// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. #include #include #include "go.h" #include "md5.h" #include "y.tab.h" #include "yerr.h" typedef struct Error Error; struct Error { int lineno; int seq; char *msg; }; static Error *err; static int nerr; static int merr; void errorexit(void) { flusherrors(); if(outfile) remove(outfile); exits("error"); } extern int yychar; int parserline(void) { if(yychar != 0 && yychar != -2) // parser has one symbol lookahead return prevlineno; return lineno; } static void adderr(int line, char *fmt, va_list arg) { Fmt f; Error *p; fmtstrinit(&f); fmtprint(&f, "%L: ", line); fmtvprint(&f, fmt, arg); fmtprint(&f, "\n"); if(nerr >= merr) { if(merr == 0) merr = 16; else merr *= 2; p = realloc(err, merr*sizeof err[0]); if(p == nil) { merr = nerr; flusherrors(); print("out of memory\n"); errorexit(); } err = p; } err[nerr].seq = nerr; err[nerr].lineno = line; err[nerr].msg = fmtstrflush(&f); nerr++; } static int errcmp(const void *va, const void *vb) { Error *a, *b; a = (Error*)va; b = (Error*)vb; if(a->lineno != b->lineno) return a->lineno - b->lineno; if(a->seq != b->seq) return a->seq - b->seq; return strcmp(a->msg, b->msg); } void flusherrors(void) { int i; if(nerr == 0) return; qsort(err, nerr, sizeof err[0], errcmp); for(i=0; i= 10 && !debug['e']) { flusherrors(); print("%L: too many errors\n", line); errorexit(); } } extern int yystate, yychar; void yyerror(char *fmt, ...) { int i; static int lastsyntax; va_list arg; char buf[512], *p; if(strncmp(fmt, "syntax error", 12) == 0) { nsyntaxerrors++; if(debug['x']) print("yyerror: yystate=%d yychar=%d\n", yystate, yychar); // An unexpected EOF caused a syntax error. Use the previous // line number since getc generated a fake newline character. if(curio.eofnl) lexlineno = prevlineno; // only one syntax error per line if(lastsyntax == lexlineno) return; lastsyntax = lexlineno; if(strstr(fmt, "{ or {") || strstr(fmt, " or ?") || strstr(fmt, " or @")) { // The grammar has { and LBRACE but both show up as {. // Rewrite syntax error referring to "{ or {" to say just "{". strecpy(buf, buf+sizeof buf, fmt); p = strstr(buf, "{ or {"); if(p) memmove(p+1, p+6, strlen(p+6)+1); // The grammar has ? and @ but only for reading imports. // Silence them in ordinary errors. p = strstr(buf, " or ?"); if(p) memmove(p, p+5, strlen(p+5)+1); p = strstr(buf, " or @"); if(p) memmove(p, p+5, strlen(p+5)+1); fmt = buf; } // look for parse state-specific errors in list (see go.errors). for(i=0; i= 10 && !debug['e']) { flusherrors(); print("%L: too many errors\n", parserline()); errorexit(); } } void warn(char *fmt, ...) { va_list arg; va_start(arg, fmt); adderr(parserline(), fmt, arg); va_end(arg); hcrash(); } void warnl(int line, char *fmt, ...) { va_list arg; va_start(arg, fmt); adderr(line, fmt, arg); va_end(arg); if(debug['m']) flusherrors(); } void fatal(char *fmt, ...) { va_list arg; flusherrors(); print("%L: internal compiler error: ", lineno); va_start(arg, fmt); vfprint(1, fmt, arg); va_end(arg); print("\n"); // If this is a released compiler version, ask for a bug report. if(strncmp(getgoversion(), "release", 7) == 0) { print("\n"); print("Please file a bug report including a short program that triggers the error.\n"); print("http://code.google.com/p/go/issues/entry?template=compilerbug\n"); } hcrash(); errorexit(); } void linehist(char *file, int32 off, int relative) { Hist *h; char *cp; if(debug['i']) { if(file != nil) { if(off < 0) print("pragma %s", file); else if(off > 0) print("line %s", file); else print("import %s", file); } else print("end of import"); print(" at line %L\n", lexlineno); } if(off < 0 && file[0] != '/' && !relative) { cp = mal(strlen(file) + strlen(pathname) + 2); sprint(cp, "%s/%s", pathname, file); file = cp; } h = mal(sizeof(Hist)); h->name = file; h->line = lexlineno; h->offset = off; h->link = H; if(ehist == H) { hist = h; ehist = h; return; } ehist->link = h; ehist = h; } int32 setlineno(Node *n) { int32 lno; lno = lineno; if(n != N) switch(n->op) { case ONAME: case OTYPE: case OPACK: case OLITERAL: break; default: lineno = n->lineno; if(lineno == 0) { if(debug['K']) warn("setlineno: line 0"); lineno = lno; } } return lno; } uint32 stringhash(char *p) { int32 h; int c; h = 0; for(;;) { c = *p++; if(c == 0) break; h = h*PRIME1 + c; } if(h < 0) { h = -h; if(h < 0) h = 0; } return h; } Sym* lookup(char *name) { return pkglookup(name, localpkg); } Sym* pkglookup(char *name, Pkg *pkg) { Sym *s; uint32 h; int c; h = stringhash(name) % NHASH; c = name[0]; for(s = hash[h]; s != S; s = s->link) { if(s->name[0] != c || s->pkg != pkg) continue; if(strcmp(s->name, name) == 0) return s; } s = mal(sizeof(*s)); s->name = mal(strlen(name)+1); strcpy(s->name, name); s->pkg = pkg; s->link = hash[h]; hash[h] = s; s->lexical = LNAME; return s; } Sym* restrictlookup(char *name, Pkg *pkg) { if(!exportname(name) && pkg != localpkg) yyerror("cannot refer to unexported name %s.%s", pkg->name, name); return pkglookup(name, pkg); } // find all the exported symbols in package opkg // and make them available in the current package void importdot(Pkg *opkg, Node *pack) { Sym *s, *s1; uint32 h; int n; char *pkgerror; n = 0; for(h=0; hlink) { if(s->pkg != opkg) continue; if(s->def == N) continue; if(!exportname(s->name) || utfrune(s->name, 0xb7)) // 0xb7 = center dot continue; s1 = lookup(s->name); if(s1->def != N) { pkgerror = smprint("during import \"%Z\"", opkg->path); redeclare(s1, pkgerror); continue; } s1->def = s->def; s1->block = s->block; s1->def->pack = pack; s1->origpkg = opkg; n++; } } if(n == 0) { // can't possibly be used - there were no symbols yyerrorl(pack->lineno, "imported and not used: \"%Z\"", opkg->path); } } static void gethunk(void) { char *h; int32 nh; nh = NHUNK; if(thunk >= 10L*NHUNK) nh = 10L*NHUNK; h = (char*)malloc(nh); if(h == nil) { flusherrors(); yyerror("out of memory"); errorexit(); } hunk = h; nhunk = nh; thunk += nh; } void* mal(int32 n) { void *p; if(n >= NHUNK) { p = malloc(n); if(p == nil) { flusherrors(); yyerror("out of memory"); errorexit(); } memset(p, 0, n); return p; } while((uintptr)hunk & MAXALIGN) { hunk++; nhunk--; } if(nhunk < n) gethunk(); p = hunk; nhunk -= n; hunk += n; memset(p, 0, n); return p; } void* remal(void *p, int32 on, int32 n) { void *q; q = (uchar*)p + on; if(q != hunk || nhunk < n) { if(on+n >= NHUNK) { q = mal(on+n); memmove(q, p, on); return q; } if(nhunk < on+n) gethunk(); memmove(hunk, p, on); p = hunk; hunk += on; nhunk -= on; } hunk += n; nhunk -= n; return p; } Node* nod(int op, Node *nleft, Node *nright) { Node *n; n = mal(sizeof(*n)); n->op = op; n->left = nleft; n->right = nright; n->lineno = parserline(); n->xoffset = BADWIDTH; n->orig = n; n->curfn = curfn; return n; } void saveorignode(Node *n) { Node *norig; if(n->orig != N) return; norig = nod(n->op, N, N); *norig = *n; n->orig = norig; } // ispaddedfield returns whether the given field // is followed by padding. For the case where t is // the last field, total gives the size of the enclosing struct. static int ispaddedfield(Type *t, vlong total) { if(t->etype != TFIELD) fatal("ispaddedfield called non-field %T", t); if(t->down == T) return t->width + t->type->width != total; return t->width + t->type->width != t->down->width; } int algtype1(Type *t, Type **bad) { int a, ret; Type *t1; if(bad) *bad = T; switch(t->etype) { case TINT8: case TUINT8: case TINT16: case TUINT16: case TINT32: case TUINT32: case TINT64: case TUINT64: case TINT: case TUINT: case TUINTPTR: case TBOOL: case TPTR32: case TPTR64: case TCHAN: case TUNSAFEPTR: return AMEM; case TFUNC: case TMAP: if(bad) *bad = t; return ANOEQ; case TFLOAT32: return AFLOAT32; case TFLOAT64: return AFLOAT64; case TCOMPLEX64: return ACPLX64; case TCOMPLEX128: return ACPLX128; case TSTRING: return ASTRING; case TINTER: if(isnilinter(t)) return ANILINTER; return AINTER; case TARRAY: if(isslice(t)) { if(bad) *bad = t; return ANOEQ; } if(t->bound == 0) return AMEM; a = algtype1(t->type, bad); if(a == ANOEQ || a == AMEM) { if(a == ANOEQ && bad) *bad = t; return a; } return -1; // needs special compare case TSTRUCT: if(t->type != T && t->type->down == T) { // One-field struct is same as that one field alone. return algtype1(t->type->type, bad); } ret = AMEM; for(t1=t->type; t1!=T; t1=t1->down) { // Blank fields and padding must be ignored, // so need special compare. if(isblanksym(t1->sym) || ispaddedfield(t1, t->width)) { ret = -1; continue; } a = algtype1(t1->type, bad); if(a == ANOEQ) return ANOEQ; // not comparable if(a != AMEM) ret = -1; // needs special compare } return ret; } fatal("algtype1: unexpected type %T", t); return 0; } int algtype(Type *t) { int a; a = algtype1(t, nil); if(a == AMEM || a == ANOEQ) { if(isslice(t)) return ASLICE; switch(t->width) { case 0: return a + AMEM0 - AMEM; case 1: return a + AMEM8 - AMEM; case 2: return a + AMEM16 - AMEM; case 4: return a + AMEM32 - AMEM; case 8: return a + AMEM64 - AMEM; case 16: return a + AMEM128 - AMEM; } } return a; } Type* maptype(Type *key, Type *val) { Type *t; if(key != nil) { switch(key->etype) { default: if(algtype1(key, nil) == ANOEQ) yyerror("invalid map key type %T", key); break; case TANY: // will be resolved later. break; case TFORW: // map[key] used during definition of key. // postpone check until key is fully defined. // if there are multiple uses of map[key] // before key is fully defined, the error // will only be printed for the first one. // good enough. if(key->maplineno == 0) key->maplineno = lineno; break; } } t = typ(TMAP); t->down = key; t->type = val; return t; } Type* typ(int et) { Type *t; t = mal(sizeof(*t)); t->etype = et; t->width = BADWIDTH; t->lineno = lineno; t->orig = t; return t; } static int methcmp(const void *va, const void *vb) { Type *a, *b; int i; a = *(Type**)va; b = *(Type**)vb; i = strcmp(a->sym->name, b->sym->name); if(i != 0) return i; if(!exportname(a->sym->name)) { i = strcmp(a->sym->pkg->path->s, b->sym->pkg->path->s); if(i != 0) return i; } return 0; } Type* sortinter(Type *t) { Type *f; int i; Type **a; if(t->type == nil || t->type->down == nil) return t; i=0; for(f=t->type; f; f=f->down) i++; a = mal(i*sizeof f); i = 0; for(f=t->type; f; f=f->down) a[i++] = f; qsort(a, i, sizeof a[0], methcmp); while(i-- > 0) { a[i]->down = f; f = a[i]; } t->type = f; return t; } Node* nodintconst(int64 v) { Node *c; c = nod(OLITERAL, N, N); c->addable = 1; c->val.u.xval = mal(sizeof(*c->val.u.xval)); mpmovecfix(c->val.u.xval, v); c->val.ctype = CTINT; c->type = types[TIDEAL]; ullmancalc(c); return c; } Node* nodfltconst(Mpflt* v) { Node *c; c = nod(OLITERAL, N, N); c->addable = 1; c->val.u.fval = mal(sizeof(*c->val.u.fval)); mpmovefltflt(c->val.u.fval, v); c->val.ctype = CTFLT; c->type = types[TIDEAL]; ullmancalc(c); return c; } void nodconst(Node *n, Type *t, int64 v) { memset(n, 0, sizeof(*n)); n->op = OLITERAL; n->addable = 1; ullmancalc(n); n->val.u.xval = mal(sizeof(*n->val.u.xval)); mpmovecfix(n->val.u.xval, v); n->val.ctype = CTINT; n->type = t; if(isfloat[t->etype]) fatal("nodconst: bad type %T", t); } Node* nodnil(void) { Node *c; c = nodintconst(0); c->val.ctype = CTNIL; c->type = types[TNIL]; return c; } Node* nodbool(int b) { Node *c; c = nodintconst(0); c->val.ctype = CTBOOL; c->val.u.bval = b; c->type = idealbool; return c; } Type* aindex(Node *b, Type *t) { Type *r; int bound; bound = -1; // open bound typecheck(&b, Erv); if(b != nil) { switch(consttype(b)) { default: yyerror("array bound must be an integer expression"); break; case CTINT: case CTRUNE: bound = mpgetfix(b->val.u.xval); if(bound < 0) yyerror("array bound must be non negative"); break; } } // fixed array r = typ(TARRAY); r->type = t; r->bound = bound; return r; } Node* treecopy(Node *n) { Node *m; if(n == N) return N; switch(n->op) { default: m = nod(OXXX, N, N); *m = *n; m->orig = m; m->left = treecopy(n->left); m->right = treecopy(n->right); m->list = listtreecopy(n->list); if(m->defn) abort(); break; case ONONAME: if(n->sym == lookup("iota")) { // Not sure yet whether this is the real iota, // but make a copy of the Node* just in case, // so that all the copies of this const definition // don't have the same iota value. m = nod(OXXX, N, N); *m = *n; m->iota = iota; break; } // fall through case ONAME: case OLITERAL: case OTYPE: m = n; break; } return m; } int isnil(Node *n) { if(n == N) return 0; if(n->op != OLITERAL) return 0; if(n->val.ctype != CTNIL) return 0; return 1; } int isptrto(Type *t, int et) { if(t == T) return 0; if(!isptr[t->etype]) return 0; t = t->type; if(t == T) return 0; if(t->etype != et) return 0; return 1; } int istype(Type *t, int et) { return t != T && t->etype == et; } int isfixedarray(Type *t) { return t != T && t->etype == TARRAY && t->bound >= 0; } int isslice(Type *t) { return t != T && t->etype == TARRAY && t->bound < 0; } int isblank(Node *n) { if(n == N) return 0; return isblanksym(n->sym); } int isblanksym(Sym *s) { char *p; if(s == S) return 0; p = s->name; if(p == nil) return 0; return p[0] == '_' && p[1] == '\0'; } int isinter(Type *t) { return t != T && t->etype == TINTER; } int isnilinter(Type *t) { if(!isinter(t)) return 0; if(t->type != T) return 0; return 1; } int isideal(Type *t) { if(t == T) return 0; if(t == idealstring || t == idealbool) return 1; switch(t->etype) { case TNIL: case TIDEAL: return 1; } return 0; } /* * given receiver of type t (t == r or t == *r) * return type to hang methods off (r). */ Type* methtype(Type *t, int mustname) { if(t == T) return T; // strip away pointer if it's there if(isptr[t->etype]) { if(t->sym != S) return T; t = t->type; if(t == T) return T; } // need a type name if(t->sym == S && (mustname || t->etype != TSTRUCT)) return T; // check types if(!issimple[t->etype]) switch(t->etype) { default: return T; case TSTRUCT: case TARRAY: case TMAP: case TCHAN: case TSTRING: case TFUNC: break; } return t; } int cplxsubtype(int et) { switch(et) { case TCOMPLEX64: return TFLOAT32; case TCOMPLEX128: return TFLOAT64; } fatal("cplxsubtype: %E\n", et); return 0; } static int eqnote(Strlit *a, Strlit *b) { if(a == b) return 1; if(a == nil || b == nil) return 0; if(a->len != b->len) return 0; return memcmp(a->s, b->s, a->len) == 0; } typedef struct TypePairList TypePairList; struct TypePairList { Type *t1; Type *t2; TypePairList *next; }; static int onlist(TypePairList *l, Type *t1, Type *t2) { for(; l; l=l->next) if((l->t1 == t1 && l->t2 == t2) || (l->t1 == t2 && l->t2 == t1)) return 1; return 0; } static int eqtype1(Type*, Type*, TypePairList*); // Return 1 if t1 and t2 are identical, following the spec rules. // // Any cyclic type must go through a named type, and if one is // named, it is only identical to the other if they are the same // pointer (t1 == t2), so there's no chance of chasing cycles // ad infinitum, so no need for a depth counter. int eqtype(Type *t1, Type *t2) { return eqtype1(t1, t2, nil); } static int eqtype1(Type *t1, Type *t2, TypePairList *assumed_equal) { TypePairList l; if(t1 == t2) return 1; if(t1 == T || t2 == T || t1->etype != t2->etype) return 0; if(t1->sym || t2->sym) { // Special case: we keep byte and uint8 separate // for error messages. Treat them as equal. switch(t1->etype) { case TUINT8: if((t1 == types[TUINT8] || t1 == bytetype) && (t2 == types[TUINT8] || t2 == bytetype)) return 1; break; case TINT: case TINT32: if((t1 == types[runetype->etype] || t1 == runetype) && (t2 == types[runetype->etype] || t2 == runetype)) return 1; break; } return 0; } if(onlist(assumed_equal, t1, t2)) return 1; l.next = assumed_equal; l.t1 = t1; l.t2 = t2; switch(t1->etype) { case TINTER: case TSTRUCT: for(t1=t1->type, t2=t2->type; t1 && t2; t1=t1->down, t2=t2->down) { if(t1->etype != TFIELD || t2->etype != TFIELD) fatal("struct/interface missing field: %T %T", t1, t2); if(t1->sym != t2->sym || t1->embedded != t2->embedded || !eqtype1(t1->type, t2->type, &l) || !eqnote(t1->note, t2->note)) goto no; } if(t1 == T && t2 == T) goto yes; goto no; case TFUNC: // Loop over structs: receiver, in, out. for(t1=t1->type, t2=t2->type; t1 && t2; t1=t1->down, t2=t2->down) { Type *ta, *tb; if(t1->etype != TSTRUCT || t2->etype != TSTRUCT) fatal("func missing struct: %T %T", t1, t2); // Loop over fields in structs, ignoring argument names. for(ta=t1->type, tb=t2->type; ta && tb; ta=ta->down, tb=tb->down) { if(ta->etype != TFIELD || tb->etype != TFIELD) fatal("func struct missing field: %T %T", ta, tb); if(ta->isddd != tb->isddd || !eqtype1(ta->type, tb->type, &l)) goto no; } if(ta != T || tb != T) goto no; } if(t1 == T && t2 == T) goto yes; goto no; case TARRAY: if(t1->bound != t2->bound) goto no; break; case TCHAN: if(t1->chan != t2->chan) goto no; break; } if(eqtype1(t1->down, t2->down, &l) && eqtype1(t1->type, t2->type, &l)) goto yes; goto no; yes: return 1; no: return 0; } // Are t1 and t2 equal struct types when field names are ignored? // For deciding whether the result struct from g can be copied // directly when compiling f(g()). int eqtypenoname(Type *t1, Type *t2) { if(t1 == T || t2 == T || t1->etype != TSTRUCT || t2->etype != TSTRUCT) return 0; t1 = t1->type; t2 = t2->type; for(;;) { if(!eqtype(t1, t2)) return 0; if(t1 == T) return 1; t1 = t1->down; t2 = t2->down; } } // Is type src assignment compatible to type dst? // If so, return op code to use in conversion. // If not, return 0. int assignop(Type *src, Type *dst, char **why) { Type *missing, *have; int ptr; if(why != nil) *why = ""; // TODO(rsc,lvd): This behaves poorly in the presence of inlining. // https://code.google.com/p/go/issues/detail?id=2795 if(safemode && importpkg == nil && src != T && src->etype == TUNSAFEPTR) { yyerror("cannot use unsafe.Pointer"); errorexit(); } if(src == dst) return OCONVNOP; if(src == T || dst == T || src->etype == TFORW || dst->etype == TFORW || src->orig == T || dst->orig == T) return 0; // 1. src type is identical to dst. if(eqtype(src, dst)) return OCONVNOP; // 2. src and dst have identical underlying types // and either src or dst is not a named type or // both are interface types. if(eqtype(src->orig, dst->orig) && (src->sym == S || dst->sym == S || src->etype == TINTER)) return OCONVNOP; // 3. dst is an interface type and src implements dst. if(dst->etype == TINTER && src->etype != TNIL) { if(implements(src, dst, &missing, &have, &ptr)) return OCONVIFACE; // we'll have complained about this method anyway, supress spurious messages. if(have && have->sym == missing->sym && (have->type->broke || missing->type->broke)) return OCONVIFACE; if(why != nil) { if(isptrto(src, TINTER)) *why = smprint(":\n\t%T is pointer to interface, not interface", src); else if(have && have->sym == missing->sym) *why = smprint(":\n\t%T does not implement %T (wrong type for %S method)\n" "\t\thave %S%hhT\n\t\twant %S%hhT", src, dst, missing->sym, have->sym, have->type, missing->sym, missing->type); else if(ptr) *why = smprint(":\n\t%T does not implement %T (%S method requires pointer receiver)", src, dst, missing->sym); else if(have) *why = smprint(":\n\t%T does not implement %T (missing %S method)\n" "\t\thave %S%hhT\n\t\twant %S%hhT", src, dst, missing->sym, have->sym, have->type, missing->sym, missing->type); else *why = smprint(":\n\t%T does not implement %T (missing %S method)", src, dst, missing->sym); } return 0; } if(isptrto(dst, TINTER)) { if(why != nil) *why = smprint(":\n\t%T is pointer to interface, not interface", dst); return 0; } if(src->etype == TINTER && dst->etype != TBLANK) { if(why != nil && implements(dst, src, &missing, &have, &ptr)) *why = ": need type assertion"; return 0; } // 4. src is a bidirectional channel value, dst is a channel type, // src and dst have identical element types, and // either src or dst is not a named type. if(src->etype == TCHAN && src->chan == Cboth && dst->etype == TCHAN) if(eqtype(src->type, dst->type) && (src->sym == S || dst->sym == S)) return OCONVNOP; // 5. src is the predeclared identifier nil and dst is a nillable type. if(src->etype == TNIL) { switch(dst->etype) { case TARRAY: if(dst->bound != -100) // not slice break; case TPTR32: case TPTR64: case TFUNC: case TMAP: case TCHAN: case TINTER: return OCONVNOP; } } // 6. rule about untyped constants - already converted by defaultlit. // 7. Any typed value can be assigned to the blank identifier. if(dst->etype == TBLANK) return OCONVNOP; return 0; } // Can we convert a value of type src to a value of type dst? // If so, return op code to use in conversion (maybe OCONVNOP). // If not, return 0. int convertop(Type *src, Type *dst, char **why) { int op; if(why != nil) *why = ""; if(src == dst) return OCONVNOP; if(src == T || dst == T) return 0; // 1. src can be assigned to dst. if((op = assignop(src, dst, why)) != 0) return op; // The rules for interfaces are no different in conversions // than assignments. If interfaces are involved, stop now // with the good message from assignop. // Otherwise clear the error. if(src->etype == TINTER || dst->etype == TINTER) return 0; if(why != nil) *why = ""; // 2. src and dst have identical underlying types. if(eqtype(src->orig, dst->orig)) return OCONVNOP; // 3. src and dst are unnamed pointer types // and their base types have identical underlying types. if(isptr[src->etype] && isptr[dst->etype] && src->sym == S && dst->sym == S) if(eqtype(src->type->orig, dst->type->orig)) return OCONVNOP; // 4. src and dst are both integer or floating point types. if((isint[src->etype] || isfloat[src->etype]) && (isint[dst->etype] || isfloat[dst->etype])) { if(simtype[src->etype] == simtype[dst->etype]) return OCONVNOP; return OCONV; } // 5. src and dst are both complex types. if(iscomplex[src->etype] && iscomplex[dst->etype]) { if(simtype[src->etype] == simtype[dst->etype]) return OCONVNOP; return OCONV; } // 6. src is an integer or has type []byte or []rune // and dst is a string type. if(isint[src->etype] && dst->etype == TSTRING) return ORUNESTR; if(isslice(src) && dst->etype == TSTRING) { if(src->type->etype == bytetype->etype) return OARRAYBYTESTR; if(src->type->etype == runetype->etype) return OARRAYRUNESTR; } // 7. src is a string and dst is []byte or []rune. // String to slice. if(src->etype == TSTRING && isslice(dst)) { if(dst->type->etype == bytetype->etype) return OSTRARRAYBYTE; if(dst->type->etype == runetype->etype) return OSTRARRAYRUNE; } // 8. src is a pointer or uintptr and dst is unsafe.Pointer. if((isptr[src->etype] || src->etype == TUINTPTR) && dst->etype == TUNSAFEPTR) return OCONVNOP; // 9. src is unsafe.Pointer and dst is a pointer or uintptr. if(src->etype == TUNSAFEPTR && (isptr[dst->etype] || dst->etype == TUINTPTR)) return OCONVNOP; return 0; } // Convert node n for assignment to type t. Node* assignconv(Node *n, Type *t, char *context) { int op; Node *r, *old; char *why; if(n == N || n->type == T) return n; old = n; old->diag++; // silence errors about n; we'll issue one below defaultlit(&n, t); old->diag--; if(t->etype == TBLANK) return n; // Convert ideal bool from comparison to plain bool // if the next step is non-bool (like interface{}). if(n->type == idealbool && t->etype != TBOOL) { if(n->op == ONAME || n->op == OLITERAL) { r = nod(OCONVNOP, n, N); r->type = types[TBOOL]; r->typecheck = 1; r->implicit = 1; n = r; } } if(eqtype(n->type, t)) return n; op = assignop(n->type, t, &why); if(op == 0) { yyerror("cannot use %lN as type %T in %s%s", n, t, context, why); op = OCONV; } r = nod(op, n, N); r->type = t; r->typecheck = 1; r->implicit = 1; r->orig = n->orig; return r; } static int subtype(Type **stp, Type *t, int d) { Type *st; loop: st = *stp; if(st == T) return 0; d++; if(d >= 10) return 0; switch(st->etype) { default: return 0; case TPTR32: case TPTR64: case TCHAN: case TARRAY: stp = &st->type; goto loop; case TANY: if(!st->copyany) return 0; *stp = t; break; case TMAP: if(subtype(&st->down, t, d)) break; stp = &st->type; goto loop; case TFUNC: for(;;) { if(subtype(&st->type, t, d)) break; if(subtype(&st->type->down->down, t, d)) break; if(subtype(&st->type->down, t, d)) break; return 0; } break; case TSTRUCT: for(st=st->type; st!=T; st=st->down) if(subtype(&st->type, t, d)) return 1; return 0; } return 1; } /* * Is this a 64-bit type? */ int is64(Type *t) { if(t == T) return 0; switch(simtype[t->etype]) { case TINT64: case TUINT64: case TPTR64: return 1; } return 0; } /* * Is a conversion between t1 and t2 a no-op? */ int noconv(Type *t1, Type *t2) { int e1, e2; e1 = simtype[t1->etype]; e2 = simtype[t2->etype]; switch(e1) { case TINT8: case TUINT8: return e2 == TINT8 || e2 == TUINT8; case TINT16: case TUINT16: return e2 == TINT16 || e2 == TUINT16; case TINT32: case TUINT32: case TPTR32: return e2 == TINT32 || e2 == TUINT32 || e2 == TPTR32; case TINT64: case TUINT64: case TPTR64: return e2 == TINT64 || e2 == TUINT64 || e2 == TPTR64; case TFLOAT32: return e2 == TFLOAT32; case TFLOAT64: return e2 == TFLOAT64; } return 0; } void argtype(Node *on, Type *t) { dowidth(t); if(!subtype(&on->type, t, 0)) fatal("argtype: failed %N %T\n", on, t); } Type* shallow(Type *t) { Type *nt; if(t == T) return T; nt = typ(0); *nt = *t; if(t->orig == t) nt->orig = nt; return nt; } static Type* deep(Type *t) { Type *nt, *xt; if(t == T) return T; switch(t->etype) { default: nt = t; // share from here down break; case TANY: nt = shallow(t); nt->copyany = 1; break; case TPTR32: case TPTR64: case TCHAN: case TARRAY: nt = shallow(t); nt->type = deep(t->type); break; case TMAP: nt = shallow(t); nt->down = deep(t->down); nt->type = deep(t->type); break; case TFUNC: nt = shallow(t); nt->type = deep(t->type); nt->type->down = deep(t->type->down); nt->type->down->down = deep(t->type->down->down); break; case TSTRUCT: nt = shallow(t); nt->type = shallow(t->type); xt = nt->type; for(t=t->type; t!=T; t=t->down) { xt->type = deep(t->type); xt->down = shallow(t->down); xt = xt->down; } break; } return nt; } Node* syslook(char *name, int copy) { Sym *s; Node *n; s = pkglookup(name, runtimepkg); if(s == S || s->def == N) fatal("syslook: can't find runtime.%s", name); if(!copy) return s->def; n = nod(0, N, N); *n = *s->def; n->type = deep(s->def->type); return n; } /* * compute a hash value for type t. * if t is a method type, ignore the receiver * so that the hash can be used in interface checks. * %T already contains * all the necessary logic to generate a representation * of the type that completely describes it. * using smprint here avoids duplicating that code. * using md5 here is overkill, but i got tired of * accidental collisions making the runtime think * two types are equal when they really aren't. */ uint32 typehash(Type *t) { char *p; MD5 d; if(t->thistuple) { // hide method receiver from Tpretty t->thistuple = 0; p = smprint("%-uT", t); t->thistuple = 1; } else p = smprint("%-uT", t); //print("typehash: %s\n", p); md5reset(&d); md5write(&d, (uchar*)p, strlen(p)); free(p); return md5sum(&d); } Type* ptrto(Type *t) { Type *t1; if(tptr == 0) fatal("ptrto: no tptr"); t1 = typ(tptr); t1->type = t; t1->width = widthptr; t1->align = widthptr; return t1; } void frame(int context) { char *p; NodeList *l; Node *n; int flag; p = "stack"; l = nil; if(curfn) l = curfn->dcl; if(context) { p = "external"; l = externdcl; } flag = 1; for(; l; l=l->next) { n = l->n; switch(n->op) { case ONAME: if(flag) print("--- %s frame ---\n", p); print("%O %S G%d %T\n", n->op, n->sym, n->vargen, n->type); flag = 0; break; case OTYPE: if(flag) print("--- %s frame ---\n", p); print("%O %T\n", n->op, n->type); flag = 0; break; } } } /* * calculate sethi/ullman number * roughly how many registers needed to * compile a node. used to compile the * hardest side first to minimize registers. */ void ullmancalc(Node *n) { int ul, ur; if(n == N) return; if(n->ninit != nil) { ul = UINF; goto out; } switch(n->op) { case OREGISTER: case OLITERAL: case ONAME: ul = 1; if(n->class == PPARAMREF || (n->class & PHEAP)) ul++; goto out; case OCALL: case OCALLFUNC: case OCALLMETH: case OCALLINTER: ul = UINF; goto out; } ul = 1; if(n->left != N) ul = n->left->ullman; ur = 1; if(n->right != N) ur = n->right->ullman; if(ul == ur) ul += 1; if(ur > ul) ul = ur; out: n->ullman = ul; } void badtype(int o, Type *tl, Type *tr) { Fmt fmt; char *s; fmtstrinit(&fmt); if(tl != T) fmtprint(&fmt, "\n %T", tl); if(tr != T) fmtprint(&fmt, "\n %T", tr); // common mistake: *struct and *interface. if(tl && tr && isptr[tl->etype] && isptr[tr->etype]) { if(tl->type->etype == TSTRUCT && tr->type->etype == TINTER) fmtprint(&fmt, "\n (*struct vs *interface)"); else if(tl->type->etype == TINTER && tr->type->etype == TSTRUCT) fmtprint(&fmt, "\n (*interface vs *struct)"); } s = fmtstrflush(&fmt); yyerror("illegal types for operand: %O%s", o, s); } /* * iterator to walk a structure declaration */ Type* structfirst(Iter *s, Type **nn) { Type *n, *t; n = *nn; if(n == T) goto bad; switch(n->etype) { default: goto bad; case TSTRUCT: case TINTER: case TFUNC: break; } t = n->type; if(t == T) goto rnil; if(t->etype != TFIELD) fatal("structfirst: not field %T", t); s->t = t; return t; bad: fatal("structfirst: not struct %T", n); rnil: return T; } Type* structnext(Iter *s) { Type *n, *t; n = s->t; t = n->down; if(t == T) goto rnil; if(t->etype != TFIELD) goto bad; s->t = t; return t; bad: fatal("structnext: not struct %T", n); rnil: return T; } /* * iterator to this and inargs in a function */ Type* funcfirst(Iter *s, Type *t) { Type *fp; if(t == T) goto bad; if(t->etype != TFUNC) goto bad; s->tfunc = t; s->done = 0; fp = structfirst(s, getthis(t)); if(fp == T) { s->done = 1; fp = structfirst(s, getinarg(t)); } return fp; bad: fatal("funcfirst: not func %T", t); return T; } Type* funcnext(Iter *s) { Type *fp; fp = structnext(s); if(fp == T && !s->done) { s->done = 1; fp = structfirst(s, getinarg(s->tfunc)); } return fp; } Type** getthis(Type *t) { if(t->etype != TFUNC) fatal("getthis: not a func %T", t); return &t->type; } Type** getoutarg(Type *t) { if(t->etype != TFUNC) fatal("getoutarg: not a func %T", t); return &t->type->down; } Type** getinarg(Type *t) { if(t->etype != TFUNC) fatal("getinarg: not a func %T", t); return &t->type->down->down; } Type* getthisx(Type *t) { return *getthis(t); } Type* getoutargx(Type *t) { return *getoutarg(t); } Type* getinargx(Type *t) { return *getinarg(t); } /* * return !(op) * eg == <=> != */ int brcom(int a) { switch(a) { case OEQ: return ONE; case ONE: return OEQ; case OLT: return OGE; case OGT: return OLE; case OLE: return OGT; case OGE: return OLT; } fatal("brcom: no com for %A\n", a); return a; } /* * return reverse(op) * eg a op b <=> b r(op) a */ int brrev(int a) { switch(a) { case OEQ: return OEQ; case ONE: return ONE; case OLT: return OGT; case OGT: return OLT; case OLE: return OGE; case OGE: return OLE; } fatal("brcom: no rev for %A\n", a); return a; } /* * return side effect-free n, appending side effects to init. * result is assignable if n is. */ Node* safeexpr(Node *n, NodeList **init) { Node *l; Node *r; Node *a; if(n == N) return N; if(n->ninit) { walkstmtlist(n->ninit); *init = concat(*init, n->ninit); n->ninit = nil; } switch(n->op) { case ONAME: case OLITERAL: return n; case ODOT: l = safeexpr(n->left, init); if(l == n->left) return n; r = nod(OXXX, N, N); *r = *n; r->left = l; typecheck(&r, Erv); walkexpr(&r, init); return r; case ODOTPTR: case OIND: l = safeexpr(n->left, init); if(l == n->left) return n; a = nod(OXXX, N, N); *a = *n; a->left = l; walkexpr(&a, init); return a; case OINDEX: case OINDEXMAP: l = safeexpr(n->left, init); r = safeexpr(n->right, init); if(l == n->left && r == n->right) return n; a = nod(OXXX, N, N); *a = *n; a->left = l; a->right = r; walkexpr(&a, init); return a; } // make a copy; must not be used as an lvalue if(islvalue(n)) fatal("missing lvalue case in safeexpr: %N", n); return cheapexpr(n, init); } Node* copyexpr(Node *n, Type *t, NodeList **init) { Node *a, *l; l = temp(t); a = nod(OAS, l, n); typecheck(&a, Etop); walkexpr(&a, init); *init = list(*init, a); return l; } /* * return side-effect free and cheap n, appending side effects to init. * result may not be assignable. */ Node* cheapexpr(Node *n, NodeList **init) { switch(n->op) { case ONAME: case OLITERAL: return n; } return copyexpr(n, n->type, init); } /* * return n in a local variable of type t if it is not already. * the value is guaranteed not to change except by direct * assignment to it. */ Node* localexpr(Node *n, Type *t, NodeList **init) { if(n->op == ONAME && !n->addrtaken && (n->class == PAUTO || n->class == PPARAM || n->class == PPARAMOUT) && convertop(n->type, t, nil) == OCONVNOP) return n; return copyexpr(n, t, init); } void setmaxarg(Type *t) { int32 w; dowidth(t); w = t->argwid; if(t->argwid >= MAXWIDTH) fatal("bad argwid %T", t); if(w > maxarg) maxarg = w; } /* * unicode-aware case-insensitive strcmp */ static int ucistrcmp(char *p, char *q) { Rune rp, rq; while(*p || *q) { if(*p == 0) return +1; if(*q == 0) return -1; p += chartorune(&rp, p); q += chartorune(&rq, q); rp = tolowerrune(rp); rq = tolowerrune(rq); if(rp < rq) return -1; if(rp > rq) return +1; } return 0; } /* * code to resolve elided DOTs * in embedded types */ // search depth 0 -- // return count of fields+methods // found with a given name static int lookdot0(Sym *s, Type *t, Type **save, int ignorecase) { Type *f, *u; int c; u = t; if(isptr[u->etype]) u = u->type; c = 0; if(u->etype == TSTRUCT || u->etype == TINTER) { for(f=u->type; f!=T; f=f->down) if(f->sym == s || (ignorecase && ucistrcmp(f->sym->name, s->name) == 0)) { if(save) *save = f; c++; } } u = methtype(t, 0); if(u != T) { for(f=u->method; f!=T; f=f->down) if(f->embedded == 0 && (f->sym == s || (ignorecase && ucistrcmp(f->sym->name, s->name) == 0))) { if(save) *save = f; c++; } } return c; } // search depth d for field/method s -- // return count of fields+methods // found at search depth. // answer is in dotlist array and // count of number of ways is returned. int adddot1(Sym *s, Type *t, int d, Type **save, int ignorecase) { Type *f, *u; int c, a; if(t->trecur) return 0; t->trecur = 1; if(d == 0) { c = lookdot0(s, t, save, ignorecase); goto out; } c = 0; u = t; if(isptr[u->etype]) u = u->type; if(u->etype != TSTRUCT && u->etype != TINTER) goto out; d--; for(f=u->type; f!=T; f=f->down) { if(!f->embedded) continue; if(f->sym == S) continue; a = adddot1(s, f->type, d, save, ignorecase); if(a != 0 && c == 0) dotlist[d].field = f; c += a; } out: t->trecur = 0; return c; } // in T.field // find missing fields that // will give shortest unique addressing. // modify the tree with missing type names. Node* adddot(Node *n) { Type *t; Sym *s; int c, d; typecheck(&n->left, Etype|Erv); t = n->left->type; if(t == T) goto ret; if(n->left->op == OTYPE) goto ret; if(n->right->op != ONAME) goto ret; s = n->right->sym; if(s == S) goto ret; for(d=0; d 0) goto out; } goto ret; out: if(c > 1) { yyerror("ambiguous selector %N", n); n->left = N; return n; } // rebuild elided dots for(c=d-1; c>=0; c--) n->left = nod(ODOT, n->left, newname(dotlist[c].field->sym)); ret: return n; } /* * code to help generate trampoline * functions for methods on embedded * subtypes. * these are approx the same as * the corresponding adddot routines * except that they expect to be called * with unique tasks and they return * the actual methods. */ typedef struct Symlink Symlink; struct Symlink { Type* field; uchar good; uchar followptr; Symlink* link; }; static Symlink* slist; static void expand0(Type *t, int followptr) { Type *f, *u; Symlink *sl; u = t; if(isptr[u->etype]) { followptr = 1; u = u->type; } if(u->etype == TINTER) { for(f=u->type; f!=T; f=f->down) { if(f->sym->flags & SymUniq) continue; f->sym->flags |= SymUniq; sl = mal(sizeof(*sl)); sl->field = f; sl->link = slist; sl->followptr = followptr; slist = sl; } return; } u = methtype(t, 0); if(u != T) { for(f=u->method; f!=T; f=f->down) { if(f->sym->flags & SymUniq) continue; f->sym->flags |= SymUniq; sl = mal(sizeof(*sl)); sl->field = f; sl->link = slist; sl->followptr = followptr; slist = sl; } } } static void expand1(Type *t, int d, int followptr) { Type *f, *u; if(t->trecur) return; if(d == 0) return; t->trecur = 1; if(d != nelem(dotlist)-1) expand0(t, followptr); u = t; if(isptr[u->etype]) { followptr = 1; u = u->type; } if(u->etype != TSTRUCT && u->etype != TINTER) goto out; for(f=u->type; f!=T; f=f->down) { if(!f->embedded) continue; if(f->sym == S) continue; expand1(f->type, d-1, followptr); } out: t->trecur = 0; } void expandmeth(Type *t) { Symlink *sl; Type *f; int c, d; if(t == T || t->xmethod != nil) return; // mark top-level method symbols // so that expand1 doesn't consider them. for(f=t->method; f != nil; f=f->down) f->sym->flags |= SymUniq; // generate all reachable methods slist = nil; expand1(t, nelem(dotlist)-1, 0); // check each method to be uniquely reachable for(sl=slist; sl!=nil; sl=sl->link) { sl->field->sym->flags &= ~SymUniq; for(d=0; dfield->sym, t, d, &f, 0); if(c == 0) continue; if(c == 1) { // addot1 may have dug out arbitrary fields, we only want methods. if(f->type->etype == TFUNC && f->type->thistuple > 0) { sl->good = 1; sl->field = f; } } break; } } for(f=t->method; f != nil; f=f->down) f->sym->flags &= ~SymUniq; t->xmethod = t->method; for(sl=slist; sl!=nil; sl=sl->link) { if(sl->good) { // add it to the base type method list f = typ(TFIELD); *f = *sl->field; f->embedded = 1; // needs a trampoline if(sl->followptr) f->embedded = 2; f->down = t->xmethod; t->xmethod = f; } } } /* * Given funarg struct list, return list of ODCLFIELD Node fn args. */ static NodeList* structargs(Type **tl, int mustname) { Iter savet; Node *a, *n; NodeList *args; Type *t; char buf[100]; int gen; args = nil; gen = 0; for(t = structfirst(&savet, tl); t != T; t = structnext(&savet)) { n = N; if(mustname && (t->sym == nil || strcmp(t->sym->name, "_") == 0)) { // invent a name so that we can refer to it in the trampoline snprint(buf, sizeof buf, ".anon%d", gen++); n = newname(lookup(buf)); } else if(t->sym) n = newname(t->sym); a = nod(ODCLFIELD, n, typenod(t->type)); a->isddd = t->isddd; if(n != N) n->isddd = t->isddd; args = list(args, a); } return args; } /* * Generate a wrapper function to convert from * a receiver of type T to a receiver of type U. * That is, * * func (t T) M() { * ... * } * * already exists; this function generates * * func (u U) M() { * u.M() * } * * where the types T and U are such that u.M() is valid * and calls the T.M method. * The resulting function is for use in method tables. * * rcvr - U * method - M func (t T)(), a TFIELD type struct * newnam - the eventual mangled name of this function */ void genwrapper(Type *rcvr, Type *method, Sym *newnam, int iface) { Node *this, *fn, *call, *n, *t, *pad; NodeList *l, *args, *in, *out; Type *tpad; int isddd; Val v; if(debug['r']) print("genwrapper rcvrtype=%T method=%T newnam=%S\n", rcvr, method, newnam); lineno = 1; // less confusing than end of input dclcontext = PEXTERN; markdcl(); this = nod(ODCLFIELD, newname(lookup(".this")), typenod(rcvr)); this->left->ntype = this->right; in = structargs(getinarg(method->type), 1); out = structargs(getoutarg(method->type), 0); t = nod(OTFUNC, N, N); l = list1(this); if(iface && rcvr->width < types[tptr]->width) { // Building method for interface table and receiver // is smaller than the single pointer-sized word // that the interface call will pass in. // Add a dummy padding argument after the // receiver to make up the difference. tpad = typ(TARRAY); tpad->type = types[TUINT8]; tpad->bound = types[tptr]->width - rcvr->width; pad = nod(ODCLFIELD, newname(lookup(".pad")), typenod(tpad)); l = list(l, pad); } t->list = concat(l, in); t->rlist = out; fn = nod(ODCLFUNC, N, N); fn->nname = newname(newnam); fn->nname->defn = fn; fn->nname->ntype = t; declare(fn->nname, PFUNC); funchdr(fn); // arg list args = nil; isddd = 0; for(l=in; l; l=l->next) { args = list(args, l->n->left); isddd = l->n->left->isddd; } // generate nil pointer check for better error if(isptr[rcvr->etype] && rcvr->type == getthisx(method->type)->type->type) { // generating wrapper from *T to T. n = nod(OIF, N, N); n->ntest = nod(OEQ, this->left, nodnil()); // these strings are already in the reflect tables, // so no space cost to use them here. l = nil; v.ctype = CTSTR; v.u.sval = strlit(rcvr->type->sym->pkg->name); // package name l = list(l, nodlit(v)); v.u.sval = strlit(rcvr->type->sym->name); // type name l = list(l, nodlit(v)); v.u.sval = strlit(method->sym->name); l = list(l, nodlit(v)); // method name call = nod(OCALL, syslook("panicwrap", 0), N); call->list = l; n->nbody = list1(call); fn->nbody = list(fn->nbody, n); } // generate call call = nod(OCALL, adddot(nod(OXDOT, this->left, newname(method->sym))), N); call->list = args; call->isddd = isddd; if(method->type->outtuple > 0) { n = nod(ORETURN, N, N); n->list = list1(call); call = n; } fn->nbody = list(fn->nbody, call); if(0 && debug['r']) dumplist("genwrapper body", fn->nbody); funcbody(fn); curfn = fn; // wrappers where T is anonymous (struct{ NamedType }) can be duplicated. if(rcvr->etype == TSTRUCT || isptr[rcvr->etype] && rcvr->type->etype == TSTRUCT) fn->dupok = 1; typecheck(&fn, Etop); typechecklist(fn->nbody, Etop); curfn = nil; funccompile(fn, 0); } static Node* hashmem(Type *t) { Node *tfn, *n; Sym *sym; sym = pkglookup("memhash", runtimepkg); n = newname(sym); n->class = PFUNC; tfn = nod(OTFUNC, N, N); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(ptrto(types[TUINTPTR])))); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(types[TUINTPTR]))); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(ptrto(t)))); typecheck(&tfn, Etype); n->type = tfn->type; return n; } static Node* hashfor(Type *t) { int a; Sym *sym; Node *tfn, *n; a = algtype1(t, nil); switch(a) { case AMEM: return hashmem(t); case AINTER: sym = pkglookup("interhash", runtimepkg); break; case ANILINTER: sym = pkglookup("nilinterhash", runtimepkg); break; case ASTRING: sym = pkglookup("strhash", runtimepkg); break; case AFLOAT32: sym = pkglookup("f32hash", runtimepkg); break; case AFLOAT64: sym = pkglookup("f64hash", runtimepkg); break; case ACPLX64: sym = pkglookup("c64hash", runtimepkg); break; case ACPLX128: sym = pkglookup("c128hash", runtimepkg); break; default: sym = typesymprefix(".hash", t); break; } n = newname(sym); n->class = PFUNC; tfn = nod(OTFUNC, N, N); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(ptrto(types[TUINTPTR])))); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(types[TUINTPTR]))); tfn->list = list(tfn->list, nod(ODCLFIELD, N, typenod(ptrto(t)))); typecheck(&tfn, Etype); n->type = tfn->type; return n; } /* * Generate a helper function to compute the hash of a value of type t. */ void genhash(Sym *sym, Type *t) { Node *n, *fn, *np, *nh, *ni, *call, *nx, *na, *tfn; Node *hashel; Type *first, *t1; int old_safemode; int64 size, mul, offend; if(debug['r']) print("genhash %S %T\n", sym, t); lineno = 1; // less confusing than end of input dclcontext = PEXTERN; markdcl(); // func sym(h *uintptr, s uintptr, p *T) fn = nod(ODCLFUNC, N, N); fn->nname = newname(sym); fn->nname->class = PFUNC; tfn = nod(OTFUNC, N, N); fn->nname->ntype = tfn; n = nod(ODCLFIELD, newname(lookup("h")), typenod(ptrto(types[TUINTPTR]))); tfn->list = list(tfn->list, n); nh = n->left; n = nod(ODCLFIELD, newname(lookup("s")), typenod(types[TUINTPTR])); tfn->list = list(tfn->list, n); n = nod(ODCLFIELD, newname(lookup("p")), typenod(ptrto(t))); tfn->list = list(tfn->list, n); np = n->left; funchdr(fn); typecheck(&fn->nname->ntype, Etype); // genhash is only called for types that have equality but // cannot be handled by the standard algorithms, // so t must be either an array or a struct. switch(t->etype) { default: fatal("genhash %T", t); case TARRAY: if(isslice(t)) fatal("genhash %T", t); // An array of pure memory would be handled by the // standard algorithm, so the element type must not be // pure memory. hashel = hashfor(t->type); n = nod(ORANGE, N, nod(OIND, np, N)); ni = newname(lookup("i")); ni->type = types[TINT]; n->list = list1(ni); n->colas = 1; colasdefn(n->list, n); ni = n->list->n; // *h = *h<<3 | *h>>61 n->nbody = list(n->nbody, nod(OAS, nod(OIND, nh, N), nod(OOR, nod(OLSH, nod(OIND, nh, N), nodintconst(3)), nod(ORSH, nod(OIND, nh, N), nodintconst(widthptr*8-3))))); // *h *= mul // Same multipliers as in runtime.memhash. if(widthptr == 4) mul = 3267000013LL; else mul = 23344194077549503LL; n->nbody = list(n->nbody, nod(OAS, nod(OIND, nh, N), nod(OMUL, nod(OIND, nh, N), nodintconst(mul)))); // hashel(h, sizeof(p[i]), &p[i]) call = nod(OCALL, hashel, N); call->list = list(call->list, nh); call->list = list(call->list, nodintconst(t->type->width)); nx = nod(OINDEX, np, ni); nx->bounded = 1; na = nod(OADDR, nx, N); na->etype = 1; // no escape to heap call->list = list(call->list, na); n->nbody = list(n->nbody, call); fn->nbody = list(fn->nbody, n); break; case TSTRUCT: // Walk the struct using memhash for runs of AMEM // and calling specific hash functions for the others. first = T; offend = 0; for(t1=t->type;; t1=t1->down) { if(t1 != T && algtype1(t1->type, nil) == AMEM && !isblanksym(t1->sym)) { offend = t1->width + t1->type->width; if(first == T) first = t1; // If it's a memory field but it's padded, stop here. if(ispaddedfield(t1, t->width)) t1 = t1->down; else continue; } // Run memhash for fields up to this one. if(first != T) { size = offend - first->width; // first->width is offset hashel = hashmem(first->type); // hashel(h, size, &p.first) call = nod(OCALL, hashel, N); call->list = list(call->list, nh); call->list = list(call->list, nodintconst(size)); nx = nod(OXDOT, np, newname(first->sym)); // TODO: fields from other packages? na = nod(OADDR, nx, N); na->etype = 1; // no escape to heap call->list = list(call->list, na); fn->nbody = list(fn->nbody, call); first = T; } if(t1 == T) break; if(isblanksym(t1->sym)) continue; // Run hash for this field. hashel = hashfor(t1->type); // hashel(h, size, &p.t1) call = nod(OCALL, hashel, N); call->list = list(call->list, nh); call->list = list(call->list, nodintconst(t1->type->width)); nx = nod(OXDOT, np, newname(t1->sym)); // TODO: fields from other packages? na = nod(OADDR, nx, N); na->etype = 1; // no escape to heap call->list = list(call->list, na); fn->nbody = list(fn->nbody, call); } // make sure body is not empty. fn->nbody = list(fn->nbody, nod(ORETURN, N, N)); break; } if(debug['r']) dumplist("genhash body", fn->nbody); funcbody(fn); curfn = fn; fn->dupok = 1; typecheck(&fn, Etop); typechecklist(fn->nbody, Etop); curfn = nil; // Disable safemode while compiling this code: the code we // generate internally can refer to unsafe.Pointer. // In this case it can happen if we need to generate an == // for a struct containing a reflect.Value, which itself has // an unexported field of type unsafe.Pointer. old_safemode = safemode; safemode = 0; funccompile(fn, 0); safemode = old_safemode; } // Return node for // if p.field != q.field { *eq = false; return } static Node* eqfield(Node *p, Node *q, Node *field, Node *eq) { Node *nif, *nx, *ny; nx = nod(OXDOT, p, field); ny = nod(OXDOT, q, field); nif = nod(OIF, N, N); nif->ntest = nod(ONE, nx, ny); nif->nbody = list(nif->nbody, nod(OAS, nod(OIND, eq, N), nodbool(0))); nif->nbody = list(nif->nbody, nod(ORETURN, N, N)); return nif; } static Node* eqmemfunc(vlong size, Type *type) { char buf[30]; Node *fn; switch(size) { default: fn = syslook("memequal", 1); break; case 1: case 2: case 4: case 8: case 16: snprint(buf, sizeof buf, "memequal%d", (int)size*8); fn = syslook(buf, 1); break; } argtype(fn, type); argtype(fn, type); return fn; } // Return node for // if memequal(size, &p.field, &q.field, eq); !*eq { return } static Node* eqmem(Node *p, Node *q, Node *field, vlong size, Node *eq) { Node *nif, *nx, *ny, *call; nx = nod(OADDR, nod(OXDOT, p, field), N); nx->etype = 1; // does not escape ny = nod(OADDR, nod(OXDOT, q, field), N); ny->etype = 1; // does not escape typecheck(&nx, Erv); typecheck(&ny, Erv); call = nod(OCALL, eqmemfunc(size, nx->type->type), N); call->list = list(call->list, eq); call->list = list(call->list, nodintconst(size)); call->list = list(call->list, nx); call->list = list(call->list, ny); nif = nod(OIF, N, N); nif->ninit = list(nif->ninit, call); nif->ntest = nod(ONOT, nod(OIND, eq, N), N); nif->nbody = list(nif->nbody, nod(ORETURN, N, N)); return nif; } /* * Generate a helper function to check equality of two values of type t. */ void geneq(Sym *sym, Type *t) { Node *n, *fn, *np, *neq, *nq, *tfn, *nif, *ni, *nx, *ny, *nrange; Type *t1, *first; int old_safemode; int64 size; int64 offend; if(debug['r']) print("geneq %S %T\n", sym, t); lineno = 1; // less confusing than end of input dclcontext = PEXTERN; markdcl(); // func sym(eq *bool, s uintptr, p, q *T) fn = nod(ODCLFUNC, N, N); fn->nname = newname(sym); fn->nname->class = PFUNC; tfn = nod(OTFUNC, N, N); fn->nname->ntype = tfn; n = nod(ODCLFIELD, newname(lookup("eq")), typenod(ptrto(types[TBOOL]))); tfn->list = list(tfn->list, n); neq = n->left; n = nod(ODCLFIELD, newname(lookup("s")), typenod(types[TUINTPTR])); tfn->list = list(tfn->list, n); n = nod(ODCLFIELD, newname(lookup("p")), typenod(ptrto(t))); tfn->list = list(tfn->list, n); np = n->left; n = nod(ODCLFIELD, newname(lookup("q")), typenod(ptrto(t))); tfn->list = list(tfn->list, n); nq = n->left; funchdr(fn); // geneq is only called for types that have equality but // cannot be handled by the standard algorithms, // so t must be either an array or a struct. switch(t->etype) { default: fatal("geneq %T", t); case TARRAY: if(isslice(t)) fatal("geneq %T", t); // An array of pure memory would be handled by the // standard memequal, so the element type must not be // pure memory. Even if we unrolled the range loop, // each iteration would be a function call, so don't bother // unrolling. nrange = nod(ORANGE, N, nod(OIND, np, N)); ni = newname(lookup("i")); ni->type = types[TINT]; nrange->list = list1(ni); nrange->colas = 1; colasdefn(nrange->list, nrange); ni = nrange->list->n; // if p[i] != q[i] { *eq = false; return } nx = nod(OINDEX, np, ni); nx->bounded = 1; ny = nod(OINDEX, nq, ni); ny->bounded = 1; nif = nod(OIF, N, N); nif->ntest = nod(ONE, nx, ny); nif->nbody = list(nif->nbody, nod(OAS, nod(OIND, neq, N), nodbool(0))); nif->nbody = list(nif->nbody, nod(ORETURN, N, N)); nrange->nbody = list(nrange->nbody, nif); fn->nbody = list(fn->nbody, nrange); // *eq = true; fn->nbody = list(fn->nbody, nod(OAS, nod(OIND, neq, N), nodbool(1))); break; case TSTRUCT: // Walk the struct using memequal for runs of AMEM // and calling specific equality tests for the others. // Skip blank-named fields. first = T; offend = 0; for(t1=t->type;; t1=t1->down) { if(t1 != T && algtype1(t1->type, nil) == AMEM && !isblanksym(t1->sym)) { offend = t1->width + t1->type->width; if(first == T) first = t1; // If it's a memory field but it's padded, stop here. if(ispaddedfield(t1, t->width)) t1 = t1->down; else continue; } // Run memequal for fields up to this one. // TODO(rsc): All the calls to newname are wrong for // cross-package unexported fields. if(first != T) { if(first->down == t1) { fn->nbody = list(fn->nbody, eqfield(np, nq, newname(first->sym), neq)); } else if(first->down->down == t1) { fn->nbody = list(fn->nbody, eqfield(np, nq, newname(first->sym), neq)); first = first->down; if(!isblanksym(first->sym)) fn->nbody = list(fn->nbody, eqfield(np, nq, newname(first->sym), neq)); } else { // More than two fields: use memequal. size = offend - first->width; // first->width is offset fn->nbody = list(fn->nbody, eqmem(np, nq, newname(first->sym), size, neq)); } first = T; } if(t1 == T) break; if(isblanksym(t1->sym)) continue; // Check this field, which is not just memory. fn->nbody = list(fn->nbody, eqfield(np, nq, newname(t1->sym), neq)); } // *eq = true; fn->nbody = list(fn->nbody, nod(OAS, nod(OIND, neq, N), nodbool(1))); break; } if(debug['r']) dumplist("geneq body", fn->nbody); funcbody(fn); curfn = fn; fn->dupok = 1; typecheck(&fn, Etop); typechecklist(fn->nbody, Etop); curfn = nil; // Disable safemode while compiling this code: the code we // generate internally can refer to unsafe.Pointer. // In this case it can happen if we need to generate an == // for a struct containing a reflect.Value, which itself has // an unexported field of type unsafe.Pointer. old_safemode = safemode; safemode = 0; funccompile(fn, 0); safemode = old_safemode; } static Type* ifacelookdot(Sym *s, Type *t, int *followptr, int ignorecase) { int i, c, d; Type *m; *followptr = 0; if(t == T) return T; for(d=0; d 1) { yyerror("%T.%S is ambiguous", t, s); return T; } if(c == 1) { for(i=0; itype->etype]) { *followptr = 1; break; } } if(m->type->etype != TFUNC || m->type->thistuple == 0) { yyerror("%T.%S is a field, not a method", t, s); return T; } return m; } } return T; } int implements(Type *t, Type *iface, Type **m, Type **samename, int *ptr) { Type *t0, *im, *tm, *rcvr, *imtype; int followptr; t0 = t; if(t == T) return 0; // if this is too slow, // could sort these first // and then do one loop. if(t->etype == TINTER) { for(im=iface->type; im; im=im->down) { for(tm=t->type; tm; tm=tm->down) { if(tm->sym == im->sym) { if(eqtype(tm->type, im->type)) goto found; *m = im; *samename = tm; *ptr = 0; return 0; } } *m = im; *samename = nil; *ptr = 0; return 0; found:; } return 1; } t = methtype(t, 0); if(t != T) expandmeth(t); for(im=iface->type; im; im=im->down) { imtype = methodfunc(im->type, 0); tm = ifacelookdot(im->sym, t, &followptr, 0); if(tm == T || tm->nointerface || !eqtype(methodfunc(tm->type, 0), imtype)) { if(tm == T) tm = ifacelookdot(im->sym, t, &followptr, 1); *m = im; *samename = tm; *ptr = 0; return 0; } // if pointer receiver in method, // the method does not exist for value types. rcvr = getthisx(tm->type)->type->type; if(isptr[rcvr->etype] && !isptr[t0->etype] && !followptr && !isifacemethod(tm->type)) { if(0 && debug['r']) yyerror("interface pointer mismatch"); *m = im; *samename = nil; *ptr = 1; return 0; } } return 1; } /* * even simpler simtype; get rid of ptr, bool. * assuming that the front end has rejected * all the invalid conversions (like ptr -> bool) */ int simsimtype(Type *t) { int et; if(t == 0) return 0; et = simtype[t->etype]; switch(et) { case TPTR32: et = TUINT32; break; case TPTR64: et = TUINT64; break; case TBOOL: et = TUINT8; break; } return et; } NodeList* concat(NodeList *a, NodeList *b) { if(a == nil) return b; if(b == nil) return a; a->end->next = b; a->end = b->end; b->end = nil; return a; } NodeList* list1(Node *n) { NodeList *l; if(n == nil) return nil; if(n->op == OBLOCK && n->ninit == nil) { // Flatten list and steal storage. // Poison pointer to catch errant uses. l = n->list; n->list = (NodeList*)1; return l; } l = mal(sizeof *l); l->n = n; l->end = l; return l; } NodeList* list(NodeList *l, Node *n) { return concat(l, list1(n)); } void listsort(NodeList** l, int(*f)(Node*, Node*)) { NodeList *l1, *l2, *le; if(*l == nil || (*l)->next == nil) return; l1 = *l; l2 = *l; for(;;) { l2 = l2->next; if(l2 == nil) break; l2 = l2->next; if(l2 == nil) break; l1 = l1->next; } l2 = l1->next; l1->next = nil; l2->end = (*l)->end; (*l)->end = l1; l1 = *l; listsort(&l1, f); listsort(&l2, f); if((*f)(l1->n, l2->n) < 0) { *l = l1; } else { *l = l2; l2 = l1; l1 = *l; } // now l1 == *l; and l1 < l2 while ((l1 != nil) && (l2 != nil)) { while ((l1->next != nil) && (*f)(l1->next->n, l2->n) < 0) l1 = l1->next; // l1 is last one from l1 that is < l2 le = l1->next; // le is the rest of l1, first one that is >= l2 if(le != nil) le->end = (*l)->end; (*l)->end = l1; // cut *l at l1 *l = concat(*l, l2); // glue l2 to *l's tail l1 = l2; // l1 is the first element of *l that is < the new l2 l2 = le; // ... because l2 now is the old tail of l1 } *l = concat(*l, l2); // any remainder } NodeList* listtreecopy(NodeList *l) { NodeList *out; out = nil; for(; l; l=l->next) out = list(out, treecopy(l->n)); return out; } Node* liststmt(NodeList *l) { Node *n; n = nod(OBLOCK, N, N); n->list = l; if(l) n->lineno = l->n->lineno; return n; } /* * return nelem of list */ int count(NodeList *l) { int n; n = 0; for(; l; l=l->next) n++; return n; } /* * return nelem of list */ int structcount(Type *t) { int v; Iter s; v = 0; for(t = structfirst(&s, &t); t != T; t = structnext(&s)) v++; return v; } /* * return power of 2 of the constant * operand. -1 if it is not a power of 2. * 1000+ if it is a -(power of 2) */ int powtwo(Node *n) { uvlong v, b; int i; if(n == N || n->op != OLITERAL || n->type == T) goto no; if(!isint[n->type->etype]) goto no; v = mpgetfix(n->val.u.xval); b = 1ULL; for(i=0; i<64; i++) { if(b == v) return i; b = b<<1; } if(!issigned[n->type->etype]) goto no; v = -v; b = 1ULL; for(i=0; i<64; i++) { if(b == v) return i+1000; b = b<<1; } no: return -1; } /* * return the unsigned type for * a signed integer type. * returns T if input is not a * signed integer type. */ Type* tounsigned(Type *t) { // this is types[et+1], but not sure // that this relation is immutable switch(t->etype) { default: print("tounsigned: unknown type %T\n", t); t = T; break; case TINT: t = types[TUINT]; break; case TINT8: t = types[TUINT8]; break; case TINT16: t = types[TUINT16]; break; case TINT32: t = types[TUINT32]; break; case TINT64: t = types[TUINT64]; break; } return t; } /* * magic number for signed division * see hacker's delight chapter 10 */ void smagic(Magic *m) { int p; uint64 ad, anc, delta, q1, r1, q2, r2, t; uint64 mask, two31; m->bad = 0; switch(m->w) { default: m->bad = 1; return; case 8: mask = 0xffLL; break; case 16: mask = 0xffffLL; break; case 32: mask = 0xffffffffLL; break; case 64: mask = 0xffffffffffffffffLL; break; } two31 = mask ^ (mask>>1); p = m->w-1; ad = m->sd; if(m->sd < 0) ad = -m->sd; // bad denominators if(ad == 0 || ad == 1 || ad == two31) { m->bad = 1; return; } t = two31; ad &= mask; anc = t - 1 - t%ad; anc &= mask; q1 = two31/anc; r1 = two31 - q1*anc; q1 &= mask; r1 &= mask; q2 = two31/ad; r2 = two31 - q2*ad; q2 &= mask; r2 &= mask; for(;;) { p++; q1 <<= 1; r1 <<= 1; q1 &= mask; r1 &= mask; if(r1 >= anc) { q1++; r1 -= anc; q1 &= mask; r1 &= mask; } q2 <<= 1; r2 <<= 1; q2 &= mask; r2 &= mask; if(r2 >= ad) { q2++; r2 -= ad; q2 &= mask; r2 &= mask; } delta = ad - r2; delta &= mask; if(q1 < delta || (q1 == delta && r1 == 0)) { continue; } break; } m->sm = q2+1; if(m->sm & two31) m->sm |= ~mask; m->s = p-m->w; } /* * magic number for unsigned division * see hacker's delight chapter 10 */ void umagic(Magic *m) { int p; uint64 nc, delta, q1, r1, q2, r2; uint64 mask, two31; m->bad = 0; m->ua = 0; switch(m->w) { default: m->bad = 1; return; case 8: mask = 0xffLL; break; case 16: mask = 0xffffLL; break; case 32: mask = 0xffffffffLL; break; case 64: mask = 0xffffffffffffffffLL; break; } two31 = mask ^ (mask>>1); m->ud &= mask; if(m->ud == 0 || m->ud == two31) { m->bad = 1; return; } nc = mask - (-m->ud&mask)%m->ud; p = m->w-1; q1 = two31/nc; r1 = two31 - q1*nc; q1 &= mask; r1 &= mask; q2 = (two31-1) / m->ud; r2 = (two31-1) - q2*m->ud; q2 &= mask; r2 &= mask; for(;;) { p++; if(r1 >= nc-r1) { q1 <<= 1; q1++; r1 <<= 1; r1 -= nc; } else { q1 <<= 1; r1 <<= 1; } q1 &= mask; r1 &= mask; if(r2+1 >= m->ud-r2) { if(q2 >= two31-1) { m->ua = 1; } q2 <<= 1; q2++; r2 <<= 1; r2++; r2 -= m->ud; } else { if(q2 >= two31) { m->ua = 1; } q2 <<= 1; r2 <<= 1; r2++; } q2 &= mask; r2 &= mask; delta = m->ud - 1 - r2; delta &= mask; if(p < m->w+m->w) if(q1 < delta || (q1 == delta && r1 == 0)) { continue; } break; } m->um = q2+1; m->s = p-m->w; } Sym* ngotype(Node *n) { if(n->type != T) return typenamesym(n->type); return S; } /* * Convert raw string to the prefix that will be used in the symbol * table. All control characters, space, '%' and '"', as well as * non-7-bit clean bytes turn into %xx. The period needs escaping * only in the last segment of the path, and it makes for happier * users if we escape that as little as possible. * * If you edit this, edit ../ld/lib.c:/^pathtoprefix copy too. */ static char* pathtoprefix(char *s) { static char hex[] = "0123456789abcdef"; char *p, *r, *w, *l; int n; // find first character past the last slash, if any. l = s; for(r=s; *r; r++) if(*r == '/') l = r+1; // check for chars that need escaping n = 0; for(r=s; *r; r++) if(*r <= ' ' || (*r == '.' && r >= l) || *r == '%' || *r == '"' || *r >= 0x7f) n++; // quick exit if(n == 0) return s; // escape p = mal((r-s)+1+2*n); for(r=s, w=p; *r; r++) { if(*r <= ' ' || (*r == '.' && r >= l) || *r == '%' || *r == '"' || *r >= 0x7f) { *w++ = '%'; *w++ = hex[(*r>>4)&0xF]; *w++ = hex[*r&0xF]; } else *w++ = *r; } *w = '\0'; return p; } Pkg* mkpkg(Strlit *path) { Pkg *p; int h; h = stringhash(path->s) & (nelem(phash)-1); for(p=phash[h]; p; p=p->link) if(p->path->len == path->len && memcmp(path->s, p->path->s, path->len) == 0) return p; p = mal(sizeof *p); p->path = path; p->prefix = pathtoprefix(path->s); p->link = phash[h]; phash[h] = p; return p; } Strlit* strlit(char *s) { Strlit *t; t = mal(sizeof *t + strlen(s)); strcpy(t->s, s); t->len = strlen(s); return t; } void addinit(Node **np, NodeList *init) { Node *n; if(init == nil) return; n = *np; switch(n->op) { case ONAME: case OLITERAL: // There may be multiple refs to this node; // introduce OCONVNOP to hold init list. n = nod(OCONVNOP, n, N); n->type = n->left->type; n->typecheck = 1; *np = n; break; } n->ninit = concat(init, n->ninit); n->ullman = UINF; } static char* reservedimports[] = { "go", "type", }; int isbadimport(Strlit *path) { int i; char *s; Rune r; if(strlen(path->s) != path->len) { yyerror("import path contains NUL"); return 1; } for(i=0; is, reservedimports[i]) == 0) { yyerror("import path \"%s\" is reserved and cannot be used", path->s); return 1; } } s = path->s; while(*s) { s += chartorune(&r, s); if(r == Runeerror) { yyerror("import path contains invalid UTF-8 sequence: \"%Z\"", path); return 1; } if(r < 0x20 || r == 0x7f) { yyerror("import path contains control character: \"%Z\"", path); return 1; } if(r == '\\') { yyerror("import path contains backslash; use slash: \"%Z\"", path); return 1; } if(isspacerune(r)) { yyerror("import path contains space character: \"%Z\"", path); return 1; } if(utfrune("!\"#$%&'()*,:;<=>?[]^`{|}", r)) { yyerror("import path contains invalid character '%C': \"%Z\"", r, path); return 1; } } return 0; }