ref: 58a13c39b7f3e6ab0bf950908e98b9f0dfb7c951
dir: /parse/infer.c/
#include <stdlib.h> #include <stdio.h> #include <stdarg.h> #include <inttypes.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 <assert.h> #include "util.h" #include "parse.h" typedef struct Traitmap Traitmap; typedef struct Postcheck Postcheck; struct Traitmap { Bitset *traits; Traitmap *sub[Ntypes]; Htab *name; /* name => bitset(traits) */ Type **filter; size_t nfilter; Trait **filtertr; size_t nfiltertr; }; struct Postcheck { Node *node; Stab *stab; Tyenv *env; }; int allowhidden; static void infernode(Node **np, Type *ret, int *sawret); static void inferexpr(Node **np, Type *ret, int *sawret); static void inferdecl(Node *n); static int tryconstrain(Type *ty, Trait *tr, int update); static Type *tyfreshen(Tysubst *subst, Type *orig); static Type *tf(Type *t); static Type *basetype(Type *a); static Type *unify(Node *ctx, Type *a, Type *b); static Type *tyfix(Node *ctx, Type *orig, int noerr); static void typesub(Node *n, int noerr); /* tracking where we are in the inference */ static int ingeneric; static int inaggr; static int indentdepth; static Srcloc *unifysrc; static size_t nunifysrc; /* post-inference checking/unification */ static Htab *delayed; static Postcheck **postcheck; static size_t npostcheck; /* generic declarations to be specialized */ static Node **genericdecls; static size_t ngenericdecls; static Node **impldecl; static size_t nimpldecl; /* specializations of generics */ static Node **specializations; static size_t nspecializations; static Stab **specializationscope; static size_t nspecializationscope; static Traitmap *traitmap; static Bitset *tytraits[Ntypes]; static void ctxstrcall(char *buf, size_t sz, Node *n) { char *p, *end, *sep, *t; size_t nargs, i; Node **args; Type *et; args = n->expr.args; nargs = n->expr.nargs; p = buf; end = buf + sz; sep = ""; if (exprop(args[0]) == Ovar) p += bprintf(p, end - p, "%s(", namestr(args[0]->expr.args[0])); else p += bprintf(p, end - p, "<e>("); for (i = 1; i < nargs; i++) { et = tyfix(NULL, exprtype(args[i]), 1); if (et != NULL) t = tystr(et); else t = strdup("?"); if (exprop(args[i]) == Ovar) p += bprintf(p, end - p, "%s%s:%s", sep, namestr(args[i]->expr.args[0]), t); else p += bprintf(p, end - p, "%s<e%zd>:%s", sep, i, t); sep = ", "; free(t); } if (exprtype(args[0])->nsub) t = tystr(tyfix(NULL, exprtype(args[0])->sub[0], 1)); else t = strdup("unknown"); p += bprintf(p, end - p, "): %s", t); free(t); } static char * nodetystr(Node *n) { Type *t; t = NULL; if (n->type == Nexpr && exprtype(n) != NULL) t = tysearch(exprtype(n)); else if (n->type == Ndecl && decltype(n) != NULL) t = tysearch(decltype(n)); if (t && tybase(t)->type != Tyvar) return tystr(t); else return strdup("unknown"); } static void marksrc(Type *t, Srcloc l) { t = tf(t); if (t->tid >= nunifysrc) { unifysrc = zrealloc(unifysrc, nunifysrc*sizeof(Srcloc), (t->tid + 1)*sizeof(Srcloc)); nunifysrc = t->tid + 1; } if (unifysrc[t->tid].line <= 0) unifysrc[t->tid] = l; } static char * srcstr(Type *ty) { char src[128]; Srcloc l; char *s; src[0] = 0; if (nunifysrc > ty->tid && unifysrc[ty->tid].line > 0) { l = unifysrc[ty->tid]; s = tystr(ty); snprintf(src, sizeof src, "\n\t%s from %s:%d", s, fname(l), lnum(l)); free(s); } return strdup(src); } /* Tries to give a good string describing the context * for the sake of error messages. */ static char * ctxstr(Node *n) { char *t, *t1, *t2, *t3; char *s, *d; size_t nargs; Node **args; char buf[512]; if (!n) return strdup("???"); switch (n->type) { default: s = strdup(nodestr[n->type]); break; case Ndecl: d = declname(n); t = nodetystr(n); bprintf(buf, sizeof buf, "%s:%s", d, t); s = strdup(buf); free(t); break; case Nname: s = strdup(namestr(n)); break; case Nexpr: args = n->expr.args; nargs = n->expr.nargs; t1 = NULL; t2 = NULL; t3 = NULL; if (exprop(n) == Ovar) d = namestr(args[0]); else d = opstr[exprop(n)]; t = nodetystr(n); if (nargs >= 1) t1 = nodetystr(args[0]); if (nargs >= 2) t2 = nodetystr(args[1]); if (nargs >= 3) t3 = nodetystr(args[2]); switch (opclass[exprop(n)]) { case OTpre: bprintf(buf, sizeof buf, "%s<e:%s>", oppretty[exprop(n)], t1); break; case OTpost: bprintf(buf, sizeof buf, "<e:%s>%s", t1, oppretty[exprop(n)]); break; case OTzarg: bprintf(buf, sizeof buf, "%s", oppretty[exprop(n)]); break; case OTbin: bprintf(buf, sizeof buf, "<e1:%s> %s <e2:%s>", t1, oppretty[exprop(n)], t2); break; case OTmisc: switch (exprop(n)) { case Ovar: bprintf(buf, sizeof buf, "%s:%s", namestr(args[0]), t); break; case Ocall: ctxstrcall(buf, sizeof buf,n); break; case Oidx: if (exprop(args[0]) == Ovar) bprintf(buf, sizeof buf, "%s[<e1:%s>]", namestr(args[0]->expr.args[0]), t2); else bprintf(buf, sizeof buf, "<sl:%s>[<e1%s>]", t1, t2); break; case Oslice: if (exprop(args[0]) == Ovar) bprintf(buf, sizeof buf, "%s[<e1:%s>:<e2:%s>]", namestr(args[0]->expr.args[0]), t2, t3); else bprintf( buf, sizeof buf, "<sl:%s>[<e1%s>:<e2:%s>]", t1, t2, t3); break; case Omemb: bprintf(buf, sizeof buf, "<%s>.%s", t1, namestr(args[1])); break; case Otupmemb: bprintf(buf, sizeof buf, "<%s>.%llu", t1, args[1]->lit.intval); break; default: bprintf(buf, sizeof buf, "%s:%s", d, t); break; } break; default: bprintf(buf, sizeof buf, "%s", d); break; } free(t); free(t1); free(t2); free(t3); s = strdup(buf); break; } return s; } static void addspecialization(Node *n, Stab *stab) { Node *dcl; dcl = decls[n->expr.did]; lappend(&specializationscope, &nspecializationscope, stab); lappend(&specializations, &nspecializations, n); lappend(&genericdecls, &ngenericdecls, dcl); } static void adddispspecialization(Node *n, Stab *stab) { Trait *tr; Type *ty; tr = traittab[Tcdisp]; ty = exprtype(n); assert(tr->nproto == 1); if (hthas(tr->proto[0]->decl.impls, ty)) return; lappend(&specializationscope, &nspecializationscope, stab); lappend(&specializations, &nspecializations, n); lappend(&genericdecls, &ngenericdecls, tr->proto[0]); } static void additerspecialization(Node *n, Stab *stab) { Trait *tr; Type *ty; size_t i; tr = traittab[Tciter]; ty = exprtype(n->iterstmt.seq); if (ty->type == Tyslice || ty->type == Tyarray || ty->type == Typtr) return; ty = tyfreshen(NULL, ty); for (i = 0; i < tr->nproto; i++) { ty = exprtype(n->iterstmt.seq); if (hthas(tr->proto[i]->decl.impls, ty)) continue; lappend(&specializationscope, &nspecializationscope, stab); lappend(&specializations, &nspecializations, n); lappend(&genericdecls, &ngenericdecls, tr->proto[i]); } } static void delayedcheck(Node *n) { Postcheck *pc; pc = xalloc(sizeof(Postcheck)); pc->node = n; pc->stab = curstab(); pc->env = curenv(); lappend(&postcheck, &npostcheck, pc); } static void typeerror(Type *a, Type *b, Node *ctx, char *msg) { char *t1, *t2, *s1, *s2, *c; t1 = tystr(tyfix(NULL, a, 1)); t2 = tystr(tyfix(NULL, b, 1)); s1 = srcstr(a); s2 = srcstr(b); c = ctxstr(ctx); if (msg) fatal(ctx, "type \"%s\" incompatible with \"%s\" near %s: %s%s%s", t1, t2, c, msg, s1, s2); else fatal(ctx, "type \"%s\" incompatible with \"%s\" near %s%s%s", t1, t2, c, s1, s2); free(t1); free(t2); free(s1); free(s2); free(c); } /* Set a scope's enclosing scope up correctly. */ static void setsuperenv(Tyenv *e, Tyenv *super) { if (e) e->super = super; } /* Set a scope's enclosing scope up correctly. */ static void setsuper(Stab *st, Stab *super) { Stab *s; /* verify that we don't accidentally create loops */ for (s = super; s; s = s->super) assert(s->super != st); st->super = super; } /* Checks if a type that directly contains itself. * Recursive types that contain themselves through * pointers or slices are fine, but any other self-inclusion * would lead to a value of infinite size */ static int occurs_rec(Type *sub, Bitset *bs) { size_t i; sub = tf(sub); if (bshas(bs, sub->tid)) return 1; bsput(bs, sub->tid); switch (sub->type) { case Typtr: case Tyslice: break; case Tystruct: for (i = 0; i < sub->nmemb; i++) if (occurs_rec(decltype(sub->sdecls[i]), bs)) return 1; break; case Tyunion: for (i = 0; i < sub->nmemb; i++) { if (!sub->udecls[i]->etype) continue; if (occurs_rec(sub->udecls[i]->etype, bs)) return 1; } break; default: for (i = 0; i < sub->nsub; i++) if (occurs_rec(sub->sub[i], bs)) return 1; break; } bsdel(bs, sub->tid); return 0; } static int occursin(Type *a, Type *b) { Bitset *bs; int r; bs = mkbs(); a = tf(a); bsput(bs, a->tid); r = occurs_rec(b, bs); bsfree(bs); return r; } static int occurs(Type *t) { Bitset *bs; int r; bs = mkbs(); r = occurs_rec(t, bs); bsfree(bs); return r; } static int needfreshenrec(Type *t, Bitset *visited) { size_t i; t = tysearch(t); if (bshas(visited, t->tid)) return 0; bsput(visited, t->tid); switch (t->type) { case Typaram: return 1; case Tygeneric: return 1; case Tyname: for (i = 0; i < t->narg; i++) if (needfreshenrec(t->arg[i], visited)) return 1; return needfreshenrec(t->sub[0], visited); case Tystruct: for (i = 0; i < t->nmemb; i++) if (needfreshenrec(decltype(t->sdecls[i]), visited)) return 1; break; case Tyunion: for (i = 0; i < t->nmemb; i++) if (t->udecls[i]->etype && needfreshenrec(t->udecls[i]->etype, visited)) return 1; break; default: for (i = 0; i < t->nsub; i++) if (needfreshenrec(t->sub[i], visited)) return 1; break; } return 0; } static int needfreshen(Type *t) { Bitset *visited; int ret; visited = mkbs(); ret = needfreshenrec(t, visited); bsfree(visited); return ret; } /* Freshens the type of a declaration. */ static Type * tyfreshen(Tysubst *subst, Type *orig) { Type *ty, *base; if (!needfreshen(orig)) return orig; pushenv(orig->env); if (!subst) { subst = mksubst(); ty = tyspecialize(orig, subst, delayed); substfree(subst); } else { ty = tyspecialize(orig, subst, delayed); } ty->spec = orig->spec; ty->nspec = orig->nspec; base = basetype(ty); if (base) ty->seqaux = base; popenv(orig->env); return ty; } /* Resolves a type and all its subtypes recursively. */ static void tyresolve(Type *t) { size_t i, j; Trait *tr; if (t->resolved) return; /* type resolution should never throw errors about non-generic * showing up within a generic type, so we push and pop a generic * around resolution */ ingeneric++; t->resolved = 1; /* Walk through aggregate type members */ pushenv(t->env); switch (t->type) { case Tystruct: inaggr++; for (i = 0; i < t->nmemb; i++) infernode(&t->sdecls[i], NULL, NULL); inaggr--; break; case Tyunion: inaggr++; for (i = 0; i < t->nmemb; i++) { if (!t->udecls[i]->utype) t->udecls[i]->utype = t; t->udecls[i]->utype = tf(t->udecls[i]->utype); if (t->udecls[i]->etype) { tyresolve(t->udecls[i]->etype); t->udecls[i]->etype = tf(t->udecls[i]->etype); } } inaggr--; break; case Tyarray: if (!inaggr && !t->asize) lfatal(t->loc, "unsized array type outside of struct"); infernode(&t->asize, NULL, NULL); break; case Typaram: if (!boundtype(t)) lfatal(t->loc, "type parameter %s is undefined in generic context", tystr(t)); break; default: break; } for (i = 0; i < t->nspec; i++) { for (j = 0; j < t->spec[i]->ntrait; j++) { tr = gettrait(curstab(), t->spec[i]->trait[j]); if (!tr) lfatal(t->loc, "trait %s does not exist", ctxstr(t->spec[i]->trait[j])); if (!t->trneed) t->trneed = mkbs(); bsput(t->trneed, tr->uid); if (nameeq(t->spec[i]->trait[j], traittab[Tciter]->name)) t->seqaux = t->spec[i]->aux; t->spec[i]->trait[j] = tr->name; } } for (i = 0; i < t->nsub; i++) { t->sub[i] = tf(t->sub[i]); if (t->sub[i] == t) { lfatal(t->loc, "%s occurs within %s, leading to infinite type\n", tystr(t->sub[i]), tystr(t)); } } if (occurs(t)) lfatal(t->loc, "type %s includes itself", tystr(t)); popenv(t->env); ingeneric--; } Type * tysearch(Type *t) { if (!t) return t; while (tytab[t->tid]) t = tytab[t->tid]; return t; } /* Look up the best type to date in the unification table, returning it */ static Type * tylookup(Type *t) { Type *lu; Stab *ns; assert(t != NULL); lu = NULL; while (1) { if (!tytab[t->tid] && t->type == Tyunres) { ns = curstab(); if (t->name->name.ns) ns = getns(t->name->name.ns); if (!ns) fatal(t->name, "no namespace \"%s\"", t->name->name.ns); lu = gettype(ns, t->name); if (!lu) fatal(t->name, "no type %s", tystr(t)); if (lu && lu != t) tytab[t->tid] = lu; } if (!tytab[t->tid]) break; /* compress paths: shift the link up one level */ if (tytab[tytab[t->tid]->tid]) tytab[t->tid] = tytab[tytab[t->tid]->tid]; t = tytab[t->tid]; } return t; } static Type * tysubstmap(Tysubst *subst, Type *t, Type *orig) { size_t i; for (i = 0; i < t->ngparam; i++) substput(subst, t->gparam[i], tf(orig->arg[i])); t = tyfreshen(subst, t); return t; } static Type * tysubst(Type *t, Type *orig) { Tysubst *subst; subst = mksubst(); t = tysubstmap(subst, t, orig); substfree(subst); return t; } /* find the most accurate type mapping we have (ie, * the end of the unification chain */ static Type * tf(Type *orig) { int isgeneric; Type *t, *tt; assert(orig != NULL); t = tylookup(orig); isgeneric = t->type == Tygeneric; ingeneric += isgeneric; pushenv(orig->env); tyresolve(t); if ((tt = boundtype(t)) != NULL) { t = tt; tyresolve(t); } popenv(orig->env); /* If this is an instantiation of a generic type, we want the params to * match the instantiation */ if (orig->type == Tyunres && t->type == Tygeneric) { if (t->ngparam != orig->narg) { lfatal(orig->loc, "%s incompatibly specialized with %s, declared on %s:%d", tystr(orig), tystr(t), file.files[t->loc.file], t->loc.line); } pushenv(orig->env); t = tysubst(t, orig); popenv(orig->env); } ingeneric -= isgeneric; return t; } /* set the type of any typable node */ static void settype(Node *n, Type *t) { t = tf(t); switch (n->type) { case Nexpr: n->expr.type = t; break; case Ndecl: n->decl.type = t; break; case Nlit: n->lit.type = t; break; case Nfunc: n->func.type = t; break; default: die("untypable node %s", nodestr[n->type]); break; } if (t->type != Tyvar) marksrc(t, n->loc); } static Type* mktylike(Srcloc l, Ty other) { Type *t; t = mktyvar(l); /* not perfect in general, but good enough for all places mktylike is used. */ t->trneed = bsdup(tytraits[other]); return t; } /* Gets the type of a literal value */ static Type * littype(Node *n) { Type *t; t = NULL; if (!n->lit.type) { switch (n->lit.littype) { case Lvoid: t = mktype(n->loc, Tyvoid); break; case Lchr: t = mktype(n->loc, Tychar); break; case Lbool: t = mktype(n->loc, Tybool); break; case Lint: t = mktylike(n->loc, Tyint); break; case Lflt: t = mktylike(n->loc, Tyflt64); break; case Lstr: t = mktyslice(n->loc, mktype(n->loc, Tybyte)); break; case Llbl: t = mktyptr(n->loc, mktype(n->loc, Tyvoid)); break; case Lfunc: t = n->lit.fnval->func.type; break; } n->lit.type = t; } return n->lit.type; } static Type * delayeducon(Type *fallback) { Type *t; if (fallback->type != Tyunion) return fallback; t = mktylike(fallback->loc, fallback->type); htput(delayed, t, fallback); return t; } /* Finds the type of any typable node */ static Type * type(Node *n) { Type *t; switch (n->type) { case Nlit: t = littype(n); break; case Nexpr: t = n->expr.type; break; case Ndecl: t = decltype(n); break; case Nfunc: t = n->func.type; break; default: t = NULL; die("untypeable node %s", nodestr[n->type]); break; }; return tf(t); } static Ucon * uconresolve(Node *n) { Ucon *uc; Node **args; Stab *ns; args = n->expr.args; ns = curstab(); if (args[0]->name.ns) ns = getns(args[0]->name.ns); if (!ns) fatal(n, "no namespace %s\n", args[0]->name.ns); uc = getucon(ns, args[0]); if (!uc) fatal(n, "no union constructor `%s", ctxstr(args[0])); if (!uc->etype && n->expr.nargs > 1) fatal(n, "nullary union constructor `%s passed arg ", ctxstr(args[0])); else if (uc->etype && n->expr.nargs != 2) fatal(n, "union constructor `%s needs arg ", ctxstr(args[0])); return uc; } /* this doesn't walk through named types, so it can't recurse infinitely. */ int tymatchrank(Type *pat, Type *to) { int match, q; size_t i; Ucon *puc, *tuc; pat = tysearch(pat); to = tysearch(to); if (pat->type == Typaram) { if (!pat->trneed) return 0; for (i = 0; bsiter(pat->trneed, &i); i++) if (!tryconstrain(to, traittab[i], 0)) return -1; return 0; } else if (pat->type == Tyvar) { return 1; } else if (pat->type != to->type) { return -1; } match = 0; switch (pat->type) { case Tystruct: if (pat->nmemb != to->nmemb) return -1; for (i = 0; i < pat->nmemb; i++) { if (!streq(declname(pat->sdecls[i]),declname( to->sdecls[i]))) return -1; q = tymatchrank(decltype(pat->sdecls[i]), decltype(to->sdecls[i])); if (q < 0) return -1; match += q; } break; case Tyunion: if (pat->nmemb != to->nmemb) return -1; for (i = 0; i < pat->nmemb; i++) { if (!nameeq(pat->udecls[i], to->udecls[i])) return -1; puc = pat->udecls[i]; tuc = to->udecls[i]; if (puc->etype && tuc->etype) { q = tymatchrank(puc->etype, tuc->etype); if (q < 0) return -1; match += q; } else if (puc->etype != tuc->etype) { return -1; } } break; case Tyname: if (!nameeq(pat->name, to->name)) return -1; if (pat->narg != to->narg) return -1; for (i = 0; i < pat->narg; i++) { q = tymatchrank(pat->arg[i], to->arg[i]); if (q < 0) return -1; match += q; } break; case Tyarray: /* unsized arrays are ok */ if (pat->asize && to->asize) { if (!!litvaleq(pat->asize->expr.args[0], to->asize->expr.args[0])) return -1; } else if (pat->asize != to->asize) { return -1; } else return tymatchrank(pat->sub[0], to->sub[0]); break; default: if (pat->nsub != to->nsub) break; if (pat->type == to->type) match = 1; for (i = 0; i < pat->nsub; i++) { q = tymatchrank(pat->sub[i], to->sub[i]); if (q < 0) return -1; match += q; } break; } return match; } static int tryconstrain(Type *base, Trait *tr, int update) { Traitmap *tm; Bitset *bs; Type *ty; size_t i; while(1) { ty = base; tm = traitmap->sub[ty->type]; while (1) { if (ty->type == Typaram) if (ty->trneed && bshas(ty->trneed, tr->uid)) return 1; if (ty->type == Tyvar) { if (!ty->trneed) ty->trneed = mkbs(); if (update) bsput(ty->trneed, tr->uid); return 1; } if (bshas(tm->traits, tr->uid)) return 1; if (tm->name && ty->type == Tyname) { bs = htget(tm->name, ty->name); if (bs && bshas(bs, tr->uid)) return 1; } for (i = 0; i < tm->nfilter; i++) { if (tm->filtertr[i]->uid != tr->uid) continue; if (tymatchrank(tm->filter[i], ty) >= 0) return 1; } if (!ty->sub || ty->nsub != 1) break; ty = ty->sub[0]; tm = tm->sub[ty->type]; if (!tm) break; } if (base->type != Tyname) break; base = base->sub[0]; } return 0; } /* Constrains a type to implement the required constraints. On * type variables, the constraint is added to the required * constraint list. Otherwise, the type is checked to see * if it has the required constraint */ static void constrain(Node *ctx, Type *base, Trait *tr) { if (!tryconstrain(base, tr, 1)) fatal(ctx, "%s needs trait %s near %s", tystr(base), namestr(tr->name), ctxstr(ctx)); } static void traitsfor(Type *base, Bitset *dst) { Traitmap *tm; Bitset *bs; Type *ty; size_t i; while(1) { ty = base; tm = traitmap->sub[ty->type]; while (1) { if (ty->type == Tyvar) break; if (ty->type == Tyname && ty->ngparam == 0) bs = htget(tm->name, ty->name); else bs = tm->traits; if (bs) bsunion(dst, bs); for (i = 0; i < tm->nfilter; i++) { if (tymatchrank(tm->filter[i], ty) >= 0) bsput(dst, tm->filtertr[i]->uid); } if (!tm->sub[ty->type] || ty->nsub != 1) break; tm = tm->sub[ty->type]; ty = ty->sub[0]; } if (base->type != Tyname) break; base = base->sub[0]; } } static void verifytraits(Node *ctx, Type *a, Type *b) { char traitbuf[64], abuf[64], bbuf[64]; char asrc[128], bsrc[128]; Bitset *abs, *bbs; size_t i, n; Srcloc l; char *sep; abs = a->trneed; if (!abs) { abs = mkbs(); traitsfor(a, abs); } bbs = b->trneed; if (!bbs) { bbs = mkbs(); traitsfor(b, bbs); } if (!bsissubset(abs, bbs)) { sep = ""; n = 0; *traitbuf = 0; for (i = 0; bsiter(abs, &i); i++) { if (!bshas(bbs, i)) { n += bprintf(traitbuf + n, sizeof(traitbuf) - n, "%s%s", sep, namestr(traittab[i]->name)); sep = ","; } } tyfmt(abuf, sizeof abuf, a); tyfmt(bbuf, sizeof bbuf, b); bsrc[0] = 0; if (nunifysrc > b->tid && unifysrc[b->tid].line > 0) { l = unifysrc[b->tid]; snprintf(bsrc, sizeof asrc, "\n\t%s from %s:%d", bbuf, fname(l), lnum(l)); } fatal(ctx, "%s needs trait %s near %s%s%s", bbuf, traitbuf, ctxstr(ctx), srcstr(a), srcstr(b)); } if (!a->trneed) bsfree(abs); if (!b->trneed) bsfree(bbs); } /* Merges the constraints on types */ static void mergetraits(Node *ctx, Type *a, Type *b) { if (b->type == Tyvar) { /* make sure that if a = b, both have same traits */ if (a->trneed && b->trneed) bsunion(b->trneed, a->trneed); else if (a->trneed) b->trneed = bsdup(a->trneed); else if (b->trneed) a->trneed = bsdup(b->trneed); } else { verifytraits(ctx, a, b); } } /* Computes the 'rank' of the type; ie, in which * direction should we unify. A lower ranked type * should be mapped to the higher ranked (ie, more * specific) type. */ static int tyrank(Type *t) { if (t->type == Tyvar) { /* has associated iterator type */ if (t->seqaux) return 1; else return 0; } return 2; } static void unionunify(Node *ctx, Type *u, Type *v) { size_t i, j; int found; if (u->nmemb != v->nmemb) fatal(ctx, "can't unify %s and %s near %s%s%s\n", tystr(u), tystr(v), ctxstr(ctx), srcstr(u), srcstr(v)); for (i = 0; i < u->nmemb; i++) { found = 0; for (j = 0; j < v->nmemb; j++) { if (!nameeq(u->udecls[i]->name, v->udecls[j]->name)) continue; found = 1; if (u->udecls[i]->etype == NULL && v->udecls[j]->etype == NULL) continue; else if (u->udecls[i]->etype && v->udecls[j]->etype) unify(ctx, u->udecls[i]->etype, v->udecls[j]->etype); else fatal(ctx, "can't unify %s and %s near %s%s%s", tystr(u), tystr(v), ctxstr(ctx), srcstr(u), srcstr(v)); } if (!found) fatal(ctx, "can't unify %s and %s near %s%s%s", tystr(u), tystr(v), ctxstr(ctx), srcstr(u), srcstr(v)); } } static void structunify(Node *ctx, Type *u, Type *v) { size_t i, j; int found; char *ud, *vd; if (u->nmemb != v->nmemb) fatal(ctx, "can't unify %s and %s near %s%s%s", tystr(u), tystr(v), ctxstr(ctx), srcstr(u), srcstr(v)); for (i = 0; i < u->nmemb; i++) { found = 0; for (j = 0; j < v->nmemb; j++) { ud = namestr(u->sdecls[i]->decl.name); vd = namestr(v->sdecls[j]->decl.name); if (strcmp(ud, vd) == 0) { found = 1; unify(ctx, type(u->sdecls[i]), type(v->sdecls[j])); } } /* we had at least one missing member */ if (!found) fatal(ctx, "can't unify %s and %s near %s%s%s", tystr(u), tystr(v), ctxstr(ctx), srcstr(u), srcstr(v)); } } static void membunify(Node *ctx, Type *u, Type *v) { if (hthas(delayed, u)) u = htget(delayed, u); u = tybase(u); if (hthas(delayed, v)) v = htget(delayed, v); v = tybase(v); if (u->type == Tyunion && v->type == Tyunion && u != v) unionunify(ctx, u, v); else if (u->type == Tystruct && v->type == Tystruct && u != v) structunify(ctx, u, v); } static Type * basetype(Type *a) { Type *t; t = a->seqaux; while (!t && a->type == Tyname) { a = a->sub[0]; t = a->seqaux; } if (!t && (a->type == Tyslice || a->type == Tyarray || a->type == Typtr)) t = a->sub[0]; if (t) t = tf(t); return t; } static void checksize(Node *ctx, Type *a, Type *b) { if (a->asize) a->asize = fold(a->asize, 1); if (b->asize) b->asize = fold(b->asize, 1); if (a->asize && exprop(a->asize) != Olit) lfatal(ctx->loc, "%s: array size is not constant near %s", tystr(a), ctxstr(ctx)); if (b->asize && exprop(b->asize) != Olit) lfatal(ctx->loc, "%s: array size is not constant near %s", tystr(b), ctxstr(ctx)); if (!a->asize) a->asize = b->asize; else if (!b->asize) b->asize = a->asize; else if (a->asize && b->asize) if (!litvaleq(a->asize->expr.args[0], b->asize->expr.args[0])) lfatal(ctx->loc, "array size of %s does not match %s near %s", tystr(a), tystr(b), ctxstr(ctx)); } static int hasargs(Type *t) { return t->type == Tyname && t->narg > 0; } /* Unifies two types, or errors if the types are not unifiable. */ static Type * unify(Node *ctx, Type *u, Type *v) { Type *t, *r; Type *a, *b; Type *ea, *eb; size_t i; /* a ==> b */ a = tf(u); b = tf(v); if (a->tid == b->tid) return a; /* we unify from lower to higher ranked types */ if (tyrank(b) < tyrank(a)) { t = a; a = b; b = t; } /* Disallow recursive types */ if (a->type == Tyvar && b->type != Tyvar) { if (occursin(a, b)) fatal(ctx, "%s occurs within %s, leading to infinite type near %s\n", tystr(a), tystr(b), ctxstr(ctx)); } r = NULL; if (a->type == Tyvar || tyeq(a, b)) { tytab[a->tid] = b; if (ctx) { marksrc(a, ctx->loc); marksrc(b, ctx->loc); } } if (a->type == Tyvar) { ea = basetype(a); eb = basetype(b); if (ea && eb) unify(ctx, ea, eb); r = b; } if (a->type == Tyarray && b->type == Tyarray) { checksize(ctx, a, b); } /* if the tyrank of a is 0 (ie, a raw tyvar), just unify. * Otherwise, match up subtypes. */ if (a->type == b->type && a->type != Tyvar) { if (a->type == Tyname) if (!nameeq(a->name, b->name)) typeerror(a, b, ctx, "incompatible types"); if (hasargs(a) && hasargs(b)) { /* Only Tygeneric and Tyname should be able to unify. And they * should have the same names for this to be true. */ if (!nameeq(a->name, b->name)) typeerror(a, b, ctx, NULL); if (a->narg != b->narg) typeerror(a, b, ctx, "incompatible parameter lists"); for (i = 0; i < a->narg; i++) unify(ctx, a->arg[i], b->arg[i]); r = b; } if (a->nsub != b->nsub) { verifytraits(ctx, a, b); if (tybase(a)->type == Tyfunc) typeerror(a, b, ctx, "function arity mismatch"); else typeerror(a, b, ctx, "subtype counts incompatible"); } for (i = 0; i < b->nsub; i++) unify(ctx, a->sub[i], b->sub[i]); r = b; } else if (a->type != Tyvar) { typeerror(a, b, ctx, NULL); } mergetraits(ctx, a, b); if (a->isreflect || b->isreflect) { tagreflect(r); tagreflect(a); tagreflect(b); } membunify(ctx, a, b); /* if we have delayed types for a tyvar, transfer it over. */ if (a->type == Tyvar && b->type == Tyvar) { if (hthas(delayed, a) && !hthas(delayed, b)) htput(delayed, b, htget(delayed, a)); else if (hthas(delayed, b) && !hthas(delayed, a)) htput(delayed, a, htget(delayed, b)); } else if (hthas(delayed, a)) { unify(ctx, htget(delayed, a), tybase(b)); } return r; } /* Applies unifications to function calls. * Funciton application requires a slightly * different approach to unification. */ static void unifycall(Node *n) { size_t i; Type *ft; ft = type(n->expr.args[0]); if (ft->type == Tyvar) { /* the first arg is the function itself, so it shouldn't be counted */ ft = mktyfunc(n->loc, &n->expr.args[1], n->expr.nargs - 1, mktyvar(n->loc)); unify(n, ft, type(n->expr.args[0])); } else if (tybase(ft)->type != Tyfunc) { fatal(n, "calling uncallable type %s", tystr(ft)); } /* first arg: function itself */ for (i = 1; i < n->expr.nargs; i++) { if (i == ft->nsub) fatal(n, "%s arity mismatch (expected %zd args, got %zd)", ctxstr(n->expr.args[0]), ft->nsub - 1, n->expr.nargs - 1); if (ft->sub[i]->type == Tyvalist) { break; } unify(n->expr.args[0], ft->sub[i], type(n->expr.args[i])); } if (i < ft->nsub && ft->sub[i]->type != Tyvalist) fatal(n, "%s arity mismatch (expected %zd args, got %zd)", ctxstr(n->expr.args[0]), ft->nsub - 1, i - 1); settype(n, ft->sub[0]); } static void unifyparams(Node *ctx, Type *a, Type *b) { size_t i; /* The only types with unifiable params are Tyunres and Tyname. * Tygeneric should always be freshened, and no other types have * parameters attached. * * FIXME: Is it possible to have parameterized typarams? */ if (a->type != Tyunres && a->type != Tyname) return; if (b->type != Tyunres && b->type != Tyname) return; if (a->narg != b->narg) fatal(ctx, "mismatched arg list sizes: %s with %s near %s", tystr(a), tystr(b), ctxstr(ctx)); for (i = 0; i < a->narg; i++) unify(ctx, a->arg[i], b->arg[i]); } static Type * initvar(Node *n, Node *s) { Type *t, *u, *param; Tysubst *subst; if (s->decl.ishidden && !allowhidden) fatal(n, "attempting to refer to hidden decl %s", ctxstr(n)); param = n->expr.param; if (param) tyresolve(param); if (s->decl.isgeneric) { subst = mksubst(); if (param) substput(subst, s->decl.trait->param, param); pushenv(s->decl.env); t = tysubstmap(subst, tf(s->decl.type), s->decl.type); if (s->decl.trait && !param) { u = tf(s->decl.trait->param); param = substget(subst, u); if (!param) fatal(n, "ambiguous trait decl %s", ctxstr(s)); } popenv(s->decl.env); substfree(subst); } else { t = s->decl.type; } n->expr.did = s->decl.did; n->expr.isconst = s->decl.isconst; if (param) { n->expr.param = param; delayedcheck(n); } if (s->decl.isgeneric && !ingeneric) { t = tyfreshen(NULL, t); addspecialization(n, curstab()); if (t->type == Tyvar) { settype(n, mktyvar(n->loc)); delayedcheck(n); } else { settype(n, t); } } else { settype(n, t); } return t; } /* Finds out if the member reference is actually * referring to a namespaced name, instead of a struct * member. If it is, it transforms it into the variable * reference we should have, instead of the Omemb expr * that we do have */ static Node * checkns(Node *n, Node **ret) { Node *var, *name, *nsname; Node **args; Stab *stab; Node *s; /* check that this is a namespaced declaration */ args = n->expr.args; if (n->type != Nexpr || exprop(n) != Omemb || exprop(args[0]) != Ovar) return n; name = args[0]->expr.args[0]; stab = getns(namestr(name)); if (!stab || getdcl(curstab(), name)) return n; /* substitute the namespaced name */ nsname = mknsname(n->loc, namestr(name), namestr(args[1])); s = getdcl(stab, args[1]); if (!s) fatal(n, "undeclared var %s.%s", nsname->name.ns, nsname->name.name); var = mkexpr(n->loc, Ovar, nsname, NULL); var->expr.idx = n->expr.idx; initvar(var, s); *ret = var; return var; } static void inferstruct(Node *n, int *isconst) { size_t i; *isconst = 1; /* we want to check outer nodes before inner nodes when unifying nested structs */ delayedcheck(n); for (i = 0; i < n->expr.nargs; i++) { infernode(&n->expr.args[i], NULL, NULL); if (!n->expr.args[i]->expr.isconst) *isconst = 0; } settype(n, mktyvar(n->loc)); } static int64_t arraysize(Node *n) { int64_t sz, off, i; Node **args, *idx; sz = 0; args = n->expr.args; for (i = 0; i < n->expr.nargs; i++) { if (args[i]->expr.idx) { args[i]->expr.idx = fold(args[i]->expr.idx, 1); idx = args[i]->expr.idx; if (exprop(idx) != Olit) fatal(idx, "nonconstant array initializer index near %s\n", ctxstr(idx)); if (idx->expr.args[0]->lit.littype == Lchr) off = idx->expr.args[0]->lit.chrval; else if (idx->expr.args[0]->lit.littype == Lint) off = idx->expr.args[0]->lit.intval; else fatal(idx, "noninteger array initializer index near %s\n", ctxstr(idx)); if (off >= sz) sz = off + 1; } else { sz++; } } return sz; } static void inferarray(Node *n, int *isconst) { size_t i; Type *t; Node *len; *isconst = 1; len = mkintlit(n->loc, arraysize(n)); t = mktyarray(n->loc, mktyvar(n->loc), len); for (i = 0; i < n->expr.nargs; i++) { infernode(&n->expr.args[i], NULL, NULL); unify(n, t->sub[0], type(n->expr.args[i])); if (!n->expr.args[i]->expr.isconst) *isconst = 0; } settype(n, t); } static void infertuple(Node *n, int *isconst) { Type **types; size_t i; *isconst = 1; types = xalloc(sizeof(Type *) * n->expr.nargs); for (i = 0; i < n->expr.nargs; i++) { infernode(&n->expr.args[i], NULL, NULL); n->expr.isconst = n->expr.isconst && n->expr.args[i]->expr.isconst; types[i] = type(n->expr.args[i]); } *isconst = n->expr.isconst; settype(n, mktytuple(n->loc, types, n->expr.nargs)); } static void inferucon(Node *n, int *isconst) { Ucon *uc; Type *t; *isconst = 1; uc = uconresolve(n); /* Hackety hack hack. * the types in a generic union may be bound from the tyname that * defined it, which is not accessible here. * * To make it compile, for now, we just bind the types in here. */ t = uc->utype; if (t->type != Tyunion) t = t->sub[0]; assert(t->type == Tyunion); t = tysubst(tf(t), t); uc = tybase(t)->udecls[uc->id]; if (uc->etype) { inferexpr(&n->expr.args[1], NULL, NULL); unify(n, uc->etype, type(n->expr.args[1])); *isconst = n->expr.args[1]->expr.isconst; } settype(n, delayeducon(uc->utype)); } static void inferpat(Node **np, Node *val, Node ***bind, size_t *nbind) { size_t i; Node **args; Node *s, *n; Stab *ns; Type *t; n = *np; n = checkns(n, np); n->expr.ispat = 1; args = n->expr.args; for (i = 0; i < n->expr.nargs; i++) if (args[i]->type == Nexpr) { inferpat(&args[i], val, bind, nbind); } switch (exprop(n)) { case Otup: case Ostruct: case Oarr: case Olit: case Omemb: case Olor: infernode(np, NULL, NULL); break; /* arithmetic expressions just need to be constant */ case Oneg: case Oadd: case Osub: case Omul: case Odiv: case Obsl: case Obsr: case Oband: case Obor: case Obxor: case Obnot: infernode(np, NULL, NULL); if (!n->expr.isconst) fatal(n, "matching against non-constant expression near %s", ctxstr(n)); break; case Oucon: inferucon(n, &n->expr.isconst); break; case Ovar: ns = curstab(); if (args[0]->name.ns) ns = getns(args[0]->name.ns); s = getdcl(ns, args[0]); if (s && !s->decl.ishidden) { if (s->decl.isgeneric) t = tysubst(s->decl.type, s->decl.type); else if (s->decl.isconst) t = s->decl.type; else fatal(n, "pattern shadows variable declared on %s:%d near %s", fname(s->loc), lnum(s->loc), ctxstr(s)); } else { /* Scan the already collected bound variables in the pattern of this match case. * If a bound variable with the same name is found, assign the variable the existing decl. * Otherwise, create a new decl for the variable */ s = NULL; for (i = 0; !s && i < *nbind; i++) if (nameeq(args[0], (*bind)[i]->decl.name)) s = (*bind)[i]; if (s) { t = s->decl.type; } else { t = mktyvar(n->loc); s = mkdecl(n->loc, n->expr.args[0], t); s->decl.init = val; settype(n, t); lappend(bind, nbind, s); } } settype(n, t); n->expr.did = s->decl.did; n->expr.isconst = s->decl.isconst; break; case Oaddr: infernode(np, NULL, NULL); break; case Ogap: infernode(np, NULL, NULL); break; default: fatal(n, "invalid pattern"); break; } } void addbindings(Node *n, Node **bind, size_t nbind) { size_t i; /* order of binding shouldn't matter, so push them into the block * in reverse order. */ for (i = 0; i < nbind; i++) { putdcl(n->block.scope, bind[i]); linsert(&n->block.stmts, &n->block.nstmts, 0, bind[i]); } } static void infersub(Node *n, Type *ret, int *sawret, int *exprconst) { Node **args; size_t i, nargs; int isconst; /* Ovar has no subexpressions */ if (exprop(n) == Ovar) return; args = n->expr.args; nargs = n->expr.nargs; isconst = 1; for (i = 0; i < nargs; i++) { /* Nlit, Nvar, etc should not be inferred as exprs */ if (args[i]->type == Nexpr) { /* Omemb can sometimes resolve to a namespace. We have to check * this. Icky. */ checkns(args[i], &args[i]); inferexpr(&args[i], ret, sawret); isconst = isconst && args[i]->expr.isconst; } } if (opispure[exprop(n)]) n->expr.isconst = isconst; *exprconst = n->expr.isconst; } static void inferexpr(Node **np, Type *ret, int *sawret) { Node **args; size_t i, nargs; Node *s, *n; Type *t, *b; int isconst; Stab *ns; n = *np; assert(n->type == Nexpr); args = n->expr.args; nargs = n->expr.nargs; infernode(&n->expr.idx, NULL, NULL); n = checkns(n, np); switch (exprop(n)) { case Oauto: /* @a -> @a */ infersub(n, ret, sawret, &isconst); t = type(args[0]); constrain(n, t, traittab[Tcdisp]); n->expr.isconst = isconst; settype(n, t); break; /* all operands are same type */ case Oadd: /* @a + @a -> @a */ case Osub: /* @a - @a -> @a */ case Omul: /* @a * @a -> @a */ case Odiv: /* @a / @a -> @a */ case Oneg: /* -@a -> @a */ case Oaddeq: /* @a += @a -> @a */ case Osubeq: /* @a -= @a -> @a */ case Omuleq: /* @a *= @a -> @a */ case Odiveq: /* @a /= @a -> @a */ infersub(n, ret, sawret, &isconst); t = type(args[0]); constrain(n, t, traittab[Tcnum]); isconst = args[0]->expr.isconst; for (i = 1; i < nargs; i++) { isconst = isconst && args[i]->expr.isconst; t = unify(n, t, type(args[i])); } n->expr.isconst = isconst; settype(n, t); break; case Omod: /* @a % @a -> @a */ case Obor: /* @a | @a -> @a */ case Oband: /* @a & @a -> @a */ case Obxor: /* @a ^ @a -> @a */ case Obsl: /* @a << @a -> @a */ case Obsr: /* @a >> @a -> @a */ case Obnot: /* ~@a -> @a */ case Opreinc: /* ++@a -> @a */ case Opredec: /* --@a -> @a */ case Opostinc: /* @a++ -> @a */ case Opostdec: /* @a-- -> @a */ case Omodeq: /* @a %= @a -> @a */ case Oboreq: /* @a |= @a -> @a */ case Obandeq: /* @a &= @a -> @a */ case Obxoreq: /* @a ^= @a -> @a */ case Obsleq: /* @a <<= @a -> @a */ case Obsreq: /* @a >>= @a -> @a */ infersub(n, ret, sawret, &isconst); t = type(args[0]); constrain(n, t, traittab[Tcnum]); constrain(n, t, traittab[Tcint]); isconst = args[0]->expr.isconst; for (i = 1; i < nargs; i++) { isconst = isconst && args[i]->expr.isconst; t = unify(n, t, type(args[i])); } n->expr.isconst = isconst; settype(n, t); break; case Oasn: /* @a = @a -> @a */ infersub(n, ret, sawret, &isconst); t = type(args[0]); for (i = 1; i < nargs; i++) t = unify(n, t, type(args[i])); settype(n, t); if (args[0]->expr.isconst) fatal(n, "attempting to assign constant \"%s\"", ctxstr(args[0])); break; /* operands same type, returning bool */ case Olor: /* @a || @b -> bool */ if (n->expr.ispat) { infersub(n, ret, sawret, &isconst); t = type(args[0]); for (i = 1; i < nargs; i++) t = unify(n, t, type(args[i])); n->expr.isconst = isconst; settype(n, t); break; } case Oland: /* @a && @b -> bool */ case Oeq: /* @a == @a -> bool */ case One: /* @a != @a -> bool */ case Ogt: /* @a > @a -> bool */ case Oge: /* @a >= @a -> bool */ case Olt: /* @a < @a -> bool */ case Ole: /* @a <= @b -> bool */ infersub(n, ret, sawret, &isconst); t = type(args[0]); for (i = 1; i < nargs; i++) unify(n, t, type(args[i])); settype(n, mktype(Zloc, Tybool)); break; case Olnot: /* !bool -> bool */ infersub(n, ret, sawret, &isconst); t = unify(n, type(args[0]), mktype(Zloc, Tybool)); settype(n, t); break; /* reach into a type and pull out subtypes */ case Oaddr: /* &@a -> @a* */ infersub(n, ret, sawret, &isconst); settype(n, mktyptr(n->loc, type(args[0]))); break; case Oderef: /* @a# -> @a */ infersub(n, ret, sawret, &isconst); t = unify(n, type(args[0]), mktyptr(n->loc, mktyvar(n->loc))); settype(n, t->sub[0]); break; case Oidx: /* @a[@b::tcint] -> @a */ infersub(n, ret, sawret, &isconst); b = mktyvar(n->loc); t = mktyvar(n->loc); t->seqaux = b; unify(n, type(args[0]), t); constrain(n, type(args[0]), traittab[Tcidx]); constrain(n, type(args[1]), traittab[Tcint]); settype(n, b); break; case Oslice: /* @a[@b::tcint,@b::tcint] -> @a[,] */ infersub(n, ret, sawret, &isconst); b = mktyvar(n->loc); t = mktyvar(n->loc); t->seqaux = b; unify(n, type(args[0]), t); constrain(n, type(args[1]), traittab[Tcint]); constrain(n, type(args[1]), traittab[Tcnum]); constrain(n, type(args[2]), traittab[Tcint]); constrain(n, type(args[2]), traittab[Tcnum]); settype(n, mktyslice(n->loc, b)); break; /* special cases */ case Otupmemb: /* @a.N -> @b, verify type(@a.N)==@b later */ case Omemb: /* @a.Ident -> @b, verify type(@a.Ident)==@b later */ infersub(n, ret, sawret, &isconst); settype(n, mktyvar(n->loc)); delayedcheck(n); break; case Osize: /* sizeof(@a) -> size */ settype(n, mktylike(n->loc, Tyuint)); inferdecl(args[0]); n->expr.isconst = 1; break; case Ocall: /* (@a, @b, @c, ... -> @r)(@a, @b, @c, ...) -> @r */ infersub(n, ret, sawret, &isconst); unifycall(n); break; case Ocast: /* (@a : @b) -> @b */ infersub(n, ret, sawret, &isconst); delayedcheck(n); break; case Oret: /* -> @a -> void */ infersub(n, ret, sawret, &isconst); if (!ret) fatal(n, "returns are not valid near %s", ctxstr(n)); if (sawret) *sawret = 1; t = unify(n, ret, type(args[0])); settype(n, t); break; case Obreak: case Ocontinue: /* nullary: nothing to infer. */ settype(n, mktype(Zloc, Tyvoid)); break; case Ojmp: /* goto void* -> void */ if (args[0]->type == Nlit && args[0]->lit.littype == Llbl) args[0] = getlbl(curstab(), args[0]->loc, args[0]->lit.lblname); infersub(n, ret, sawret, &isconst); settype(n, mktype(Zloc, Tyvoid)); break; case Ovar: /* a:@a -> @a */ infersub(n, ret, sawret, &isconst); /* if we created this from a namespaced var, the type should be * set, and the normal lookup is expected to fail. Since we're * already done with this node, we can just return. */ if (n->expr.type) return; ns = curstab(); if (args[0]->name.ns) ns = getns(args[0]->name.ns); s = getdcl(ns, args[0]); if (!s) fatal(n, "undeclared var %s", ctxstr(args[0])); if (n->expr.param && !s->decl.trait) fatal(n, "var %s must refer to a trait decl", ctxstr(args[0])); pushenv(s->decl.env); initvar(n, s); popenv(s->decl.env); break; case Ogap: /* _ -> @a */ if (n->expr.type) return; n->expr.type = mktyvar(n->loc); break; case Oucon: inferucon(n, &n->expr.isconst); break; case Otup: infertuple(n, &n->expr.isconst); break; case Ostruct: inferstruct(n, &n->expr.isconst); break; case Oarr: inferarray(n, &n->expr.isconst); break; case Olit: /* <lit>:@a::tyclass -> @a */ infersub(n, ret, sawret, &isconst); switch (args[0]->lit.littype) { case Lfunc: infernode(&args[0]->lit.fnval, NULL, NULL); /* FIXME: env capture means this is non-const */ n->expr.isconst = 1; break; case Llbl: s = getlbl(curstab(), args[0]->loc, args[0]->lit.lblname); if (!s) fatal(n, "unable to find label %s in function scope\n", args[0]->lit.lblname); *np = s; break; default: n->expr.isconst = 1; break; } settype(n, type(args[0])); break; case Otern: infersub(n, NULL, sawret, &isconst); unify(n, type(args[0]), mktype(n->loc, Tybool)); unify(n, type(args[1]), type(args[2])); settype(n, type(args[1])); break; case Oundef: infersub(n, ret, sawret, &isconst); settype(n, mktype(n->loc, Tyvoid)); break; case Odef: case Odead: n->expr.type = mktype(n->loc, Tyvoid); break; /* unexpected in frontend */ case Obad: case Ocjmp: case Ovjmp: case Oset: case Oslbase: case Osllen: case Outag: case Ocallind: case Oblit: case Oclear: case Oudata: case Otrunc: case Oswiden: case Ozwiden: case Oint2flt: case Oflt2int: case Oflt2flt: case Ofadd: case Ofsub: case Ofmul: case Ofdiv: case Ofneg: case Ofeq: case Ofne: case Ofgt: case Ofge: case Oflt: case Ofle: case Oueq: case Oune: case Ougt: case Ouge: case Oult: case Oule: case Otupget: case Numops: die("Should not see %s in fe", opstr[exprop(n)]); break; } } static void inferfunc(Node *n) { size_t i; int sawret; sawret = 0; for (i = 0; i < n->func.nargs; i++) infernode(&n->func.args[i], NULL, NULL); infernode(&n->func.body, n->func.type->sub[0], &sawret); /* if there's no return stmt in the function, assume void ret */ if (!sawret) unify(n, type(n)->sub[0], mktype(Zloc, Tyvoid)); } static void specializeimpl(Node *n) { Node *dcl, *proto, *name, *sym; Tysubst *subst; Type *ty; Trait *tr; size_t i, j; int generic; char *traitns; tr = gettrait(curstab(), n->impl.traitname); if (!tr) fatal(n, "no trait %s\n", namestr(n->impl.traitname)); n->impl.trait = tr; traitns = tr->name->name.ns; dcl = NULL; if (n->impl.naux != tr->naux) fatal(n, "%s incompatibly specialized with %zd types instead of %zd types", namestr(n->impl.traitname), n->impl.naux, tr->naux); n->impl.type = tf(n->impl.type); pushenv(n->impl.env); for (i = 0; i < n->impl.naux; i++) n->impl.aux[i] = tf(n->impl.aux[i]); for (i = 0; i < n->impl.ndecls; i++) { /* look up the prototype */ proto = NULL; dcl = n->impl.decls[i]; /* since the decls in an impl are not installed in a namespace, their names are not updated when we call updatens() on the symbol table. Because we need to do namespace dependent comparisons for specializing, we need to set the namespace here. */ if (file.globls->name) setns(dcl->decl.name, traitns); for (j = 0; j < tr->nproto; j++) { if (nsnameeq(dcl->decl.name, tr->proto[j]->decl.name)) { proto = tr->proto[j]; break; } } if (!proto) fatal(n, "declaration %s missing in %s, near %s", namestr(dcl->decl.name), namestr(tr->name), ctxstr(n)); /* infer and unify types */ pushenv(proto->decl.env); verifytraits(n, tr->param, n->impl.type); subst = mksubst(); substput(subst, tr->param, n->impl.type); for (j = 0; j < tr->naux; j++) substput(subst, tr->aux[j], n->impl.aux[j]); ty = tyspecialize(type(proto), subst, delayed); substfree(subst); popenv(proto->decl.env); generic = hasparams(ty); if (generic) ingeneric++; inferdecl(dcl); unify(n, type(dcl), ty); /* and put the specialization into the global stab */ name = genericname(proto, n->impl.type, ty); sym = getdcl(file.globls, name); if (sym) fatal(n, "trait %s already specialized with %s on %s:%d", namestr(tr->name), tystr(n->impl.type), fname(sym->loc), lnum(sym->loc)); dcl->decl.name = name; putdcl(file.globls, dcl); htput(proto->decl.impls, n->impl.type, dcl); dcl->decl.isconst = 1; if (ty->type == Tygeneric || hasparams(ty)) { dcl->decl.isgeneric = 1; lappend(&proto->decl.gimpl, &proto->decl.ngimpl, dcl); lappend(&proto->decl.gtype, &proto->decl.ngtype, ty); } dcl->decl.vis = tr->vis; lappend(&impldecl, &nimpldecl, dcl); if (generic) ingeneric--; } popenv(n->impl.env); } static void inferdecl(Node *n) { Type *t; t = tf(decltype(n)); if (t->type == Tygeneric && !n->decl.isgeneric) { t = tyfreshen(NULL, t); unifyparams(n, t, decltype(n)); } settype(n, t); if (n->decl.init) { inferexpr(&n->decl.init, NULL, NULL); unify(n, type(n), type(n->decl.init)); if (n->decl.isconst && !n->decl.init->expr.isconst) fatal(n, "non-const initializer for \"%s\"", ctxstr(n)); } } static void inferstab(Stab *s) { void **k; size_t n, i; Node *dcl; Type *t; void *se; k = htkeys(s->dcl, &n); se = curenv(); for (i = 0; i < n; i++) { dcl = htget(s->dcl, k[i]); pushenv(dcl->decl.env); tf(type(dcl)); popenv(dcl->decl.env); assert(se == curenv()); } free(k); k = htkeys(s->ty, &n); for (i = 0; i < n; i++) { t = gettype(s, k[i]); if (!t) fatal(k[i], "undefined type %s", namestr(k[i])); t = tysearch(t); setsuperenv(t->env, curenv()); pushenv(t->env); tyresolve(t); popenv(t->env); updatetype(s, k[i], t); } free(k); } static void infernode(Node **np, Type *ret, int *sawret) { size_t i, nbound; Node **bound, *n, *pat; Type *t, *b, *e; n = *np; if (!n) return; if (n->inferred) return; n->inferred = 1; switch (n->type) { case Ndecl: if (n->decl.isgeneric) ingeneric++; indentdepth++; setsuperenv(n->decl.env, curenv()); pushenv(n->decl.env); inferdecl(n); if (hasparams(type(n)) && !ingeneric) fatal(n, "generic type in non-generic near %s", ctxstr(n)); popenv(n->decl.env); indentdepth--; if (n->decl.isgeneric) ingeneric--; break; case Nblock: setsuper(n->block.scope, curstab()); pushstab(n->block.scope); inferstab(n->block.scope); for (i = 0; i < n->block.nstmts; i++) infernode(&n->block.stmts[i], ret, sawret); popstab(); break; case Nifstmt: infernode(&n->ifstmt.cond, NULL, sawret); infernode(&n->ifstmt.iftrue, ret, sawret); infernode(&n->ifstmt.iffalse, ret, sawret); unify(n, type(n->ifstmt.cond), mktype(n->loc, Tybool)); break; case Nloopstmt: setsuper(n->loopstmt.scope, curstab()); pushstab(n->loopstmt.scope); infernode(&n->loopstmt.init, ret, sawret); infernode(&n->loopstmt.cond, NULL, sawret); infernode(&n->loopstmt.step, ret, sawret); infernode(&n->loopstmt.body, ret, sawret); unify(n, type(n->loopstmt.cond), mktype(n->loc, Tybool)); popstab(); break; case Niterstmt: bound = NULL; nbound = 0; inferpat(&n->iterstmt.elt, NULL, &bound, &nbound); addbindings(n->iterstmt.body, bound, nbound); infernode(&n->iterstmt.seq, NULL, sawret); infernode(&n->iterstmt.body, ret, sawret); e = type(n->iterstmt.elt); t = type(n->iterstmt.seq); constrain(n, t, traittab[Tciter]); b = basetype(t); if (b && t->type != Typtr) unify(n, e, b); else t->seqaux = e; delayedcheck(n); break; case Nmatchstmt: infernode(&n->matchstmt.val, NULL, sawret); for (i = 0; i < n->matchstmt.nmatches; i++) { infernode(&n->matchstmt.matches[i], ret, sawret); pat = n->matchstmt.matches[i]->match.pat; unify(pat, type(n->matchstmt.val), type(n->matchstmt.matches[i]->match.pat)); } break; case Nmatch: bound = NULL; nbound = 0; inferpat(&n->match.pat, NULL, &bound, &nbound); addbindings(n->match.block, bound, nbound); infernode(&n->match.block, ret, sawret); break; case Nexpr: inferexpr(np, ret, sawret); break; case Nfunc: setsuper(n->func.scope, curstab()); pushstab(n->func.scope); setsuperenv(n->func.env, curenv()); pushenv(n->func.env); inferstab(n->func.scope); inferfunc(n); popenv(n->func.env); popstab(); break; case Nimpl: specializeimpl(n); break; case Nlit: case Nname: case Nuse: break; case Nnone: die("Nnone should not be seen as node type!"); break; } } /* returns the final type for t, after all unification * and default constraint selections */ static Type * tyfix(Node *ctx, Type *orig, int noerr) { static Type *tyint, *tyflt; static Bitset *intset, *fltset; Type *t, *d, *base; Tyenv *env; vlong val; size_t i; char buf[1024]; if (!tyint) { tyint = mktype(Zloc, Tyint); intset = mkbs(); traitsfor(tyint, intset); } if (!tyflt) { tyflt = mktype(Zloc, Tyflt64); fltset = mkbs(); traitsfor(tyflt, fltset); } t = tysearch(tf(orig)); env = t->env; if (env) pushenv(env); base = orig->seqaux; /* Process delayed type mappings. */ if (orig->type == Tyvar && hthas(delayed, orig)) { d = htget(delayed, orig); if (t->type == Tyvar) { /* tyvar is guaranteed to unify error-free */ unify(ctx, t, d); t = tf(t); } else if (tybase(t)->type != d->type && !noerr) { fatal(ctx, "type %s not compatible with %s near %s\n", tystr(t), tystr(d), ctxstr(ctx)); } } /* Default the type */ if (t->type == Tyvar && t->trneed) { if (bsissubset(t->trneed, intset)) t = tyint; else if (bsissubset(t->trneed, fltset)) t = tyflt; } if (!t->fixed) { t->fixed = 1; switch(t->type) { case Tyarray: if (t->type == Tyarray && t->asize) t->asize = fold(t->asize, 1); if (t->asize && getintlit(t->asize, &val) && val < 0) fatal(t->asize, "negative array size %lld\n", val); typesub(t->asize, noerr); break; case Tystruct: inaggr++; for (i = 0; i < t->nmemb; i++) typesub(t->sdecls[i], noerr); inaggr--; break; case Tyunion: for (i = 0; i < t->nmemb; i++) { if (t->udecls[i]->etype) { tyresolve(t->udecls[i]->etype); t->udecls[i]->etype = tyfix(ctx, t->udecls[i]->etype, noerr); } } break; case Tyname: for (i = 0; i < t->narg; i++) t->arg[i] = tyfix(ctx, t->arg[i], noerr); break; default: break; } } for (i = 0; i < t->nsub; i++) t->sub[i] = tyfix(ctx, t->sub[i], noerr); if (t->type == Tyvar && !noerr) fatal(ctx, "underconstrained type %s near %s", tyfmt(buf, 1024, t), ctxstr(ctx)); if (base) { if (base != orig) base = tyfix(ctx, base, noerr); t->seqaux = base; } if (env) popenv(env); return t; } static void checkcast(Node *n, Postcheck ***pc, size_t *npc) { /* FIXME: actually verify the casts. Right now, it's ok to leave thi * unimplemented because bad casts get caught by the backend. */ } static void infercompn(Node *n, Postcheck ***post, size_t *npost) { Node *aggr, *memb, **nl; int found, ismemb; Postcheck *pc; uvlong idx; size_t i; Type *t; aggr = n->expr.args[0]; memb = n->expr.args[1]; ismemb = n->expr.op == Omemb; found = 0; t = tybase(tf(type(aggr))); /* all array-like types have a fake "len" member that we emulate */ if (ismemb && (t->type == Tyslice || t->type == Tyarray)) { if (!strcmp(namestr(memb), "len")) { constrain(n, type(n), traittab[Tcnum]); constrain(n, type(n), traittab[Tcint]); found = 1; } } else if (ismemb && t->type == Tyunion) { if (!strcmp(namestr(memb), "tag")) { constrain(n, type(n), traittab[Tcnum]); constrain(n, type(n), traittab[Tcint]); found = 1; } } else { if (tybase(t)->type == Typtr) t = tybase(tf(t->sub[0])); if (tybase(t)->type == Tyvar) { pc = xalloc(sizeof(Postcheck)); pc->node = n; pc->stab = curstab(); pc->env = curenv(); lappend(post, npost, pc); return; } if (ismemb) { /* * aggregate types for the member, and unify the expression with the * member type; ie: * * x: aggrtype y : memb in aggrtype * --------------------------------------- * x.y : membtype */ if (tybase(t)->type != Tystruct) fatal(n, "type %s does not support member operators near %s", tystr(t), ctxstr(n)); nl = t->sdecls; for (i = 0; i < t->nmemb; i++) { if (!strcmp(namestr(memb), declname(nl[i]))) { unify(n, type(n), decltype(nl[i])); found = 1; break; } } } else { /* tuple access; similar to the logic for member accesses */ if (tybase(t)->type != Tytuple) fatal(n, "type %s does not support tuple access operators near %s", tystr(t), ctxstr(n)); assert(memb->type == Nlit); idx = memb->lit.intval; if (idx >= t->nsub) fatal(n, "cannot access element %llu of a tuple of type %s near %s", idx, tystr(t), ctxstr(n)); unify(n, type(n), t->sub[idx]); found = 1; } } if (!found) fatal(aggr, "type %s has no member \"%s\" near %s", tystr(type(aggr)), ctxstr(memb), ctxstr(aggr)); } static void checkstruct(Node *n, Postcheck ***post, size_t *npost) { Type *t, *et; Node *val, *name; size_t i, j; Postcheck *pc; t = tybase(tf(n->lit.type)); /* * If we haven't inferred the type, and it's inside another struct, * we'll eventually get to it. * * If, on the other hand, it is genuinely underspecified, we'll give * a better error on it later. */ if (t->type == Tyvar) return; if (t->type != Tystruct) fatal(n, "struct literal is used as non struct type %s", tystr(n->lit.type)); for (i = 0; i < n->expr.nargs; i++) { val = n->expr.args[i]; name = val->expr.idx; et = NULL; for (j = 0; j < t->nmemb; j++) { if (!strcmp(namestr(t->sdecls[j]->decl.name), namestr(name))) { et = type(t->sdecls[j]); break; } } if (et) { unify(val, et, type(val)); } else { assert(post != NULL); pc = xalloc(sizeof(Postcheck)); pc->node = n; pc->stab = curstab(); pc->env = curenv(); lappend(post, npost, pc); return; } } } static void checkvar(Node *n, Postcheck ***post, size_t *npost) { Node *proto, *dcl; Type *ty; proto = decls[n->expr.did]; ty = NULL; dcl = NULL; pushenv(proto->decl.env); if (n->expr.param) dcl = htget(proto->decl.impls, tf(n->expr.param)); if (dcl) ty = dcl->decl.type; if (!ty) ty = tyfreshen(NULL, type(proto)); unify(n, type(n), ty); popenv(proto->decl.env); } static void fixiter(Node *n, Type *ty, Type *base) { size_t i, bestidx; int r, bestrank; Type *b, *t, *orig; Tysubst *ts; Node *impl; ty = tysearch(ty); b = ty->seqaux; if (!b) return; bestrank = -1; bestidx = 0; for (i = 0; i < nimpltab; i++) { if (impltab[i]->impl.trait != traittab[Tciter]) continue; r = tymatchrank(impltab[i]->impl.type, ty); if (r > bestrank) { bestrank = r; bestidx = i; } } if (bestrank >= 0) { impl = impltab[bestidx]; orig = impl->impl.type; t = tf(impl->impl.aux[0]); ts = mksubst(); for (i = 0; i < ty->narg; i++) substput(ts, tf(orig->arg[i]), ty->arg[i]); t = tyfreshen(ts, t); substfree(ts); unify(n, t, base); } } static void postcheckpass(Postcheck ***post, size_t *npost) { size_t i; Node *n; for (i = 0; i < npostcheck; i++) { n = postcheck[i]->node; pushstab(postcheck[i]->stab); pushenv(postcheck[i]->env); if (n->type == Nexpr) { switch (exprop(n)) { case Otupmemb: case Omemb: infercompn(n, post, npost); break; case Ocast: checkcast(n, post, npost); break; case Ostruct: checkstruct(n, post, npost); break; case Ovar: checkvar(n, post, npost); break; default: die("should not see %s in postcheck\n", opstr[exprop(n)]); break; } } else if (n->type == Niterstmt) { fixiter(n, type(n->iterstmt.seq), type(n->iterstmt.elt)); } popenv(postcheck[i]->env); popstab(); } } static void postinfer(void) { Postcheck **post; size_t npost, nlast; /* Iterate until we reach a fixpoint. */ nlast = 0; while (1) { post = NULL; npost = 0; postcheckpass(&post, &npost); if (npost == nlast) { break; } nlast = npost; } } /* After inference, replace all * types in symbol tables with * the final computed types */ static void stabsub(Stab *s) { void **k; size_t n, i; Type *t; Node *d; char *dt; k = htkeys(s->ty, &n); for (i = 0; i < n; i++) { t = tysearch(gettype(s, k[i])); updatetype(s, k[i], t); tyfix(k[i], t, 0); } free(k); k = htkeys(s->dcl, &n); for (i = 0; i < n; i++) { d = getdcl(s, k[i]); pushenv(d->decl.env); d->decl.type = tyfix(d, d->decl.type, 0); popenv(d->decl.env); if (!d->decl.isconst && !d->decl.isgeneric) continue; if (d->decl.trait) continue; dt = "const"; if (d->decl.isgeneric) dt = "generic"; if (!d->decl.isimport && !d->decl.isextern && !d->decl.init) fatal(d, "non-extern %s \"%s\" has no initializer", dt, ctxstr(d)); } free(k); } static void checkrange(Node *n) { Type *t; int64_t sval; uint64_t uval; static const int64_t svranges[][2] = { /* signed ints */ [Tyint8] = {-128LL, 127LL}, [Tyint16] = {-32768LL, 32767LL}, /* FIXME: this has been doubled allow for uints... */ [Tyint32] = {-2147483648LL, 2 * 2147483647LL}, [Tyint] = {-2147483648LL, 2 * 2147483647LL}, [Tyint64] = {-9223372036854775808ULL, 9223372036854775807LL}, }; static const uint64_t uvranges[][2] = { [Tybyte] = {0, 255ULL}, [Tyuint8] = {0, 255ULL}, [Tyuint16] = {0, 65535ULL}, [Tyuint32] = {0, 4294967295ULL}, [Tyuint64] = {0, 18446744073709551615ULL}, [Tychar] = {0, 4294967295ULL}, }; /* signed types */ t = type(n); if (t->type >= Tyint8 && t->type <= Tyint64) { sval = n->lit.intval; if (sval < svranges[t->type][0] || sval > svranges[t->type][1]) fatal(n, "literal value %lld out of range for type \"%s\"", sval, tystr(t)); } else if ((t->type >= Tybyte && t->type <= Tyint64) || t->type == Tychar) { uval = n->lit.intval; if (uval < uvranges[t->type][0] || uval > uvranges[t->type][1]) fatal(n, "literal value %llu out of range for type \"%s\"", uval, tystr(t)); } } static int initcompatible(Type *t) { if (t->type != Tyfunc) return 0; if (t->nsub != 1) return 0; if (tybase(t->sub[0])->type != Tyvoid) return 0; return 1; } static int maincompatible(Type *t) { if (t->nsub > 2) return 0; if (tybase(t->sub[0])->type != Tyvoid) return 0; if (t->nsub == 2) { t = tybase(t->sub[1]); if (t->type != Tyslice) return 0; t = tybase(t->sub[0]); if (t->type != Tyslice) return 0; t = tybase(t->sub[0]); if (t->type != Tybyte) return 0; } return 1; } static void verifyop(Node *n) { Type *ty, *bty; Node *a; char *sa, *sb; size_t i, j; int found; ty = exprtype(n); bty = tybase(ty); switch (exprop(n)) { case Ostruct: if (bty->type != Tystruct) fatal(n, "wrong type for struct literal: %s\n", tystr(ty)); for (i = 0; i < n->expr.nargs; i++) { found = 0; a = n->expr.args[i]; for (j = 0; j < bty->nmemb; j++) { sa = namestr(a->expr.idx); sb = declname(bty->sdecls[j]); if (!strcmp(sa, sb)) found = 1; } if (!found) fatal(n, "type %s has no member %s", tystr(ty), namestr(a->expr.idx)); } break; case Oarr: if (bty->type != Tyarray) fatal(n, "wrong type for struct literal: %s\n", tystr(ty)); break; default: break; } } /* After type inference, replace all type * with the final computed type */ static void typesub(Node *n, int noerr) { char *name; size_t i; Node *l; if (!n) return; switch (n->type) { case Ndecl: pushenv(n->decl.env); settype(n, tyfix(n, type(n), noerr)); if (n->decl.init) typesub(n->decl.init, noerr); if (streq(declname(n), "main")) if (!maincompatible(tybase(decltype(n)))) fatal(n, "main must be (->void) or (byte[:][:] -> void), got %s", tystr(decltype(n))); name = declname(n); if (streq(name, "__init__") || streq(name, "__fini__")) if (!initcompatible(tybase(decltype(n)))) fatal(n, "%s must be (->void), got %s", name, tystr(decltype(n))); popenv(n->decl.env); break; case Nblock: pushstab(n->block.scope); for (i = 0; i < n->block.nstmts; i++) typesub(n->block.stmts[i], noerr); popstab(); break; case Nifstmt: typesub(n->ifstmt.cond, noerr); typesub(n->ifstmt.iftrue, noerr); typesub(n->ifstmt.iffalse, noerr); break; case Nloopstmt: typesub(n->loopstmt.cond, noerr); typesub(n->loopstmt.init, noerr); typesub(n->loopstmt.step, noerr); typesub(n->loopstmt.body, noerr); break; case Niterstmt: typesub(n->iterstmt.elt, noerr); typesub(n->iterstmt.seq, noerr); typesub(n->iterstmt.body, noerr); if (!ingeneric) additerspecialization(n, curstab()); break; case Nmatchstmt: typesub(n->matchstmt.val, noerr); for (i = 0; i < n->matchstmt.nmatches; i++) { typesub(n->matchstmt.matches[i], noerr); } break; case Nmatch: typesub(n->match.pat, noerr); typesub(n->match.block, noerr); break; case Nexpr: settype(n, tyfix(n, type(n), 0)); if (n->expr.param) n->expr.param = tyfix(n, n->expr.param, 0); typesub(n->expr.idx, noerr); if (exprop(n) == Ocast && exprop(n->expr.args[0]) == Olit) { l = n->expr.args[0]->expr.args[0]; if(l->lit.littype == Lint && istyint(exprtype(n))) { settype(n->expr.args[0], exprtype(n)); settype(n->expr.args[0]->expr.args[0], exprtype(n)); } } if (exprop(n) == Oauto) adddispspecialization(n, curstab()); for (i = 0; i < n->expr.nargs; i++) typesub(n->expr.args[i], noerr); if (!noerr) verifyop(n); break; case Nfunc: pushstab(n->func.scope); settype(n, tyfix(n, n->func.type, 0)); for (i = 0; i < n->func.nargs; i++) typesub(n->func.args[i], noerr); typesub(n->func.body, noerr); popstab(); break; case Nlit: settype(n, tyfix(n, type(n), 0)); switch (n->lit.littype) { case Lfunc: typesub(n->lit.fnval, noerr); break; case Lint: checkrange(n); break; default: break; } break; case Nimpl: pushenv(n->impl.env); putimpl(curstab(), n); popenv(n->impl.env); case Nname: case Nuse: break; case Nnone: die("Nnone should not be seen as node type!"); break; } } static Type * itertype(Node *n, Type *ret) { Type *it, *val, *itp, *valp, *fn; it = exprtype(n); itp = mktyptr(n->loc, it); val = basetype(it); if (!val) die("FAIL! %s", tystr(it)); valp = mktyptr(n->loc, val); fn = mktyfunc(n->loc, NULL, 0, ret); lappend(&fn->sub, &fn->nsub, itp); lappend(&fn->sub, &fn->nsub, valp); return fn; } /* Take generics and build new versions of them * with the type parameters replaced with the * specialized types */ static void specialize(void) { Node *d, *n, *name; Type *ty, *it, *dt; size_t i; Trait *tr; for (i = 0; i < nimpldecl; i++) { d = impldecl[i]; lappend(&file.stmts, &file.nstmts, d); typesub(d, 0); } for (i = 0; i < nspecializations; i++) { pushstab(specializationscope[i]); n = specializations[i]; if (n->type == Nexpr && exprop(n) == Oauto) { tr = traittab[Tcdisp]; assert(tr->nproto == 1); ty = exprtype(n); dt = mktyfunc(n->loc, NULL, 0, mktype(n->loc, Tyvoid)); lappend(&dt->sub, &dt->nsub, ty); d = specializedcl(tr->proto[0], ty, dt, &name); htput(tr->proto[0]->decl.impls, ty, d); } else if (n->type == Nexpr && exprop(n) == Ovar) { d = specializedcl(genericdecls[i], n->expr.param, n->expr.type, &name); n->expr.args[0] = name; n->expr.did = d->decl.did; /* we need to sub in default types in the specialization, so call * typesub on the specialized function */ typesub(d, 0); } else if (n->type == Niterstmt) { tr = traittab[Tciter]; assert(tr->nproto == 2); ty = exprtype(n->iterstmt.seq); if (ty->type == Typaram) goto enditer; it = itertype(n->iterstmt.seq, mktype(n->loc, Tybool)); d = specializedcl(tr->proto[0], ty, it, &name); htput(tr->proto[0]->decl.impls, ty, d); it = itertype(n->iterstmt.seq, mktype(n->loc, Tyvoid)); d = specializedcl(tr->proto[1], ty, it, &name); htput(tr->proto[1]->decl.impls, ty, d); } else { die("unknown node for specialization\n"); } enditer: popstab(); } } static Traitmap * mktraitmap(void) { Traitmap *m; m = zalloc(sizeof(Traitmap)); m->traits = mkbs(); m->name = mkht(namehash, nameeq); return m; } static void builtintraits(void) { size_t i; /* char::(numeric,integral) */ for (i = 0; i < Ntypes; i++) tytraits[i] = mkbs(); bsput(tytraits[Tychar], Tcnum); bsput(tytraits[Tychar], Tcint); bsput(tytraits[Tybyte], Tcnum); bsput(tytraits[Tybyte], Tcint); /* <integer types>::(numeric,integral) */ for (i = Tyint8; i < Tyflt32; i++) { bsput(tytraits[i], Tcnum); bsput(tytraits[i], Tcint); } /* <floats>::(numeric,floating) */ bsput(tytraits[Tyflt32], Tcnum); bsput(tytraits[Tyflt32], Tcflt); bsput(tytraits[Tyflt64], Tcnum); bsput(tytraits[Tyflt64], Tcflt); /* @a*::(sliceable) */ bsput(tytraits[Typtr], Tcslice); /* @a[:]::(indexable,sliceable) */ bsput(tytraits[Tyslice], Tcidx); bsput(tytraits[Tyslice], Tcslice); bsput(tytraits[Tyslice], Tciter); /* @a[SZ]::(indexable,sliceable) */ bsput(tytraits[Tyarray], Tcidx); bsput(tytraits[Tyarray], Tcslice); bsput(tytraits[Tyarray], Tciter); /* @a::function */ bsput(tytraits[Tyfunc], Tcfunc); for (i = 0; i < Ntypes; i++) { traitmap->sub[i] = mktraitmap(); bsunion(traitmap->sub[i]->traits, tytraits[i]); } } static Trait* findtrait(Node *impl) { Trait *tr; Node *n; Stab *ns; tr = impl->impl.trait; if (!tr) { n = impl->impl.traitname; ns = file.globls; if (n->name.ns) ns = getns(n->name.ns); if (ns) tr = gettrait(ns, n); if (!tr) fatal(impl, "trait %s does not exist near %s", namestr(impl->impl.traitname), ctxstr(impl)); if (tr->naux != impl->impl.naux) fatal(impl, "incompatible implementation of %s: mismatched aux types", namestr(impl->impl.traitname), ctxstr(impl)); } return tr; } static void addtraittab(Traitmap *m, Trait *tr, Type *ty) { Bitset *bs; Traitmap *mm; size_t i; if (!m->sub[ty->type]) m->sub[ty->type] = mktraitmap(); mm = m->sub[ty->type]; switch (ty->type) { case Tygeneric: case Typaram: for (i = 0; i < Ntypes; i++) { if (i == Typaram) continue; if (!m->sub[i]) m->sub[i] = mktraitmap(); mm = m->sub[i]; lappend(&mm->filter, &mm->nfilter, ty); lappend(&mm->filtertr, &mm->nfiltertr, tr); } break; case Tyname: if (ty->ngparam == 0) { bs = htget(mm->name, ty->name); if (!bs) { bs = mkbs(); htput(mm->name, ty->name, bs); } bsput(bs, tr->uid); } else { lappend(&mm->filter, &m->nfilter, ty); lappend(&mm->filtertr, &m->nfiltertr, tr); } break; case Typtr: case Tyarray: addtraittab(mm, tr, ty->sub[0]); break; default: if (istyprimitive(ty)) { bsput(mm->traits, tr->uid); } else { lappend(&mm->filter, &mm->nfilter, ty); lappend(&mm->filtertr, &mm->nfiltertr, tr); } } } static void initimpl(void) { size_t i; Node *impl; Trait *tr; Type *ty; pushstab(file.globls); traitmap = zalloc(sizeof(Traitmap)); builtintraits(); for (i = 0; i < nimpltab; i++) { impl = impltab[i]; tr = findtrait(impl); pushenv(impl->impl.env); ty = tf(impl->impl.type); addtraittab(traitmap, tr, ty); if (tr->uid == Tciter) ty->seqaux = tf(impl->impl.aux[0]); popenv(impl->impl.env); } popstab(); } static void verify(void) { Type *t; Node *n; size_t i; pushstab(file.globls); /* for now, traits can only be declared globally */ for (i = 0; i < file.nstmts; i++) { n = file.stmts[i]; if (n->type == Nimpl) { /* we merge, so we need to get it back again when error checking */ if (n->impl.isproto) fatal(n, "missing implementation for prototype '%s %s'", namestr(n->impl.traitname), tystr(n->impl.type)); } } for (i = 0; i < ntypes; i++) { t = types[i]; if (t->type != Tyarray) continue; t->asize = fold(t->asize, 1); if (t->asize && exprop(t->asize) != Olit) fatal(t->asize, "nonconstant array size near %s\n", ctxstr(t->asize)); } } void infer(void) { size_t i; delayed = mkht(tyhash, tyeq); initimpl(); /* do the inference */ pushstab(file.globls); inferstab(file.globls); for (i = 0; i < file.nstmts; i++) infernode(&file.stmts[i], NULL, 0); popstab(); postinfer(); /* and replace type vars with actual types */ pushstab(file.globls); stabsub(file.globls); for (i = 0; i < file.nstmts; i++) typesub(file.stmts[i], 0); popstab(); specialize(); verify(); }