i2d); hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); break; } /* fallthrough */ case IR_ALOAD: case IR_HLOAD: case IR_ULOAD: case IR_VLOAD: case IR_STRTO: hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); break; case IR_XLOAD: { IRIns inslo = *nir; /* Save/undo the emit of the lo XLOAD. */ J->cur.nins--; hi = split_ptr(J, oir, ir->op1); /* Insert the hiref ADD. */ nref = lj_ir_nextins(J); nir = IR(nref); *nir = inslo; /* Re-emit lo XLOAD immediately before hi XLOAD. */ hi = split_emit(J, IRT(IR_XLOAD, IRT_SOFTFP), hi, ir->op2); #if LJ_LE ir->prev = nref; #else ir->prev = hi; hi = nref; #endif break; } case IR_ASTORE: case IR_HSTORE: case IR_USTORE: case IR_XSTORE: split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nir->op1, hisubst[ir->op2]); break; case IR_CONV: { /* Conversion to number. Others handled below. */ IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); UNUSED(st); #if LJ_32 && LJ_HASFFI if (st == IRT_I64 || st == IRT_U64) { hi = split_call_l(J, hisubst, oir, ir, st == IRT_I64 ? IRCALL_fp64_l2d : IRCALL_fp64_ul2d); break; } #endif lua_assert(st == IRT_INT || (LJ_32 && LJ_HASFFI && (st == IRT_U32 || st == IRT_FLOAT))); nir->o = IR_CALLN; #if LJ_32 && LJ_HASFFI nir->op2 = st == IRT_INT ? IRCALL_softfp_i2d : st == IRT_FLOAT ? IRCALL_softfp_f2d : IRCALL_softfp_ui2d; #else nir->op2 = IRCALL_softfp_i2d; #endif hi = split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); break; } case IR_CALLN: case IR_CALLL: case IR_CALLS: case IR_CALLXS: goto split_call; case IR_PHI: if (nir->op1 == nir->op2) J->cur.nins--; /* Drop useless PHIs. */ if (hisubst[ir->op1] != hisubst[ir->op2]) split_emit(J, IRT(IR_PHI, IRT_SOFTFP), hisubst[ir->op1], hisubst[ir->op2]); break; case IR_HIOP: J->cur.nins--; /* Drop joining HIOP. */ ir->prev = nir->op1; hi = nir->op2; break; default: lua_assert(ir->o <= IR_NE || ir->o == IR_MIN || ir->o == IR_MAX); hi = split_emit(J, IRTG(IR_HIOP, IRT_SOFTFP), hisubst[ir->op1], hisubst[ir->op2]); break; } } else #endif #if LJ_32 && LJ_HASFFI if (irt_isint64(ir->t)) { IRRef hiref = hisubst[ir->op1]; nir->t.irt = IRT_INT | (nir->t.irt & IRT_GUARD); /* Turn into INT op. */ switch (ir->o) { case IR_ADD: case IR_SUB: /* Use plain op for hiword if loword cannot produce a carry/borrow. */ if (irref_isk(nir->op2) && IR(nir->op2)->i == 0) { ir->prev = nir->op1; /* Pass through loword. */ nir->op1 = hiref; nir->op2 = hisubst[ir->op2]; hi = nref; break; } /* fallthrough */ case IR_NEG: hi = split_emit(J, IRTI(IR_HIOP), hiref, hisubst[ir->op2]); break; case IR_MUL: hi = split_call_ll(J, hisubst, oir, ir, IRCALL_lj_carith_mul64); break; case IR_DIV: hi = split_call_ll(J, hisubst, oir, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_divi64 : IRCALL_lj_carith_divu64); break; case IR_MOD: hi = split_call_ll(J, hisubst, oir, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_modi64 : IRCALL_lj_carith_modu64); break; case IR_POW: hi = split_call_ll(J, hisubst, oir, ir, irt_isi64(ir->t) ? IRCALL_lj_carith_powi64 : IRCALL_lj_carith_powu64); break; case IR_FLOAD: lua_assert(ir->op2 == IRFL_CDATA_INT64); hi = split_emit(J, IRTI(IR_FLOAD), nir->op1, IRFL_CDATA_INT64_4); #if LJ_BE ir->prev = hi; hi = nref; #endif break; case IR_XLOAD: hi = split_emit(J, IRTI(IR_XLOAD), split_ptr(J, oir, ir->op1), ir->op2); #if LJ_BE ir->prev = hi; hi = nref; #endif break; case IR_XSTORE: split_emit(J, IRTI(IR_HIOP), nir->op1, hisubst[ir->op2]); break; case IR_CONV: { /* Conversion to 64 bit integer. Others handled below. */ IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); #if LJ_SOFTFP if (st == IRT_NUM) { /* NUM to 64 bit int conv. */ hi = split_call_l(J, hisubst, oir, ir, irt_isi64(ir->t) ? IRCALL_fp64_d2l : IRCALL_fp64_d2ul); } else if (st == IRT_FLOAT) { /* FLOAT to 64 bit int conv. */ nir->o = IR_CALLN; nir->op2 = irt_isi64(ir->t) ? IRCALL_fp64_f2l : IRCALL_fp64_f2ul; hi = split_emit(J, IRTI(IR_HIOP), nref, nref); } #else if (st == IRT_NUM || st == IRT_FLOAT) { /* FP to 64 bit int conv. */ hi = split_emit(J, IRTI(IR_HIOP), nir->op1, nref); } #endif else if (st == IRT_I64 || st == IRT_U64) { /* 64/64 bit cast. */ /* Drop cast, since assembler doesn't care. But fwd both parts. */ hi = hiref; goto fwdlo; } else if ((ir->op2 & IRCONV_SEXT)) { /* Sign-extend to 64 bit. */ IRRef k31 = lj_ir_kint(J, 31); nir = IR(nref); /* May have been reallocated. */ ir->prev = nir->op1; /* Pass through loword. */ nir->o = IR_BSAR; /* hi = bsar(lo, 31). */ nir->op2 = k31; hi = nref; } else { /* Zero-extend to 64 bit. */ hi = lj_ir_kint(J, 0); goto fwdlo; } break; } case IR_CALLXS: goto split_call; case IR_PHI: { IRRef hiref2; if ((irref_isk(nir->op1) && irref_isk(nir->op2)) || nir->op1 == nir->op2) J->cur.nins--; /* Drop useless PHIs. */ hiref2 = hisubst[ir->op2]; if (!((irref_isk(hiref) && irref_isk(hiref2)) || hiref == hiref2)) split_emit(J, IRTI(IR_PHI), hiref, hiref2); break; } case IR_HIOP: J->cur.nins--; /* Drop joining HIOP. */ ir->prev = nir->op1; hi = nir->op2; break; default: lua_assert(ir->o <= IR_NE); /* Comparisons. */ split_emit(J, IRTGI(IR_HIOP), hiref, hisubst[ir->op2]); break; } } else #endif #if LJ_SOFTFP if (ir->o == IR_SLOAD) { if ((nir->op2 & IRSLOAD_CONVERT)) { /* Convert from number to int. */ nir->op2 &= ~IRSLOAD_CONVERT; if (!(nir->op2 & IRSLOAD_TYPECHECK)) nir->t.irt = IRT_INT; /* Drop guard. */ split_emit(J, IRT(IR_HIOP, IRT_SOFTFP), nref, nref); ir->prev = split_num2int(J, nref, nref+1, irt_isguard(ir->t)); } } else if (ir->o == IR_TOBIT) { IRRef tmp, op1 = ir->op1; J->cur.nins--; #if LJ_LE tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), oir[op1].prev, hisubst[op1]); #else tmp = split_emit(J, IRT(IR_CARG, IRT_NIL), hisubst[op1], oir[op1].prev); #endif ir->prev = split_emit(J, IRTI(IR_CALLN), tmp, IRCALL_lj_vm_tobit); } else if (ir->o == IR_TOSTR) { if (hisubst[ir->op1]) { if (irref_isk(ir->op1)) nir->op1 = ir->op1; else split_emit(J, IRT(IR_HIOP, IRT_NIL), hisubst[ir->op1], nref); } } else if (ir->o == IR_HREF || ir->o == IR_NEWREF) { if (irref_isk(ir->op2) && hisubst[ir->op2]) nir->op2 = ir->op2; } else #endif if (ir->o == IR_CONV) { /* See above, too. */ IRType st = (IRType)(ir->op2 & IRCONV_SRCMASK); #if LJ_32 && LJ_HASFFI if (st == IRT_I64 || st == IRT_U64) { /* Conversion from 64 bit int. */ #if LJ_SOFTFP if (irt_isfloat(ir->t)) { split_call_l(J, hisubst, oir, ir, st == IRT_I64 ? IRCALL_fp64_l2f : IRCALL_fp64_ul2f); J->cur.nins--; /* Drop unused HIOP. */ } #else if (irt_isfp(ir->t)) { /* 64 bit integer to FP conversion. */ ir->prev = split_emit(J, IRT(IR_HIOP, irt_type(ir->t)), hisubst[ir->op1], nref); } #endif else { /* Truncate to lower 32 bits. */ fwdlo: ir->prev = nir->op1; /* Forward loword. */ /* Replace with NOP to avoid messing up the snapshot logic. */ nir->ot = IRT(IR_NOP, IRT_NIL); nir->op1 = nir->op2 = 0; } } #endif #if LJ_SOFTFP && LJ_32 && LJ_HASFFI else if (irt_isfloat(ir->t)) { if (st == IRT_NUM) { split_call_l(J, hisubst, oir, ir, IRCALL_softfp_d2f); J->cur.nins--; /* Drop unused HIOP. */ } else { nir->o = IR_CALLN; nir->op2 = st == IRT_INT ? IRCALL_softfp_i2f : IRCALL_softfp_ui2f; } } else if (st == IRT_FLOAT) { nir->o = IR_CALLN; nir->op2 = irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui; } else #endif #if LJ_SOFTFP if (st == IRT_NUM || (LJ_32 && LJ_HASFFI && st == IRT_FLOAT)) { if (irt_isguard(ir->t)) { lua_assert(st == IRT_NUM && irt_isint(ir->t)); J->cur.nins--; ir->prev = split_num2int(J, nir->op1, hisubst[ir->op1], 1); } else { split_call_l(J, hisubst, oir, ir, #if LJ_32 && LJ_HASFFI st == IRT_NUM ? (irt_isint(ir->t) ? IRCALL_softfp_d2i : IRCALL_softfp_d2ui) : (irt_isint(ir->t) ? IRCALL_softfp_f2i : IRCALL_softfp_f2ui) #else IRCALL_softfp_d2i #endif ); J->cur.nins--; /* Drop unused HIOP. */ } } #endif } else if (ir->o == IR_CALLXS) { IRRef hiref; split_call: hiref = hisubst[ir->op1]; if (hiref) { IROpT ot = nir->ot; IRRef op2 = nir->op2; nir->ot = IRT(IR_CARG, IRT_NIL); #if LJ_LE nir->op2 = hiref; #else nir->op2 = nir->op1; nir->op1 = hiref; #endif ir->prev = nref = split_emit(J, ot, nref, op2); } if (LJ_SOFTFP ? irt_is64(ir->t) : irt_isint64(ir->t)) hi = split_emit(J, IRT(IR_HIOP, (LJ_SOFTFP && irt_isnum(ir->t)) ? IRT_SOFTFP : IRT_INT), nref, nref); } else if (ir->o == IR_CARG) { IRRef hiref = hisubst[ir->op1]; if (hiref) { IRRef op2 = nir->op2; #if LJ_LE nir->op2 = hiref; #else nir->op2 = nir->op1; nir->op1 = hiref; #endif ir->prev = nref = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, op2); nir = IR(nref); } hiref = hisubst[ir->op2]; if (hiref) { #if !LJ_TARGET_X86 int carg = 0; IRIns *cir; for (cir = IR(nir->op1); cir->o == IR_CARG; cir = IR(cir->op1)) carg++; if ((carg & 1) == 0) { /* Align 64 bit arguments. */ IRRef op2 = nir->op2; nir->op2 = REF_NIL; nref = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, op2); nir = IR(nref); } #endif #if LJ_BE { IRRef tmp = nir->op2; nir->op2 = hiref; hiref = tmp; } #endif ir->prev = split_emit(J, IRT(IR_CARG, IRT_NIL), nref, hiref); } } else if (ir->o == IR_CNEWI) { if (hisubst[ir->op2]) split_emit(J, IRT(IR_HIOP, IRT_NIL), nref, hisubst[ir->op2]); } else if (ir->o == IR_LOOP) { J->loopref = nref; /* Needed by assembler. */ } hisubst[ref] = hi; /* Store hiword substitution. */ } if (snref == nins) { /* Substitution for last snapshot. */ snap->ref = J->cur.nins; split_subst_snap(J, snap, oir); } /* Add PHI marks. */ for (ref = J->cur.nins-1; ref >= REF_FIRST; ref--) { IRIns *ir = IR(ref); if (ir->o != IR_PHI) break; if (!irref_isk(ir->op1)) irt_setphi(IR(ir->op1)->t); if (ir->op2 > J->loopref) irt_setphi(IR(ir->op2)->t); } } /* Protected callback for split pass. */ static TValue *cpsplit(lua_State *L, lua_CFunction dummy, void *ud) { jit_State *J = (jit_State *)ud; split_ir(J); UNUSED(L); UNUSED(dummy); return NULL; } #if defined(LUA_USE_ASSERT) || LJ_SOFTFP /* Slow, but sure way to check whether a SPLIT pass is needed. */ static int split_needsplit(jit_State *J) { IRIns *ir, *irend; IRRef ref; for (ir = IR(REF_FIRST), irend = IR(J->cur.nins); ir < irend; ir++) if (LJ_SOFTFP ? irt_is64orfp(ir->t) : irt_isint64(ir->t)) return 1; if (LJ_SOFTFP) { for (ref = J->chain[IR_SLOAD]; ref; ref = IR(ref)->prev) if ((IR(ref)->op2 & IRSLOAD_CONVERT)) return 1; if (J->chain[IR_TOBIT]) return 1; } for (ref = J->chain[IR_CONV]; ref; ref = IR(ref)->prev) { IRType st = (IR(ref)->op2 & IRCONV_SRCMASK); if ((LJ_SOFTFP && (st == IRT_NUM || st == IRT_FLOAT)) || st == IRT_I64 || st == IRT_U64) return 1; } return 0; /* Nope. */ } #endif /* SPLIT pass. */ void lj_opt_split(jit_State *J) { #if LJ_SOFTFP if (!J->needsplit) J->needsplit = split_needsplit(J); #else lua_assert(J->needsplit >= split_needsplit(J)); /* Verify flag. */ #endif if (J->needsplit) { int errcode = lj_vm_cpcall(J->L, NULL, J, cpsplit); if (errcode) { /* Completely reset the trace to avoid inconsistent dump on abort. */ J->cur.nins = J->cur.nk = REF_BASE; J->cur.nsnap = 0; lj_err_throw(J->L, errcode); /* Propagate errors. */ } } } #undef IR #endif