/***** * exp.cc * 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. *****/ #include "exp.h" #include "errormsg.h" #include "runtime.h" #include "runmath.h" #include "runpicture.h" #include "runarray.h" #include "runpair.h" #include "runtriple.h" #include "runpath.h" #include "coenv.h" #include "application.h" #include "dec.h" #include "stm.h" #include "inst.h" #include "opsymbols.h" #include "process.h" //void runCode(absyntax::block *code); namespace absyntax { using namespace types; using namespace trans; using vm::inst; using mem::vector; using mem::stdString; using vm::getPos; #if 0 void exp::prettyprint(ostream &out, Int indent) { prettyname(out, "exp",indent, getPos()); } #endif void exp::transAsType(coenv &e, types::ty *target) { trans(e); // types::ty *t=trans(e); // assert(t->kind==ty_error || equivalent(t,target)); } void exp::transToType(coenv &e, types::ty *target) { types::ty *ct=cgetType(e); if (equivalent(target, ct)) { transAsType(e, target); return; } // See if the cast can be handled by the fastLookupCast method, which does // less memory allocation. if (ct->kind != ty_overloaded && ct->kind != ty_error && target->kind != ty_error) { access *a = e.e.fastLookupCast(target, ct); if (a) { transAsType(e, ct); a->encode(trans::CALL, getPos(), e.c); return; } } types::ty *source = e.e.castSource(target, ct, symbol::castsym); if (source==0) { if (target->kind != ty_error) { types::ty *sources=cgetType(e); em.error(getPos()); em << "cannot cast "; if (sources->kind==ty_overloaded) em << "expression"; else em << "'" << *sources << "'"; em << " to '" << *target << "'"; } } else if (source->kind==ty_overloaded) { if (target->kind != ty_error) { em.error(getPos()); em << "expression is ambiguous in cast to '" << *target << "'"; } } else { transAsType(e, source); e.implicitCast(getPos(), target, source); } } void exp::testCachedType(coenv &e) { if (ct != 0) { types::ty *t = getType(e); if (!equivalent(t, ct)) { em.compiler(getPos()); em << "cached type '" << *ct << "' doesn't match actual type '" << *t << "'"; em.sync(); } } } void exp::transCall(coenv &e, types::ty *target) { transAsType(e, target); e.c.encode(inst::popcall); } void exp::transConditionalJump(coenv &e, bool cond, label dest) { transToType(e, primBoolean()); e.c.useLabel(cond ? inst::cjmp : inst::njmp, dest); } exp *exp::evaluate(coenv &e, types::ty *target) { return new tempExp(e, this, target); } tempExp::tempExp(coenv &e, varinit *v, types::ty *t) : exp(v->getPos()), a(e.c.allocLocal()), t(t) { v->transToType(e, t); a->encode(WRITE, getPos(), e.c); e.c.encodePop(); } void tempExp::prettyprint(ostream &out, Int indent) { prettyname(out, "tempExp", indent, getPos()); } types::ty *tempExp::trans(coenv &e) { a->encode(READ, getPos(), e.c); return t; } varEntryExp::varEntryExp(position pos, types::ty *t, access *a) : exp(pos), v(new trans::varEntry(t, a, 0, position())) {} varEntryExp::varEntryExp(position pos, types::ty *t, vm::bltin f) : exp(pos), v(new trans::varEntry(t, new bltinAccess(f), 0, position())) {} void varEntryExp::prettyprint(ostream &out, Int indent) { prettyname(out, "varEntryExp", indent, getPos()); } types::ty *varEntryExp::getType(coenv &) { return v->getType(); } types::ty *varEntryExp::trans(coenv &e) { v->encode(READ, getPos(), e.c); return getType(e); } trans::varEntry *varEntryExp::getCallee(coenv &e, types::signature *sig) { return equivalent(sig, v->getType()->getSignature()) ? v : 0; } void varEntryExp::transAct(action act, coenv &e, types::ty *target) { assert(equivalent(getType(e),target)); v->encode(act, getPos(), e.c); } void varEntryExp::transAsType(coenv &e, types::ty *target) { transAct(READ, e, target); } void varEntryExp::transWrite(coenv &e, types::ty *target, exp *value) { value->transToType(e, target); transAct(WRITE, e, target); } void varEntryExp::transCall(coenv &e, types::ty *target) { transAct(trans::CALL, e, target); } void nameExp::prettyprint(ostream &out, Int indent) { prettyname(out, "nameExp",indent, getPos()); value->prettyprint(out, indent+1); } void nameExp::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP AsymptoteLsp::SymbolLit accessedName(value->getLit()); position basePos = getPos(); AsymptoteLsp::filePos castedPos = dynamic_cast(value) ? std::make_pair(stdString(basePos.filename()), std::make_pair(basePos.Line(), basePos.Column() + 1)) : static_cast(basePos); auto varUsageIt = symContext->symMap.varUsage.find(accessedName); if (varUsageIt == symContext->symMap.varUsage.end()) { symContext->symMap.varUsage.emplace(accessedName, castedPos); } else { varUsageIt->second.add(castedPos); } symContext->symMap.usageByLines.emplace_back(castedPos.second, accessedName); #endif } void fieldExp::pseudoName::prettyprint(ostream &out, Int indent) { // This should never be called. prettyindent(out, indent); out << "pseudoName" << "\n"; object->prettyprint(out, indent+1); } void fieldExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "fieldExp '" << field << "'\n"; object->prettyprint(out, indent+1); } types::ty *fieldExp::getObject(coenv& e) { types::ty *t = object->cgetType(e); if (t->kind == ty_overloaded) { t=((overloaded *)t)->signatureless(); if(!t) return primError(); } return t; } array *arrayExp::getArrayType(coenv &e) { types::ty *a = set->cgetType(e); if (a->kind == ty_overloaded) { a = ((overloaded *)a)->signatureless(); if (!a) return 0; } switch (a->kind) { case ty_array: return (array *)a; case ty_error: return 0; default: return 0; } } array *arrayExp::transArray(coenv &e) { types::ty *a = set->cgetType(e); if (a->kind == ty_overloaded) { a = ((overloaded *)a)->signatureless(); if (!a) { em.error(set->getPos()); em << "expression is not an array"; return 0; } } set->transAsType(e, a); switch (a->kind) { case ty_array: return (array *)a; case ty_error: return 0; default: em.error(set->getPos()); em << "expression is not an array"; return 0; } } // Checks if the expression can be translated as an array. bool isAnArray(coenv &e, exp *x) { types::ty *t=x->cgetType(e); if (t->kind == ty_overloaded) t=dynamic_cast(t)->signatureless(); return t && t->kind==ty_array; } void subscriptExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "subscriptExp\n"; set->prettyprint(out, indent+1); index->prettyprint(out, indent+1); } types::ty *subscriptExp::trans(coenv &e) { array *a = transArray(e); if (!a) return primError(); if (isAnArray(e, index)) { index->transToType(e, types::IntArray()); e.c.encode(inst::builtin, run::arrayIntArray); return getArrayType(e); } else { index->transToType(e, types::primInt()); e.c.encode(inst::builtin, a->celltype->kind==ty_array ? run::arrayArrayRead : run::arrayRead); return a->celltype; } } types::ty *subscriptExp::getType(coenv &e) { array *a = getArrayType(e); return a ? (isAnArray(e, index) ? a : a->celltype) : primError(); } void subscriptExp::transWrite(coenv &e, types::ty *t, exp *value) { // Put array, index, and value on the stack in that order, then call // arrayWrite. array *a = transArray(e); if (!a) return; if (!equivalent(a->celltype, t)) { em.error(getPos()); em << "array expression cannot be used as an address"; // Translate the value for errors. value->transToType(e, t); return; } index->transToType(e, types::primInt()); value->transToType(e, t); e.c.encode(inst::builtin, run::arrayWrite); } void slice::prettyprint(ostream &out, Int indent) { prettyname(out, "slice", indent, getPos()); if (left) left->prettyprint(out, indent+1); else prettyname(out, "left omitted", indent+1, getPos()); if (right) right->prettyprint(out, indent+1); else prettyname(out, "right omitted", indent+1, getPos()); } void slice::trans(coenv &e) { if (left) left->transToType(e, types::primInt()); else // If the left index is omitted it can be assumed to be zero. e.c.encode(inst::intpush, (Int)0); if (right) right->transToType(e, types::primInt()); } void sliceExp::prettyprint(ostream &out, Int indent) { prettyname(out, "sliceExp", indent, getPos()); set->prettyprint(out, indent+1); index->prettyprint(out, indent+1); } types::ty *sliceExp::trans(coenv &e) { array *a = transArray(e); if (!a) return primError(); index->trans(e); e.c.encode(inst::builtin, index->getRight() ? run::arraySliceRead : run::arraySliceReadToEnd); return a; } types::ty *sliceExp::getType(coenv &e) { array *a = getArrayType(e); return a ? a : primError(); } void sliceExp::transWrite(coenv &e, types::ty *t, exp *value) { array *a = transArray(e); if (!a) return; assert(equivalent(a, t)); index->trans(e); value->transToType(e, t); e.c.encode(inst::builtin, index->getRight() ? run::arraySliceWrite : run::arraySliceWriteToEnd); } void thisExp::prettyprint(ostream &out, Int indent) { prettyname(out, "thisExp", indent, getPos()); } types::ty *thisExp::trans(coenv &e) { if (!e.c.encodeThis()) { em.error(getPos()); em << "static use of 'this' expression"; } return cgetType(e); } types::ty *thisExp::getType(coenv &e) { return e.c.thisType(); } void equalityExp::prettyprint(ostream &out, Int indent) { prettyname(out, "equalityExp", indent, getPos()); callExp::prettyprint(out, indent+1); } types::ty *equalityExp::getType(coenv &e) { // Try to the resolve the expression as a function call first. types::ty *t = callExp::getType(e); assert(t); if (t->kind != ty_error) return t; else // Either an error or handled by the function equality methods. In the // first case, we may return whatever we like, and the second case always // returns bool. In either case, it is safe to return bool. return primBoolean(); } // From a possibly overloaded type, if there is a unique function type, return // it, otherwise 0. types::ty *uniqueFunction(types::ty *t) { if (t->kind == types::ty_function) return t; if (t->isOverloaded()) { types::ty *ft = 0; for (ty_iterator i = t->begin(); i != t->end(); ++i) { if ((*i)->kind != types::ty_function) continue; if (ft) { // Multiple function types. return 0; } ft = *i; } return ft; } // Not a function. return 0; } // From two possibly overloaded types, if there is a unique function type // common to both, return it, otherwise 0. types::ty *uniqueFunction(types::ty *t1, types::ty *t2) { if (t1->kind == types::ty_function) return equivalent(t1, t2) ? t1 : 0; if (t1->isOverloaded()) { types::ty *ft = 0; for (ty_iterator i = t1->begin(); i != t1->end(); ++i) { if ((*i)->kind != types::ty_function) continue; if (!equivalent(*i, t2)) continue; if (ft) { // Multiple function types. return 0; } ft = *i; } return ft; } // Not a function. return 0; } bltin bltinFromName(symbol name) { if (name == SYM_EQ) return run::boolFuncEq; assert(name == SYM_NEQ); return run::boolFuncNeq; } types::ty *equalityExp::trans(coenv &e) { // First, try to handle by normal function resolution. types::ty *t = callExp::getType(e); assert(t); if (t->kind != ty_error) return callExp::trans(e); // Then, check for the function equality case. exp *left = (*this->args)[0].val; exp *right = (*this->args)[1].val; types::ty *lt = left->getType(e); types::ty *rt = right->getType(e); // TODO: decide what null == null should do. // Check for function == null and null == function types::ty *ft = 0; if (rt->kind == types::ty_null) ft = uniqueFunction(lt); else if (lt->kind == types::ty_null) ft = uniqueFunction(rt); else ft = uniqueFunction(lt, rt); if (ft) { assert(ft->kind == ty_function); left->transToType(e, ft); right->transToType(e, ft); e.c.encode(inst::builtin, bltinFromName(callee->getName())); return primBoolean(); } else { // Let callExp report a "no such function" error. types::ty *t = callExp::trans(e); assert(t->kind == ty_error); return t; } } void scaleExp::prettyprint(ostream &out, Int indent) { exp *left=getLeft(); exp *right=getRight(); prettyname(out, "scaleExp",indent, getPos()); left->prettyprint(out, indent+1); right->prettyprint(out, indent+1); } types::ty *scaleExp::trans(coenv &e) { exp *left=getLeft(); exp *right=getRight(); types::ty *lt = left->cgetType(e); if (lt->kind != types::ty_Int && lt->kind != types::ty_real) { if (lt->kind != types::ty_error) { em.error(left->getPos()); em << "only numeric constants can do implicit scaling"; } right->trans(e); return types::primError(); } if (!right->scalable()) { em.warning(right->getPos()); em << "implicit scaling may be unintentional"; } // Defer to the binaryExp for multiplication. return binaryExp::trans(e); } void intExp::prettyprint(ostream &out, Int indent) { prettyindent(out,indent); out << "intExp: " << value << "\n"; } types::ty *intExp::trans(coenv &e) { e.c.encode(inst::intpush,value); return types::primInt(); } void realExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "realExp: " << value << "\n"; } types::ty *realExp::trans(coenv &e) { e.c.encode(inst::constpush,(item)value); return types::primReal(); } void stringExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "stringExp '" << str << "'\n"; } types::ty *stringExp::trans(coenv &e) { e.c.encode(inst::constpush,(item) string(str)); return types::primString(); } void booleanExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "booleanExp: " << value << "\n"; } types::ty *booleanExp::trans(coenv &e) { e.c.encode(inst::constpush,(item)value); return types::primBoolean(); } void newPictureExp::prettyprint(ostream &out, Int indent) { prettyname(out, "newPictureExp",indent, getPos()); } types::ty *newPictureExp::trans(coenv &e) { e.c.encode(inst::builtin, run::newPicture); return types::primPicture(); } void cycleExp::prettyprint(ostream &out, Int indent) { prettyname(out, "cycleExp",indent, getPos()); } types::ty *cycleExp::trans(coenv &e) { e.c.encode(inst::builtin, run::newCycleToken); return types::primCycleToken(); } void nullPathExp::prettyprint(ostream &out, Int indent) { prettyname(out, "nullPathExp",indent, getPos()); } types::ty *nullPathExp::trans(coenv &e) { e.c.encode(inst::builtin, run::nullPath); return types::primPath(); } void nullExp::prettyprint(ostream &out, Int indent) { prettyname(out, "nullExp",indent, getPos()); } types::ty *nullExp::trans(coenv &) { // Things get put on the stack when ty_null // is cast to an appropriate type return types::primNull(); } void quoteExp::prettyprint(ostream &out, Int indent) { prettyname(out, "quoteExp", indent, getPos()); value->prettyprint(out, indent+1); } types::ty *quoteExp::trans(coenv &e) { e.c.encode(inst::constpush,(item)value); return types::primCode(); } void explist::prettyprint(ostream &out, Int indent) { prettyname(out, "explist",indent, getPos()); for (expvector::iterator p = exps.begin(); p != exps.end(); ++p) (*p)->prettyprint(out, indent+1); } void argument::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "explist"; if (name) out << " '" << name << "'"; out << '\n'; val->prettyprint(out, indent+1); } void argument::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP val->createSymMap(symContext); #endif } void arglist::prettyprint(ostream &out, Int indent) { prettyname(out, "arglist",indent, getPos()); for (argvector::iterator p = args.begin(); p != args.end(); ++p) p->prettyprint(out, indent+1); } void arglist::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP for (auto& p: args) { p.createSymMap(symContext); } #endif } void callExp::prettyprint(ostream &out, Int indent) { prettyname(out, "callExp",indent, getPos()); callee->prettyprint(out, indent+1); args->prettyprint(out, indent+1); } signature *callExp::argTypes(coenv &e, bool *searchable) { signature *source=new signature; // The signature is searchable unless one of the arguments is overloaded or // named. *searchable = true; size_t n = args->size(); for (size_t i = 0; i < n; i++) { if(string(args->args[i].name) == "KEY") { stringExp *s=dynamic_cast(args->args[i].val); if(s) { if(getPos().filename() == processData().fileName) { processDataStruct *P=&processData(); P->xkey[getPos().shift(P->xmapCount).LineColumn()]= Strdup(s->getString()); } args->args.erase(args->args.begin()+i); --n; if(i == n) break; } } argument a=(*args)[i]; types::ty *t = a.val->cgetType(e); if (t->kind == types::ty_error) return 0; if (t->kind == types::ty_overloaded || a.name) *searchable = false; source->add(types::formal(t,a.name)); } if (args->rest.val) { argument a=args->rest; types::ty *t = a.val->cgetType(e); if (t->kind == types::ty_error) return 0; if (t->kind == types::ty_overloaded || a.name) *searchable = false; source->addRest(types::formal(t,a.name)); } return source; } application *callExp::resolve(coenv &e, overloaded *o, signature *source, bool tacit) { app_list l=multimatch(e.e, o, source, *args); if (l.empty()) { //cerr << "l is empty\n"; if (!tacit) { em.error(getPos()); symbol s = callee->getName(); if (s) em << "no matching function \'" << s; else em << "no matching function for signature \'"; em << *source << "\'"; } return 0; } else if (l.size() > 1) { // This may take O(n) time. //cerr << "l is full\n"; if (!tacit) { em.error(getPos()); symbol s = callee->getName(); if(s) em << "call of function \'" << s; else em << "call with signature \'"; em << *source << "\' is ambiguous:\n\n"; for(app_list::iterator p=l.begin(); p != l.end(); ++p) em << *(*p)->getType() << "\n"; } return 0; } else { //cerr << "l is singleton\n"; return l.front(); } } bool hasNamedParameters(signature *sig) { for (size_t i=0; i < sig->getNumFormals(); ++i) if (sig->getFormal(i).name) return true; return false; } void callExp::reportMismatch(function *ft, signature *source) { symbol s = callee->getName(); const char *separator=ft->getSignature()->getNumFormals() > 1 ? "\n" : " "; em.error(getPos()); em << "cannot call" << separator << "'" << *ft->getResult() << " "; if(s) em << s; em << *ft->getSignature() << "'" << separator; if (ft->getSignature()->isOpen && hasNamedParameters(source)) em << "with named parameters"; else switch(source->getNumFormals()) { case 0: em << "without parameters"; break; case 1: em << "with parameter '" << toString(*source) << "'"; break; default: em << "with parameters\n'" << toString(*source) << "'"; } } void callExp::reportArgErrors(coenv &e) { // Cycle through the parameters to report all errors. // NOTE: This may report inappropriate ambiguity errors. for (size_t i = 0; i < args->size(); i++) { (*args)[i].val->trans(e); } if (args->rest.val) args->rest.val->trans(e); } void callExp::reportNonFunction() { em.error(getPos()); symbol s = callee->getName(); if (s) em << "\'" << s << "\' is not a function"; else em << "called expression is not a function"; } types::ty *callExp::cacheAppOrVarEntry(coenv &e, bool tacit) { assert(cachedVarEntry == 0 && cachedApp == 0); // First figure out the signature of what we want to call. bool searchable; signature *source=argTypes(e, &searchable); #ifdef DEBUG_GETAPP /* {{{ */ cout << "getApp for "; if (callee->getName()) cout << *callee->getName(); else cout << "unnamed"; cout << " at " << getPos() << endl; cout << "searchable: " << searchable << endl; #endif /* }}} */ if (!source) { return primError(); } // An attempt at speeding up compilation: See if the source arguments match // the (possibly overloaded) function exactly. if (searchable) { varEntry *ve = callee->getCallee(e, source); #ifdef DEBUG_GETAPP cout << "guessed: " << (ve!=0) << endl; #endif if (ve) { cachedVarEntry = ve; #ifndef DEBUG_CACHE // Normally DEBUG_CACHE is not defined and we return here for efficiency // reasons. If DEBUG_CACHE is defined, we instead proceed to resolve // the function by the normal techniques and make sure we get the same // result. return ((function *)ve->getType())->getResult(); #endif } } // Figure out what function types we can call. types::ty *ft = callee->cgetType(e); #ifdef DEBUG_GETAPP string name = callee->getName() ? string(*callee->getName()) : string("unnamed"); if (!callee->getName()) cout << getPos() << endl; #endif switch (ft->kind) { case ty_error: if (!tacit) // Report callee errors. callee->trans(e); break; case ty_function: //cout << "name " << name << endl; cachedApp = application::match(e.e, (function *)ft, source, *args); if (!cachedApp && !tacit) reportMismatch((function *)ft, source); break; case ty_overloaded: { #ifdef DEBUG_GETAPP int size = ((overloaded *)ft)->sub.size(); for (int i = 0; i < size; ++i) cout << "name " << name << endl; #endif cachedApp = resolve(e, (overloaded *)ft, source, tacit); break; } default: if (!tacit) reportNonFunction(); break; } #ifdef DEBUG_GETAPP cout << name << " " << *source << " --> " << *cachedApp->getType()->getSignature() << endl; #endif #if DEBUG_CACHE // Make sure cachedVarEntry is giving us the right function. if (cachedVarEntry) assert(equivalent(cachedVarEntry->getType(), cachedApp->getType())); #endif // getType relies on this method for the type. return cachedApp ? cachedApp->getType()->getResult() : primError(); } types::ty *callExp::transPerfectMatch(coenv &e) { // The varEntry of the callee. (No longer needed after translation.) varEntry *ve = cachedVarEntry; cachedVarEntry = 0; assert(ve); // Translate the arguments in turn. for (size_t i = 0; i < args->size(); ++i) (*args)[i].val->trans(e); if (args->rest.val) args->rest.val->trans(e); // Call the function. ve->encode(trans::CALL, getPos(), e.c); // That's it. Return the return type of the function. return ct ? ct : dynamic_cast(ve->getType())->getResult(); } types::ty *callExp::trans(coenv &e) { if (cachedVarEntry == 0 && cachedApp == 0) cacheAppOrVarEntry(e, false); if (cachedVarEntry) return transPerfectMatch(e); // The cached data is no longer needed after translation, so let it be // garbage collected. application *a = cachedApp; cachedApp=0; if (!a) { reportArgErrors(e); return primError(); } // To simulate left-to-right order of evaluation, produce the // side-effects for the callee. assert(a); function *t=a->getType(); assert(t); exp *temp=callee->evaluate(e, t); // Let the application handle the argument translation. a->transArgs(e); // Translate the call. temp->transCall(e, t); return t->result; } types::ty *callExp::getType(coenv &e) { if (cachedApp) return cachedApp->getType()->getResult(); if (cachedVarEntry) { function *ft = dynamic_cast(cachedVarEntry->getType()); assert(ft); return ft->getResult(); } return cacheAppOrVarEntry(e, true); } bool callExp::resolved(coenv &e) { if (cachedApp == 0 && cachedVarEntry == 0) cacheAppOrVarEntry(e, true); return cachedApp || cachedVarEntry; } void callExp::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP callee->createSymMap(symContext); args->createSymMap(symContext); if (auto col=getColorInformation()) { auto const& v=col.value(); auto const& colVal=std::get<0>(v); auto const& alpha=std::get<1>(v); auto const& beginArgPos=std::get<2>(v); auto const& lastArgPos=std::get<3>(v); if (alpha.has_value()) { auto const& red=std::get<0>(colVal); auto const& green=std::get<1>(colVal); auto const& blue=std::get<2>(colVal); std::tuple rgba(red, green, blue, alpha.value()); symContext->addRGBAColor(rgba, beginArgPos, lastArgPos); } else { symContext->addRGBColor(colVal, beginArgPos, lastArgPos); } } #endif } optional, AsymptoteLsp::posInFile, AsymptoteLsp::posInFile>> callExp::getColorInformation() { #ifdef HAVE_LSP if (auto* namedCallee = dynamic_cast(callee)) { std::string calleeName = static_cast(namedCallee->getName()); std::vector colors; auto getLineColumn = [&argsval = args->args](int const& idx) { return argsval[idx].val->getPos().LineColumn(); }; if (calleeName == "rgb" || calleeName == "rgba") { for (auto const& expVec : args->args) { if (auto* valExp=dynamic_cast(expVec.val)) { colors.push_back(valExp->getValue()); } else if (auto* valExpI=dynamic_cast(expVec.val)) { colors.push_back(valExpI->getValue()); } } } if (calleeName == "rgb" && colors.size() == 3) { callExp::colorInfo col(colors[0], colors[1], colors[2]); return std::make_tuple(col, optional(), callee->getPos().LineColumn(), getLineColumn(2)); } else if (calleeName == "rgba" && colors.size() == 4) { callExp::colorInfo col(colors[0], colors[1], colors[2]); return std::make_tuple(col, optional(colors[3]), callee->getPos().LineColumn(), getLineColumn(3)); } } #endif return nullopt; } void pairExp::prettyprint(ostream &out, Int indent) { prettyname(out, "pairExp",indent, getPos()); x->prettyprint(out, indent+1); y->prettyprint(out, indent+1); } types::ty *pairExp::trans(coenv &e) { x->transToType(e, types::primReal()); y->transToType(e, types::primReal()); e.c.encode(inst::builtin, run::realRealToPair); return types::primPair(); } void tripleExp::prettyprint(ostream &out, Int indent) { prettyname(out, "tripleExp",indent, getPos()); x->prettyprint(out, indent+1); y->prettyprint(out, indent+1); z->prettyprint(out, indent+1); } types::ty *tripleExp::trans(coenv &e) { x->transToType(e, types::primReal()); y->transToType(e, types::primReal()); z->transToType(e, types::primReal()); e.c.encode(inst::builtin, run::realRealRealToTriple); return types::primTriple(); } void transformExp::prettyprint(ostream &out, Int indent) { prettyname(out, "transformExp",indent, getPos()); x->prettyprint(out, indent+1); y->prettyprint(out, indent+1); xx->prettyprint(out, indent+1); xy->prettyprint(out, indent+1); yx->prettyprint(out, indent+1); yy->prettyprint(out, indent+1); } types::ty *transformExp::trans(coenv &e) { x->transToType(e, types::primReal()); y->transToType(e, types::primReal()); xx->transToType(e, types::primReal()); xy->transToType(e, types::primReal()); yx->transToType(e, types::primReal()); yy->transToType(e, types::primReal()); e.c.encode(inst::builtin, run::real6ToTransform); return types::primTransform(); } void castExp::prettyprint(ostream &out, Int indent) { prettyname(out, "castExp",indent, getPos()); target->prettyprint(out, indent+1); castee->prettyprint(out, indent+1); } types::ty *castExp::tryCast(coenv &e, types::ty *t, types::ty *s, symbol csym) { types::ty *ss=e.e.castSource(t, s, csym); if (ss == 0) { return 0; } if (ss->kind == ty_overloaded) { em.error(getPos()); em << "cast is ambiguous"; return primError(); } else { castee->transAsType(e, ss); access *a=e.e.lookupCast(t, ss, csym); assert(a); a->encode(trans::CALL, getPos(), e.c); return ss; } } types::ty *castExp::trans(coenv &e) { target->addOps(e, (record *)0); types::ty *t=target->trans(e); types::ty *s=castee->cgetType(e); if (!tryCast(e, t, s, symbol::ecastsym)) if (!tryCast(e, t, s, symbol::castsym)) { em.error(getPos()); em << "cannot cast '" << *s << "' to '" << *t << "'"; } return t; } types::ty *castExp::getType(coenv &e) { return target->trans(e, true); } void castExp::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP castee->createSymMap(symContext); #endif } void conditionalExp::prettyprint(ostream &out, Int indent) { prettyname(out, "conditionalExp",indent, getPos()); test->prettyprint(out, indent+1); onTrue->prettyprint(out, indent+1); onFalse->prettyprint(out, indent+1); } void conditionalExp::baseTransToType(coenv &e, types::ty *target) { test->transToType(e, types::primBoolean()); label tlabel = e.c.fwdLabel(); e.c.useLabel(inst::cjmp,tlabel); onFalse->transToType(e, target); label end = e.c.fwdLabel(); e.c.useLabel(inst::jmp,end); e.c.defLabel(tlabel); onTrue->transToType(e, target); e.c.defLabel(end); } void conditionalExp::transToType(coenv &e, types::ty *target) { if (isAnArray(e, test)) { if (target->kind != ty_array) { em.error(getPos()); em << "cannot cast vectorized conditional to '" << *target << "'"; } test->transToType(e, types::booleanArray()); onTrue->transToType(e, target); onFalse->transToType(e, target); e.c.encode(inst::builtin, run::arrayConditional); } else { baseTransToType(e, target); } } types::ty *promote(coenv &e, types::ty *x, types::ty *y) { struct promoter : public collector { env &e; promoter(env &e) : e(e) {} types::ty *both (types::ty *x, types::ty *y) { overloaded *o=new overloaded; o->add(x); o->add(y); return o; } types::ty *base (types::ty *x, types::ty *y) { if (equivalent(x,y)) return x; else { bool castToFirst=e.castable(x, y, symbol::castsym); bool castToSecond=e.castable(y, x, symbol::castsym); return (castToFirst && castToSecond) ? both(x,y) : castToFirst ? x : castToSecond ? y : 0; } } }; promoter p(e.e); return p.collect(x,y); } types::ty *conditionalExp::trans(coenv &e) { types::ty *tt=onTrue->cgetType(e); types::ty *ft=onFalse->cgetType(e); if (tt->kind==ty_error) return onTrue->trans(e); if (ft->kind==ty_error) return onFalse->trans(e); types::ty *t=promote(e, tt, ft); if (!t) { em.error(getPos()); em << "types in conditional expression do not match"; return primError(); } else if (t->kind == ty_overloaded) { em.error(getPos()); em << "type of conditional expression is ambiguous"; return primError(); } transToType(e,t); return t; } types::ty *conditionalExp::getType(coenv &e) { types::ty *tt=onTrue->cgetType(e); types::ty *ft=onFalse->cgetType(e); if (tt->kind==ty_error || ft->kind==ty_error) return primError(); types::ty *t = promote(e, tt, ft); return t ? t : primError(); } void orExp::prettyprint(ostream &out, Int indent) { prettyname(out, "orExp", indent, getPos()); left->prettyprint(out, indent+1); right->prettyprint(out, indent+1); } types::ty *orExp::trans(coenv &e) { // a || b // translates into // a ? true : b booleanExp be(pos, true); conditionalExp ce(pos, left, &be, right); ce.baseTransToType(e, primBoolean()); return getType(e); } void orExp::transConditionalJump(coenv &e, bool cond, label dest) { if (cond == true) { left->transConditionalJump(e, true, dest); right->transConditionalJump(e, true, dest); } else { /* cond == false */ label end = e.c.fwdLabel(); left->transConditionalJump(e, true, end); right->transConditionalJump(e, false, dest); e.c.defLabel(end); } } void andExp::prettyprint(ostream &out, Int indent) { prettyname(out, "andExp", indent, getPos()); left->prettyprint(out, indent+1); right->prettyprint(out, indent+1); } types::ty *andExp::trans(coenv &e) { // a && b // translates into // a ? b : false booleanExp be(pos, false); conditionalExp ce(pos, left, right, &be); ce.baseTransToType(e, primBoolean()); return getType(e); } void andExp::transConditionalJump(coenv &e, bool cond, label dest) { if (cond == true) { label end = e.c.fwdLabel(); left->transConditionalJump(e, false, end); right->transConditionalJump(e, true, dest); e.c.defLabel(end); } else { /* cond == false */ left->transConditionalJump(e, false, dest); right->transConditionalJump(e, false, dest); } } void joinExp::prettyprint(ostream &out, Int indent) { prettyname(out, "joinExp",indent, getPos()); callee->prettyprint(out, indent+1); args->prettyprint(out, indent+1); } void specExp::prettyprint(ostream &out, Int indent) { prettyindent(out,indent); out << "specExp '" << op << "' " << (s==camp::OUT ? "out" : s==camp::IN ? "in" : "invalid side") << '\n'; arg->prettyprint(out, indent+1); } types::ty *specExp::trans(coenv &e) { intExp ie(getPos(), (Int)s); binaryExp be(getPos(), arg, op, &ie); return be.trans(e); } types::ty *specExp::getType(coenv &e) { intExp ie(getPos(), (Int)s); binaryExp be(getPos(), arg, op, &ie); return be.cgetType(e); } void assignExp::prettyprint(ostream &out, Int indent) { prettyname(out, "assignExp",indent, getPos()); dest->prettyprint(out, indent+1); value->prettyprint(out, indent+1); } void assignExp::transAsType(coenv &e, types::ty *target) { #if 0 // For left-to-right order, we have to evaluate the side-effects of the // destination first. exp *temp=dest->evaluate(e, target); ultimateValue(temp)->transToType(e, target); temp->transWrite(e, target); #endif // All of the heavy work is handled by transWrite. dest->transWrite(e, target, value); } types::ty *assignExp::trans(coenv &e) { exp *uvalue=ultimateValue(dest); types::ty *lt = dest->cgetType(e), *rt = uvalue->cgetType(e); if (lt->kind == ty_error) return dest->trans(e); if (rt->kind == ty_error) return uvalue->trans(e); types::ty *t = e.e.castTarget(lt, rt, symbol::castsym); if (!t) { em.error(getPos()); em << "cannot convert '" << *rt << "' to '" << *lt << "' in assignment"; return primError(); } else if (t->kind == ty_overloaded) { em.error(getPos()); em << "assignment is ambiguous"; return primError(); } else { transAsType(e, t); return t; } } types::ty *assignExp::getType(coenv &e) { types::ty *lt = dest->cgetType(e), *rt = ultimateValue(dest)->cgetType(e); if (lt->kind==ty_error || rt->kind==ty_error) return primError(); types::ty *t = e.e.castTarget(lt, rt, symbol::castsym); return t ? t : primError(); } void assignExp::createSymMap(AsymptoteLsp::SymbolContext* symContext) { #ifdef HAVE_LSP dest->createSymMap(symContext); value->createSymMap(symContext); #endif } void selfExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "selfExp '" << op << "'\n"; dest->prettyprint(out, indent+1); value->prettyprint(out, indent+1); } void selfExp::transAsType(coenv &e, types::ty *target) { // Create a temp expression for the destination, so it is not evaluated // twice. exp *temp=dest->evaluate(e, target); temp->transWrite(e, target, ultimateValue(temp)); } void prefixExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "prefixExp '" << op << "'\n"; dest->prettyprint(out, indent+1); } types::ty *prefixExp::trans(coenv &e) { // Convert into the operation and the assign. // NOTE: This can cause multiple evaluations. intExp ie(getPos(), 1); selfExp se(getPos(), dest, op, &ie); return se.trans(e); } types::ty *prefixExp::getType(coenv &e) { // Convert into the operation and the assign. intExp ie(getPos(), 1); selfExp se(getPos(), dest, op, &ie); return se.getType(e); } void postfixExp::prettyprint(ostream &out, Int indent) { prettyindent(out, indent); out << "postfixExp '" << op << "'\n"; dest->prettyprint(out, indent+1); } types::ty *postfixExp::trans(coenv &) { em.error(getPos()); em << "postfix expressions are not allowed"; return primError(); } } // namespace absyntax