/***** * types.h * Andy Hammerlindl 2002/06/20 * * Used by the compiler as a way to keep track of the type of a variable * or expression. * *****/ #ifndef TYPES_H #define TYPES_H #include #include #include #include "errormsg.h" #include "symbol.h" #include "common.h" #include "util.h" using std::ostream; using sym::symbol; // Forward declaration. namespace trans { class access; class varEntry; } namespace absyntax { class varinit; extern varinit *Default; } namespace types { enum ty_kind { ty_null, ty_record, // "struct" in Asymptote language ty_function, ty_overloaded, #define PRIMITIVE(name,Name,asyName) ty_##name, #define PRIMERROR #include "primitives.h" #undef PRIMERROR #undef PRIMITIVE ty_array }; // Forward declarations. class ty; struct signature; typedef mem::vector ty_vector; typedef ty_vector::iterator ty_iterator; // Checks if two types are equal in the sense of the language. // That is primitive types are equal if they are the same kind. // Structures are equal if they come from the same struct definition. // Arrays are equal if their cell types are equal. bool equivalent(const ty *t1, const ty *t2); // If special is true, this is the same as above. If special is false, just // the signatures are compared. bool equivalent(const ty *t1, const ty *t2, bool special); class caster { public: virtual ~caster() {} virtual trans::access *operator() (ty *target, ty *source) = 0; virtual bool castable(ty *target, ty *source) = 0; }; class ty : public gc { public: const ty_kind kind; ty(ty_kind kind) : kind(kind) {} virtual ~ty(); virtual void print (ostream& out) const; virtual void printVar (ostream& out, string name) const { print(out); out << " " << name; } // Returns true if the type is a user-defined type or the null type. // While the pair, path, etc. are stored by reference, this is // transparent to the user. virtual bool isReference() { return true; } virtual signature *getSignature() { return 0; } virtual const signature *getSignature() const { return 0; } virtual bool primitive() { return false; } bool isError() const { return kind == ty_error; } bool isNotError() const { return !isError(); } // The following are only used by the overloaded type, but it is so common // to test for an overloaded type then iterate over its types, that this // allows the code: // if (t->isOverloaded()) { // for (ty_iterator i = t->begin(); i != t->end(); ++i) { // ... // } // } // For speed reasons, only begin has an assert to test if t is overloaded. bool isOverloaded() const { return kind == ty_overloaded; } bool isNotOverloaded() const { return !isOverloaded(); } ty_iterator begin(); ty_iterator end(); // If a default initializer is not stored in the environment, the abstract // syntax asks the type if it has a "default" default initializer, by calling // this method. virtual trans::access *initializer() { return 0; } // If a cast function is not stored in the environment, ask the type itself. // This handles null->record casting, and the like. The caster is used as a // callback to the environment for casts of subtypes. virtual trans::access *castTo(ty *, caster &) { return 0; } // Just checks if a cast is possible. virtual bool castable(ty *target, caster &c) { return castTo(target, c); } // For pair's x and y, and array's length, this is a special type of // "field". // In actually, it returns a function which takes the object as its // parameter and returns the necessary result. // These should not have public permission, as modifying them would // have strange results. virtual trans::varEntry *virtualField(symbol, signature *) { return 0; } // varGetType for virtual fields. // Unless you are using functions for virtual fields, the base implementation // should work fine. virtual ty *virtualFieldGetType(symbol id); #if 0 // Returns the type. In case of functions, return the equivalent type // but with no default values for parameters. virtual ty *stripDefaults() { return this; } #endif // Returns true if the other type is equivalent to this one. // The general function equivalent should be preferably used, as it properly // handles overloaded type comparisons. virtual bool equiv(const ty *other) const { return this==other; } // Returns a number for the type for use in a hash table. Equivalent types // must yield the same number. virtual size_t hash() const = 0; }; class primitiveTy : public ty { public: primitiveTy(ty_kind kind) : ty(kind) {} bool primitive() { return true; } bool isReference() { return false; } ty *virtualFieldGetType(symbol ); trans::varEntry *virtualField(symbol, signature *); bool equiv(const ty *other) const { return this->kind==other->kind; } size_t hash() const { return (size_t)kind + 47; } }; class nullTy : public primitiveTy { public: nullTy() : primitiveTy(ty_null) {} bool isReference() { return true; } trans::access *castTo(ty *target, caster &); size_t hash() const { return (size_t)kind + 47; } }; // Ostream output, just defer to print. inline ostream& operator<< (ostream& out, const ty& t) { t.print(out); return out; } struct array : public ty { ty *celltype; ty *pushtype; ty *poptype; ty *appendtype; ty *inserttype; ty *deletetype; array(ty *celltype) : ty(ty_array), celltype(celltype), pushtype(0), poptype(0), appendtype(0), inserttype(0), deletetype(0) {} virtual bool isReference() { return true; } bool equiv(const ty *other) const { return other->kind==ty_array && equivalent(this->celltype,((array *)other)->celltype); } size_t hash() const { return 1007 * celltype->hash(); } Int depth() { if (array *cell=dynamic_cast(celltype)) return cell->depth() + 1; else return 1; } void print(ostream& out) const { out << *celltype << "[]"; } ty *pushType(); ty *popType(); ty *appendType(); ty *insertType(); ty *deleteType(); // Initialize to an empty array by default. trans::access *initializer(); // NOTE: General vectorization of casts would be here. // Add length and push as virtual fields. ty *virtualFieldGetType(symbol id); trans::varEntry *virtualField(symbol id, signature *sig); }; /* Base types */ #define PRIMITIVE(name,Name,asyName) \ ty *prim##Name(); \ ty *name##Array(); \ ty *name##Array2(); \ ty *name##Array3(); #define PRIMERROR #include "primitives.h" #undef PRIMERROR #undef PRIMITIVE ty *primNull(); struct formal { ty *t; symbol name; bool defval; bool Explicit; formal(ty *t, symbol name=symbol::nullsym, bool optional=false, bool Explicit=false) : t(t), name(name), defval(optional), Explicit(Explicit) {} // string->symbol translation is costly if done too many times. This // constructor has been disabled to make this cost more visible to the // programmer. #if 0 formal(ty *t, const char *name, bool optional=false, bool Explicit=false) : t(t), name(symbol::trans(name)), defval(optional ? absyntax::Default : 0), Explicit(Explicit) {} #endif friend ostream& operator<< (ostream& out, const formal& f); }; bool equivalent(const formal& f1, const formal& f2); bool argumentEquivalent(const formal &f1, const formal& f2); typedef mem::vector formal_vector; // Holds the parameters of a function and if they have default values // (only applicable in some cases). struct signature : public gc { formal_vector formals; // The number of keyword-only formals. These formals always come after the // regular formals. size_t numKeywordOnly; // Formal for the rest parameter. If there is no rest parameter, then the // type is null. formal rest; bool isOpen; signature() : numKeywordOnly(0), rest(0), isOpen(false) {} struct OPEN_t {}; static const OPEN_t OPEN; explicit signature(OPEN_t) : numKeywordOnly(0), rest(0), isOpen(true) {} signature(signature &sig) : formals(sig.formals), numKeywordOnly(sig.numKeywordOnly), rest(sig.rest), isOpen(sig.isOpen) {} virtual ~signature() {} void add(formal f) { formals.push_back(f); } void addKeywordOnly(formal f) { add(f); ++numKeywordOnly; } void addRest(formal f) { rest=f; } bool hasRest() const { return rest.t; } size_t getNumFormals() const { return rest.t ? formals.size() + 1 : formals.size(); } formal& getFormal(size_t n) { assert(n < formals.size()); return formals[n]; } const formal& getFormal(size_t n) const { assert(n < formals.size()); return formals[n]; } formal& getRest() { return rest; } const formal& getRest() const { return rest; } bool formalIsKeywordOnly(size_t n) const { assert(n < formals.size()); return n >= formals.size() - numKeywordOnly; } friend string toString(const signature& s); friend ostream& operator<< (ostream& out, const signature& s); friend bool equivalent(const signature *s1, const signature *s2); // Check if a signature of argument types (as opposed to formal parameters) // are equivalent. Here, the arguments, if named, must have the same names, // and (for simplicity) no overloaded arguments are allowed. friend bool argumentEquivalent(const signature *s1, const signature *s2); #if 0 friend bool castable(signature *target, signature *source); friend Int numFormalsMatch(signature *s1, signature *s2); #endif size_t hash() const; // Return a unique handle for this signature size_t handle(); }; struct function : public ty { ty *result; signature sig; function(ty *result) : ty(ty_function), result(result) {} function(ty *result, signature::OPEN_t) : ty(ty_function), result(result), sig(signature::OPEN) {} function(ty *result, signature *sig) : ty(ty_function), result(result), sig(*sig) {} function(ty *result, formal f1) : ty(ty_function), result(result) { add(f1); } function(ty *result, formal f1, formal f2) : ty(ty_function), result(result) { add(f1); add(f2); } function(ty *result, formal f1, formal f2, formal f3) : ty(ty_function), result(result) { add(f1); add(f2); add(f3); } function(ty *result, formal f1, formal f2, formal f3, formal f4) : ty(ty_function), result(result) { add(f1); add(f2); add(f3); add(f4); } virtual ~function() {} void add(formal f) { sig.add(f); } void addRest(formal f) { sig.addRest(f); } virtual bool isReference() { return true; } bool equiv(const ty *other) const { if (other->kind==ty_function) { function *that=(function *)other; return equivalent(this->result,that->result) && equivalent(&this->sig,&that->sig); } else return false; } size_t hash() const { return sig.hash()*0x1231+result->hash(); } void print(ostream& out) const { out << *result << sig; } void printVar (ostream& out, string name) const { result->printVar(out,name); out << sig; } ty *getResult() { return result; } signature *getSignature() { return &sig; } const signature *getSignature() const { return &sig; } #if 0 ty *stripDefaults(); #endif // Initialized to null. trans::access *initializer(); }; // This is used in getType expressions when an overloaded variable is accessed. class overloaded : public ty { public: ty_vector sub; // Warning: The venv endScope routine relies heavily on the current // implementation of overloaded. public: overloaded() : ty(ty_overloaded) {} overloaded(ty *t) : ty(ty_overloaded) { add(t); } virtual ~overloaded() {} bool equiv(const ty *other) const { for(ty_vector::const_iterator i=sub.begin();i!=sub.end();++i) if (equivalent(*i,other)) return true; return false; } size_t hash() const { // Overloaded types should not be hashed. assert(False); return 0; } void add(ty *t) { if (t->kind == ty_overloaded) { overloaded *ot = (overloaded *)t; copy(ot->sub.begin(), ot->sub.end(), inserter(this->sub, this->sub.end())); } else sub.push_back(t); } // Only add a type distinct from the ones currently in the overloaded type. // If special is false, just the distinct signatures are added. void addDistinct(ty *t, bool special=false); // If there are less than two overloaded types, the type isn't really // overloaded. This gives a more appropriate type in this case. ty *simplify() { switch (sub.size()) { case 0: return 0; case 1: { return sub.front(); } default: return new overloaded(*this); } } // Returns the signature-less type of the set. ty *signatureless(); // True if one of the subtypes is castable. bool castable(ty *target, caster &c); size_t size() const { return sub.size(); } // Use default printing for now. }; inline ty_iterator ty::begin() { assert(this->isOverloaded()); return ((overloaded *)this)->sub.begin(); } inline ty_iterator ty::end() { return ((overloaded *)this)->sub.end(); } // This is used to encapsulate iteration over the subtypes of an overloaded // type. The base method need only be implemented to handle non-overloaded // types. class collector { public: virtual ~collector() {} virtual ty *base(ty *target, ty *source) = 0; virtual ty *collect(ty *target, ty *source) { if (overloaded *o=dynamic_cast(target)) { ty_vector &sub=o->sub; overloaded *oo=new overloaded; for(ty_vector::iterator x = sub.begin(); x != sub.end(); ++x) { types::ty *t=collect(*x, source); if (t) oo->add(t); } return oo->simplify(); } else if (overloaded *o=dynamic_cast(source)) { ty_vector &sub=o->sub; overloaded *oo=new overloaded; for(ty_vector::iterator y = sub.begin(); y != sub.end(); ++y) { // NOTE: A possible speed optimization would be to replace this with a // call to base(), but this is only correct if we can guarantee that an // overloaded type has no overloaded sub-types. types::ty *t=collect(target, *y); if (t) oo->add(t); } return oo->simplify(); } else return base(target, source); } }; class tester { public: virtual ~tester() {} virtual bool base(ty *target, ty *source) = 0; virtual bool test(ty *target, ty *source) { if (overloaded *o=dynamic_cast(target)) { ty_vector &sub=o->sub; for(ty_vector::iterator x = sub.begin(); x != sub.end(); ++x) if (test(*x, source)) return true; return false; } else if (overloaded *o=dynamic_cast(source)) { ty_vector &sub=o->sub; for(ty_vector::iterator y = sub.begin(); y != sub.end(); ++y) if (base(target, *y)) return true; return false; } else return base(target, source); } }; } // namespace types GC_DECLARE_PTRFREE(types::primitiveTy); GC_DECLARE_PTRFREE(types::nullTy); #endif