/* Tuplr: A programming language * Copyright (C) 2008-2009 David Robillard * * Tuplr is free software: you can redistribute it and/or modify it under * the terms of the GNU Affero General Public License as published by the * Free Software Foundation, either version 3 of the License, or (at your * option) any later version. * * Tuplr is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Affero General * Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with Tuplr. If not, see . */ #ifndef TUPLR_HPP #define TUPLR_HPP #include #include #include #include #include #include #include #include #define FOREACH(IT, i, c) for (IT i = (c).begin(); i != (c).end(); ++i) using namespace std; using boost::format; /*************************************************************************** * Basic Utility Classes * ***************************************************************************/ /// Location in textual code struct Cursor { Cursor(const string& n="", unsigned l=1, unsigned c=0) : name(n), line(l), col(c) {} operator bool() const { return !(line == 1 && col == 0); } string str() const { return (format("%1%:%2%:%3%") % name % line % col).str(); } string name; unsigned line; unsigned col; }; /// Compiler error struct Error { Error(const string& m, Cursor c=Cursor()) : msg(m), loc(c) {} const string what() const { return (loc ? loc.str() + ": " : "") + "error: " + msg; } string msg; Cursor loc; }; /// Expression ::= Atom | (Expression*) template struct Exp { Exp(Cursor c) : type(LIST), loc(c) {} Exp(Cursor c, const Atom& a) : type(ATOM), loc(c), atom(a) {} typedef std::vector< Exp > List; enum { ATOM, LIST } type; Cursor loc; Atom atom; List list; }; /// Lexical Address struct LAddr { LAddr(unsigned u=0, unsigned o=0) : up(u), over(o) {} operator bool() const { return !(up == 0 && over == 0); } unsigned up, over; }; /// Generic Lexical Environment template struct Env : public list< vector< pair > > { typedef vector< pair > Frame; Env() : list(1) {} virtual void push(Frame f=Frame()) { list::push_front(f); } virtual void pop() { assert(!this->empty()); list::pop_front(); } const V& def(const K& k, const V& v) { for (typename Frame::iterator b = this->begin()->begin(); b != this->begin()->end(); ++b) if (b->first == k) return (b->second = v); this->front().push_back(make_pair(k, v)); return v; } V* ref(const K& key) { for (typename Env::iterator f = this->begin(); f != this->end(); ++f) for (typename Frame::iterator b = f->begin(); b != f->end(); ++b) if (b->first == key) return &b->second; return NULL; } LAddr lookup(const K& key) const { unsigned up = 0; for (typename Env::const_iterator f = this->begin(); f != this->end(); ++f, ++up) for (unsigned over = 0; over < f->size(); ++over) if ((*f)[over].first == key) return LAddr(up + 1, over + 1); return LAddr(); } V& deref(LAddr addr) { assert(addr); typename Env::iterator f = this->begin(); for (unsigned u = 1; u < addr.up; ++u, ++f) { assert(f != this->end()); } if (!(f->size() > addr.over - 1)) { std::cerr << "WTF: " << addr << " : " << this->size() << "." << f->size() << endl; } assert(f->size() > addr.over - 1); return (*f)[addr.over - 1].second; } }; /*************************************************************************** * Lexer: Text (istream) -> S-Expressions (SExp) * ***************************************************************************/ typedef Exp SExp; ///< Textual S-Expression SExp readExpression(Cursor& cur, std::istream& in); /*************************************************************************** * Backend Types * ***************************************************************************/ typedef void* CValue; ///< Compiled value (opaque) typedef void* CFunction; ///< Compiled function (opaque) typedef void* CEngine; ///< Compiler Engine (opaque) /*************************************************************************** * Abstract Syntax Tree * ***************************************************************************/ struct Constraint; ///< Type Constraint struct TEnv; ///< Type-Time Environment struct CEnv; ///< Compile-Time Environment struct AST; struct Constraints; struct Subst; extern ostream& operator<<(ostream& out, const AST* ast); /// Base class for all AST nodes struct AST { AST(Cursor c=Cursor()) : loc(c) {} virtual ~AST() {} virtual bool operator==(const AST& o) const = 0; virtual bool contains(const AST* child) const { return false; } virtual void constrain(TEnv& tenv, Constraints& c) const {} virtual void lift(CEnv& cenv) {} string str() const { ostringstream ss; ss << this; return ss.str(); } Cursor loc; private: friend class CEnv; virtual CValue compile(CEnv& cenv) = 0; }; /// Literal value template struct ALiteral : public AST { ALiteral(VT v, Cursor c) : AST(c), val(v) {} bool operator==(const AST& rhs) const { const ALiteral* r = dynamic_cast*>(&rhs); return (r && (val == r->val)); } void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); const VT val; }; /// Symbol, e.g. "a" struct ASymbol : public AST { bool operator==(const AST& rhs) const { return this == &rhs; } void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); mutable LAddr addr; private: friend class PEnv; ASymbol(const string& s, Cursor c) : AST(c), cppstr(s) {} friend ostream& operator<<(ostream&, const AST*); const string cppstr; }; /// Tuple (heterogeneous sequence of fixed length), e.g. "(a b c)" struct ATuple : public AST, public vector { ATuple(const vector& t=vector(), Cursor c=Cursor()) : AST(c), vector(t) {} ATuple(size_t size, Cursor c) : AST(c), vector(size) {} ATuple(Cursor c, AST* ast, ...) : AST(c) { if (!ast) return; va_list args; va_start(args, ast); push_back(ast); for (AST* a = va_arg(args, AST*); a; a = va_arg(args, AST*)) push_back(a); va_end(args); } bool operator==(const AST& rhs) const { const ATuple* rt = dynamic_cast(&rhs); if (!rt || rt->size() != size()) return false; const_iterator l = begin(); FOREACH(const_iterator, r, *rt) if (!(*(*l++) == *(*r))) return false; return true; } void lift(CEnv& cenv) { FOREACH(iterator, t, *this) (*t)->lift(cenv); } bool contains(AST* child) const { if (*this == *child) return true; FOREACH(const_iterator, p, *this) if (**p == *child || (*p)->contains(child)) return true; return false; } void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv) { throw Error("tuple compiled"); } }; /// Type Expression, e.g. "Int", "(Fn (Int Int) Float)" struct AType : public ATuple { AType(unsigned i, LAddr a, Cursor c=Cursor()) : ATuple(0, c), kind(VAR), addr(a), id(i) {} AType(ASymbol* s) : ATuple(0, s->loc), kind(PRIM), id(0) { push_back(s); } AType(const ATuple& t, Cursor c) : ATuple(t, c), kind(EXPR), id(0) {} AType(Cursor c, AST* ast, ...) : ATuple(0, c), kind(EXPR), id(0) { va_list args; va_start(args, ast); if (!ast) return; push_back(ast); for (AST* a = va_arg(args, AST*); a; a = va_arg(args, AST*)) push_back(a); va_end(args); } CValue compile(CEnv& cenv) { return NULL; } bool var() const { return kind == VAR; } bool concrete() const { switch (kind) { case VAR: return false; case PRIM: return true; case EXPR: FOREACH(const_iterator, t, *this) { AType* kid = dynamic_cast(*t); if (kid && !kid->concrete()) return false; } } return true; } bool operator==(const AST& rhs) const { const AType* rt = dynamic_cast(&rhs); if (!rt || kind != rt->kind) return false; else switch (kind) { case VAR: return id == rt->id; case PRIM: return at(0)->str() == rt->at(0)->str(); case EXPR: return ATuple::operator==(rhs); } return false; // never reached } enum { VAR, PRIM, EXPR } kind; LAddr addr; unsigned id; }; /// Lifted system functions (of various types) for a single Tuplr function struct Funcs : public list< pair > { CFunction find(AType* type) const { for (const_iterator f = begin(); f != end(); ++f) if (*f->first == *type) return f->second; return NULL; } }; /// Closure (first-class function with captured lexical bindings) struct AClosure : public ATuple { AClosure(Cursor c, ASymbol* fn, ATuple* p, const string& n="") : ATuple(c, fn, p, NULL), subst(0), name(n) {} bool operator==(const AST& rhs) const { return this == &rhs; } void constrain(TEnv& tenv, Constraints& c) const; void lift(CEnv& cenv); void liftCall(CEnv& cenv, const vector& argsT); CValue compile(CEnv& cenv); ATuple* prot() const { return dynamic_cast(at(1)); } Funcs funcs; mutable Subst* subst; private: string name; }; /// Function call/application, e.g. "(func arg1 arg2)" struct ACall : public ATuple { ACall(const SExp& e, const ATuple& t) : ATuple(t, e.loc) {} void constrain(TEnv& tenv, Constraints& c) const; void lift(CEnv& cenv); CValue compile(CEnv& cenv); }; /// Definition special form, e.g. "(def x 2)" struct ADefinition : public ACall { ADefinition(const SExp& e, const ATuple& t) : ACall(e, t) {} ASymbol* sym() const { return dynamic_cast(at(1)); } void constrain(TEnv& tenv, Constraints& c) const; void lift(CEnv& cenv); CValue compile(CEnv& cenv); }; /// Conditional special form, e.g. "(if cond thenexp elseexp)" struct AIf : public ACall { AIf(const SExp& e, const ATuple& t) : ACall(e, t) {} void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); }; /// Primitive (builtin arithmetic function), e.g. "(+ 2 3)" struct APrimitive : public ACall { APrimitive(const SExp& e, const ATuple& t) : ACall(e, t) {} void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); }; /// Cons special form, e.g. "(cons 1 2)" struct AConsCall : public ACall { AConsCall(const SExp& e, const ATuple& t) : ACall(e, t) {} AType* functionType(CEnv& cenv); void constrain(TEnv& tenv, Constraints& c) const; void lift(CEnv& cenv); CValue compile(CEnv& cenv); static Funcs funcs; }; /// Car special form, e.g. "(car p)" struct ACarCall : public ACall { ACarCall(const SExp& e, const ATuple& t) : ACall(e, t) {} void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); }; /// Cdr special form, e.g. "(cdr p)" struct ACdrCall : public ACall { ACdrCall(const SExp& e, const ATuple& t) : ACall(e, t) {} void constrain(TEnv& tenv, Constraints& c) const; CValue compile(CEnv& cenv); }; /*************************************************************************** * Parser: S-Expressions (SExp) -> AST Nodes (AST) * ***************************************************************************/ /// Parse Time Environment (really just a symbol table) struct PEnv : private map { typedef AST* (*PF)(PEnv&, const SExp&, void*); // Parse Function struct Handler { Handler(PF f, void* a=0) : func(f), arg(a) {} PF func; void* arg; }; map aHandlers; ///< Atom parse functions map lHandlers; ///< List parse functions void reg(bool list, const string& s, const Handler& h) { (list ? lHandlers : aHandlers).insert(make_pair(sym(s)->str(), h)); } const Handler* handler(bool list, const string& s) const { const map& handlers = list ? lHandlers : aHandlers; map::const_iterator i = handlers.find(s); return (i != handlers.end()) ? &i->second : NULL; } ASymbol* sym(const string& s, Cursor c=Cursor()) { const const_iterator i = find(s); return ((i != end()) ? i->second : insert(make_pair(s, new ASymbol(s, c))).first->second); } ATuple parseTuple(const SExp& e) { ATuple ret(e.list.size(), e.loc); size_t n = 0; FOREACH(SExp::List::const_iterator, i, e.list) ret[n++] = parse(*i); return ret; } AST* parse(const SExp& exp) { if (exp.type == SExp::LIST) { if (exp.list.empty()) throw Error("call to empty list", exp.loc); if (exp.list.front().type == SExp::ATOM) { const PEnv::Handler* h = handler(true, exp.list.front().atom); if (h) return h->func(*this, exp, h->arg); } return new ACall(exp, parseTuple(exp)); // Parse as regular call } else if (isdigit(exp.atom[0])) { if (exp.atom.find('.') == string::npos) return new ALiteral(strtol(exp.atom.c_str(), NULL, 10), exp.loc); else return new ALiteral(strtod(exp.atom.c_str(), NULL), exp.loc); } else { const PEnv::Handler* h = handler(false, exp.atom); if (h) return h->func(*this, exp, h->arg); } return sym(exp.atom, exp.loc); } }; /*************************************************************************** * Typing * ***************************************************************************/ struct Constraint : public pair { Constraint(AType* a, AType* b, Cursor c) : pair(a, b), loc(c) {} Cursor loc; }; struct Constraints : public list { void constrain(TEnv& tenv, const AST* o, AType* t); }; inline ostream& operator<<(ostream& out, const Constraints& c) { for (Constraints::const_iterator i = c.begin(); i != c.end(); ++i) out << i->first << " : " << i->second << endl; return out; } struct Subst : public map { Subst(AType* s=0, AType* t=0) { if (s && t) { assert(s != t); insert(make_pair(s, t)); } } static Subst compose(const Subst& delta, const Subst& gamma); AST* apply(AST* ast) const { AType* in = dynamic_cast(ast); if (!in) return ast; if (in->kind == AType::EXPR) { AType* out = new AType(in->loc, NULL); for (size_t i = 0; i < in->size(); ++i) out->push_back(apply(in->at(i))); return out; } else { Subst copy(*this); iterator i; while ((i = copy.find(in)) != copy.end()) { in = i->second; copy.erase(i); } return in; } } }; /// Type-Time Environment struct TEnv : public Env { TEnv(PEnv& p) : penv(p), varID(1) {} AType* fresh(const ASymbol* sym) { assert(sym); return def(sym, new AType(varID++, LAddr(), sym->loc)); } AType* var(const AST* ast=0) { const ASymbol* sym = dynamic_cast(ast); if (sym) return deref(lookup(sym)); Vars::iterator v = vars.find(ast); if (v != vars.end()) return v->second; AType* ret = new AType(varID++, LAddr(), ast ? ast->loc : Cursor()); if (ast) vars[ast] = ret; return ret; } AType* named(const string& name) { return *ref(penv.sym(name)); } static Subst unify(const Constraints& c); typedef map Vars; typedef map GenericTypes; Vars vars; GenericTypes genericTypes; PEnv& penv; Constraints constraints; unsigned varID; }; /*************************************************************************** * Code Generation * ***************************************************************************/ /// Compile-Time Environment struct CEnv { CEnv(PEnv& p, TEnv& t, CEngine e, ostream& os=std::cout, ostream& es=std::cerr); ~CEnv(); typedef Env Code; typedef Env Vals; CEngine engine(); string gensym(const char* s="_") { return (format("%s%d") % s % symID++).str(); } void push() { code.push(); vals.push(); tenv.push(); } void pop() { code.pop(); vals.pop(); tenv.pop(); } void precompile(AST* obj, CValue value) { vals.def(obj, value); } CValue compile(AST* obj); void optimise(CFunction f); void write(std::ostream& os); AType* type(AST* ast, const Subst& subst = Subst()) const { ASymbol* sym = dynamic_cast(ast); if (sym) return tenv.deref(sym->addr); return dynamic_cast(tsubst.apply(subst.apply(tenv.vars[ast]))); } void def(ASymbol* sym, AST* c, AType* t, CValue v) { code.def(sym, c); tenv.def(sym, t); vals.def(sym, v); } ostream& out; ostream& err; PEnv& penv; TEnv& tenv; Code code; Vals vals; unsigned symID; CFunction alloc; Subst tsubst; private: struct PImpl; ///< Private Implementation PImpl* _pimpl; }; /*************************************************************************** * EVAL/REPL/MAIN * ***************************************************************************/ void initLang(PEnv& penv, TEnv& tenv); CEnv* newCenv(PEnv& penv, TEnv& tenv); int eval(CEnv& cenv, const string& name, istream& is); int repl(CEnv& cenv); #endif // TUPLR_HPP