#include "gc.h" void codgen(Node *n, Node *nn) { Prog *sp; argoff = 0; inargs = 0; for(;; nn = nn->left) { if(nn == Z) { diag(Z, "cant find function name"); return; } if(nn->op == ONAME) break; } nearln = nn->lineno; gpseudo(ATEXT, nn->sym, D_CONST, stkoff); sp = p; retok = 0; gen(n); if(!retok) if(thisfn->link->etype != TVOID) warn(Z, "no return at end of function: %s", nn->sym->name); noretval(3); gbranch(ORETURN); if(!debug['N'] || debug['R'] || debug['P']) regopt(sp); } void gen(Node *n) { Node *l; Prog *sp, *spc, *spb; Case *cn; long sbc, scc; int g, o; loop: if(n == Z) return; nearln = n->lineno; o = n->op; if(debug['G']) if(o != OLIST) print("%L %O\n", nearln, o); retok = 0; switch(o) { default: complex(n); doinc(n, PRE); cgen(n, D_NONE, n); doinc(n, POST); break; case OLIST: gen(n->left); rloop: n = n->right; goto loop; case ORETURN: retok = 1; complex(n); if(n->type == T) break; l = n->left; if(l == Z) { noretval(3); gbranch(ORETURN); break; } doinc(l, PRE); if(typesuv[n->type->etype]) { sugen(l, D_TREE, nodret, n->type->width); doinc(l, POST); noretval(3); gbranch(ORETURN); break; } g = regalloc(n->type, regret(n->type)); cgen(l, g, n); doinc(l, POST); if(typefd[n->type->etype]) noretval(1); else noretval(2); gbranch(ORETURN); regfree(g); break; case OLABEL: l = n->left; if(l) { l->xoffset = pc; if(l->label) patch(l->label, pc); } gbranch(OGOTO); /* prevent self reference in reg */ patch(p, pc); goto rloop; case OGOTO: retok = 1; n = n->left; if(n == Z) return; if(n->complex == 0) { diag(Z, "label undefined: %s", n->sym->name); return; } gbranch(OGOTO); if(n->xoffset) { patch(p, n->xoffset); return; } if(n->label) patch(n->label, pc-1); n->label = p; return; case OCASE: l = n->left; if(cases == C) diag(n, "case/default outside a switch"); if(l == Z) { cas(); cases->val = 0; cases->def = 1; cases->label = pc; setsp();; goto rloop; } complex(l); if(l->type == T) goto rloop; if(l->op == OCONST) if(typechl[l->type->etype]) { cas(); cases->val = l->vconst; cases->def = 0; cases->label = pc; setsp(); goto rloop; } diag(n, "case expression must be integer constant"); goto rloop; case OSWITCH: l = n->left; complex(l); doinc(l, PRE); if(l->type == T) break; if(!typechl[l->type->etype]) { diag(n, "switch expression must be integer"); break; } g = regalloc(types[TLONG], D_NONE); n->type = types[TLONG]; cgen(l, g, n); regfree(g); doinc(l, POST); setsp(); gbranch(OGOTO); /* entry */ sp = p; cn = cases; cases = C; cas(); sbc = breakpc; breakpc = pc; gbranch(OGOTO); spb = p; gen(n->right); gbranch(OGOTO); patch(p, breakpc); patch(sp, pc); doswit(g, l); patch(spb, pc); cases = cn; breakpc = sbc; setsp(); break; case OWHILE: case ODWHILE: l = n->left; gbranch(OGOTO); /* entry */ sp = p; scc = continpc; continpc = pc; gbranch(OGOTO); spc = p; sbc = breakpc; breakpc = pc; gbranch(OGOTO); spb = p; patch(spc, pc); if(n->op == OWHILE) patch(sp, pc); bcomplex(l); /* test */ patch(p, breakpc); if(n->op == ODWHILE) patch(sp, pc); gen(n->right); /* body */ gbranch(OGOTO); patch(p, continpc); patch(spb, pc); continpc = scc; breakpc = sbc; break; case OFOR: l = n->left; gen(l->right->left); /* init */ gbranch(OGOTO); /* entry */ sp = p; scc = continpc; continpc = pc; gbranch(OGOTO); spc = p; sbc = breakpc; breakpc = pc; gbranch(OGOTO); spb = p; patch(spc, pc); gen(l->right->right); /* inc */ patch(sp, pc); if(l->left != Z) { /* test */ bcomplex(l->left); patch(p, breakpc); } gen(n->right); /* body */ gbranch(OGOTO); patch(p, continpc); patch(spb, pc); continpc = scc; breakpc = sbc; break; case OCONTINUE: if(continpc < 0) { diag(n, "continue not in a loop"); break; } gbranch(OGOTO); patch(p, continpc); break; case OBREAK: if(breakpc < 0) { diag(n, "break not in a loop"); break; } gbranch(OGOTO); patch(p, breakpc); break; case OIF: l = n->left; bcomplex(l); sp = p; if(n->right->left != Z) gen(n->right->left); if(n->right->right != Z) { gbranch(OGOTO); patch(sp, pc); sp = p; gen(n->right->right); } patch(sp, pc); break; case OSET: case OUSED: usedset(n->left, o); break; } } void usedset(Node *n, int o) { if(n->op == OLIST) { usedset(n->left, o); usedset(n->right, o); return; } complex(n); switch(n->op) { case OADDR: /* volatile */ gopcode(OTST, types[TINT], D_TREE, n, D_NONE, Z); p->as = ANOP; break; case ONAME: if(o == OSET) gopcode(OTST, types[TINT], D_NONE, Z, D_TREE, n); else gopcode(OTST, types[TINT], D_TREE, n, D_NONE, Z); p->as = ANOP; break; } } void noretval(int n) { if(n & 1) { gopcode(OTST, types[TINT], D_NONE, Z, regret(types[TLONG]), Z); p->as = ANOP; } if(n & 2) { gopcode(OTST, types[TINT], D_NONE, Z, regret(types[TDOUBLE]), Z); p->as = ANOP; } } /* * calculate addressability as follows * REGISTER ==> 12 register * NAME ==> 11 name+value(SB/SP) * note that 10 is no longer generated * CONST ==> 20 $value * *(20) ==> 21 value * &(10) ==> 12 $name+value(SB) * &(11) ==> 1 $name+value(SP) * (12) + (20) ==> 12 fold constants * (1) + (20) ==> 1 fold constants * *(12) ==> 10 back to name * *(1) ==> 11 back to name * * (2,10,11) + (20) ==> 2 indirect w offset * (2) ==> &13 * *(10,11) ==> 13 indirect, no index * * (20) * (X) ==> 7 multiplier in indexing * (X,7) + (12,1) ==> 8 adder in indexing (addresses) * (X,7) + (10,11,2) ==> 8 adder in indexing (names) * (8) ==> &9 index, almost addressable * * (X)++ ==> X fake addressability * * calculate complexity (number of registers) */ void xcom(Node *n) { Node *l, *r; int g; if(n == Z) return; l = n->left; r = n->right; n->complex = 0; n->addable = 0; switch(n->op) { case OCONST: n->addable = 20; break; case ONAME: n->addable = 11; /* difference to make relocatable */ break; case OREGISTER: n->addable = 12; break; case OADDR: xcom(l); if(l->addable == 10) n->addable = 12; else if(l->addable == 11) n->addable = 1; break; case OADD: xcom(l); xcom(r); if(n->type->etype != TIND) break; if(l->addable == 20) switch(r->addable) { case 12: case 1: n->addable = r->addable; goto brk; } if(r->addable == 20) switch(l->addable) { case 12: case 1: n->addable = l->addable; goto brk; } break; case OIND: xcom(l); if(l->op == OADDR) { l = l->left; l->type = n->type; *n = *l; return; } switch(l->addable) { case 20: n->addable = 21; break; case 1: n->addable = 11; break; case 12: n->addable = 10; break; } break; case OASHL: xcom(l); xcom(r); if(typev[n->type->etype]) break; g = vconst(r); if(g >= 0 && g < 4) n->addable = 7; break; case OMUL: case OLMUL: xcom(l); xcom(r); if(typev[n->type->etype]) break; g = vlog(r); if(g >= 0) { n->op = OASHL; r->vconst = g; if(g < 4) n->addable = 7; break; } g = vlog(l); if(g >= 0) { n->left = r; n->right = l; l = r; r = n->right; n->op = OASHL; r->vconst = g; if(g < 4) n->addable = 7; break; } break; case ODIV: case OLDIV: xcom(l); xcom(r); if(typev[n->type->etype]) break; g = vlog(r); if(g >= 0) { if(n->op == ODIV) n->op = OASHR; else n->op = OLSHR; r->vconst = g; } break; case OSUB: xcom(l); xcom(r); if(typev[n->type->etype]) break; if(vconst(l) == 0) { n->op = ONEG; n->left = r; n->right = Z; } break; case OXOR: xcom(l); xcom(r); if(typev[n->type->etype]) break; if(vconst(l) == -1) { n->op = OCOM; n->left = r; n->right = Z; } break; case OASMUL: case OASLMUL: xcom(l); xcom(r); if(typev[n->type->etype]) break; g = vlog(r); if(g >= 0) { n->op = OASASHL; r->vconst = g; } goto aseae; case OASDIV: case OASLDIV: xcom(l); xcom(r); if(typev[n->type->etype]) break; g = vlog(r); if(g >= 0) { if(n->op == OASDIV) n->op = OASASHR; else n->op = OASLSHR; r->vconst = g; } goto aseae; case OASLMOD: case OASMOD: xcom(l); xcom(r); if(typev[n->type->etype]) break; aseae: /* hack that there are no byte/short mul/div operators */ if(n->type->etype == TCHAR || n->type->etype == TSHORT) { n->right = new1(OCAST, n->right, Z); n->right->type = types[TLONG]; n->type = types[TLONG]; } if(n->type->etype == TUCHAR || n->type->etype == TUSHORT) { n->right = new1(OCAST, n->right, Z); n->right->type = types[TULONG]; n->type = types[TULONG]; } goto asop; case OASXOR: case OASOR: case OASADD: case OASSUB: case OASLSHR: case OASASHR: case OASASHL: case OASAND: case OAS: xcom(l); xcom(r); if(typev[n->type->etype]) break; asop: if(l->addable > INDEXED && l->complex < FNX && r && r->complex < FNX) n->addable = l->addable; break; case OPOSTINC: case OPREINC: case OPOSTDEC: case OPREDEC: xcom(l); if(typev[n->type->etype]) break; if(l->addable > INDEXED && l->complex < FNX) n->addable = l->addable; break; default: if(l != Z) xcom(l); if(r != Z) xcom(r); break; } brk: n->complex = 0; if(n->addable >= 10) return; if(l != Z) n->complex = l->complex; if(r != Z) { if(r->complex == n->complex) n->complex = r->complex+1; else if(r->complex > n->complex) n->complex = r->complex; } if(n->complex == 0) n->complex++; if(com64(n)) return; switch(n->op) { case OFUNC: n->complex = FNX; break; case OADD: case OMUL: case OLMUL: case OXOR: case OAND: case OOR: /* * symmetric operators, make right side simple * if same, put constant on left to get movq */ if(r->complex > l->complex || (r->complex == l->complex && r->addable == 20)) { n->left = r; n->right = l; } break; case OLE: case OLT: case OGE: case OGT: case OEQ: case ONE: /* * relational operators, make right side simple * if same, put constant on left to get movq */ if(r->complex > l->complex || r->addable == 20) { n->left = r; n->right = l; n->op = invrel[relindex(n->op)]; } break; } } void bcomplex(Node *n) { complex(n); if(n->type != T) if(tcompat(n, T, n->type, tnot)) n->type = T; if(n->type != T) { bool64(n); doinc(n, PRE); boolgen(n, 1, D_NONE, Z, n); } else gbranch(OGOTO); } Node* nodconst(long v) { return (Node*)v; }