ref: 7937358e3e356a62b5c52b67bc1f1daf32924a02
dir: /mi/flatten.c/
#include <stdlib.h> #include <stdio.h> #include <stdarg.h> #include <inttypes.h> #include <ctype.h> #include <string.h> #include <assert.h> #include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> #include <unistd.h> #include "util.h" #include "parse.h" #include "mi.h" #include "../config.h" typedef struct Flattenctx Flattenctx; typedef struct Loop Loop; struct Loop { Node *lcnt; Node *lbrk; Stab *body; }; /* takes a list of nodes, and reduces it (and it's subnodes) to a list * following these constraints: * - All nodes are expression node * - Nodes with side effects are root node * - All nodes operate on machine-primitive types and tuple */ struct Flattenctx { int isglobl; Node **stmts; size_t nstmts; /* return handling */ Node *tret; /* pre/postinc handling */ Node **incqueue; size_t nqueue; /* break/continue handling */ Loop loop; unsigned inloop; Stab *curst; /* location handling */ Htab *globls; size_t stksz; }; static Node *flatten(Flattenctx *s, Node *n); static Node *rval(Flattenctx *s, Node *n); static Node *lval(Flattenctx *s, Node *n); static Node *assign(Flattenctx *s, Node *lhs, Node *rhs); static void append(Flattenctx *s, Node *n) { if (debugopt['F']) dump(n, stdout); lappend(&s->stmts, &s->nstmts, n); } static void cjmp(Flattenctx *s, Node *cond, Node *iftrue, Node *iffalse) { Node *jmp; jmp = mkexpr(cond->loc, Ocjmp, cond, iftrue, iffalse, NULL); jmp->expr.type = mktype(cond->loc, Tyvoid); append(s, jmp); } static void jmp(Flattenctx *s, Node *lbl) { Node *n; n = mkexpr(lbl->loc, Ojmp, lbl, NULL); n->expr.type = mktype(n->loc, Tyvoid); append(s, n); } static Node * asn(Node *a, Node *b) { Node *n; assert(a != NULL && b != NULL); if (tybase(exprtype(a))->type == Tyvoid) return a; n = mkexpr(a->loc, Oasn, a, b, NULL); n->expr.type = exprtype(a); return n; } static int islbl(Node *n) { Node *l; if (exprop(n) != Olit) return 0; l = n->expr.args[0]; return l->type == Nlit && l->lit.littype == Llbl; } static Node * temp(Flattenctx *flatten, Node *e) { Node *t, *dcl; assert(e->type == Nexpr); t = gentemp(e->loc, e->expr.type, &dcl); return t; } static Node * add(Node *a, Node *b) { Node *n; n = mkexpr(a->loc, Oadd, a, b, NULL); n->expr.type = a->expr.type; return n; } static Node * addk(Node *n, uvlong v) { Node *k; k = mkintlit(n->loc, v); k->expr.type = exprtype(n); return add(n, k); } static Node * sub(Node *a, Node *b) { Node *n; n = mkexpr(a->loc, Osub, a, b, NULL); n->expr.type = a->expr.type; return n; } static Node * subk(Node *n, uvlong v) { Node *k; k = mkintlit(n->loc, v); k->expr.type = exprtype(n); return sub(n, k); } static Node * seqlen(Flattenctx *s, Node *n, Type *ty) { Node *r; if (!ty) ty = n->expr.type; if (exprtype(n)->type == Tyarray) { r = mkexpr(n->loc, Osllen, rval(s, n), NULL); r->expr.type = ty; } else if (exprtype(n)->type == Tyslice) { r = mkexpr(n->loc, Osllen, rval(s, n), NULL); r->expr.type = ty; } else { die("invalid seq type for len"); } return r; } static Node * visit(Flattenctx *s, Node *n) { size_t i; Node *r; for (i = 0; i < n->expr.nargs; i++) n->expr.args[i] = rval(s, n->expr.args[i]); if (opispure[exprop(n)]) { r = n; } else { if (exprtype(n)->type == Tyvoid) { r = mkexpr(n->loc, Olit, mkvoid(n->loc), NULL); r->expr.type = mktype(n->loc, Tyvoid); append(s, n); } else { r = temp(s, n); append(s, asn(r, n)); } } return r; } static Node * traitfn(Srcloc loc, Trait *tr, char *fn, Type *ty) { Node *proto, *dcl, *var; char *name; size_t i; for (i = 0; i < tr->nproto; i++) { name = declname(tr->proto[i]); if (!strcmp(fn, name)) { proto = tr->proto[i]; dcl = htget(proto->decl.impls, ty); var = mkexpr(loc, Ovar, dcl->decl.name, NULL); var->expr.type = dcl->decl.type; var->expr.did = dcl->decl.did; return var; } } return NULL; } static void dispose(Flattenctx *s, Stab *st) { Node *d, *call, *func, *val; Trait *tr; Type *ty; size_t i; tr = traittab[Tcdisp]; /* dispose in reverse order of declaration */ for (i = st->nautodcl; i-- > 0;) { d = st->autodcl[i]; ty = decltype(d); val = mkexpr(Zloc, Ovar, d->decl.name, NULL); val->expr.type = ty; val->expr.did = d->decl.did; func = traitfn(Zloc, tr, "__dispose__", ty); call = mkexpr(Zloc, Ocall, func, val, NULL); call->expr.type = mktype(Zloc, Tyvoid); flatten(s, call); } } static void flattencond(Flattenctx *s, Node *n, Node *ltrue, Node *lfalse) { Node **args; Node *v, *lnext; args = n->expr.args; switch (exprop(n)) { case Oland: lnext = genlbl(n->loc); flattencond(s, args[0], lnext, lfalse); append(s, lnext); flattencond(s, args[1], ltrue, lfalse); break; case Olor: lnext = genlbl(n->loc); flattencond(s, args[0], ltrue, lnext); append(s, lnext); flattencond(s, args[1], ltrue, lfalse); break; case Olnot: flattencond(s, args[0], lfalse, ltrue); break; default: v = rval(s, n); cjmp(s, v, ltrue, lfalse); break; } } /* flatten * a || b * to * if a || b * t = true * else * t = false * ;; */ static Node * flattenlazy(Flattenctx *s, Node *n) { Node *r, *t, *u; Node *ltrue, *lfalse, *ldone; /* set up temps and labels */ r = temp(s, n); ltrue = genlbl(n->loc); lfalse = genlbl(n->loc); ldone = genlbl(n->loc); /* flatten the conditional */ flattencond(s, n, ltrue, lfalse); /* if true */ append(s, ltrue); u = mkexpr(n->loc, Olit, mkbool(n->loc, 1), NULL); u->expr.type = mktype(n->loc, Tybool); t = asn(r, u); append(s, t); jmp(s, ldone); /* if false */ append(s, lfalse); u = mkexpr(n->loc, Olit, mkbool(n->loc, 0), NULL); u->expr.type = mktype(n->loc, Tybool); t = asn(r, u); append(s, t); jmp(s, ldone); /* finish */ append(s, ldone); return r; } static Node * destructure(Flattenctx *s, Node *lhs, Node *rhs) { Node *lv, *rv, *idx; Node **args; size_t i; args = lhs->expr.args; rhs = rval(s, rhs); for (i = 0; i < lhs->expr.nargs; i++) { idx = mkintlit(rhs->loc, i); idx->expr.type = mktype(rhs->loc, Tyuint64); rv = mkexpr(rhs->loc, Otupget, rhs, idx, NULL); rv->expr.type = lhs->expr.type; if (exprop(args[i]) == Otup) { destructure(s, args[i], rv); } else { lv = lval(s, args[i]); append(s, assign(s, lv, rv)); } } return rhs; } static Node * comparecomplex(Flattenctx *s, Node *n, Op op) { fatal(n, "Complex comparisons not yet supported\n"); return NULL; } static Node * compare(Flattenctx *s, Node *n, int fields) { const Op cmpmap[Numops][3] = { [Oeq] = {Oeq, Oueq, Ofeq}, [One] = {One, Oune, Ofne}, [Ogt] = {Ogt, Ougt, Ofgt}, [Oge] = {Oge, Ouge, Ofge}, [Olt] = {Olt, Oult, Oflt}, [Ole] = {Ole, Oule, Ofle} }; Node *r; Type *ty; Op newop; /* void is always void */ if (tybase(exprtype(n->expr.args[0]))->type == Tyvoid) return mkboollit(n->loc, 1); newop = Obad; ty = tybase(exprtype(n->expr.args[0])); if (istysigned(ty)) newop = cmpmap[n->expr.op][0]; else if (istyunsigned(ty)) newop = cmpmap[n->expr.op][1]; else if (istyunsigned(ty)) newop = cmpmap[n->expr.op][1]; else if (ty->type == Typtr) newop = cmpmap[n->expr.op][1]; else if (istyfloat(ty)) newop = cmpmap[n->expr.op][2]; if (newop != Obad) { n->expr.op = newop; r = visit(s, n); } else if (fields) { r = comparecomplex(s, n, exprop(n)); } else { fatal(n, "unsupported comparison on type %s", tystr(ty)); } r->expr.type = mktype(n->loc, Tybool); return r; } static Node * assign(Flattenctx *s, Node *lhs, Node *rhs) { Node *r, *t, *u; if (exprop(lhs) == Otup) { r = destructure(s, lhs, rhs); } else if (tybase(exprtype(lhs))->type != Tyvoid) { t = lval(s, lhs); u = rval(s, rhs); r = asn(t, u); } else { r = rval(s, rhs); } return r; } /* returns 1 when the exit jump needs to be emitted */ static int exitscope(Flattenctx *s, Stab *stop, Srcloc loc, int x) { Stab *st; for (st = s->curst;; st = st->super) { if (st->exit[x]) { jmp(s, st->exit[x]); return 0; } st->exit[x] = genlbl(loc); flatten(s, st->exit[x]); dispose(s, st); if ((!stop && st->isfunc) || st == stop) { return 1; } } } static Node * rval(Flattenctx *s, Node *n) { Node *t, *u, *v; /* temporary nodes */ Node *r; /* expression result */ Node **args; size_t i; Type *ty; const Op fusedmap[Numops] = { [Oaddeq] = Oadd, [Osubeq] = Osub, [Omuleq] = Omul, [Odiveq] = Odiv, [Omodeq] = Omod, [Oboreq] = Obor, [Obandeq] = Oband, [Obxoreq] = Obxor, [Obsleq] = Obsl, [Obsreq] = Obsr, }; r = NULL; args = n->expr.args; switch (exprop(n)) { case Osize: r = n; /* don't touch subexprs; they're a pseudo decl */ break; case Olor: case Oland: r = flattenlazy(s, n); break; case Oidx: t = rval(s, n->expr.args[0]); u = rval(s, n->expr.args[1]); r = mkexpr(n->loc, Oidx, t, u, NULL); r->expr.type = n->expr.type; break; /* array.len slice.len are magic 'virtual' members. * they need to be special cased. */ case Omemb: ty = tybase(exprtype(args[0])); if (ty->type == Tyslice || ty->type == Tyarray) { r = seqlen(s, args[0], exprtype(n)); } else { t = rval(s, args[0]); r = mkexpr(n->loc, Omemb, t, args[1], NULL); r->expr.type = n->expr.type; } break; case Oucon: if (n->expr.nargs > 1) t = rval(s, args[1]); else t = NULL; r = mkexpr(n->loc, Oucon, args[0], t, NULL); r->expr.type = n->expr.type; break; /* fused ops: * foo ?= blah * => * foo = foo ? blah*/ case Oaddeq: case Osubeq: case Omuleq: case Odiveq: case Omodeq: case Oboreq: case Obandeq: case Obxoreq: case Obsleq: case Obsreq: assert(fusedmap[exprop(n)] != Obad); u = lval(s, args[0]); v = rval(s, args[1]); v = mkexpr(n->loc, fusedmap[exprop(n)], u, v, NULL); v->expr.type = u->expr.type; r = asn(u, v); break; /* ++expr(x) * => args[0] = args[0] + 1 * expr(x) */ case Opreinc: t = lval(s, args[0]); v = asn(t, addk(t, 1)); append(s, v); r = rval(s, t); break; case Opredec: t = lval(s, args[0]); v = asn(t, subk(t, 1)); append(s, v); r = rval(s, t); break; /* expr(x++) * => expr * x = x + 1 */ case Opostinc: r = lval(s, args[0]); t = asn(r, addk(r, 1)); lappend(&s->incqueue, &s->nqueue, t); break; case Opostdec: r = lval(s, args[0]); t = asn(r, subk(r, 1)); lappend(&s->incqueue, &s->nqueue, t); break; case Olit: switch (args[0]->lit.littype) { case Lvoid: case Lchr: case Lbool: case Llbl: case Lint: case Lstr: case Lflt: case Lfunc: r = n; //capture(s, n, dst); break; } break; case Ovar: r = n; break;; case Oret: /* drain the increment queue before we return */ v = rval(s, args[0]); if (!s->nqueue) { t = v; } else { t = temp(s, v); u = assign(s, t, v); append(s, u); for (i = 0; i < s->nqueue; i++) append(s, s->incqueue[i]); lfree(&s->incqueue, &s->nqueue); } if (!s->tret) s->tret = temp(s, v); flatten(s, asn(lval(s, s->tret), t)); if (exitscope(s, NULL, Zloc, Xret)) append(s, mkexpr(n->loc, Oret, s->tret, NULL)); break; case Oasn: r = assign(s, args[0], args[1]); break; case Obreak: r = NULL; if (s->inloop == 0) fatal(n, "trying to break when not in loop"); if (exitscope(s, s->loop.body, n->loc, Xbrk)) jmp(s, s->loop.lbrk); break; case Ocontinue: r = NULL; if (s->inloop == 0) fatal(n, "trying to continue when not in loop"); if (exitscope(s, s->loop.body, n->loc, Xcnt)) jmp(s, s->loop.lcnt); break; case Oeq: case One: r = compare(s, n, 1); break; case Ogt: case Oge: case Olt: case Ole: r = compare(s, n, 0); break; default: if (istyfloat(exprtype(n))) { switch (exprop(n)) { case Oadd: n->expr.op = Ofadd; break; case Osub: n->expr.op = Ofsub; break; case Omul: n->expr.op = Ofmul; break; case Odiv: n->expr.op = Ofdiv; break; default: break; } } r = visit(s, n); break; } if (r && n->expr.idx) r->expr.idx = n->expr.idx; return r; } static Node * lval(Flattenctx *s, Node *n) { Node *r; switch (exprop(n)) { case Ovar: r = n; break; case Oidx: r = rval(s, n); break; case Oderef: r = rval(s, n); break; case Omemb: r = rval(s, n); break; case Ostruct: r = rval(s, n); break; /* for chaining */ case Oucon: r = rval(s, n); break; case Oarr: r = rval(s, n); break; case Ogap: r = temp(s, n); break; /* not actually expressible as lvalues in syntax, but we generate them */ case Oudata: r = rval(s, n); break; case Outag: r = rval(s, n); break; case Otupget: r = rval(s, n); break; default: fatal(n, "%s cannot be an lvalue", opstr[exprop(n)]); break; } return r; } static void flattenblk(Flattenctx *s, Node *n) { Stab *st; size_t i; st = s->curst; s->curst = n->block.scope; for (i = 0; i < n->block.nstmts; i++) { n->block.stmts[i] = fold(n->block.stmts[i], 0); flatten(s, n->block.stmts[i]); } assert(s->curst == n->block.scope); dispose(s, s->curst); s->curst = st; } /* init; while cond; body;; * => init * jmp :cond * :body * ...body... * ...step... * :cond * ...cond... * cjmp (cond) :body :end * :end */ static void flattenloop(Flattenctx *s, Node *n) { Stab *b; Loop l; Node *lbody; Node *lend; Node *ldec; Node *lcond; Node *lstep; size_t i; lbody = genlbl(n->loc); ldec = genlbl(n->loc); lcond = genlbl(n->loc); lstep = genlbl(n->loc); lend = genlbl(n->loc); b = s->curst; s->curst = n->loopstmt.scope; l = s->loop; s->loop.lcnt = lstep; s->loop.lbrk = lend; s->loop.body = n->loopstmt.scope; s->inloop++; flatten(s, n->loopstmt.init); /* init */ jmp(s, lcond); /* goto test */ flatten(s, lbody); /* body lbl */ flatten(s, n->loopstmt.body); /* body */ flatten(s, lstep); /* test lbl */ flatten(s, n->loopstmt.step); /* step */ flatten(s, lcond); /* test lbl */ flattencond(s, n->loopstmt.cond, ldec, lend); /* repeat? */ flatten(s, ldec); /* drain decrements */ for (i = 0; i < s->nqueue; i++) append(s, s->incqueue[i]); jmp(s, lbody); /* goto test */ flatten(s, lend); /* exit */ for (i = 0; i < s->nqueue; i++) append(s, s->incqueue[i]); lfree(&s->incqueue, &s->nqueue); s->inloop--; s->loop = l; s->curst = b; } /* if foo; bar; else baz;; * => cjmp (foo) :bar :baz */ static void flattenif(Flattenctx *s, Node *n, Node *exit) { Node *l1, *l2, *l3; Node *iftrue, *iffalse; size_t i; l1 = genlbl(n->loc); l2 = genlbl(n->loc); if (exit) l3 = exit; else l3 = genlbl(n->loc); iftrue = n->ifstmt.iftrue; iffalse = n->ifstmt.iffalse; flattencond(s, n->ifstmt.cond, l1, l2); flatten(s, l1); for (i = 0; i < s->nqueue; i++) append(s, s->incqueue[i]); /* goto test */ flatten(s, iftrue); jmp(s, l3); flatten(s, l2); for (i = 0; i < s->nqueue; i++) append(s, s->incqueue[i]); lfree(&s->incqueue, &s->nqueue); /* because lots of bunched up end labels are ugly, * coalesce them by handling 'elif'-like construct * separately */ if (iffalse && iffalse->type == Nifstmt) { flattenif(s, iffalse, exit); } else { flatten(s, iffalse); jmp(s, l3); } if (!exit) flatten(s, l3); } static void flattenloopmatch(Flattenctx *s, Node *pat, Node *val, Node *ltrue, Node *lfalse) { Node **cap, **out, *lload; size_t i, ncap, nout; /* pattern match */ lload = genlbl(pat->loc); out = NULL; nout = 0; cap = NULL; ncap = 0; genonematch(pat, val, lload, lfalse, &out, &nout, &cap, &ncap); for (i = 0; i < nout; i++) flatten(s, out[i]); flatten(s, lload); for (i = 0; i < ncap; i++) flatten(s, cap[i]); jmp(s, ltrue); } /* pat; seq; * body;; * * => * .pseudo = seqinit * jmp :cond * :body * ...body... * :step * ...step... * :cond * ...cond... * cjmp (cond) :match :end * :match * ...match... * cjmp (match) :load :step * :load * matchval = load * :end */ static void flattenidxiter(Flattenctx *s, Node *n) { Loop l; Node *lbody, *lstep, *lcond, *lmatch, *lend; Node *idx, *len, *dcl, *seq, *val, *done; Node *zero; Type *idxtype; lbody = genlbl(n->loc); lstep = genlbl(n->loc); lcond = genlbl(n->loc); lmatch = genlbl(n->loc); lend = genlbl(n->loc); s->inloop++; l = s->loop; s->loop.lcnt = lstep; s->loop.lbrk = lend; s->loop.body = n->iterstmt.body->block.scope; /* FIXME: pass this in from main() */ idxtype = mktype(n->loc, Tyuint64); zero = mkintlit(n->loc, 0); zero->expr.type = idxtype; seq = rval(s, n->iterstmt.seq); idx = gentemp(n->loc, idxtype, &dcl); /* setup */ append(s, asn(idx, zero)); jmp(s, lcond); flatten(s, lbody); /* body */ flatten(s, n->iterstmt.body); /* step */ flatten(s, lstep); flatten(s, asn(idx, addk(idx, 1))); /* condition */ flatten(s, lcond); len = seqlen(s, seq, idxtype); done = mkexpr(n->loc, Olt, idx, len, NULL); done->expr.type = mktype(n->loc, Tybool); cjmp(s, done, lmatch, lend); flatten(s, lmatch); val = mkexpr(n->loc, Oidx, seq, idx, NULL); val->expr.type = tybase(exprtype(seq))->sub[0]; /* pattern match */ flattenloopmatch(s, n->iterstmt.elt, val, lbody, lstep); jmp(s, lbody); flatten(s, lend); s->inloop--; s->loop = l; } /* for pat in seq * body;; * => * .seq = seq * .elt = elt * :body * ..body.. * :step * __iterfin__(&seq, &elt) * cond = __iternext__(&seq, &eltout) * cjmp (cond) :match :end * :match * ...match... * cjmp (match) :load :step * :load * ...load matches... * :end */ static void flattentraititer(Flattenctx *s, Node *n) { Loop l; Node *lbody, *lclean, *lstep, *lmatch, *lend; Node *done, *val, *iter, *valptr, *iterptr; Node *func, *call, *seq; Trait *tr; val = temp(s, n->iterstmt.elt); valptr = mkexpr(val->loc, Oaddr, val, NULL); valptr->expr.type = mktyptr(n->loc, exprtype(val)); iter = temp(s, n->iterstmt.seq); iterptr = mkexpr(val->loc, Oaddr, iter, NULL); iterptr->expr.type = mktyptr(n->loc, exprtype(iter)); tr = traittab[Tciter]; /* create labels */ lbody = genlbl(n->loc); lclean = genlbl(n->loc); lstep = genlbl(n->loc); lmatch = genlbl(n->loc); lend = genlbl(n->loc); s->inloop++; l = s->loop; s->loop.lcnt = lstep; s->loop.lbrk = lend; s->loop.body = n->iterstmt.body->block.scope; seq = rval(s, n->iterstmt.seq); append(s, asn(iter, seq)); jmp(s, lstep); flatten(s, lbody); /* body */ flatten(s, n->iterstmt.body); flatten(s, lclean); /* call iterator cleanup */ func = traitfn(n->loc, tr, "__iterfin__", exprtype(iter)); call = mkexpr(n->loc, Ocall, func, iterptr, valptr, NULL); call->expr.type = mktype(n->loc, Tyvoid); append(s, call); flatten(s, lstep); /* call iterator step */ func = traitfn(n->loc, tr, "__iternext__", exprtype(iter)); call = mkexpr(n->loc, Ocall, func, iterptr, valptr, NULL); done = gentemp(n->loc, mktype(n->loc, Tybool), NULL); call->expr.type = exprtype(done); append(s, asn(done, call)); cjmp(s, done, lmatch, lend); /* pattern match */ flatten(s, lmatch); flattenloopmatch(s, n->iterstmt.elt, val, lbody, lclean); jmp(s, lbody); flatten(s, lend); s->inloop--; s->loop = l; } static void flatteniter(Flattenctx *s, Node *n) { switch (tybase(exprtype(n->iterstmt.seq))->type) { case Tyarray: flattenidxiter(s, n); break; case Tyslice: flattenidxiter(s, n); break; default: flattentraititer(s, n); break; } } static void flattenmatch(Flattenctx *fc, Node *n) { Node *val; Node **match; size_t i, nmatch; val = rval(fc, n->matchstmt.val); match = NULL; nmatch = 0; genmatch(n, val, &match, &nmatch); for (i = 0; i < nmatch; i++) flatten(fc, match[i]); } static void flattenexpr(Flattenctx *fc, Node *n) { Node *r; size_t i; if (islbl(n)) { append(fc, n); return; } r = rval(fc, n); if (r) append(fc, r); for (i = 0; i < fc->nqueue; i++) append(fc, fc->incqueue[i]); lfree(&fc->incqueue, &fc->nqueue); } static Node * flatten(Flattenctx *fc, Node *n) { Node *r, *u, *t; if (!n) return NULL; r = NULL; switch (n->type) { case Nblock: flattenblk(fc, n); break; case Nloopstmt: flattenloop(fc, n); break; case Niterstmt: flatteniter(fc, n); break; case Nifstmt: flattenif(fc, n, NULL); break; case Nmatchstmt: flattenmatch(fc, n); break; case Nexpr: flattenexpr(fc, n); break; case Ndecl: append(fc, n); r = mkexpr(n->loc, Ovar, n->decl.name, NULL); if (n->decl.init) { t = rval(fc, n->decl.init); u = mkexpr(n->loc, Oasn, r, t, NULL); u->expr.type = n->decl.type; r->expr.type = n->decl.type; r->expr.did = n->decl.did; flatten(fc, u); } break; default: dump(n, stderr); die("bad node passsed to flatten()"); break; } return r; } static Node * flatteninit(Node *dcl) { Flattenctx fc = {0,}; Node *lit, *fn, *blk, *body; lit = dcl->decl.init->expr.args[0]; fn = lit->lit.fnval; body = fn->func.body; fc.curst = fn->func.scope; flatten(&fc, fn->func.body); blk = mkblock(fn->loc, body->block.scope); blk->block.stmts = fc.stmts; blk->block.nstmts = fc.nstmts; fn->func.body = blk; return dcl; } static int ismain(Node *n) { n = n->decl.name; if (n->name.ns) return 0; return strcmp(n->name.name, "main") == 0; } Node * flattenfn(Node *dcl) { if (ismain(dcl)) dcl->decl.vis = Vishidden; if (dcl->decl.isextern || dcl->decl.isgeneric) return dcl; if (isconstfn(dcl)) { dcl = flatteninit(dcl); //lappend(fn, nfn, f); } //lappend(fn, nfn, f); return dcl; } int isconstfn(Node *n) { Node *d, *e; Type *t; if (n->type == Nexpr) { if (exprop(n) != Ovar) return 0; d = decls[n->expr.did]; } else { d = n; } t = tybase(decltype(d)); if (!d || !d->decl.isconst || d->decl.isgeneric) return 0; if (!d->decl.isglobl && !d->decl.isextern) return 0; if (t->type != Tyfunc && t->type != Tycode) return 0; e = d->decl.init; if (e && (exprop(e) != Olit || e->expr.args[0]->lit.littype != Lfunc)) return 0; if (!e && !d->decl.isextern && !d->decl.isimport) return 0; return 1; }