// Part of the Carbon Language project, under the Apache License v2.0 with LLVM // Exceptions. See /LICENSE for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception #include "executable_semantics/interpreter/value.h" #include #include #include "executable_semantics/interpreter/interpreter.h" namespace Carbon { auto FindInVarValues(const std::string& field, VarValues* inits) -> const Value* { for (auto& i : *inits) { if (i.first == field) { return i.second; } } return nullptr; } auto FieldsEqual(VarValues* ts1, VarValues* ts2) -> bool { if (ts1->size() == ts2->size()) { for (auto& iter1 : *ts1) { auto t2 = FindInVarValues(iter1.first, ts2); if (t2 == nullptr) { return false; } if (!TypeEqual(iter1.second, t2)) { return false; } } return true; } else { return false; } } auto FindTupleField(const std::string& name, const Value* tuple) -> std::optional

{ assert(tuple->tag == ValKind::TupleV); for (const auto& i : *tuple->u.tuple.elts) { if (i.first == name) { return i.second; } } return std::nullopt; } auto MakeIntVal(int i) -> const Value* { auto* v = new Value(); v->tag = ValKind::IntV; v->u.integer = i; return v; } auto MakeBoolVal(bool b) -> const Value* { auto* v = new Value(); v->tag = ValKind::BoolV; v->u.boolean = b; return v; } auto MakeFunVal(std::string name, const Value* param, const Statement* body) -> const Value* { auto* v = new Value(); v->tag = ValKind::FunV; v->u.fun.name = new std::string(std::move(name)); v->u.fun.param = param; v->u.fun.body = body; return v; } auto MakePtrVal(Address addr) -> const Value* { auto* v = new Value(); v->tag = ValKind::PtrV; v->u.ptr = addr; return v; } auto MakeStructVal(const Value* type, const Value* inits) -> const Value* { auto* v = new Value(); v->tag = ValKind::StructV; v->u.struct_val.type = type; v->u.struct_val.inits = inits; return v; } auto MakeTupleVal(std::vector>* elts) -> const Value* { auto* v = new Value(); v->tag = ValKind::TupleV; v->u.tuple.elts = elts; return v; } auto MakeAltVal(std::string alt_name, std::string choice_name, Address argument) -> const Value* { auto* v = new Value(); v->tag = ValKind::AltV; v->u.alt.alt_name = new std::string(std::move(alt_name)); v->u.alt.choice_name = new std::string(std::move(choice_name)); v->u.alt.argument = argument; return v; } auto MakeAltCons(std::string alt_name, std::string choice_name) -> const Value* { auto* v = new Value(); v->tag = ValKind::AltConsV; v->u.alt.alt_name = new std::string(std::move(alt_name)); v->u.alt.choice_name = new std::string(std::move(choice_name)); return v; } // Return a first-class continuation represented a fragment // of the stack. auto MakeContinuation(std::vector stack) -> Value* { auto* v = new Value(); v->tag = ValKind::ContinuationV; v->u.continuation.stack = new std::vector(stack); return v; } auto MakeVarPatVal(std::string name, const Value* type) -> const Value* { auto* v = new Value(); v->tag = ValKind::VarPatV; v->u.var_pat.name = new std::string(std::move(name)); v->u.var_pat.type = type; return v; } auto MakeVarTypeVal(std::string name) -> const Value* { auto* v = new Value(); v->tag = ValKind::VarTV; v->u.var_type = new std::string(std::move(name)); return v; } auto MakeIntTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::IntTV; return v; } auto MakeBoolTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::BoolTV; return v; } auto MakeTypeTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::TypeTV; return v; } // Return a Continuation type. auto MakeContinuationTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::ContinuationTV; return v; } auto MakeAutoTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::AutoTV; return v; } auto MakeFunTypeVal(const Value* param, const Value* ret) -> const Value* { auto* v = new Value(); v->tag = ValKind::FunctionTV; v->u.fun_type.param = param; v->u.fun_type.ret = ret; return v; } auto MakePtrTypeVal(const Value* type) -> const Value* { auto* v = new Value(); v->tag = ValKind::PointerTV; v->u.ptr_type.type = type; return v; } auto MakeStructTypeVal(std::string name, VarValues* fields, VarValues* methods) -> const Value* { auto* v = new Value(); v->tag = ValKind::StructTV; v->u.struct_type.name = new std::string(std::move(name)); v->u.struct_type.fields = fields; v->u.struct_type.methods = methods; return v; } auto MakeVoidTypeVal() -> const Value* { auto* v = new Value(); v->tag = ValKind::TupleV; v->u.tuple.elts = new std::vector>(); return v; } auto MakeChoiceTypeVal(std::string name, std::list>* alts) -> const Value* { auto* v = new Value(); v->tag = ValKind::ChoiceTV; // Transitional leak: when we get rid of all pointers, this will disappear. v->u.choice_type.name = new std::string(name); v->u.choice_type.alternatives = alts; return v; } void PrintValue(const Value* val, std::ostream& out) { switch (val->tag) { case ValKind::AltConsV: { out << *val->u.alt_cons.choice_name << "." << *val->u.alt_cons.alt_name; break; } case ValKind::VarPatV: { PrintValue(val->u.var_pat.type, out); out << ": " << *val->u.var_pat.name; break; } case ValKind::AltV: { out << "alt " << *val->u.alt.choice_name << "." << *val->u.alt.alt_name << " "; PrintValue(state->heap[val->u.alt.argument], out); break; } case ValKind::StructV: { out << *val->u.struct_val.type->u.struct_type.name; PrintValue(val->u.struct_val.inits, out); break; } case ValKind::TupleV: { out << "("; bool add_commas = false; for (const auto& elt : *val->u.tuple.elts) { if (add_commas) { out << ", "; } else { add_commas = true; } out << elt.first << " = "; PrintValue(state->heap[elt.second], out); out << "@" << elt.second; } out << ")"; break; } case ValKind::IntV: out << val->u.integer; break; case ValKind::BoolV: out << std::boolalpha << val->u.boolean; break; case ValKind::FunV: out << "fun<" << *val->u.fun.name << ">"; break; case ValKind::PtrV: out << "ptr<" << val->u.ptr << ">"; break; case ValKind::BoolTV: out << "Bool"; break; case ValKind::IntTV: out << "Int"; break; case ValKind::TypeTV: out << "Type"; break; case ValKind::AutoTV: out << "auto"; break; case ValKind::ContinuationTV: out << "Continuation"; break; case ValKind::PointerTV: out << "Ptr("; PrintValue(val->u.ptr_type.type, out); out << ")"; break; case ValKind::FunctionTV: out << "fn "; PrintValue(val->u.fun_type.param, out); out << " -> "; PrintValue(val->u.fun_type.ret, out); break; case ValKind::VarTV: out << *val->u.var_type; break; case ValKind::StructTV: out << "struct " << *val->u.struct_type.name; break; case ValKind::ChoiceTV: out << "choice " << *val->u.choice_type.name; break; case ValKind::ContinuationV: out << "continuation[["; for (Frame* frame : *val->u.continuation.stack) { PrintFrame(frame, out); out << " :: "; } out << "]]"; break; } } auto TypeEqual(const Value* t1, const Value* t2) -> bool { if (t1->tag != t2->tag) { return false; } switch (t1->tag) { case ValKind::VarTV: return *t1->u.var_type == *t2->u.var_type; case ValKind::PointerTV: return TypeEqual(t1->u.ptr_type.type, t2->u.ptr_type.type); case ValKind::FunctionTV: return TypeEqual(t1->u.fun_type.param, t2->u.fun_type.param) && TypeEqual(t1->u.fun_type.ret, t2->u.fun_type.ret); case ValKind::StructTV: return *t1->u.struct_type.name == *t2->u.struct_type.name; case ValKind::ChoiceTV: return *t1->u.choice_type.name == *t2->u.choice_type.name; case ValKind::TupleV: { if (t1->u.tuple.elts->size() != t2->u.tuple.elts->size()) { return false; } for (size_t i = 0; i < t1->u.tuple.elts->size(); ++i) { std::optional

t2_field = FindTupleField((*t1->u.tuple.elts)[i].first, t2); if (t2_field == std::nullopt) { return false; } if (!TypeEqual(state->heap[(*t1->u.tuple.elts)[i].second], state->heap[*t2_field])) { return false; } } return true; } case ValKind::IntTV: case ValKind::BoolTV: case ValKind::ContinuationTV: return true; default: std::cerr << "TypeEqual used to compare non-type values" << std::endl; exit(-1); } } auto ValueEqual(const Value* v1, const Value* v2, int line_num) -> bool { if (v1->tag != v2->tag) { return false; } switch (v1->tag) { case ValKind::IntV: return v1->u.integer == v2->u.integer; case ValKind::BoolV: return v1->u.boolean == v2->u.boolean; case ValKind::PtrV: CheckAlive(v1->u.ptr, line_num); CheckAlive(v2->u.ptr, line_num); return v1->u.ptr == v2->u.ptr; case ValKind::FunV: return v1->u.fun.body == v2->u.fun.body; case ValKind::VarTV: case ValKind::IntTV: case ValKind::BoolTV: case ValKind::TypeTV: case ValKind::FunctionTV: case ValKind::PointerTV: case ValKind::AutoTV: case ValKind::StructTV: case ValKind::ChoiceTV: case ValKind::ContinuationTV: return TypeEqual(v1, v2); case ValKind::TupleV: case ValKind::StructV: case ValKind::AltV: case ValKind::VarPatV: case ValKind::AltConsV: case ValKind::ContinuationV: std::cerr << "ValueEqual does not support this kind of value." << std::endl; exit(-1); } } auto ToInteger(const Value* v) -> int { switch (v->tag) { case ValKind::IntV: return v->u.integer; default: std::cerr << "expected an integer, not "; PrintValue(v, std::cerr); exit(-1); } } void CheckAlive(Address address, int line_num) { if (!state->alive[address]) { std::cerr << line_num << ": undefined behavior: access to dead value "; PrintValue(state->heap[address], std::cerr); std::cerr << std::endl; exit(-1); } } } // namespace Carbon