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exp.h
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exp.h
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/*****
* exp.h
* Andy Hammerlindl 2002/8/19
*
* Represents the abstract syntax tree for the expressions in the
* language. this is translated into virtual machine code using trans()
* and with the aid of the environment class.
*****/
#ifndef EXP_H
#define EXP_H
#include "types.h"
#include "symbol.h"
#include "absyn.h"
#include "varinit.h"
#include "name.h"
#include "guideflags.h"
namespace trans {
class coenv;
class coder;
struct label_t;
typedef label_t *label;
class application;
}
namespace absyntax {
using trans::coenv;
using trans::label;
using trans::application;
using trans::access;
using sym::symbol;
using types::record;
using types::array;
class exp : public varinit {
protected:
// The cached type (from a call to cgetType).
types::ty *ct;
public:
exp(position pos)
: varinit(pos), ct(0) {}
void prettyprint(ostream &out, Int indent) = 0;
// When reporting errors with function calls, it is nice to say "no
// function f(int)" instead of "no function matching signature
// (int)." Hence, this method returns the name of the expression if
// there is one.
virtual symbol getName()
{
return symbol::nullsym;
}
// Checks if the expression can be used as the right side of a scale
// expression. ie. 3sin(x)
// If a "non-scalable" expression is scaled a warning is issued.
virtual bool scalable() { return true; }
// Specifies if the value of the expression should be written to interactive
// prompt if typed as a stand-alone expression. For example:
// > 2+3;
// should write 5, but
// > x=2+3;
// shouldn't. (These choices are largely aesthetic)
virtual bool writtenToPrompt() { return true; }
// Translates the expression to the given target type. This should only be
// called with a type returned by getType(). It does not perform implicit
// casting.
virtual void transAsType(coenv &e, types::ty *target);
// Translates the expression to the given target type, possibly using an
// implicit cast.
void transToType(coenv &e, types::ty *target);
// Translates the expression and returns the resultant type.
// For some expressions, this will be ambiguous and return an error.
// Trans may only return ty_error, if it (or one of its recursively
// called children in the syntax tree) reported an error to em.
virtual types::ty *trans(coenv &) = 0;
// getType() figures out the type of the expression without translating
// the code into the virtual machine language or reporting errors to em.
// This must follow a few rules to ensure proper translation:
// 1. If this returns a valid type, t, trans(e) must return t or
// report an error, and transToType(e, t) must run either reporting
// an error or reporting no error and yielding the same result as
// trans(e).
// 2. If this returns a superposition of types (ie. for overloaded
// functions), trans must not return a singular type, and every
// type in the superposition must run without error properly
// if fed to transAsType(e, t).
// 3. If this returns ty_error, then so must a call to trans(e) and any
// call to trans, transAsType, or transToType must report an error
// to em.
// 4. Any call to transAsType(e, t) with a type that is not returned by
// getType() (or one of the subtypes in case of a superposition)
// must report an error.
// Any call to transToType(e, t) with a type that is not returned by
// getType() (or one of the subtypes in case of a superposition)
// or any type not implicitly castable from the above must report an
// error.
virtual types::ty *getType(coenv &) = 0;
// This is an optimization which works in some cases to by-pass the slow
// overloaded function resolution provided by the application class.
//
// If an expression is called with arguments given by sig, getCallee must
// either return 0 (the default), or if it returns a varEntry, the varEntry
// must correspond to the function which would be called after normal
// function resolution.
//
// The callee must produce no side effects as there are no guarantees when
// the varEntry will be translated.
virtual trans::varEntry *getCallee(coenv &e, types::signature *sig) {
//#define DEBUG_GETAPP
#if DEBUG_GETAPP
cout << "exp fail" << endl;
cout << "exp fail at " << getPos() << endl;
prettyprint(cout, 2);
#endif
return 0;
}
// Same result as getType, but caches the result so that subsequent
// calls are faster. For this to work correctly, the expression should
// only be used in one place, so the environment doesn't change between
// calls.
virtual types::ty *cgetType(coenv &e) {
#ifdef DEBUG_CACHE
testCachedType(e);
#endif
return ct ? ct : ct = getType(e);
}
void testCachedType(coenv &e);
// The expression is being written. Translate code such that the value
// (represented by the exp value) is stored into the address represented by
// this expression.
// In terms of side-effects, this expression must be evaluated (once) before
// value is evaluated (once).
virtual void transWrite(coenv &e, types::ty *t, exp *value) {
em.error(getPos());
em << "expression cannot be used as an address";
// Translate the value for errors.
value->transToType(e, t);
}
// Translates code for calling a function. The arguments, in the order they
// appear in the function's signature, must all be on the stack.
virtual void transCall(coenv &e, types::ty *target);
// transConditionalJump must produce code equivalent to the following:
// Evaluate the expression as a boolean. If the result equals cond, jump to
// the label dest, otherwise do not jump. In either case, no value is left
// on the stack.
virtual void transConditionalJump(coenv &e, bool cond, label dest);
// This is used to ensure the proper order and number of evaluations. When
// called, it immediately translates code to perform the side-effects
// consistent with a corresponding call to transAsType(e, target).
//
// The return value, called an evaluation for lack of a better name, is
// another expression that responds to the trans methods exactly as would the
// original expression, but without producing side-effects. It is also no
// longer overloaded, due to the resolution effected by giving a target type
// to evaluate().
//
// The methods transAsType, transWrite, and transCall of the evaluation must
// be called with the same target type as the original call to evaluate.
// When evaluate() is called during the translation of a function, that
// function must still be in translation when the evaluation is translated.
//
// The base implementation uses a tempExp (see below). This is
// sufficient for most expressions.
virtual exp *evaluate(coenv &e, types::ty *target);
// NOTE: could add a "side-effects" method which says if the expression has
// side-effects. This might allow some small optimizations in translating.
};
class tempExp : public exp {
access *a;
types::ty *t;
public:
tempExp(coenv &e, varinit *v, types::ty *t);
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) {
return t;
}
};
// Wrap a varEntry so that it can be used as an expression.
// Translating the varEntry must cause no side-effects.
class varEntryExp : public exp {
trans::varEntry *v;
public:
varEntryExp(position pos, trans::varEntry *v)
: exp(pos), v(v) {}
varEntryExp(position pos, types::ty *t, access *a);
varEntryExp(position pos, types::ty *t, vm::bltin f);
void prettyprint(ostream &out, Int indent);
types::ty *getType(coenv &);
types::ty *trans(coenv &e);
trans::varEntry *getCallee(coenv &e, types::signature *sig);
void transAct(action act, coenv &e, types::ty *target);
void transAsType(coenv &e, types::ty *target);
void transWrite(coenv &e, types::ty *t, exp *value);
void transCall(coenv &e, types::ty *target);
};
class nameExp : public exp {
name *value;
public:
nameExp(position pos, name *value)
: exp(pos), value(value) {}
nameExp(position pos, symbol id)
: exp(pos), value(new simpleName(pos, id)) {}
nameExp(position pos, string s)
: exp(pos), value(new simpleName(pos, symbol::trans(s))) {}
void prettyprint(ostream &out, Int indent);
symbol getName()
{
return value->getName();
}
void transAsType(coenv &e, types::ty *target) {
value->varTrans(trans::READ, e, target);
// After translation, the cached type is no longer needed and should be
// garbage collected. This could presumably be done in every class derived
// from exp, but here it is most important as nameExp can have heavily
// overloaded types cached.
ct=0;
}
types::ty *trans(coenv &e) {
types::ty *t=cgetType(e);
if (t->kind == types::ty_error) {
em.error(getPos());
em << "no matching variable \'" << *value << "\'";
return types::primError();
}
if (t->kind == types::ty_overloaded) {
em.error(getPos());
em << "use of variable \'" << *value << "\' is ambiguous";
return types::primError();
}
else {
transAsType(e, t);
return t;
}
}
types::ty *getType(coenv &e) {
types::ty *t=value->varGetType(e);
return t ? t : types::primError();
}
trans::varEntry *getCallee(coenv &e, types::signature *sig) {
#ifdef DEBUG_GETAPP
cout << "nameExp" << endl;
#endif
return value->getCallee(e, sig);
}
void transWrite(coenv &e, types::ty *target, exp *newValue) {
newValue->transToType(e, target);
this->value->varTrans(trans::WRITE, e, target);
ct=0; // See note in transAsType.
}
void transCall(coenv &e, types::ty *target) {
value->varTrans(trans::CALL, e, target);
ct=0; // See note in transAsType.
}
exp *evaluate(coenv &, types::ty *) {
// Names have no side-effects.
return this;
}
};
// Most fields accessed are handled as parts of qualified names, but in cases
// like f().x or (new t).x, a separate expression is needed.
class fieldExp : public nameExp {
exp *object;
symbol field;
// fieldExp has a lot of common functionality with qualifiedName, so we
// essentially hack qualifiedName, by making our object expression look
// like a name.
class pseudoName : public name {
exp *object;
public:
pseudoName(exp *object)
: name(object->getPos()), object(object) {}
// As a variable:
void varTrans(trans::action act, coenv &e, types::ty *target) {
assert(act == trans::READ);
object->transToType(e, target);
}
types::ty *varGetType(coenv &e) {
return object->getType(e);
}
trans::varEntry *getCallee(coenv &, types::signature *) {
#ifdef DEBUG_GETAPP
cout << "pseudoName" << endl;
#endif
return 0;
}
// As a type:
types::ty *typeTrans(coenv &, bool tacit = false) {
if (!tacit) {
em.error(getPos());
em << "expression is not a type";
}
return types::primError();
}
trans::varEntry *getVarEntry(coenv &) {
em.compiler(getPos());
em << "expression cannot be used as part of a type";
return 0;
}
trans::tyEntry *tyEntryTrans(coenv &) {
em.compiler(getPos());
em << "expression cannot be used as part of a type";
return 0;
}
trans::frame *tyFrameTrans(coenv &) {
return 0;
}
void prettyprint(ostream &out, Int indent);
void print(ostream& out) const {
out << "<exp>";
}
symbol getName() {
return object->getName();
}
};
// Try to get this into qualifiedName somehow.
types::ty *getObject(coenv &e);
public:
fieldExp(position pos, exp *object, symbol field)
: nameExp(pos, new qualifiedName(pos,
new pseudoName(object),
field)),
object(object), field(field) {}
void prettyprint(ostream &out, Int indent);
symbol getName()
{
return field;
}
exp *evaluate(coenv &e, types::ty *) {
// Evaluate the object.
return new fieldExp(getPos(),
new tempExp(e, object, getObject(e)),
field);
}
};
class arrayExp : public exp {
protected:
exp *set;
array *getArrayType(coenv &e);
array *transArray(coenv &e);
public:
arrayExp(position pos, exp *set)
: exp(pos), set(set) {}
};
class subscriptExp : public arrayExp {
exp *index;
public:
subscriptExp(position pos, exp *set, exp *index)
: arrayExp(pos, set), index(index) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
void transWrite(coenv &e, types::ty *t, exp *value);
exp *evaluate(coenv &e, types::ty *) {
return new subscriptExp(getPos(),
new tempExp(e, set, getArrayType(e)),
new tempExp(e, index, types::primInt()));
}
};
class slice : public absyn {
exp *left;
exp *right;
public:
slice(position pos, exp *left, exp *right)
: absyn(pos), left(left), right(right) {}
void prettyprint(ostream &out, Int indent);
exp *getLeft() { return left; }
exp *getRight() { return right; }
// Translates code to put the left and right expressions on the stack (in that
// order). If left is omitted, zero is pushed on the stack in it's place. If
// right is omitted, nothing is pushed in its place.
void trans(coenv &e);
slice *evaluate(coenv &e) {
return new slice(getPos(),
left ? new tempExp(e, left, types::primInt()) : 0,
right ? new tempExp(e, right, types::primInt()) : 0);
}
};
class sliceExp : public arrayExp {
slice *index;
public:
sliceExp(position pos, exp *set, slice *index)
: arrayExp(pos, set), index(index) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
void transWrite(coenv &e, types::ty *t, exp *value);
exp *evaluate(coenv &e, types::ty *) {
return new sliceExp(getPos(),
new tempExp(e, set, getArrayType(e)),
index->evaluate(e));
}
};
// The expression "this," that evaluates to the lexically enclosing record.
class thisExp : public exp {
public:
thisExp(position pos)
: exp(pos) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
exp *evaluate(coenv &, types::ty *) {
// this has no side-effects
return this;
}
};
class literalExp : public exp {
public:
literalExp(position pos)
: exp(pos) {}
bool scalable() { return false; }
exp *evaluate(coenv &, types::ty *) {
// Literals are constant, they have no side-effects.
return this;
}
};
class intExp : public literalExp {
Int value;
public:
intExp(position pos, Int value)
: literalExp(pos), value(value) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primInt(); }
};
class realExp : public literalExp {
protected:
double value;
public:
realExp(position pos, double value)
: literalExp(pos), value(value) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primReal(); }
};
class stringExp : public literalExp {
string str;
public:
stringExp(position pos, string str)
: literalExp(pos), str(str) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primString(); }
const string& getString() { return str; }
};
class booleanExp : public literalExp {
bool value;
public:
booleanExp(position pos, bool value)
: literalExp(pos), value(value) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primBoolean(); }
};
class cycleExp : public literalExp {
public:
cycleExp(position pos)
: literalExp(pos) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primCycleToken(); }
};
class newPictureExp : public literalExp {
public:
newPictureExp(position pos)
: literalExp(pos) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primPicture(); }
};
class nullPathExp : public literalExp {
public:
nullPathExp(position pos)
: literalExp(pos) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primPath(); }
};
class nullExp : public literalExp {
public:
nullExp(position pos)
: literalExp(pos) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primNull(); }
};
class quoteExp : public exp {
runnable *value;
public:
quoteExp(position pos, runnable *value)
: exp(pos), value(value) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primCode(); }
};
// A list of expressions used in a function call.
class explist : public absyn {
typedef mem::vector<exp *> expvector;
expvector exps;
public:
explist(position pos)
: absyn(pos) {}
virtual ~explist() {}
virtual void add(exp *e) {
exps.push_back(e);
}
virtual void prettyprint(ostream &out, Int indent);
virtual size_t size() {
return exps.size();
}
virtual exp * operator[] (size_t index) {
return exps[index];
}
};
struct argument {
exp *val;
symbol name;
// No constructor due to the union in camp.y
#if 0
argument(exp *val=0, symbol name=0)
: val(val), name(name) {}
#endif
void prettyprint(ostream &out, Int indent);
};
class arglist : public gc {
public:
typedef mem::vector<argument> argvector;
argvector args;
argument rest;
// As the language allows named arguments after rest arguments, store the
// index of the rest argument in order to ensure proper left-to-right
// execution.
static const size_t DUMMY_REST_POSITION = 9999;
size_t restPosition;
arglist()
: args(), rest(), restPosition(DUMMY_REST_POSITION) {}
virtual ~arglist() {}
virtual void addFront(argument a) {
args.insert(args.begin(), a);
}
virtual void addFront(exp *val, symbol name=symbol::nullsym) {
argument a; a.val=val; a.name=name;
addFront(a);
}
virtual void add(argument a) {
if (rest.val && !a.name) {
em.error(a.val->getPos());
em << "unnamed argument after rest argument";
return;
}
args.push_back(a);
}
virtual void add(exp *val, symbol name=symbol::nullsym) {
argument a; a.val=val; a.name=name;
add(a);
}
virtual void addRest(argument a) {
if (rest.val) {
em.error(a.val->getPos());
em << "additional rest argument";
return;
}
rest = a;
assert(restPosition == DUMMY_REST_POSITION);
restPosition = size();
}
virtual void prettyprint(ostream &out, Int indent);
virtual size_t size() {
return args.size();
}
virtual argument& operator[] (size_t index) {
return args[index];
}
virtual argument& getRest() {
return rest;
}
};
// callExp has a global cache of resolved overloaded functions. This clears
// this cache so the associated data can be garbage collected.
void clearCachedCalls();
class callExp : public exp {
protected:
exp *callee;
arglist *args;
private:
// Per object caching - Cache the application when it's determined.
application *cachedApp;
// In special cases, no application object is needed and we can store the
// varEntry used in advance.
trans::varEntry *cachedVarEntry;
types::signature *argTypes(coenv& e, bool *searchable);
void reportArgErrors(coenv &e);
application *resolve(coenv &e,
types::overloaded *o,
types::signature *source,
bool tacit);
application *resolveWithCache(coenv &e,
types::overloaded *o,
types::signature *source,
bool tacit);
void reportMismatch(types::function *ft,
types::signature *source);
void reportNonFunction();
// Caches either the application object used to apply the function to the
// arguments, or in cases where the arguments match the function perfectly,
// the varEntry of the callee (or neither in case of an error). Returns
// what getType should return.
types::ty *cacheAppOrVarEntry(coenv &e, bool tacit);
types::ty *transPerfectMatch(coenv &e);
public:
callExp(position pos, exp *callee, arglist *args)
: exp(pos), callee(callee), args(args),
cachedApp(0), cachedVarEntry(0) { assert(args); }
callExp(position pos, exp *callee)
: exp(pos), callee(callee), args(new arglist()),
cachedApp(0), cachedVarEntry(0) {}
callExp(position pos, exp *callee, exp *arg1)
: exp(pos), callee(callee), args(new arglist()),
cachedApp(0), cachedVarEntry(0) {
args->add(arg1);
}
callExp(position pos, exp *callee, exp *arg1, exp *arg2)
: exp(pos), callee(callee), args(new arglist()),
cachedApp(0), cachedVarEntry(0) {
args->add(arg1);
args->add(arg2);
}
callExp(position pos, exp *callee, exp *arg1, exp *arg2, exp *arg3)
: exp(pos), callee(callee), args(new arglist()),
cachedApp(0), cachedVarEntry(0) {
args->add(arg1);
args->add(arg2);
args->add(arg3);
}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
// Returns true if the function call resolves uniquely without error. Used
// in implementing the special == and != operators for functions.
virtual bool resolved(coenv &e);
};
class pairExp : public exp {
exp *x;
exp *y;
public:
pairExp(position pos, exp *x, exp *y)
: exp(pos), x(x), y(y) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primPair(); }
};
class tripleExp : public exp {
exp *x;
exp *y;
exp *z;
public:
tripleExp(position pos, exp *x, exp *y, exp *z)
: exp(pos), x(x), y(y), z(z) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primTriple(); }
};
class transformExp : public exp {
exp *x;
exp *y;
exp *xx,*xy,*yx,*yy;
public:
transformExp(position pos, exp *x, exp *y, exp *xx, exp *xy, exp *yx,
exp *yy)
: exp(pos), x(x), y(y), xx(xx), xy(xy), yx(yx), yy(yy) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &) { return types::primTransform(); }
};
class castExp : public exp {
ty *target;
exp *castee;
types::ty *tryCast(coenv &e, types::ty *t, types::ty *s,
symbol csym);
public:
castExp(position pos, ty *target, exp *castee)
: exp(pos), target(target), castee(castee) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
};
class nullaryExp : public callExp {
public:
nullaryExp(position pos, symbol op)
: callExp(pos, new nameExp(pos, op)) {}
};
class unaryExp : public callExp {
public:
unaryExp(position pos, exp *base, symbol op)
: callExp(pos, new nameExp(pos, op), base) {}
};
class binaryExp : public callExp {
public:
binaryExp(position pos, exp *left, symbol op, exp *right)
: callExp(pos, new nameExp(pos, op), left, right) {}
};
class equalityExp : public callExp {
public:
equalityExp(position pos, exp *left, symbol op, exp *right)
: callExp(pos, new nameExp(pos, op), left, right) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
};
// Scaling expressions such as 3sin(x).
class scaleExp : public binaryExp {
exp *getLeft() {
return (*this->args)[0].val;
}
exp *getRight() {
return (*this->args)[1].val;
}
public:
scaleExp(position pos, exp *left, exp *right)
: binaryExp(pos, left, symbol::trans("*"), right) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
//types::ty *getType(coenv &e);
bool scalable() { return false; }
};
// Used for tension, which takes two real values, and a boolean to denote if it
// is a tension atleast case.
class ternaryExp : public callExp {
public:
ternaryExp(position pos, exp *left, symbol op, exp *right, exp *last)
: callExp(pos, new nameExp(pos, op), left, right, last) {}
};
// The a ? b : c ternary operator.
class conditionalExp : public exp {
exp *test;
exp *onTrue;
exp *onFalse;
public:
conditionalExp(position pos, exp *test, exp *onTrue, exp *onFalse)
: exp(pos), test(test), onTrue(onTrue), onFalse(onFalse) {}
void prettyprint(ostream &out, Int indent);
void baseTransToType(coenv &e, types::ty *target);
void transToType(coenv &e, types::ty *target);
types::ty *trans(coenv &e);
types::ty *getType(coenv &e);
};
class andOrExp : public exp {
protected:
exp *left;
symbol op;
exp *right;
public:
andOrExp(position pos, exp *left, symbol op, exp *right)
: exp(pos), left(left), op(op), right(right) {}
virtual types::ty *trans(coenv &e) = 0;
virtual types::ty *getType(coenv &) {
return types::primBoolean();
}
};
class orExp : public andOrExp {
public:
orExp(position pos, exp *left, symbol op, exp *right)
: andOrExp(pos, left, op, right) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
void transConditionalJump(coenv &e, bool cond, label dest);
};
class andExp : public andOrExp {
public:
andExp(position pos, exp *left, symbol op, exp *right)
: andOrExp(pos, left, op, right) {}
void prettyprint(ostream &out, Int indent);
types::ty *trans(coenv &e);
void transConditionalJump(coenv &e, bool cond, label dest);
};
class joinExp : public callExp {
public:
joinExp(position pos, symbol op)
: callExp(pos, new nameExp(pos, op)) {}
void pushFront(exp *e) {
args->addFront(e);
}
void pushBack(exp *e) {
args->add(e);
}
void prettyprint(ostream &out, Int indent);
};