#include "all.h" #include /* For x86_64, do the following: * * - check that constants are used only in * places allowed * - ensure immediates always fit in 32b * - expose machine register contraints * on instructions like division. * - implement fast locals (the streak of * constant allocX in the first basic block) * - recognize complex addressing modes * * Invariant: the use counts that are used * in sel() must be sound. This * is not so trivial, maybe the * dce should be moved out... */ typedef struct ANum ANum; struct ANum { char n, l, r; Ins *i; }; static int amatch(Addr *, Ref, int, ANum *, Fn *); static int noimm(Ref r, Fn *fn) { int64_t val; if (rtype(r) != RCon) return 0; switch (fn->con[r.val].type) { case CAddr: /* we only support the 'small' * code model of the ABI, this * means that we can always * address data with 32bits */ return 0; case CBits: val = fn->con[r.val].bits.i; return (val < INT32_MIN || val > INT32_MAX); default: die("invalid constant"); } } static int rslot(Ref r, Fn *fn) { if (rtype(r) != RTmp) return -1; return fn->tmp[r.val].slot; } static void fixarg(Ref *r, int k, Ins *i, Fn *fn) { char buf[32]; Addr a, *m; Con cc, *c; Ref r0, r1, r2, r3; int s, n, op; r1 = r0 = *r; s = rslot(r0, fn); op = i ? i->op : Ocopy; if (KBASE(k) == 1 && rtype(r0) == RCon) { /* load floating points from memory * slots, they can't be used as * immediates */ r1 = MEM(fn->nmem); vgrow(&fn->mem, ++fn->nmem); memset(&a, 0, sizeof a); a.offset.type = CAddr; n = stashbits(&fn->con[r0.val].bits, KWIDE(k) ? 8 : 4); sprintf(buf, "\"%sfp%d\"", T.asloc, n); a.offset.sym.id = intern(buf); fn->mem[fn->nmem-1] = a; } else if (op != Ocopy && k == Kl && noimm(r0, fn)) { /* load constants that do not fit in * a 32bit signed integer into a * long temporary */ r1 = newtmp("isel", Kl, fn); emit(Ocopy, Kl, r1, r0, R); } else if (s != -1) { /* load fast locals' addresses into * temporaries right before the * instruction */ r1 = newtmp("isel", Kl, fn); emit(Oaddr, Kl, r1, SLOT(s), R); } else if (!(isstore(op) && r == &i->arg[1]) && !isload(op) && op != Ocall && rtype(r0) == RCon && fn->con[r0.val].type == CAddr) { /* apple as does not support 32-bit * absolute addressing, use a rip- * relative leaq instead */ r1 = newtmp("isel", Kl, fn); emit(Oaddr, Kl, r1, r0, R); } else if (rtype(r0) == RMem) { /* eliminate memory operands of * the form $foo(%rip, ...) */ m = &fn->mem[r0.val]; if (req(m->base, R)) if (m->offset.type == CAddr) { r0 = newtmp("isel", Kl, fn); emit(Oaddr, Kl, r0, newcon(&m->offset, fn), R); m->offset.type = CUndef; m->base = r0; } } else if (T.apple && rtype(r0) == RCon && (c = &fn->con[r0.val])->type == CAddr && c->sym.type == SThr) { r1 = newtmp("isel", Kl, fn); if (c->bits.i) { r2 = newtmp("isel", Kl, fn); cc = (Con){.type = CBits}; cc.bits.i = c->bits.i; r3 = newcon(&cc, fn); emit(Oadd, Kl, r1, r2, r3); } else r2 = r1; emit(Ocopy, Kl, r2, TMP(RAX), R); r2 = newtmp("isel", Kl, fn); r3 = newtmp("isel", Kl, fn); emit(Ocall, 0, R, r3, CALL(17)); emit(Ocopy, Kl, TMP(RDI), r2, R); emit(Oload, Kl, r3, r2, R); cc = *c; cc.bits.i = 0; r3 = newcon(&cc, fn); emit(Oload, Kl, r2, r3, R); } *r = r1; } static void seladdr(Ref *r, ANum *an, Fn *fn) { Addr a; Ref r0; r0 = *r; if (rtype(r0) == RTmp) { memset(&a, 0, sizeof a); if (!amatch(&a, r0, an[r0.val].n, an, fn)) return; if (!req(a.base, R)) if (a.offset.type == CAddr) { /* apple as does not support * $foo(%r0, %r1, M); try to * rewrite it or bail out if * impossible */ if (!req(a.index, R) || rtype(a.base) != RTmp) return; else { a.index = a.base; a.scale = 1; a.base = R; } } chuse(r0, -1, fn); vgrow(&fn->mem, ++fn->nmem); fn->mem[fn->nmem-1] = a; chuse(a.base, +1, fn); chuse(a.index, +1, fn); *r = MEM(fn->nmem-1); } } static int cmpswap(Ref arg[2], int op) { switch (op) { case NCmpI+Cflt: case NCmpI+Cfle: return 1; case NCmpI+Cfgt: case NCmpI+Cfge: return 0; } return rtype(arg[0]) == RCon; } static void selcmp(Ref arg[2], int k, int swap, Fn *fn) { Ref r; Ins *icmp; if (swap) { r = arg[1]; arg[1] = arg[0]; arg[0] = r; } emit(Oxcmp, k, R, arg[1], arg[0]); icmp = curi; if (rtype(arg[0]) == RCon) { assert(k != Kw); icmp->arg[1] = newtmp("isel", k, fn); emit(Ocopy, k, icmp->arg[1], arg[0], R); fixarg(&curi->arg[0], k, curi, fn); } fixarg(&icmp->arg[0], k, icmp, fn); fixarg(&icmp->arg[1], k, icmp, fn); } static void sel(Ins i, ANum *an, Fn *fn) { Ref r0, r1, tmp[7]; int x, j, k, kc, sh, swap; Ins *i0, *i1; if (rtype(i.to) == RTmp) if (!isreg(i.to) && !isreg(i.arg[0]) && !isreg(i.arg[1])) if (fn->tmp[i.to.val].nuse == 0) { chuse(i.arg[0], -1, fn); chuse(i.arg[1], -1, fn); return; } i0 = curi; k = i.cls; switch (i.op) { case Odiv: case Orem: case Oudiv: case Ourem: if (KBASE(k) == 1) goto Emit; if (i.op == Odiv || i.op == Oudiv) r0 = TMP(RAX), r1 = TMP(RDX); else r0 = TMP(RDX), r1 = TMP(RAX); emit(Ocopy, k, i.to, r0, R); emit(Ocopy, k, R, r1, R); if (rtype(i.arg[1]) == RCon) { /* immediates not allowed for * divisions in x86 */ r0 = newtmp("isel", k, fn); } else r0 = i.arg[1]; if (fn->tmp[r0.val].slot != -1) err("unlikely argument %%%s in %s", fn->tmp[r0.val].name, optab[i.op].name); if (i.op == Odiv || i.op == Orem) { emit(Oxidiv, k, R, r0, R); emit(Osign, k, TMP(RDX), TMP(RAX), R); } else { emit(Oxdiv, k, R, r0, R); emit(Ocopy, k, TMP(RDX), CON_Z, R); } emit(Ocopy, k, TMP(RAX), i.arg[0], R); fixarg(&curi->arg[0], k, curi, fn); if (rtype(i.arg[1]) == RCon) emit(Ocopy, k, r0, i.arg[1], R); break; case Osar: case Oshr: case Oshl: r0 = i.arg[1]; if (rtype(r0) == RCon) goto Emit; if (fn->tmp[r0.val].slot != -1) err("unlikely argument %%%s in %s", fn->tmp[r0.val].name, optab[i.op].name); i.arg[1] = TMP(RCX); emit(Ocopy, Kw, R, TMP(RCX), R); emiti(i); i1 = curi; emit(Ocopy, Kw, TMP(RCX), r0, R); fixarg(&i1->arg[0], argcls(&i, 0), i1, fn); break; case Ouwtof: r0 = newtmp("utof", Kl, fn); emit(Osltof, k, i.to, r0, R); emit(Oextuw, Kl, r0, i.arg[0], R); fixarg(&curi->arg[0], k, curi, fn); break; case Oultof: /* %mask =l and %arg.0, 1 %isbig =l shr %arg.0, 63 %divided =l shr %arg.0, %isbig %or =l or %mask, %divided %float =d sltof %or %cast =l cast %float %addend =l shl %isbig, 52 %sum =l add %cast, %addend %result =d cast %sum */ r0 = newtmp("utof", k, fn); if (k == Ks) kc = Kw, sh = 23; else kc = Kl, sh = 52; for (j=0; j<4; j++) tmp[j] = newtmp("utof", Kl, fn); for (; j<7; j++) tmp[j] = newtmp("utof", kc, fn); emit(Ocast, k, i.to, tmp[6], R); emit(Oadd, kc, tmp[6], tmp[4], tmp[5]); emit(Oshl, kc, tmp[5], tmp[1], getcon(sh, fn)); emit(Ocast, kc, tmp[4], r0, R); emit(Osltof, k, r0, tmp[3], R); emit(Oor, Kl, tmp[3], tmp[0], tmp[2]); emit(Oshr, Kl, tmp[2], i.arg[0], tmp[1]); sel(*curi++, 0, fn); emit(Oshr, Kl, tmp[1], i.arg[0], getcon(63, fn)); fixarg(&curi->arg[0], Kl, curi, fn); emit(Oand, Kl, tmp[0], i.arg[0], getcon(1, fn)); fixarg(&curi->arg[0], Kl, curi, fn); break; case Ostoui: i.op = Ostosi; kc = Ks; tmp[4] = getcon(0xdf000000, fn); goto Oftoui; case Odtoui: i.op = Odtosi; kc = Kd; tmp[4] = getcon(0xc3e0000000000000, fn); Oftoui: if (k == Kw) goto Emit; r0 = newtmp("ftou", kc, fn); for (j=0; j<4; j++) tmp[j] = newtmp("ftou", Kl, fn); emit(Oor, Kl, i.to, tmp[0], tmp[3]); emit(Oand, Kl, tmp[3], tmp[2], tmp[1]); emit(i.op, Kl, tmp[2], r0, R); emit(Oadd, kc, r0, tmp[4], i.arg[0]); i1 = curi; /* fixarg() can change curi */ fixarg(&i1->arg[0], kc, i1, fn); fixarg(&i1->arg[1], kc, i1, fn); emit(Osar, Kl, tmp[1], tmp[0], getcon(63, fn)); emit(i.op, Kl, tmp[0], i.arg[0], R); fixarg(&curi->arg[0], Kl, curi, fn); break; case Onop: break; case Ostored: case Ostores: case Ostorel: case Ostorew: case Ostoreh: case Ostoreb: if (rtype(i.arg[0]) == RCon) { if (i.op == Ostored) i.op = Ostorel; if (i.op == Ostores) i.op = Ostorew; } seladdr(&i.arg[1], an, fn); goto Emit; case_Oload: seladdr(&i.arg[0], an, fn); goto Emit; case Ocall: case Osalloc: case Ocopy: case Oadd: case Osub: case Oneg: case Omul: case Oand: case Oor: case Oxor: case Oxtest: case Ostosi: case Odtosi: case Oswtof: case Osltof: case Oexts: case Otruncd: case Ocast: case_OExt: Emit: emiti(i); i1 = curi; /* fixarg() can change curi */ fixarg(&i1->arg[0], argcls(&i, 0), i1, fn); fixarg(&i1->arg[1], argcls(&i, 1), i1, fn); break; case Oalloc4: case Oalloc8: case Oalloc16: salloc(i.to, i.arg[0], fn); break; default: if (isext(i.op)) goto case_OExt; if (isload(i.op)) goto case_Oload; if (iscmp(i.op, &kc, &x)) { switch (x) { case NCmpI+Cfeq: /* zf is set when operands are * unordered, so we may have to * check pf */ r0 = newtmp("isel", Kw, fn); r1 = newtmp("isel", Kw, fn); emit(Oand, Kw, i.to, r0, r1); emit(Oflagfo, k, r1, R, R); i.to = r0; break; case NCmpI+Cfne: r0 = newtmp("isel", Kw, fn); r1 = newtmp("isel", Kw, fn); emit(Oor, Kw, i.to, r0, r1); emit(Oflagfuo, k, r1, R, R); i.to = r0; break; } swap = cmpswap(i.arg, x); if (swap) x = cmpop(x); emit(Oflag+x, k, i.to, R, R); selcmp(i.arg, kc, swap, fn); break; } die("unknown instruction %s", optab[i.op].name); } while (i0>curi && --i0) { assert(rslot(i0->arg[0], fn) == -1); assert(rslot(i0->arg[1], fn) == -1); } } static Ins * flagi(Ins *i0, Ins *i) { while (i>i0) { i--; if (amd64_op[i->op].zflag) return i; if (amd64_op[i->op].lflag) continue; return 0; } return 0; } static void seljmp(Blk *b, Fn *fn) { Ref r; int c, k, swap; Ins *fi; Tmp *t; if (b->jmp.type == Jret0 || b->jmp.type == Jjmp || b->jmp.type == Jhlt) return; assert(b->jmp.type == Jjnz); r = b->jmp.arg; t = &fn->tmp[r.val]; b->jmp.arg = R; assert(rtype(r) == RTmp); if (b->s1 == b->s2) { chuse(r, -1, fn); b->jmp.type = Jjmp; b->s2 = 0; return; } fi = flagi(b->ins, &b->ins[b->nins]); if (!fi || !req(fi->to, r)) { selcmp((Ref[2]){r, CON_Z}, Kw, 0, fn); b->jmp.type = Jjf + Cine; } else if (iscmp(fi->op, &k, &c) && c != NCmpI+Cfeq /* see sel() */ && c != NCmpI+Cfne) { swap = cmpswap(fi->arg, c); if (swap) c = cmpop(c); if (t->nuse == 1) { selcmp(fi->arg, k, swap, fn); *fi = (Ins){.op = Onop}; } b->jmp.type = Jjf + c; } else if (fi->op == Oand && t->nuse == 1 && (rtype(fi->arg[0]) == RTmp || rtype(fi->arg[1]) == RTmp)) { fi->op = Oxtest; fi->to = R; b->jmp.type = Jjf + Cine; if (rtype(fi->arg[1]) == RCon) { r = fi->arg[1]; fi->arg[1] = fi->arg[0]; fi->arg[0] = r; } } else { /* since flags are not tracked in liveness, * the result of the flag-setting instruction * has to be marked as live */ if (t->nuse == 1) emit(Ocopy, Kw, R, r, R); b->jmp.type = Jjf + Cine; } } static int aref(Ref r, ANum *ai) { switch (rtype(r)) { case RCon: return 2; case RTmp: return ai[r.val].n; default: die("constant or temporary expected"); } } static int ascale(Ref r, Con *con) { int64_t n; if (rtype(r) != RCon) return 0; if (con[r.val].type != CBits) return 0; n = con[r.val].bits.i; return n == 1 || n == 2 || n == 4 || n == 8; } static void anumber(ANum *ai, Blk *b, Con *con) { /* This should be made obsolete by a proper * reassoc pass. * * Rules: * * RTmp(_) -> 0 tmp * ( RTmp(_) -> 1 slot ) * RCon(_) -> 2 con * 0 * 2 -> 3 s * i (when constant is 1,2,4,8) */ static char add[10][10] = { [2] [4] = 4, [4] [2] = 4, [2] [6] = 6, [6] [2] = 6, [2] [7] = 7, [7] [2] = 7, [0] [2] = 4, [2] [0] = 4, /* 4: o + b */ [0] [0] = 5, /* 5: b + s * i */ [0] [3] = 5, [3] [0] = 5, [2] [3] = 6, [3] [2] = 6, /* 6: o + s * i */ [2] [5] = 7, [5] [2] = 7, /* 7: o + b + s * i */ [0] [6] = 7, [6] [0] = 7, [4] [3] = 7, [3] [4] = 7, }; int a, a1, a2, n1, n2, t1, t2; Ins *i; for (i=b->ins; i<&b->ins[b->nins]; i++) { if (rtype(i->to) == RTmp) ai[i->to.val].i = i; if (i->op != Oadd && i->op != Omul) continue; a1 = aref(i->arg[0], ai); a2 = aref(i->arg[1], ai); t1 = a1 != 1 && a1 != 2; t2 = a2 != 1 && a2 != 2; if (i->op == Oadd) { a = add[n1 = a1][n2 = a2]; if (t1 && a < add[0][a2]) a = add[n1 = 0][n2 = a2]; if (t2 && a < add[a1][0]) a = add[n1 = a1][n2 = 0]; if (t1 && t2 && a < add[0][0]) a = add[n1 = 0][n2 = 0]; } else { n1 = n2 = a = 0; if (ascale(i->arg[0], con) && t2) a = 3, n1 = 2, n2 = 0; if (t1 && ascale(i->arg[1], con)) a = 3, n1 = 0, n2 = 2; } ai[i->to.val].n = a; ai[i->to.val].l = n1; ai[i->to.val].r = n2; } } static int amatch(Addr *a, Ref r, int n, ANum *ai, Fn *fn) { Ins *i; int nl, nr, t, s; Ref al, ar; if (rtype(r) == RCon) { if (!addcon(&a->offset, &fn->con[r.val])) err("unlikely sum of $%s and $%s", str(a->offset.sym.id), str(fn->con[r.val].sym.id)); return 1; } assert(rtype(r) == RTmp); i = ai[r.val].i; nl = ai[r.val].l; nr = ai[r.val].r; if (i) { if (nl > nr) { al = i->arg[1]; ar = i->arg[0]; t = nl, nl = nr, nr = t; } else { al = i->arg[0]; ar = i->arg[1]; } } switch (n) { case 3: /* s * i */ a->index = al; a->scale = fn->con[ar.val].bits.i; return 0; case 5: /* b + s * i */ switch (nr) { case 0: if (fn->tmp[ar.val].slot != -1) { al = i->arg[1]; ar = i->arg[0]; } a->index = ar; a->scale = 1; break; case 3: amatch(a, ar, nr, ai, fn); break; } r = al; /* fall through */ case 0: s = fn->tmp[r.val].slot; if (s != -1) r = SLOT(s); a->base = r; return n || s != -1; case 2: /* constants */ case 4: /* o + b */ case 6: /* o + s * i */ case 7: /* o + b + s * i */ amatch(a, ar, nr, ai, fn); amatch(a, al, nl, ai, fn); return 1; default: die("unreachable"); } } /* instruction selection * requires use counts (as given by parsing) */ void amd64_isel(Fn *fn) { Blk *b, **sb; Ins *i; Phi *p; uint a; int n, al; int64_t sz; ANum *ainfo; /* assign slots to fast allocs */ b = fn->start; /* specific to NAlign == 3 */ /* or change n=4 and sz /= 4 below */ for (al=Oalloc, n=4; al<=Oalloc1; al++, n*=2) for (i=b->ins; i<&b->ins[b->nins]; i++) if (i->op == al) { if (rtype(i->arg[0]) != RCon) break; sz = fn->con[i->arg[0].val].bits.i; if (sz < 0 || sz >= INT_MAX-15) err("invalid alloc size %"PRId64, sz); sz = (sz + n-1) & -n; sz /= 4; if (sz > INT_MAX - fn->slot) die("alloc too large"); fn->tmp[i->to.val].slot = fn->slot; fn->slot += sz; *i = (Ins){.op = Onop}; } /* process basic blocks */ n = fn->ntmp; ainfo = emalloc(n * sizeof ainfo[0]); for (b=fn->start; b; b=b->link) { curi = &insb[NIns]; for (sb=(Blk*[3]){b->s1, b->s2, 0}; *sb; sb++) for (p=(*sb)->phi; p; p=p->link) { for (a=0; p->blk[a] != b; a++) assert(a+1 < p->narg); fixarg(&p->arg[a], p->cls, 0, fn); } memset(ainfo, 0, n * sizeof ainfo[0]); anumber(ainfo, b, fn->con); seljmp(b, fn); for (i=&b->ins[b->nins]; i!=b->ins;) sel(*--i, ainfo, fn); b->nins = &insb[NIns] - curi; idup(&b->ins, curi, b->nins); } free(ainfo); if (debug['I']) { fprintf(stderr, "\n> After instruction selection:\n"); printfn(fn, stderr); } }