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dart / sdk.git / 3512889c4c042beef28017d0972b7bfbe08f831f / . / runtime / vm / parser.cc
blob: b7814db03ba7b36e2e3611db1d274a7903b4b16d [file] [log] [blame]
// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
// for details. All rights reserved. Use of this source code is governed by a
// BSD-style license that can be found in the LICENSE file.
#include "vm/parser.h"
#include "lib/invocation_mirror.h"
#include "vm/bigint_operations.h"
#include "vm/class_finalizer.h"
#include "vm/compiler.h"
#include "vm/compiler_stats.h"
#include "vm/dart_api_impl.h"
#include "vm/dart_entry.h"
#include "vm/flags.h"
#include "vm/growable_array.h"
#include "vm/longjump.h"
#include "vm/native_entry.h"
#include "vm/object.h"
#include "vm/object_store.h"
#include "vm/resolver.h"
#include "vm/scopes.h"
#include "vm/symbols.h"
namespace dart {
DEFINE_FLAG(bool, enable_asserts, false, "Enable assert statements.");
DEFINE_FLAG(bool, enable_type_checks, false, "Enable type checks.");
DEFINE_FLAG(bool, trace_parser, false, "Trace parser operations.");
DEFINE_FLAG(bool, warning_as_error, false, "Treat warnings as errors.");
DEFINE_FLAG(bool, silent_warnings, false, "Silence warnings.");
static void CheckedModeHandler(bool value) {
FLAG_enable_asserts = value;
FLAG_enable_type_checks = value;
}
// --enable-checked-mode and --checked both enable checked mode which is
// equivalent to setting --enable-asserts and --enable-type-checks.
DEFINE_FLAG_HANDLER(CheckedModeHandler,
enable_checked_mode,
"Enable checked mode.");
DEFINE_FLAG_HANDLER(CheckedModeHandler,
checked,
"Enable checked mode.");
#if defined(DEBUG)
class TraceParser : public ValueObject {
public:
TraceParser(intptr_t token_pos, const Script& script, const char* msg) {
if (FLAG_trace_parser) {
// Skips tracing of bootstrap libraries.
if (script.HasSource()) {
intptr_t line, column;
script.GetTokenLocation(token_pos, &line, &column);
PrintIndent();
OS::Print("%s (line %"Pd", col %"Pd", token %"Pd")\n",
msg, line, column, token_pos);
}
indent_++;
}
}
~TraceParser() { indent_--; }
private:
void PrintIndent() {
for (int i = 0; i < indent_; i++) { OS::Print(". "); }
}
static int indent_;
};
int TraceParser::indent_ = 0;
#define TRACE_PARSER(s) \
TraceParser __p__(this->TokenPos(), this->script_, s)
#else // not DEBUG
#define TRACE_PARSER(s)
#endif // DEBUG
static RawTypeArguments* NewTypeArguments(const GrowableObjectArray& objs) {
const TypeArguments& a =
TypeArguments::Handle(TypeArguments::New(objs.Length()));
AbstractType& type = AbstractType::Handle();
for (int i = 0; i < objs.Length(); i++) {
type ^= objs.At(i);
a.SetTypeAt(i, type);
}
// Cannot canonicalize TypeArgument yet as its types may not have been
// finalized yet.
return a.raw();
}
static ThrowNode* GenerateRethrow(intptr_t token_pos, const Object& obj) {
const UnhandledException& excp = UnhandledException::Cast(obj);
Instance& exception = Instance::ZoneHandle(excp.exception());
if (exception.IsNew()) {
exception ^= Object::Clone(exception, Heap::kOld);
}
Instance& stack_trace = Instance::ZoneHandle(excp.stacktrace());
if (stack_trace.IsNew()) {
stack_trace ^= Object::Clone(stack_trace, Heap::kOld);
}
return new ThrowNode(token_pos,
new LiteralNode(token_pos, exception),
new LiteralNode(token_pos, stack_trace));
}
LocalVariable* ParsedFunction::CreateExpressionTempVar(intptr_t token_pos) {
return new LocalVariable(token_pos,
Symbols::ExprTemp(),
Type::ZoneHandle(Type::DynamicType()));
}
LocalVariable* ParsedFunction::CreateArrayLiteralVar(intptr_t token_pos) {
return new LocalVariable(token_pos,
Symbols::ArrayLiteralVar(),
Type::ZoneHandle(Type::ArrayType()));
}
void ParsedFunction::SetNodeSequence(SequenceNode* node_sequence) {
ASSERT(node_sequence_ == NULL);
ASSERT(node_sequence != NULL);
node_sequence_ = node_sequence;
}
LocalVariable* ParsedFunction::GetSavedArgumentsDescriptorVar() const {
const int num_parameters = function().NumParameters();
LocalScope* scope = node_sequence()->scope();
if (scope->num_variables() > num_parameters) {
LocalVariable* saved_args_desc_var = scope->VariableAt(num_parameters);
ASSERT(saved_args_desc_var != NULL);
// The scope of the formal parameters may also contain at this position
// an alias for the saved arguments descriptor variable of the enclosing
// function (check its scope owner) or an internal variable such as the
// expression temp variable or the saved entry context variable (check its
// name).
if ((saved_args_desc_var->owner() == scope) &&
saved_args_desc_var->name().StartsWith(
Symbols::SavedArgDescVarPrefix())) {
return saved_args_desc_var;
}
}
return NULL;
}
void ParsedFunction::AllocateVariables() {
LocalScope* scope = node_sequence()->scope();
const intptr_t num_fixed_params = function().num_fixed_parameters();
const intptr_t num_opt_params = function().NumOptionalParameters();
intptr_t num_params = num_fixed_params + num_opt_params;
// Compute start indices to parameters and locals, and the number of
// parameters to copy.
if (num_opt_params == 0) {
// Parameter i will be at fp[kLastParamSlotIndex + num_params - 1 - i] and
// local variable j will be at fp[kFirstLocalSlotIndex - j].
ASSERT(GetSavedArgumentsDescriptorVar() == NULL);
first_parameter_index_ = kLastParamSlotIndex + num_params - 1;
first_stack_local_index_ = kFirstLocalSlotIndex;
num_copied_params_ = 0;
} else {
// Parameter i will be at fp[kFirstLocalSlotIndex - i] and local variable
// j will be at fp[kFirstLocalSlotIndex - num_params - j].
// The saved arguments descriptor variable must be allocated similarly to
// a parameter, so that it gets both a frame slot and a context slot when
// captured.
if (GetSavedArgumentsDescriptorVar() != NULL) {
num_params += 1;
}
first_parameter_index_ = kFirstLocalSlotIndex;
first_stack_local_index_ = first_parameter_index_ - num_params;
num_copied_params_ = num_params;
}
// Allocate parameters and local variables, either in the local frame or
// in the context(s).
LocalScope* context_owner = NULL; // No context needed yet.
int next_free_frame_index =
scope->AllocateVariables(first_parameter_index_,
num_params,
first_stack_local_index_,
scope,
&context_owner);
// If this function allocates context variables, but none of its enclosing
// functions do, the context on entry is not linked as parent of the allocated
// context but saved on entry and restored on exit as to prevent memory leaks.
// Add and allocate a local variable to this purpose.
if (context_owner != NULL) {
const ContextScope& context_scope =
ContextScope::Handle(function().context_scope());
if (context_scope.IsNull() || (context_scope.num_variables() == 0)) {
LocalVariable* context_var =
new LocalVariable(function().token_pos(),
Symbols::SavedEntryContextVar(),
Type::ZoneHandle(Type::DynamicType()));
context_var->set_index(next_free_frame_index--);
scope->AddVariable(context_var);
set_saved_entry_context_var(context_var);
}
}
// Frame indices are relative to the frame pointer and are decreasing.
ASSERT(next_free_frame_index <= first_stack_local_index_);
num_stack_locals_ = first_stack_local_index_ - next_free_frame_index;
}
struct Parser::Block : public ZoneAllocated {
Block(Block* outer_block, LocalScope* local_scope, SequenceNode* seq)
: parent(outer_block), scope(local_scope), statements(seq) {
ASSERT(scope != NULL);
ASSERT(statements != NULL);
}
Block* parent; // Enclosing block, or NULL if outermost.
LocalScope* scope;
SequenceNode* statements;
};
// Class which describes an inlined finally block which is used to generate
// inlined code for the finally blocks when there is an exit from a try
// block using 'return', 'break' or 'continue'.
class Parser::TryBlocks : public ZoneAllocated {
public:
TryBlocks(Block* try_block, TryBlocks* outer_try_block)
: try_block_(try_block),
inlined_finally_nodes_(),
outer_try_block_(outer_try_block) { }
TryBlocks* outer_try_block() const { return outer_try_block_; }
Block* try_block() const { return try_block_; }
void AddNodeForFinallyInlining(AstNode* node);
AstNode* GetNodeToInlineFinally(int index) {
if (0 <= index && index < inlined_finally_nodes_.length()) {
return inlined_finally_nodes_[index];
}
return NULL;
}
private:
Block* try_block_;
GrowableArray<AstNode*> inlined_finally_nodes_;
TryBlocks* outer_try_block_;
DISALLOW_COPY_AND_ASSIGN(TryBlocks);
};
void Parser::TryBlocks::AddNodeForFinallyInlining(AstNode* node) {
inlined_finally_nodes_.Add(node);
}
// For parsing a compilation unit.
Parser::Parser(const Script& script, const Library& library)
: script_(Script::Handle(script.raw())),
tokens_iterator_(TokenStream::Handle(script.tokens()), 0),
token_kind_(Token::kILLEGAL),
current_block_(NULL),
is_top_level_(false),
current_member_(NULL),
allow_function_literals_(true),
parsed_function_(NULL),
innermost_function_(Function::Handle()),
current_class_(Class::Handle()),
library_(Library::Handle(library.raw())),
try_blocks_list_(NULL) {
ASSERT(tokens_iterator_.IsValid());
ASSERT(!library.IsNull());
}
// For parsing a function.
Parser::Parser(const Script& script,
ParsedFunction* parsed_function,
intptr_t token_position)
: script_(Script::Handle(script.raw())),
tokens_iterator_(TokenStream::Handle(script.tokens()), token_position),
token_kind_(Token::kILLEGAL),
current_block_(NULL),
is_top_level_(false),
current_member_(NULL),
allow_function_literals_(true),
parsed_function_(parsed_function),
innermost_function_(Function::Handle(parsed_function->function().raw())),
current_class_(Class::Handle(parsed_function->function().Owner())),
library_(Library::Handle(Class::Handle(
parsed_function->function().origin()).library())),
try_blocks_list_(NULL) {
ASSERT(tokens_iterator_.IsValid());
ASSERT(!current_function().IsNull());
if (FLAG_enable_type_checks) {
EnsureExpressionTemp();
}
}
void Parser::SetScript(const Script & script, intptr_t token_pos) {
script_ = script.raw();
tokens_iterator_.SetStream(TokenStream::Handle(script.tokens()), token_pos);
token_kind_ = Token::kILLEGAL;
}
bool Parser::SetAllowFunctionLiterals(bool value) {
bool current_value = allow_function_literals_;
allow_function_literals_ = value;
return current_value;
}
const Function& Parser::current_function() const {
ASSERT(parsed_function() != NULL);
return parsed_function()->function();
}
const Function& Parser::innermost_function() const {
return innermost_function_;
}
const Class& Parser::current_class() const {
return current_class_;
}
void Parser::set_current_class(const Class& value) {
current_class_ = value.raw();
}
void Parser::SetPosition(intptr_t position) {
if (position < TokenPos() && position != 0) {
CompilerStats::num_tokens_rewind += (TokenPos() - position);
}
tokens_iterator_.SetCurrentPosition(position);
token_kind_ = Token::kILLEGAL;
}
void Parser::ParseCompilationUnit(const Library& library,
const Script& script) {
ASSERT(Isolate::Current()->long_jump_base()->IsSafeToJump());
TimerScope timer(FLAG_compiler_stats, &CompilerStats::parser_timer);
Parser parser(script, library);
parser.ParseTopLevel();
}
Token::Kind Parser::CurrentToken() {
if (token_kind_ == Token::kILLEGAL) {
token_kind_ = tokens_iterator_.CurrentTokenKind();
if (token_kind_ == Token::kERROR) {
ErrorMsg(TokenPos(), "%s", CurrentLiteral()->ToCString());
}
}
CompilerStats::num_token_checks++;
return token_kind_;
}
Token::Kind Parser::LookaheadToken(int num_tokens) {
CompilerStats::num_tokens_lookahead++;
CompilerStats::num_token_checks++;
return tokens_iterator_.LookaheadTokenKind(num_tokens);
}
String* Parser::CurrentLiteral() const {
String& result = String::ZoneHandle();
result = tokens_iterator_.CurrentLiteral();
return &result;
}
RawDouble* Parser::CurrentDoubleLiteral() const {
LiteralToken& token = LiteralToken::Handle();
token ^= tokens_iterator_.CurrentToken();
ASSERT(token.kind() == Token::kDOUBLE);
return reinterpret_cast<RawDouble*>(token.value());
}
RawInteger* Parser::CurrentIntegerLiteral() const {
LiteralToken& token = LiteralToken::Handle();
token ^= tokens_iterator_.CurrentToken();
ASSERT(token.kind() == Token::kINTEGER);
return reinterpret_cast<RawInteger*>(token.value());
}
// A QualIdent is an optionally qualified identifier.
struct QualIdent {
QualIdent() {
Clear();
}
void Clear() {
lib_prefix = NULL;
ident_pos = 0;
ident = NULL;
}
LibraryPrefix* lib_prefix;
intptr_t ident_pos;
String* ident;
};
struct ParamDesc {
ParamDesc()
: type(NULL),
name_pos(0),
name(NULL),
default_value(NULL),
is_final(false),
is_field_initializer(false) { }
const AbstractType* type;
intptr_t name_pos;
const String* name;
const Object* default_value; // NULL if not an optional parameter.
bool is_final;
bool is_field_initializer;
};
struct ParamList {
ParamList() {
Clear();
}
void Clear() {
num_fixed_parameters = 0;
num_optional_parameters = 0;
has_optional_positional_parameters = false;
has_optional_named_parameters = false;
has_field_initializer = false;
implicitly_final = false;
skipped = false;
this->parameters = new ZoneGrowableArray<ParamDesc>();
}
void AddFinalParameter(intptr_t name_pos,
const String* name,
const AbstractType* type) {
this->num_fixed_parameters++;
ParamDesc param;
param.name_pos = name_pos;
param.name = name;
param.is_final = true;
param.type = type;
this->parameters->Add(param);
}
void AddReceiver(const Type* receiver_type) {
ASSERT(this->parameters->is_empty());
AddFinalParameter(receiver_type->token_pos(),
&Symbols::This(),
receiver_type);
}
void SetImplicitlyFinal() {
implicitly_final = true;
}
int num_fixed_parameters;
int num_optional_parameters;
bool has_optional_positional_parameters;
bool has_optional_named_parameters;
bool has_field_initializer;
bool implicitly_final;
bool skipped;
ZoneGrowableArray<ParamDesc>* parameters;
};
struct MemberDesc {
MemberDesc() {
Clear();
}
void Clear() {
has_abstract = false;
has_external = false;
has_final = false;
has_const = false;
has_static = false;
has_var = false;
has_factory = false;
has_operator = false;
operator_token = Token::kILLEGAL;
type = NULL;
name_pos = 0;
name = NULL;
redirect_name = NULL;
constructor_name = NULL;
params.Clear();
kind = RawFunction::kRegularFunction;
}
bool IsConstructor() const {
return (kind == RawFunction::kConstructor) && !has_static;
}
bool IsFactory() const {
return (kind == RawFunction::kConstructor) && has_static;
}
bool IsFactoryOrConstructor() const {
return (kind == RawFunction::kConstructor);
}
bool IsGetter() const {
return kind == RawFunction::kGetterFunction;
}
bool IsSetter() const {
return kind == RawFunction::kSetterFunction;
}
bool has_abstract;
bool has_external;
bool has_final;
bool has_const;
bool has_static;
bool has_var;
bool has_factory;
bool has_operator;
Token::Kind operator_token;
const AbstractType* type;
intptr_t name_pos;
String* name;
// For constructors: NULL or name of redirected to constructor.
String* redirect_name;
// For constructors: NULL for unnamed constructor,
// identifier after classname for named constructors.
String* constructor_name;
ParamList params;
RawFunction::Kind kind;
};
class ClassDesc : public ValueObject {
public:
ClassDesc(const Class& cls,
const String& cls_name,
bool is_interface,
intptr_t token_pos)
: clazz_(cls),
class_name_(cls_name),
token_pos_(token_pos),
functions_(GrowableObjectArray::Handle(GrowableObjectArray::New())),
fields_(GrowableObjectArray::Handle(GrowableObjectArray::New())) {
}
// Parameter 'name' is the unmangled name, i.e. without the setter
// name mangling.
bool FunctionNameExists(const String& name, RawFunction::Kind kind) const {
// First check if a function or field of same name exists.
if ((kind != RawFunction::kSetterFunction) && FunctionExists(name)) {
return true;
}
// Now check whether there is a field and whether its implicit getter
// or setter collides with the name.
Field* field = LookupField(name);
if (field != NULL) {
if (kind == RawFunction::kSetterFunction) {
// It's ok to have an implicit getter, it does not collide with
// this setter function.
if (!field->is_final()) {
return true;
}
} else {
// The implicit getter of the field collides with the name.
return true;
}
}
String& accessor_name = String::Handle();
if (kind == RawFunction::kSetterFunction) {
// Check if a setter function of same name exists.
accessor_name = Field::SetterName(name);
if (FunctionExists(accessor_name)) {
return true;
}
} else {
// Check if a getter function of same name exists.
accessor_name = Field::GetterName(name);
if (FunctionExists(accessor_name)) {
return true;
}
}
return false;
}
bool FieldNameExists(const String& name, bool check_setter) const {
// First check if a function or field of same name exists.
if (FunctionExists(name) || FieldExists(name)) {
return true;
}
// Now check if a getter/setter function of same name exists.
String& getter_name = String::Handle(Field::GetterName(name));
if (FunctionExists(getter_name)) {
return true;
}
if (check_setter) {
String& setter_name = String::Handle(Field::SetterName(name));
if (FunctionExists(setter_name)) {
return true;
}
}
return false;
}
void AddFunction(const Function& function) {
ASSERT(!FunctionExists(String::Handle(function.name())));
functions_.Add(function);
}
const GrowableObjectArray& functions() const {
return functions_;
}
void AddField(const Field& field) {
ASSERT(!FieldExists(String::Handle(field.name())));
fields_.Add(field);
}
const GrowableObjectArray& fields() const {
return fields_;
}
RawClass* clazz() const {
return clazz_.raw();
}
const String& class_name() const {
return class_name_;
}
bool has_constructor() const {
Function& func = Function::Handle();
for (int i = 0; i < functions_.Length(); i++) {
func ^= functions_.At(i);
if (func.kind() == RawFunction::kConstructor) {
return true;
}
}
return false;
}
intptr_t token_pos() const {
return token_pos_;
}
void AddMember(const MemberDesc& member) {
members_.Add(member);
}
const GrowableArray<MemberDesc>& members() const {
return members_;
}
MemberDesc* LookupMember(const String& name) const {
for (int i = 0; i < members_.length(); i++) {
if (name.Equals(*members_[i].name)) {
return &members_[i];
}
}
return NULL;
}
private:
Field* LookupField(const String& name) const {
String& test_name = String::Handle();
Field& field = Field::Handle();
for (int i = 0; i < fields_.Length(); i++) {
field ^= fields_.At(i);
test_name = field.name();
if (name.Equals(test_name)) {
return &field;
}
}
return NULL;
}
bool FieldExists(const String& name) const {
return LookupField(name) != NULL;
}
Function* LookupFunction(const String& name) const {
String& test_name = String::Handle();
Function& func = Function::Handle();
for (int i = 0; i < functions_.Length(); i++) {
func ^= functions_.At(i);
test_name = func.name();
if (name.Equals(test_name)) {
return &func;
}
}
return NULL;
}
bool FunctionExists(const String& name) const {
return LookupFunction(name) != NULL;
}
const Class& clazz_;
const String& class_name_;
intptr_t token_pos_; // Token index of "class" keyword.
GrowableObjectArray& functions_;
GrowableObjectArray& fields_;
GrowableArray<MemberDesc> members_;
};
struct TopLevel {
TopLevel() :
fields(GrowableObjectArray::Handle(GrowableObjectArray::New())),
functions(GrowableObjectArray::Handle(GrowableObjectArray::New())) { }
GrowableObjectArray& fields;
GrowableObjectArray& functions;
};
static bool HasReturnNode(SequenceNode* seq) {
if (seq->length() == 0) {
return false;
} else if ((seq->length()) == 1 &&
(seq->NodeAt(seq->length() - 1)->IsSequenceNode())) {
return HasReturnNode(seq->NodeAt(seq->length() - 1)->AsSequenceNode());
} else {
return seq->NodeAt(seq->length() - 1)->IsReturnNode();
}
}
void Parser::ParseFunction(ParsedFunction* parsed_function) {
TimerScope timer(FLAG_compiler_stats, &CompilerStats::parser_timer);
Isolate* isolate = Isolate::Current();
ASSERT(isolate->long_jump_base()->IsSafeToJump());
ASSERT(parsed_function != NULL);
const Function& func = parsed_function->function();
const Script& script = Script::Handle(isolate, func.script());
Parser parser(script, parsed_function, func.token_pos());
SequenceNode* node_sequence = NULL;
Array& default_parameter_values = Array::ZoneHandle(isolate, Array::null());
switch (func.kind()) {
case RawFunction::kRegularFunction:
case RawFunction::kClosureFunction:
case RawFunction::kGetterFunction:
case RawFunction::kSetterFunction:
case RawFunction::kConstructor:
// The call to a redirecting factory is redirected.
ASSERT(!func.IsRedirectingFactory());
node_sequence = parser.ParseFunc(func, default_parameter_values);
break;
case RawFunction::kImplicitGetter:
ASSERT(!func.is_static());
node_sequence = parser.ParseInstanceGetter(func);
break;
case RawFunction::kImplicitSetter:
ASSERT(!func.is_static());
node_sequence = parser.ParseInstanceSetter(func);
break;
case RawFunction::kConstImplicitGetter:
node_sequence = parser.ParseStaticConstGetter(func);
break;
case RawFunction::kMethodExtractor:
node_sequence = parser.ParseMethodExtractor(func);
break;
default:
UNREACHABLE();
}
parsed_function->set_array_literal_var(
ParsedFunction::CreateArrayLiteralVar(func.token_pos()));
node_sequence->scope()->AddVariable(parsed_function->array_literal_var());
if (!HasReturnNode(node_sequence)) {
// Add implicit return node.
node_sequence->Add(new ReturnNode(func.end_token_pos()));
}
if (parsed_function->has_expression_temp_var()) {
node_sequence->scope()->AddVariable(parsed_function->expression_temp_var());
}
if (parsed_function->has_saved_current_context_var()) {
node_sequence->scope()->AddVariable(
parsed_function->saved_current_context_var());
}
parsed_function->SetNodeSequence(node_sequence);
// The instantiator may be required at run time for generic type checks or
// allocation of generic types.
if (parser.IsInstantiatorRequired()) {
// In the case of a local function, only set the instantiator if the
// receiver (or type arguments parameter of a factory) was captured.
LocalVariable* instantiator = NULL;
const bool kTestOnly = true;
if (parser.current_function().IsInFactoryScope()) {
instantiator = parser.LookupTypeArgumentsParameter(node_sequence->scope(),
kTestOnly);
} else {
instantiator = parser.LookupReceiver(node_sequence->scope(), kTestOnly);
}
if (!parser.current_function().IsLocalFunction() ||
((instantiator != NULL) && instantiator->is_captured())) {
parsed_function->set_instantiator(
new LoadLocalNode(node_sequence->token_pos(), instantiator));
}
}
parsed_function->set_default_parameter_values(default_parameter_values);
}
// TODO(regis): Since a const variable is implicitly final,
// rename ParseStaticConstGetter to ParseStaticFinalGetter and
// rename kConstImplicitGetter to kImplicitFinalGetter.
SequenceNode* Parser::ParseStaticConstGetter(const Function& func) {
TRACE_PARSER("ParseStaticConstGetter");
ParamList params;
ASSERT(func.num_fixed_parameters() == 0); // static.
ASSERT(!func.HasOptionalParameters());
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
// Build local scope for function and populate with the formal parameters.
OpenFunctionBlock(func);
AddFormalParamsToScope(&params, current_block_->scope);
intptr_t ident_pos = TokenPos();
const String& field_name = *ExpectIdentifier("field name expected");
const Class& field_class = Class::Handle(func.Owner());
const Field& field =
Field::ZoneHandle(field_class.LookupStaticField(field_name));
// Static const fields must have an initializer.
ExpectToken(Token::kASSIGN);
// We don't want to use ParseConstExpr() here because we don't want
// the constant folding code to create, compile and execute a code
// fragment to evaluate the expression. Instead, we just make sure
// the static const field initializer is a constant expression and
// leave the evaluation to the getter function.
const intptr_t expr_pos = TokenPos();
AstNode* expr = ParseExpr(kAllowConst, kConsumeCascades);
if (field.is_const()) {
// This getter will only be called once at compile time.
if (expr->EvalConstExpr() == NULL) {
ErrorMsg(expr_pos, "initializer must be a compile-time constant");
}
ReturnNode* return_node = new ReturnNode(ident_pos, expr);
current_block_->statements->Add(return_node);
} else {
// This getter may be called each time the static field is accessed.
// The following generated code lazily initializes the field:
// if (field.value === transition_sentinel) {
// field.value = null;
// throw("circular dependency in field initialization");
// }
// if (field.value === sentinel) {
// field.value = transition_sentinel;
// field.value = expr;
// }
// return field.value; // Type check is executed here in checked mode.
// Generate code checking for circular dependency in field initialization.
AstNode* compare_circular = new ComparisonNode(
ident_pos,
Token::kEQ_STRICT,
new LoadStaticFieldNode(ident_pos, field),
new LiteralNode(ident_pos, Object::transition_sentinel()));
// Set field to null prior to throwing exception, so that subsequent
// accesses to the field do not throw again, since initializers should only
// be executed once.
SequenceNode* report_circular = new SequenceNode(ident_pos, NULL);
report_circular->Add(
new StoreStaticFieldNode(
ident_pos,
field,
new LiteralNode(ident_pos, Instance::ZoneHandle())));
// TODO(regis): Exception to throw is not specified by spec.
const String& circular_error = String::ZoneHandle(
Symbols::New("circular dependency in field initialization"));
report_circular->Add(
new ThrowNode(ident_pos,
new LiteralNode(ident_pos, circular_error),
NULL));
AstNode* circular_check =
new IfNode(ident_pos, compare_circular, report_circular, NULL);
current_block_->statements->Add(circular_check);
// Generate code checking for uninitialized field.
AstNode* compare_uninitialized = new ComparisonNode(
ident_pos,
Token::kEQ_STRICT,
new LoadStaticFieldNode(ident_pos, field),
new LiteralNode(ident_pos, Object::sentinel()));
SequenceNode* initialize_field = new SequenceNode(ident_pos, NULL);
initialize_field->Add(
new StoreStaticFieldNode(
ident_pos,
field,
new LiteralNode(ident_pos, Object::transition_sentinel())));
// TODO(hausner): If evaluation of the field value throws an exception,
// we leave the field value as 'transition_sentinel', which is wrong.
// A second reference to the field later throws a circular dependency
// exception. The field should instead be set to null after an exception.
initialize_field->Add(new StoreStaticFieldNode(ident_pos, field, expr));
AstNode* uninitialized_check =
new IfNode(ident_pos, compare_uninitialized, initialize_field, NULL);
current_block_->statements->Add(uninitialized_check);
// Generate code returning the field value.
ReturnNode* return_node =
new ReturnNode(ident_pos,
new LoadStaticFieldNode(ident_pos, field));
current_block_->statements->Add(return_node);
}
return CloseBlock();
}
// Create AstNodes for an implicit instance getter method:
// LoadLocalNode 0 ('this');
// LoadInstanceFieldNode (field_name);
// ReturnNode (field's value);
SequenceNode* Parser::ParseInstanceGetter(const Function& func) {
TRACE_PARSER("ParseInstanceGetter");
ParamList params;
// func.token_pos() points to the name of the field.
intptr_t ident_pos = func.token_pos();
ASSERT(current_class().raw() == func.Owner());
params.AddReceiver(ReceiverType(ident_pos));
ASSERT(func.num_fixed_parameters() == 1); // receiver.
ASSERT(!func.HasOptionalParameters());
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
// Build local scope for function and populate with the formal parameters.
OpenFunctionBlock(func);
AddFormalParamsToScope(&params, current_block_->scope);
// Receiver is local 0.
LocalVariable* receiver = current_block_->scope->VariableAt(0);
LoadLocalNode* load_receiver = new LoadLocalNode(ident_pos, receiver);
ASSERT(IsIdentifier());
const String& field_name = *CurrentLiteral();
const Class& field_class = Class::Handle(func.Owner());
const Field& field =
Field::ZoneHandle(field_class.LookupInstanceField(field_name));
LoadInstanceFieldNode* load_field =
new LoadInstanceFieldNode(ident_pos, load_receiver, field);
ReturnNode* return_node = new ReturnNode(ident_pos, load_field);
current_block_->statements->Add(return_node);
return CloseBlock();
}
// Create AstNodes for an implicit instance setter method:
// LoadLocalNode 0 ('this')
// LoadLocalNode 1 ('value')
// SetInstanceField (field_name);
// ReturnNode (void);
SequenceNode* Parser::ParseInstanceSetter(const Function& func) {
TRACE_PARSER("ParseInstanceSetter");
// func.token_pos() points to the name of the field.
intptr_t ident_pos = func.token_pos();
const String& field_name = *CurrentLiteral();
const Class& field_class = Class::ZoneHandle(func.Owner());
const Field& field =
Field::ZoneHandle(field_class.LookupInstanceField(field_name));
const AbstractType& field_type = AbstractType::ZoneHandle(field.type());
ParamList params;
ASSERT(current_class().raw() == func.Owner());
params.AddReceiver(ReceiverType(ident_pos));
params.AddFinalParameter(ident_pos,
&Symbols::Value(),
&field_type);
ASSERT(func.num_fixed_parameters() == 2); // receiver, value.
ASSERT(!func.HasOptionalParameters());
ASSERT(AbstractType::Handle(func.result_type()).IsVoidType());
// Build local scope for function and populate with the formal parameters.
OpenFunctionBlock(func);
AddFormalParamsToScope(&params, current_block_->scope);
LoadLocalNode* receiver =
new LoadLocalNode(ident_pos, current_block_->scope->VariableAt(0));
LoadLocalNode* value =
new LoadLocalNode(ident_pos, current_block_->scope->VariableAt(1));
EnsureExpressionTemp();
StoreInstanceFieldNode* store_field =
new StoreInstanceFieldNode(ident_pos, receiver, field, value);
current_block_->statements->Add(store_field);
current_block_->statements->Add(new ReturnNode(ident_pos));
return CloseBlock();
}
SequenceNode* Parser::ParseMethodExtractor(const Function& func) {
TRACE_PARSER("ParseMethodExtractor");
ParamList params;
const intptr_t ident_pos = func.token_pos();
ASSERT(func.token_pos() == 0);
ASSERT(current_class().raw() == func.Owner());
params.AddReceiver(ReceiverType(ident_pos));
ASSERT(func.num_fixed_parameters() == 1); // Receiver.
ASSERT(!func.HasOptionalParameters());
// Build local scope for function and populate with the formal parameters.
OpenFunctionBlock(func);
AddFormalParamsToScope(&params, current_block_->scope);
// Receiver is local 0.
LocalVariable* receiver = current_block_->scope->VariableAt(0);
LoadLocalNode* load_receiver = new LoadLocalNode(ident_pos, receiver);
ClosureNode* closure = new ClosureNode(
ident_pos,
Function::ZoneHandle(func.extracted_method_closure()),
load_receiver,
NULL);
ReturnNode* return_node = new ReturnNode(ident_pos, closure);
current_block_->statements->Add(return_node);
return CloseBlock();
}
void Parser::SkipBlock() {
ASSERT(CurrentToken() == Token::kLBRACE);
GrowableArray<Token::Kind> token_stack(8);
const intptr_t block_start_pos = TokenPos();
bool is_match = true;
bool unexpected_token_found = false;
Token::Kind token;
intptr_t token_pos;
do {
token = CurrentToken();
token_pos = TokenPos();
switch (token) {
case Token::kLBRACE:
case Token::kLPAREN:
case Token::kLBRACK:
token_stack.Add(token);
break;
case Token::kRBRACE:
is_match = token_stack.RemoveLast() == Token::kLBRACE;
break;
case Token::kRPAREN:
is_match = token_stack.RemoveLast() == Token::kLPAREN;
break;
case Token::kRBRACK:
is_match = token_stack.RemoveLast() == Token::kLBRACK;
break;
case Token::kEOS:
unexpected_token_found = true;
break;
default:
// nothing.
break;
}
ConsumeToken();
} while (!token_stack.is_empty() && is_match && !unexpected_token_found);
if (!is_match) {
ErrorMsg(token_pos, "unbalanced '%s'", Token::Str(token));
} else if (unexpected_token_found) {
ErrorMsg(block_start_pos, "unterminated block");
}
}
void Parser::ParseFormalParameter(bool allow_explicit_default_value,
ParamList* params) {
TRACE_PARSER("ParseFormalParameter");
ParamDesc parameter;
bool var_seen = false;
bool this_seen = false;
SkipMetadata();
if (CurrentToken() == Token::kFINAL) {
ConsumeToken();
parameter.is_final = true;
} else if (CurrentToken() == Token::kVAR) {
ConsumeToken();
var_seen = true;
// The parameter type is the 'dynamic' type.
parameter.type = &Type::ZoneHandle(Type::DynamicType());
}
if (CurrentToken() == Token::kTHIS) {
ConsumeToken();
ExpectToken(Token::kPERIOD);
this_seen = true;
parameter.is_field_initializer = true;
}
if (params->implicitly_final) {
parameter.is_final = true;
}
if ((parameter.type == NULL) && (CurrentToken() == Token::kVOID)) {
ConsumeToken();
// This must later be changed to a closure type if we recognize
// a closure/function type parameter. We check this at the end
// of ParseFormalParameter.
parameter.type = &Type::ZoneHandle(Type::VoidType());
}
if (parameter.type == NULL) {
// At this point, we must see an identifier for the type or the
// function parameter.
if (!IsIdentifier()) {
ErrorMsg("parameter name or type expected");
}
// We have not seen a parameter type yet, so we check if the next
// identifier could represent a type before parsing it.
Token::Kind follower = LookaheadToken(1);
// We have an identifier followed by a 'follower' token.
// We either parse a type or assume that no type is specified.
if ((follower == Token::kLT) || // Parameterized type.
(follower == Token::kPERIOD) || // Qualified class name of type.
Token::IsIdentifier(follower) || // Parameter name following a type.
(follower == Token::kTHIS)) { // Field parameter following a type.
// The types of formal parameters are never ignored, even in unchecked
// mode, because they are part of the function type of closurized
// functions appearing in type tests with typedefs.
parameter.type = &AbstractType::ZoneHandle(
ParseType(is_top_level_ ? ClassFinalizer::kTryResolve :
ClassFinalizer::kCanonicalize));
} else {
parameter.type = &Type::ZoneHandle(Type::DynamicType());
}
}
if (!this_seen && (CurrentToken() == Token::kTHIS)) {
ConsumeToken();
ExpectToken(Token::kPERIOD);
this_seen = true;
parameter.is_field_initializer = true;
}
// At this point, we must see an identifier for the parameter name.
parameter.name_pos = TokenPos();
parameter.name = ExpectIdentifier("parameter name expected");
if (parameter.is_field_initializer) {
params->has_field_initializer = true;
}
// Check for duplicate formal parameters.
const intptr_t num_existing_parameters =
params->num_fixed_parameters + params->num_optional_parameters;
for (intptr_t i = 0; i < num_existing_parameters; i++) {
ParamDesc& existing_parameter = (*params->parameters)[i];
if (existing_parameter.name->Equals(*parameter.name)) {
ErrorMsg(parameter.name_pos, "duplicate formal parameter '%s'",
parameter.name->ToCString());
}
}
if (CurrentToken() == Token::kLPAREN) {
// This parameter is probably a closure. If we saw the keyword 'var'
// or 'final', a closure is not legal here and we ignore the
// opening parens.
if (!var_seen && !parameter.is_final) {
// The parsed parameter type is actually the function result type.
const AbstractType& result_type =
AbstractType::Handle(parameter.type->raw());
// Finish parsing the function type parameter.
ParamList func_params;
// Add implicit closure object parameter.
func_params.AddFinalParameter(
TokenPos(),
&Symbols::ClosureParameter(),
&Type::ZoneHandle(Type::DynamicType()));
const bool no_explicit_default_values = false;
ParseFormalParameterList(no_explicit_default_values, &func_params);
// The field 'is_static' has no meaning for signature functions.
const Function& signature_function = Function::Handle(
Function::New(*parameter.name,
RawFunction::kSignatureFunction,
/* is_static = */ false,
/* is_const = */ false,
/* is_abstract = */ false,
/* is_external = */ false,
current_class(),
parameter.name_pos));
signature_function.set_result_type(result_type);
AddFormalParamsToFunction(&func_params, signature_function);
const String& signature = String::Handle(signature_function.Signature());
// Lookup the signature class, i.e. the class whose name is the signature.
// We only lookup in the current library, but not in its imports, and only
// create a new canonical signature class if it does not exist yet.
Class& signature_class = Class::ZoneHandle(
library_.LookupLocalClass(signature));
if (signature_class.IsNull()) {
signature_class = Class::NewSignatureClass(signature,
signature_function,
script_,
parameter.name_pos);
// Record the function signature class in the current library, unless
// we are currently skipping a formal parameter list, in which case
// the signature class could remain unfinalized.
if (!params->skipped) {
library_.AddClass(signature_class);
}
} else {
signature_function.set_signature_class(signature_class);
}
ASSERT(signature_function.signature_class() == signature_class.raw());
Type& signature_type = Type::ZoneHandle(signature_class.SignatureType());
if (!is_top_level_ && !signature_type.IsFinalized()) {
signature_type ^= ClassFinalizer::FinalizeType(
signature_class, signature_type, ClassFinalizer::kCanonicalize);
}
// The type of the parameter is now the signature type.
parameter.type = &signature_type;
}
}
if ((CurrentToken() == Token::kASSIGN) || (CurrentToken() == Token::kCOLON)) {
if ((!params->has_optional_positional_parameters &&
!params->has_optional_named_parameters) ||
!allow_explicit_default_value) {
ErrorMsg("parameter must not specify a default value");
}
if (params->has_optional_positional_parameters) {
ExpectToken(Token::kASSIGN);
} else {
ExpectToken(Token::kCOLON);
}
params->num_optional_parameters++;
if (is_top_level_) {
// Skip default value parsing.
SkipExpr();
} else {
const Object& const_value = ParseConstExpr()->literal();
parameter.default_value = &const_value;
}
} else {
if (params->has_optional_positional_parameters ||
params->has_optional_named_parameters) {
// Implicit default value is null.
params->num_optional_parameters++;
parameter.default_value = &Object::ZoneHandle();
} else {
params->num_fixed_parameters++;
ASSERT(params->num_optional_parameters == 0);
}
}
if (parameter.type->IsVoidType()) {
ErrorMsg("parameter '%s' may not be 'void'", parameter.name->ToCString());
}
params->parameters->Add(parameter);
}
// Parses a sequence of normal or optional formal parameters.
void Parser::ParseFormalParameters(bool allow_explicit_default_values,
ParamList* params) {
TRACE_PARSER("ParseFormalParameters");
do {
ConsumeToken();
if (!params->has_optional_positional_parameters &&
!params->has_optional_named_parameters &&
(CurrentToken() == Token::kLBRACK)) {
// End of normal parameters, start of optional positional parameters.
params->has_optional_positional_parameters = true;
return;
}
if (!params->has_optional_positional_parameters &&
!params->has_optional_named_parameters &&
(CurrentToken() == Token::kLBRACE)) {
// End of normal parameters, start of optional named parameters.
params->has_optional_named_parameters = true;
return;
}
ParseFormalParameter(allow_explicit_default_values, params);
} while (CurrentToken() == Token::kCOMMA);
}
void Parser::ParseFormalParameterList(bool allow_explicit_default_values,
ParamList* params) {
TRACE_PARSER("ParseFormalParameterList");
ASSERT(CurrentToken() == Token::kLPAREN);
if (LookaheadToken(1) != Token::kRPAREN) {
// Parse fixed parameters.
ParseFormalParameters(allow_explicit_default_values, params);
if (params->has_optional_positional_parameters ||
params->has_optional_named_parameters) {
// Parse optional parameters.
ParseFormalParameters(allow_explicit_default_values, params);
if (params->has_optional_positional_parameters) {
if (CurrentToken() != Token::kRBRACK) {
ErrorMsg("',' or ']' expected");
}
} else {
if (CurrentToken() != Token::kRBRACE) {
ErrorMsg("',' or '}' expected");
}
}
ConsumeToken(); // ']' or '}'.
}
if ((CurrentToken() != Token::kRPAREN) &&
!params->has_optional_positional_parameters &&
!params->has_optional_named_parameters) {
ErrorMsg("',' or ')' expected");
}
} else {
ConsumeToken();
}
ExpectToken(Token::kRPAREN);
}
String& Parser::ParseNativeDeclaration() {
TRACE_PARSER("ParseNativeDeclaration");
ASSERT(IsLiteral("native"));
ConsumeToken();
if (CurrentToken() != Token::kSTRING) {
ErrorMsg("string literal expected");
}
String& native_name = *CurrentLiteral();
ConsumeToken();
ExpectSemicolon();
return native_name;
}
// Resolve and return the dynamic function of the given name in the superclass.
// If it is not found, and resolve_getter is true, try to resolve a getter of
// the same name. If it is still not found, return noSuchMethod and
// set is_no_such_method to true..
RawFunction* Parser::GetSuperFunction(intptr_t token_pos,
const String& name,
ArgumentListNode* arguments,
bool resolve_getter,
bool* is_no_such_method) {
const Class& super_class = Class::Handle(current_class().SuperClass());
if (super_class.IsNull()) {
ErrorMsg(token_pos, "class '%s' does not have a superclass",
String::Handle(current_class().Name()).ToCString());
}
Function& super_func = Function::Handle(
Resolver::ResolveDynamicAnyArgs(super_class, name));
if (!super_func.IsNull() &&
!super_func.AreValidArguments(arguments->length(),
arguments->names(),
NULL)) {
super_func = Function::null();
} else if (super_func.IsNull() && resolve_getter) {
const String& getter_name = String::ZoneHandle(Field::GetterName(name));
super_func = Resolver::ResolveDynamicAnyArgs(super_class, getter_name);
ASSERT(super_func.IsNull() ||
(super_func.kind() != RawFunction::kConstImplicitGetter));
}
if (super_func.IsNull()) {
super_func =
Resolver::ResolveDynamicAnyArgs(super_class, Symbols::NoSuchMethod());
ASSERT(!super_func.IsNull());
*is_no_such_method = true;
} else {
*is_no_such_method = false;
}
return super_func.raw();
}
// Lookup class in the core lib which also contains various VM
// helper methods and classes. Allow look up of private classes.
static RawClass* LookupCoreClass(const String& class_name) {
const Library& core_lib = Library::Handle(Library::CoreLibrary());
String& name = String::Handle(class_name.raw());
if (class_name.CharAt(0) == Scanner::kPrivateIdentifierStart) {
// Private identifiers are mangled on a per script basis.
name = String::Concat(name, String::Handle(core_lib.private_key()));
name = Symbols::New(name);
}
return core_lib.LookupClass(name);
}
static const String& PrivateCoreLibName(const String& str) {
const Library& core_lib = Library::Handle(Library::CoreLibrary());
const String& private_name = String::ZoneHandle(core_lib.PrivateName(str));
return private_name;
}
LocalVariable* Parser::BuildArrayTempLocal(intptr_t token_pos) {
char name[64];
OS::SNPrint(name, 64, ":arrlit%"Pd, token_pos);
LocalVariable* temp =
new LocalVariable(token_pos,
String::ZoneHandle(Symbols::New(name)),
Type::ZoneHandle(Type::ArrayType()));
current_block_->scope->AddVariable(temp);
return temp;
}
StaticCallNode* Parser::BuildInvocationMirrorAllocation(
intptr_t call_pos,
const String& function_name,
const ArgumentListNode& function_args) {
const intptr_t args_pos = function_args.token_pos();
// Build arguments to the call to the static
// InvocationMirror._allocateInvocationMirror method.
ArgumentListNode* arguments = new ArgumentListNode(args_pos);
// The first argument is the original function name.
arguments->Add(new LiteralNode(args_pos, function_name));
// The second argument is the arguments descriptor of the original function.
const Array& args_descriptor =
Array::ZoneHandle(ArgumentsDescriptor::New(function_args.length(),
function_args.names()));
arguments->Add(new LiteralNode(args_pos, args_descriptor));
// The third argument is an array containing the original function arguments,
// including the receiver.
ArrayNode* args_array = new ArrayNode(
args_pos, Type::ZoneHandle(Type::ArrayType()),
*BuildArrayTempLocal(call_pos));
for (intptr_t i = 0; i < function_args.length(); i++) {
args_array->AddElement(function_args.NodeAt(i));
}
arguments->Add(args_array);
// Lookup the static InvocationMirror._allocateInvocationMirror method.
const Class& mirror_class =
Class::Handle(LookupCoreClass(Symbols::InvocationMirror()));
ASSERT(!mirror_class.IsNull());
const Function& allocation_function = Function::ZoneHandle(
mirror_class.LookupStaticFunction(
PrivateCoreLibName(Symbols::AllocateInvocationMirror())));
ASSERT(!allocation_function.IsNull());
return new StaticCallNode(call_pos, allocation_function, arguments);
}
ArgumentListNode* Parser::BuildNoSuchMethodArguments(
intptr_t call_pos,
const String& function_name,
const ArgumentListNode& function_args) {
ASSERT(function_args.length() >= 1); // The receiver is the first argument.
const intptr_t args_pos = function_args.token_pos();
ArgumentListNode* arguments = new ArgumentListNode(args_pos);
arguments->Add(function_args.NodeAt(0));
// The second argument is the invocation mirror.
arguments->Add(BuildInvocationMirrorAllocation(
call_pos, function_name, function_args));
return arguments;
}
AstNode* Parser::ParseSuperCall(const String& function_name) {
TRACE_PARSER("ParseSuperCall");
ASSERT(CurrentToken() == Token::kLPAREN);
const intptr_t supercall_pos = TokenPos();
// 'this' parameter is the first argument to super call.
ArgumentListNode* arguments = new ArgumentListNode(supercall_pos);
AstNode* receiver = LoadReceiver(supercall_pos);
arguments->Add(receiver);
ParseActualParameters(arguments, kAllowConst);
const bool kResolveGetter = true;
bool is_no_such_method = false;
const Function& super_function = Function::ZoneHandle(
GetSuperFunction(supercall_pos,
function_name,
arguments,
kResolveGetter,
&is_no_such_method));
if (super_function.IsGetterFunction() ||
super_function.IsImplicitGetterFunction()) {
const Class& super_class = Class::ZoneHandle(current_class().SuperClass());
AstNode* closure = new StaticGetterNode(supercall_pos,
LoadReceiver(supercall_pos),
/* is_super_getter */ true,
super_class,
function_name);
EnsureSavedCurrentContext();
// 'this' is not passed as parameter to the closure.
ArgumentListNode* closure_arguments = new ArgumentListNode(supercall_pos);
for (int i = 1; i < arguments->length(); i++) {
closure_arguments->Add(arguments->NodeAt(i));
}
return new ClosureCallNode(supercall_pos, closure, closure_arguments);
}
if (is_no_such_method) {
arguments = BuildNoSuchMethodArguments(
supercall_pos, function_name, *arguments);
}
return new StaticCallNode(supercall_pos, super_function, arguments);
}
// Simple test if a node is side effect free.
static bool IsSimpleLocalOrLiteralNode(AstNode* node) {
if (node->IsLiteralNode()) {
return true;
}
if (node->IsLoadLocalNode() && !node->AsLoadLocalNode()->HasPseudo()) {
return true;
}
return false;
}
AstNode* Parser::BuildUnarySuperOperator(Token::Kind op, PrimaryNode* super) {
ASSERT(super->IsSuper());
AstNode* super_op = NULL;
const intptr_t super_pos = super->token_pos();
if ((op == Token::kNEGATE) ||
(op == Token::kBIT_NOT)) {
// Resolve the operator function in the superclass.
const String& operator_function_name =
String::ZoneHandle(Symbols::New(Token::Str(op)));
ArgumentListNode* op_arguments = new ArgumentListNode(super_pos);
AstNode* receiver = LoadReceiver(super_pos);
op_arguments->Add(receiver);
const bool kResolveGetter = false;
bool is_no_such_method = false;
const Function& super_operator = Function::ZoneHandle(
GetSuperFunction(super_pos,
operator_function_name,
op_arguments,
kResolveGetter,
&is_no_such_method));
if (is_no_such_method) {
op_arguments = BuildNoSuchMethodArguments(
super_pos, operator_function_name, *op_arguments);
}
super_op = new StaticCallNode(super_pos, super_operator, op_arguments);
} else {
ErrorMsg(super_pos, "illegal super operator call");
}
return super_op;
}
AstNode* Parser::ParseSuperOperator() {
TRACE_PARSER("ParseSuperOperator");
AstNode* super_op = NULL;
const intptr_t operator_pos = TokenPos();
if (CurrentToken() == Token::kLBRACK) {
ConsumeToken();
AstNode* index_expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kRBRACK);
AstNode* receiver = LoadReceiver(operator_pos);
const Class& super_class = Class::ZoneHandle(current_class().SuperClass());
ASSERT(!super_class.IsNull());
super_op =
new LoadIndexedNode(operator_pos, receiver, index_expr, super_class);
} else if (Token::CanBeOverloaded(CurrentToken()) ||
(CurrentToken() == Token::kNE)) {
Token::Kind op = CurrentToken();
ConsumeToken();
bool negate_result = false;
if (op == Token::kNE) {
op = Token::kEQ;
negate_result = true;
}
ASSERT(Token::Precedence(op) >= Token::Precedence(Token::kBIT_OR));
AstNode* other_operand = ParseBinaryExpr(Token::Precedence(op) + 1);
ArgumentListNode* op_arguments = new ArgumentListNode(operator_pos);
AstNode* receiver = LoadReceiver(operator_pos);
op_arguments->Add(receiver);
op_arguments->Add(other_operand);
// Resolve the operator function in the superclass.
const String& operator_function_name =
String::ZoneHandle(Symbols::New(Token::Str(op)));
const bool kResolveGetter = false;
bool is_no_such_method = false;
const Function& super_operator = Function::ZoneHandle(
GetSuperFunction(operator_pos,
operator_function_name,
op_arguments,
kResolveGetter,
&is_no_such_method));
if (is_no_such_method) {
op_arguments = BuildNoSuchMethodArguments(
operator_pos, operator_function_name, *op_arguments);
}
super_op = new StaticCallNode(operator_pos, super_operator, op_arguments);
if (negate_result) {
super_op = new UnaryOpNode(operator_pos, Token::kNOT, super_op);
}
}
return super_op;
}
AstNode* Parser::CreateImplicitClosureNode(const Function& func,
intptr_t token_pos,
AstNode* receiver) {
Function& implicit_closure_function =
Function::ZoneHandle(func.ImplicitClosureFunction());
if (receiver != NULL) {
// If we create an implicit instance closure from inside a closure of a
// parameterized class, make sure that the receiver is captured as
// instantiator.
if (current_block_->scope->function_level() > 0) {
const Class& signature_class = Class::Handle(
implicit_closure_function.signature_class());
if (signature_class.NumTypeParameters() > 0) {
CaptureInstantiator();
}
}
}
return new ClosureNode(token_pos, implicit_closure_function, receiver, NULL);
}
AstNode* Parser::ParseSuperFieldAccess(const String& field_name) {
TRACE_PARSER("ParseSuperFieldAccess");
const intptr_t field_pos = TokenPos();
const Class& super_class = Class::ZoneHandle(current_class().SuperClass());
if (super_class.IsNull()) {
ErrorMsg("class '%s' does not have a superclass",
String::Handle(current_class().Name()).ToCString());
}
AstNode* implicit_argument = LoadReceiver(field_pos);
const String& getter_name =
String::ZoneHandle(Field::GetterName(field_name));
const Function& super_getter = Function::ZoneHandle(
Resolver::ResolveDynamicAnyArgs(super_class, getter_name));
if (super_getter.IsNull()) {
const String& setter_name =
String::ZoneHandle(Field::SetterName(field_name));
const Function& super_setter = Function::ZoneHandle(
Resolver::ResolveDynamicAnyArgs(super_class, setter_name));
if (!super_setter.IsNull()) {
return new StaticGetterNode(
field_pos, implicit_argument, true, super_class, field_name);
}
}
if (super_getter.IsNull()) {
// Check if this is an access to an implicit closure using 'super'.
// If a function exists of the specified field_name then try
// accessing it as a getter, at runtime we will handle this by
// creating an implicit closure of the function and returning it.
const Function& super_function = Function::ZoneHandle(
Resolver::ResolveDynamicAnyArgs(super_class, field_name));
if (!super_function.IsNull()) {
// In case CreateAssignmentNode is called later on this
// CreateImplicitClosureNode, it will be replaced by a StaticSetterNode.
return CreateImplicitClosureNode(super_function,
field_pos,
implicit_argument);
}
// No function or field exists of the specified field_name.
// Emit a StaticGetterNode anyway, so that noSuchMethod gets called.
}
return new StaticGetterNode(
field_pos, implicit_argument, true, super_class, field_name);
}
void Parser::GenerateSuperConstructorCall(const Class& cls,
LocalVariable* receiver) {
const intptr_t supercall_pos = TokenPos();
const Class& super_class = Class::Handle(cls.SuperClass());
// Omit the implicit super() if there is no super class (i.e.
// we're not compiling class Object), or if the super class is an
// artificially generated "wrapper class" that has no constructor.
if (super_class.IsNull() ||
(super_class.num_native_fields() > 0 &&
Class::Handle(super_class.SuperClass()).IsObjectClass())) {
return;
}
String& ctor_name = String::Handle(super_class.Name());
ctor_name = String::Concat(ctor_name, Symbols::Dot());
ArgumentListNode* arguments = new ArgumentListNode(supercall_pos);
// Implicit 'this' parameter is the first argument.
AstNode* implicit_argument = new LoadLocalNode(supercall_pos, receiver);
arguments->Add(implicit_argument);
// Implicit construction phase parameter is second argument.
AstNode* phase_parameter =
new LiteralNode(supercall_pos,
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseAll)));
arguments->Add(phase_parameter);
const Function& super_ctor = Function::ZoneHandle(
super_class.LookupConstructor(ctor_name));
if (super_ctor.IsNull()) {
ErrorMsg(supercall_pos,
"unresolved implicit call to super constructor '%s()'",
String::Handle(super_class.Name()).ToCString());
}
String& error_message = String::Handle();
if (!super_ctor.AreValidArguments(arguments->length(),
arguments->names(),
&error_message)) {
ErrorMsg(supercall_pos,
"invalid arguments passed to super constructor '%s()': %s",
String::Handle(super_class.Name()).ToCString(),
error_message.ToCString());
}
current_block_->statements->Add(
new StaticCallNode(supercall_pos, super_ctor, arguments));
}
AstNode* Parser::ParseSuperInitializer(const Class& cls,
LocalVariable* receiver) {
TRACE_PARSER("ParseSuperInitializer");
ASSERT(CurrentToken() == Token::kSUPER);
const intptr_t supercall_pos = TokenPos();
ConsumeToken();
const Class& super_class = Class::Handle(cls.SuperClass());
ASSERT(!super_class.IsNull());
String& ctor_name = String::Handle(super_class.Name());
ctor_name = String::Concat(ctor_name, Symbols::Dot());
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ctor_name = String::Concat(ctor_name,
*ExpectIdentifier("constructor name expected"));
}
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("parameter list expected");
}
ArgumentListNode* arguments = new ArgumentListNode(supercall_pos);
// 'this' parameter is the first argument to super class constructor.
AstNode* implicit_argument = new LoadLocalNode(supercall_pos, receiver);
arguments->Add(implicit_argument);
// Second implicit parameter is the construction phase. We optimistically
// assume that we can execute both the super initializer and the super
// constructor body. We may later change this to only execute the
// super initializer.
AstNode* phase_parameter =
new LiteralNode(supercall_pos,
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseAll)));
arguments->Add(phase_parameter);
// 'this' parameter must not be accessible to the other super call arguments.
receiver->set_invisible(true);
ParseActualParameters(arguments, kAllowConst);
receiver->set_invisible(false);
// Resolve the constructor.
const Function& super_ctor = Function::ZoneHandle(
super_class.LookupConstructor(ctor_name));
if (super_ctor.IsNull()) {
ErrorMsg(supercall_pos,
"super class constructor '%s' not found",
ctor_name.ToCString());
}
String& error_message = String::Handle();
if (!super_ctor.AreValidArguments(arguments->length(),
arguments->names(),
&error_message)) {
ErrorMsg(supercall_pos,
"invalid arguments passed to super class constructor '%s': %s",
ctor_name.ToCString(),
error_message.ToCString());
}
return new StaticCallNode(supercall_pos, super_ctor, arguments);
}
AstNode* Parser::ParseInitializer(const Class& cls,
LocalVariable* receiver,
GrowableArray<Field*>* initialized_fields) {
TRACE_PARSER("ParseInitializer");
const intptr_t field_pos = TokenPos();
if (CurrentToken() == Token::kTHIS) {
ConsumeToken();
ExpectToken(Token::kPERIOD);
}
const String& field_name = *ExpectIdentifier("field name expected");
ExpectToken(Token::kASSIGN);
const bool saved_mode = SetAllowFunctionLiterals(false);
// "this" must not be accessible in initializer expressions.
receiver->set_invisible(true);
AstNode* init_expr = ParseConditionalExpr();
if (CurrentToken() == Token::kCASCADE) {
init_expr = ParseCascades(init_expr);
}
receiver->set_invisible(false);
SetAllowFunctionLiterals(saved_mode);
Field& field = Field::ZoneHandle(cls.LookupInstanceField(field_name));
if (field.IsNull()) {
ErrorMsg(field_pos, "unresolved reference to instance field '%s'",
field_name.ToCString());
}
CheckDuplicateFieldInit(field_pos, initialized_fields, &field);
AstNode* instance = new LoadLocalNode(field_pos, receiver);
EnsureExpressionTemp();
return new StoreInstanceFieldNode(field_pos, instance, field, init_expr);
}
void Parser::CheckConstFieldsInitialized(const Class& cls) {
const Array& fields = Array::Handle(cls.fields());
Field& field = Field::Handle();
SequenceNode* initializers = current_block_->statements;
for (int field_num = 0; field_num < fields.Length(); field_num++) {
field ^= fields.At(field_num);
if (field.is_static()) {
continue;
}
bool found = false;
for (int i = 0; i < initializers->length(); i++) {
found = false;
if (initializers->NodeAt(i)->IsStoreInstanceFieldNode()) {
StoreInstanceFieldNode* initializer =
initializers->NodeAt(i)->AsStoreInstanceFieldNode();
if (initializer->field().raw() == field.raw()) {
found = true;
break;
}
}
}
if (found) continue;
if (field.is_final()) {
ErrorMsg("final field '%s' not initialized",
String::Handle(field.name()).ToCString());
} else {
field.UpdateCid(kNullCid);
}
}
}
AstNode* Parser::ParseExternalInitializedField(const Field& field) {
// Only use this function if the initialized field originates
// from a different class. We need to save and restore current
// class, library, and token stream (script).
ASSERT(current_class().raw() != field.origin());
const Class& saved_class = Class::Handle(current_class().raw());
const Library& saved_library = Library::Handle(library().raw());
const Script& saved_script = Script::Handle(script().raw());
const intptr_t saved_token_pos = TokenPos();
set_current_class(Class::Handle(field.origin()));
set_library(Library::Handle(current_class().library()));
SetScript(Script::Handle(current_class().script()), field.token_pos());
ASSERT(IsIdentifier());
ConsumeToken();
ExpectToken(Token::kASSIGN);
AstNode* init_expr = NULL;
if (field.is_const()) {
init_expr = ParseConstExpr();
} else {
init_expr = ParseExpr(kAllowConst, kConsumeCascades);
if (init_expr->EvalConstExpr() != NULL) {
init_expr =
new LiteralNode(field.token_pos(), EvaluateConstExpr(init_expr));
}
}
set_current_class(saved_class);
set_library(saved_library);
SetScript(saved_script, saved_token_pos);
return init_expr;
}
void Parser::ParseInitializedInstanceFields(const Class& cls,
LocalVariable* receiver,
GrowableArray<Field*>* initialized_fields) {
TRACE_PARSER("ParseInitializedInstanceFields");
const Array& fields = Array::Handle(cls.fields());
Field& f = Field::Handle();
const intptr_t saved_pos = TokenPos();
for (int i = 0; i < fields.Length(); i++) {
f ^= fields.At(i);
if (!f.is_static() && f.has_initializer()) {
Field& field = Field::ZoneHandle();
field ^= fields.At(i);
if (field.is_final()) {
// Final fields with initializer expression may not be initialized
// again by constructors. Remember that this field is already
// initialized.
initialized_fields->Add(&field);
}
AstNode* init_expr = NULL;
if (current_class().raw() != field.origin()) {
init_expr = ParseExternalInitializedField(field);
} else {
SetPosition(field.token_pos());
ASSERT(IsIdentifier());
ConsumeToken();
ExpectToken(Token::kASSIGN);
if (field.is_const()) {
init_expr = ParseConstExpr();
} else {
init_expr = ParseExpr(kAllowConst, kConsumeCascades);
if (init_expr->EvalConstExpr() != NULL) {
init_expr = new LiteralNode(field.token_pos(),
EvaluateConstExpr(init_expr));
}
}
}
ASSERT(init_expr != NULL);
AstNode* instance = new LoadLocalNode(field.token_pos(), receiver);
EnsureExpressionTemp();
AstNode* field_init =
new StoreInstanceFieldNode(field.token_pos(),
instance,
field,
init_expr);
current_block_->statements->Add(field_init);
}
}
SetPosition(saved_pos);
}
void Parser::CheckDuplicateFieldInit(intptr_t init_pos,
GrowableArray<Field*>* initialized_fields,
Field* field) {
ASSERT(!field->is_static());
for (int i = 0; i < initialized_fields->length(); i++) {
Field* initialized_field = (*initialized_fields)[i];
if (initialized_field->raw() == field->raw()) {
ErrorMsg(init_pos,
"duplicate initialization for field %s",
String::Handle(field->name()).ToCString());
}
}
initialized_fields->Add(field);
}
void Parser::ParseInitializers(const Class& cls,
LocalVariable* receiver,
GrowableArray<Field*>* initialized_fields) {
TRACE_PARSER("ParseInitializers");
bool super_init_seen = false;
if (CurrentToken() == Token::kCOLON) {
if ((LookaheadToken(1) == Token::kTHIS) &&
((LookaheadToken(2) == Token::kLPAREN) ||
((LookaheadToken(2) == Token::kPERIOD) &&
(LookaheadToken(4) == Token::kLPAREN)))) {
// Either we see this(...) or this.xxx(...) which is a
// redirected constructor. We don't need to check whether
// const fields are initialized. The other constructor will
// guarantee that.
ConsumeToken(); // Colon.
ParseConstructorRedirection(cls, receiver);
return;
}
do {
ConsumeToken(); // Colon or comma.
AstNode* init_statement;
if (CurrentToken() == Token::kSUPER) {
if (super_init_seen) {
ErrorMsg("duplicate call to super constructor");
}
init_statement = ParseSuperInitializer(cls, receiver);
super_init_seen = true;
} else {
init_statement = ParseInitializer(cls, receiver, initialized_fields);
}
current_block_->statements->Add(init_statement);
} while (CurrentToken() == Token::kCOMMA);
}
if (!super_init_seen) {
// Generate implicit super() if we haven't seen an explicit super call
// or constructor redirection.
GenerateSuperConstructorCall(cls, receiver);
}
CheckConstFieldsInitialized(cls);
}
void Parser::ParseConstructorRedirection(const Class& cls,
LocalVariable* receiver) {
TRACE_PARSER("ParseConstructorRedirection");
ASSERT(CurrentToken() == Token::kTHIS);
const intptr_t call_pos = TokenPos();
ConsumeToken();
String& ctor_name = String::Handle(cls.Name());
ctor_name = String::Concat(ctor_name, Symbols::Dot());
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ctor_name = String::Concat(ctor_name,
*ExpectIdentifier("constructor name expected"));
}
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("parameter list expected");
}
ArgumentListNode* arguments = new ArgumentListNode(call_pos);
// 'this' parameter is the first argument to constructor.
AstNode* implicit_argument = new LoadLocalNode(call_pos, receiver);
arguments->Add(implicit_argument);
// Construction phase parameter is second argument.
LocalVariable* phase_param = LookupPhaseParameter();
ASSERT(phase_param != NULL);
AstNode* phase_argument = new LoadLocalNode(call_pos, phase_param);
arguments->Add(phase_argument);
receiver->set_invisible(true);
ParseActualParameters(arguments, kAllowConst);
receiver->set_invisible(false);
// Resolve the constructor.
const Function& redirect_ctor = Function::ZoneHandle(
cls.LookupConstructor(ctor_name));
if (redirect_ctor.IsNull()) {
ErrorMsg(call_pos, "constructor '%s' not found", ctor_name.ToCString());
}
String& error_message = String::Handle();
if (!redirect_ctor.AreValidArguments(arguments->length(),
arguments->names(),
&error_message)) {
ErrorMsg(call_pos,
"invalid arguments passed to constructor '%s': %s",
ctor_name.ToCString(),
error_message.ToCString());
}
current_block_->statements->Add(
new StaticCallNode(call_pos, redirect_ctor, arguments));
}
SequenceNode* Parser::MakeImplicitConstructor(const Function& func) {
ASSERT(func.IsConstructor());
const intptr_t ctor_pos = TokenPos();
OpenFunctionBlock(func);
const Class& cls = Class::Handle(func.Owner());
LocalVariable* receiver = new LocalVariable(
ctor_pos,
Symbols::This(),
Type::ZoneHandle(Type::DynamicType()));
current_block_->scope->AddVariable(receiver);
LocalVariable* phase_parameter = new LocalVariable(
ctor_pos,
Symbols::PhaseParameter(),
Type::ZoneHandle(Type::SmiType()));
current_block_->scope->AddVariable(phase_parameter);
// Parse expressions of instance fields that have an explicit
// initializer expression.
// The receiver must not be visible to field initializer expressions.
receiver->set_invisible(true);
GrowableArray<Field*> initialized_fields;
ParseInitializedInstanceFields(cls, receiver, &initialized_fields);
receiver->set_invisible(false);
GenerateSuperConstructorCall(cls, receiver);
CheckConstFieldsInitialized(cls);
// Empty constructor body.
SequenceNode* statements = CloseBlock();
return statements;
}
// Helper function to make the first num_variables variables in the
// given scope visible/invisible.
static void SetInvisible(LocalScope* scope, int num_variables, bool invisible) {
ASSERT(num_variables <= scope->num_variables());
for (int i = 0; i < num_variables; i++) {
scope->VariableAt(i)->set_invisible(invisible);
}
}
// Parser is at the opening parenthesis of the formal parameter declaration
// of function. Parse the formal parameters, initializers and code.
SequenceNode* Parser::ParseConstructor(const Function& func,
Array& default_parameter_values) {
TRACE_PARSER("ParseConstructor");
ASSERT(func.IsConstructor());
ASSERT(!func.IsFactory());
ASSERT(!func.is_static());
ASSERT(!func.IsLocalFunction());
const Class& cls = Class::Handle(func.Owner());
ASSERT(!cls.IsNull());
if (func.IsImplicitConstructor()) {
// Special case: implicit constructor.
// The parser adds an implicit default constructor when a class
// does not have any explicit constructor or factory (see
// Parser::AddImplicitConstructor).
// There is no source text to parse. We just build the
// sequence node by hand.
return MakeImplicitConstructor(func);
}
OpenFunctionBlock(func);
ParamList params;
const bool allow_explicit_default_values = true;
ASSERT(CurrentToken() == Token::kLPAREN);
// Add implicit receiver parameter which is passed the allocated
// but uninitialized instance to construct.
ASSERT(current_class().raw() == func.Owner());
params.AddReceiver(ReceiverType(TokenPos()));
// Add implicit parameter for construction phase.
params.AddFinalParameter(
TokenPos(),
&Symbols::PhaseParameter(),
&Type::ZoneHandle(Type::SmiType()));
if (func.is_const()) {
params.SetImplicitlyFinal();
}
ParseFormalParameterList(allow_explicit_default_values, &params);
SetupDefaultsForOptionalParams(&params, default_parameter_values);
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
ASSERT(func.NumParameters() == params.parameters->length());
// Now populate function scope with the formal parameters.
AddFormalParamsToScope(&params, current_block_->scope);
// Initialize instance fields that have an explicit initializer expression.
// The formal parameter names must not be visible to the instance
// field initializer expressions, yet the parameters must be added to
// the scope so the expressions use the correct offsets for 'this' when
// storing values. We make the formal parameters temporarily invisible
// while parsing the instance field initializer expressions.
SetInvisible(current_block_->scope, params.parameters->length(), true);
GrowableArray<Field*> initialized_fields;
LocalVariable* receiver = current_block_->scope->VariableAt(0);
OpenBlock();
ParseInitializedInstanceFields(cls, receiver, &initialized_fields);
// Make the parameters (which are in the outer scope) visible again.
SetInvisible(current_block_->scope->parent(),
params.parameters->length(), false);
// Turn formal field parameters into field initializers or report error
// if the function is not a constructor.
if (params.has_field_initializer) {
for (int i = 0; i < params.parameters->length(); i++) {
ParamDesc& param = (*params.parameters)[i];
if (param.is_field_initializer) {
const String& field_name = *param.name;
Field& field = Field::ZoneHandle(cls.LookupInstanceField(field_name));
if (field.IsNull()) {
ErrorMsg(param.name_pos,
"unresolved reference to instance field '%s'",
field_name.ToCString());
}
CheckDuplicateFieldInit(param.name_pos, &initialized_fields, &field);
AstNode* instance = new LoadLocalNode(param.name_pos, receiver);
LocalVariable* p =
current_block_->scope->LookupVariable(*param.name, false);
ASSERT(p != NULL);
// Initializing formals cannot be used in the explicit initializer
// list, nor can they be used in the constructor body.
// Thus, make the parameter invisible.
p->set_invisible(true);
AstNode* value = new LoadLocalNode(param.name_pos, p);
EnsureExpressionTemp();
AstNode* initializer = new StoreInstanceFieldNode(
param.name_pos, instance, field, value);
current_block_->statements->Add(initializer);
}
}
}
// Now parse the explicit initializer list or constructor redirection.
ParseInitializers(cls, receiver, &initialized_fields);
SequenceNode* init_statements = CloseBlock();
if (init_statements->length() > 0) {
// Generate guard around the initializer code.
LocalVariable* phase_param = LookupPhaseParameter();
AstNode* phase_value = new LoadLocalNode(TokenPos(), phase_param);
AstNode* phase_check = new BinaryOpNode(
TokenPos(), Token::kBIT_AND, phase_value,
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseInit))));
AstNode* comparison =
new ComparisonNode(TokenPos(), Token::kNE_STRICT,
phase_check,
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(0))));
AstNode* guarded_init_statements =
new IfNode(TokenPos(), comparison, init_statements, NULL);
current_block_->statements->Add(guarded_init_statements);
}
// Parsing of initializers done. Now we parse the constructor body
// and add the implicit super call to the super constructor's body
// if necessary.
StaticCallNode* super_call = NULL;
// Look for the super initializer call in the sequence of initializer
// statements. If it exists and is not the last initializer statement,
// we need to create an implicit super call to the super constructor's
// body.
// Thus, iterate over all but the last initializer to see whether
// it's a super constructor call.
for (int i = 0; i < init_statements->length() - 1; i++) {
if (init_statements->NodeAt(i)->IsStaticCallNode()) {
StaticCallNode* static_call =
init_statements->NodeAt(i)->AsStaticCallNode();
if (static_call->function().IsConstructor()) {
super_call = static_call;
break;
}
}
}
if (super_call != NULL) {
// Generate an implicit call to the super constructor's body.
// We need to patch the super _initializer_ call so that it
// saves the evaluated actual arguments in temporary variables.
// The temporary variables are necessary so that the argument
// expressions are not evaluated twice.
ArgumentListNode* ctor_args = super_call->arguments();
// The super initializer call has at least 2 arguments: the
// implicit receiver, and the hidden construction phase.
ASSERT(ctor_args->length() >= 2);
for (int i = 2; i < ctor_args->length(); i++) {
AstNode* arg = ctor_args->NodeAt(i);
if (!IsSimpleLocalOrLiteralNode(arg)) {
LocalVariable* temp =
CreateTempConstVariable(arg->token_pos(), "sca");
AstNode* save_temp = new StoreLocalNode(arg->token_pos(), temp, arg);
ctor_args->SetNodeAt(i, save_temp);
}
}
}
OpenBlock(); // Block to collect constructor body nodes.
// Insert the implicit super call to the super constructor body.
if (super_call != NULL) {
ArgumentListNode* initializer_args = super_call->arguments();
const Function& super_ctor = super_call->function();
// Patch the initializer call so it only executes the super initializer.
initializer_args->SetNodeAt(1,
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseInit))));
ArgumentListNode* super_call_args = new ArgumentListNode(TokenPos());
// First argument is the receiver.
super_call_args->Add(new LoadLocalNode(TokenPos(), receiver));
// Second argument is the construction phase argument.
AstNode* phase_parameter =
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseBody)));
super_call_args->Add(phase_parameter);
super_call_args->set_names(initializer_args->names());
for (int i = 2; i < initializer_args->length(); i++) {
AstNode* arg = initializer_args->NodeAt(i);
if (arg->IsLiteralNode()) {
LiteralNode* lit = arg->AsLiteralNode();
super_call_args->Add(new LiteralNode(TokenPos(), lit->literal()));
} else {
ASSERT(arg->IsLoadLocalNode() || arg->IsStoreLocalNode());
if (arg->IsLoadLocalNode()) {
const LocalVariable& temp = arg->AsLoadLocalNode()->local();
super_call_args->Add(new LoadLocalNode(TokenPos(), &temp));
} else if (arg->IsStoreLocalNode()) {
const LocalVariable& temp = arg->AsStoreLocalNode()->local();
super_call_args->Add(new LoadLocalNode(TokenPos(), &temp));
}
}
}
ASSERT(super_ctor.AreValidArguments(super_call_args->length(),
super_call_args->names(),
NULL));
current_block_->statements->Add(
new StaticCallNode(TokenPos(), super_ctor, super_call_args));
}
if (CurrentToken() == Token::kLBRACE) {
ConsumeToken();
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
} else if (CurrentToken() == Token::kARROW) {
ErrorMsg("constructors may not return a value");
} else if (IsLiteral("native")) {
ErrorMsg("native constructors not supported");
} else if (CurrentToken() == Token::kSEMICOLON) {
// Some constructors have no function body.
ConsumeToken();
} else {
UnexpectedToken();
}
SequenceNode* ctor_block = CloseBlock();
if (ctor_block->length() > 0) {
// Generate guard around the constructor body code.
LocalVariable* phase_param = LookupPhaseParameter();
AstNode* phase_value = new LoadLocalNode(TokenPos(), phase_param);
AstNode* phase_check =
new BinaryOpNode(TokenPos(), Token::kBIT_AND,
phase_value,
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(Function::kCtorPhaseBody))));
AstNode* comparison =
new ComparisonNode(TokenPos(), Token::kNE_STRICT,
phase_check,
new LiteralNode(TokenPos(),
Smi::ZoneHandle(Smi::New(0))));
AstNode* guarded_block_statements =
new IfNode(TokenPos(), comparison, ctor_block, NULL);
current_block_->statements->Add(guarded_block_statements);
}
SequenceNode* statements = CloseBlock();
return statements;
}
// Parser is at the opening parenthesis of the formal parameter
// declaration of the function or constructor.
// Parse the formal parameters and code.
SequenceNode* Parser::ParseFunc(const Function& func,
Array& default_parameter_values) {
TRACE_PARSER("ParseFunc");
Function& saved_innermost_function =
Function::Handle(innermost_function().raw());
innermost_function_ = func.raw();
// Check to ensure we don't have classes with native fields in libraries
// which do not have a native resolver. This check is delayed until the class
// is actually used. Invocation of a function in the class is the first point
// of use. Access of const static fields in the class do not trigger an error.
if (current_class().num_native_fields() != 0) {
const Library& lib = Library::Handle(current_class().library());
if (lib.native_entry_resolver() == NULL) {
const String& cls_name = String::Handle(current_class().Name());
const String& lib_name = String::Handle(lib.url());
ErrorMsg(current_class().token_pos(),
"class '%s' is trying to extend a native fields class, "
"but library '%s' has no native resolvers",
cls_name.ToCString(), lib_name.ToCString());
}
}
if (func.IsConstructor()) {
SequenceNode* statements = ParseConstructor(func, default_parameter_values);
innermost_function_ = saved_innermost_function.raw();
return statements;
}
ASSERT(!func.IsConstructor());
OpenFunctionBlock(func); // Build local scope for function.
ParamList params;
// An instance closure function may capture and access the receiver, but via
// the context and not via the first formal parameter.
if (func.IsClosureFunction()) {
// The first parameter of a closure function is the closure object.
ASSERT(!func.is_const()); // Closure functions cannot be const.
params.AddFinalParameter(
TokenPos(),
&Symbols::ClosureParameter(),
&Type::ZoneHandle(Type::DynamicType()));
} else if (!func.is_static()) {
// Static functions do not have a receiver.
ASSERT(current_class().raw() == func.Owner());
params.AddReceiver(ReceiverType(TokenPos()));
} else if (func.IsFactory()) {
// The first parameter of a factory is the AbstractTypeArguments vector of
// the type of the instance to be allocated.
params.AddFinalParameter(
TokenPos(),
&Symbols::TypeArgumentsParameter(),
&Type::ZoneHandle(Type::DynamicType()));
}
ASSERT((CurrentToken() == Token::kLPAREN) || func.IsGetterFunction());
const bool allow_explicit_default_values = true;
if (!func.IsGetterFunction()) {
ParseFormalParameterList(allow_explicit_default_values, &params);
} else {
// TODO(hausner): Remove this once we no longer support the old
// getter syntax with explicit empty parameter list.
if (CurrentToken() == Token::kLPAREN) {
ConsumeToken();
ExpectToken(Token::kRPAREN);
}
}
// The number of parameters and their type are not yet set in local functions,
// since they are not 'top-level' parsed.
if (func.IsLocalFunction()) {
AddFormalParamsToFunction(&params, func);
}
SetupDefaultsForOptionalParams(&params, default_parameter_values);
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
ASSERT(func.NumParameters() == params.parameters->length());
// Check whether the function has any field initializer formal parameters,
// which are not allowed in non-constructor functions.
if (params.has_field_initializer) {
for (int i = 0; i < params.parameters->length(); i++) {
ParamDesc& param = (*params.parameters)[i];
if (param.is_field_initializer) {
ErrorMsg(param.name_pos,
"field initializer only allowed in constructors");
}
}
}
// Populate function scope with the formal parameters.
AddFormalParamsToScope(&params, current_block_->scope);
if (FLAG_enable_type_checks &&
(current_block_->scope->function_level() > 0)) {
// We are parsing, but not compiling, a local function.
// The instantiator may be required at run time for generic type checks.
if (IsInstantiatorRequired()) {
// Make sure that the receiver of the enclosing instance function
// (or implicit first parameter of an enclosing factory) is marked as
// captured if type checks are enabled, because they may access it to
// instantiate types.
CaptureInstantiator();
}
}
OpenBlock(); // Open a nested scope for the outermost function block.
if (CurrentToken() == Token::kLBRACE) {
ConsumeToken();
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
} else if (CurrentToken() == Token::kARROW) {
ConsumeToken();
const intptr_t expr_pos = TokenPos();
AstNode* expr = ParseExpr(kAllowConst, kConsumeCascades);
ASSERT(expr != NULL);
current_block_->statements->Add(new ReturnNode(expr_pos, expr));
} else if (IsLiteral("native")) {
ParseNativeFunctionBlock(&params, func);
} else if (func.is_external()) {
// Body of an external method contains a single throw.
const String& function_name = String::ZoneHandle(func.name());
// TODO(regis): For an instance function, pass the receiver to
// NoSuchMethodError.
current_block_->statements->Add(
ThrowNoSuchMethodError(TokenPos(),
current_class(),
function_name,
func.is_static() ?
InvocationMirror::kStatic :
InvocationMirror::kDynamic,
InvocationMirror::kMethod));
} else {
UnexpectedToken();
}
SequenceNode* body = CloseBlock();
current_block_->statements->Add(body);
innermost_function_ = saved_innermost_function.raw();
return CloseBlock();
}
void Parser::SkipIf(Token::Kind token) {
if (CurrentToken() == token) {
ConsumeToken();
}
}
// Skips tokens up to matching closing parenthesis.
void Parser::SkipToMatchingParenthesis() {
ASSERT(CurrentToken() == Token::kLPAREN);
int level = 0;
do {
if (CurrentToken() == Token::kLPAREN) {
level++;
} else if (CurrentToken() == Token::kRPAREN) {
level--;
}
ConsumeToken();
} while ((level > 0) && (CurrentToken() != Token::kEOS));
}
void Parser::SkipInitializers() {
ASSERT(CurrentToken() == Token::kCOLON);
do {
ConsumeToken(); // Colon or comma.
if (CurrentToken() == Token::kSUPER) {
ConsumeToken();
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("identifier expected");
}
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
SkipToMatchingParenthesis();
} else {
SkipIf(Token::kTHIS);
SkipIf(Token::kPERIOD);
ExpectIdentifier("identifier expected");
ExpectToken(Token::kASSIGN);
SetAllowFunctionLiterals(false);
SkipExpr();
SetAllowFunctionLiterals(true);
}
} while (CurrentToken() == Token::kCOMMA);
}
void Parser::ParseQualIdent(QualIdent* qual_ident) {
TRACE_PARSER("ParseQualIdent");
ASSERT(IsIdentifier());
ASSERT(!current_class().IsNull());
qual_ident->ident_pos = TokenPos();
qual_ident->ident = CurrentLiteral();
qual_ident->lib_prefix = NULL;
ConsumeToken();
if (CurrentToken() == Token::kPERIOD) {
// An identifier cannot be resolved in a local scope when top level parsing.
if (is_top_level_ ||
!ResolveIdentInLocalScope(qual_ident->ident_pos,
*(qual_ident->ident),
NULL)) {
LibraryPrefix& lib_prefix = LibraryPrefix::ZoneHandle();
lib_prefix = current_class().LookupLibraryPrefix(*(qual_ident->ident));
if (!lib_prefix.IsNull()) {
// We have a library prefix qualified identifier, unless the prefix is
// shadowed by a type parameter in scope.
if (current_class().IsNull() ||
(current_class().LookupTypeParameter(*(qual_ident->ident),
TokenPos()) ==
TypeParameter::null())) {
ConsumeToken(); // Consume the kPERIOD token.
qual_ident->lib_prefix = &lib_prefix;
qual_ident->ident_pos = TokenPos();
qual_ident->ident =
ExpectIdentifier("identifier expected after '.'");
}
}
}
}
}
void Parser::ParseMethodOrConstructor(ClassDesc* members, MemberDesc* method) {
TRACE_PARSER("ParseMethodOrConstructor");
ASSERT(CurrentToken() == Token::kLPAREN || method->IsGetter());
intptr_t method_pos = this->TokenPos();
ASSERT(method->type != NULL);
ASSERT(method->name_pos > 0);
ASSERT(current_member_ == method);
if (method->has_var) {
ErrorMsg(method->name_pos, "keyword var not allowed for methods");
}
if (method->has_final) {
ErrorMsg(method->name_pos, "'final' not allowed for methods");
}
if (method->has_abstract && method->has_static) {
ErrorMsg(method->name_pos,
"static method '%s' cannot be abstract",
method->name->ToCString());
}
if (method->has_const && !method->IsFactoryOrConstructor()) {
ErrorMsg(method->name_pos, "'const' not allowed for methods");
}
if (method->has_abstract && method->IsFactoryOrConstructor()) {
ErrorMsg(method->name_pos, "constructor cannot be abstract");
}
if (method->has_const && method->IsConstructor()) {
Class& cls = Class::Handle(library_.LookupClass(members->class_name()));
cls.set_is_const();
}
// Parse the formal parameters.
const bool are_implicitly_final = method->has_const;
const bool allow_explicit_default_values = true;
const intptr_t formal_param_pos = TokenPos();
method->params.Clear();
// Static functions do not have a receiver.
// The first parameter of a factory is the AbstractTypeArguments vector of
// the type of the instance to be allocated.
if (!method->has_static || method->IsConstructor()) {
method->params.AddReceiver(ReceiverType(formal_param_pos));
} else if (method->IsFactory()) {
method->params.AddFinalParameter(
formal_param_pos,
&Symbols::TypeArgumentsParameter(),
&Type::ZoneHandle(Type::DynamicType()));
}
// Constructors have an implicit parameter for the construction phase.
if (method->IsConstructor()) {
method->params.AddFinalParameter(
TokenPos(),
&Symbols::PhaseParameter(),
&Type::ZoneHandle(Type::SmiType()));
}
if (are_implicitly_final) {
method->params.SetImplicitlyFinal();
}
if (!method->IsGetter()) {
ParseFormalParameterList(allow_explicit_default_values, &method->params);
}
// Now that we know the parameter list, we can distinguish between the
// unary and binary operator -.
if (method->has_operator) {
if ((method->operator_token == Token::kSUB) &&
(method->params.num_fixed_parameters == 1)) {
// Patch up name for unary operator - so it does not clash with the
// name for binary operator -.
method->operator_token = Token::kNEGATE;
*method->name = Symbols::New(Token::Str(Token::kNEGATE));
}
CheckOperatorArity(*method);
}
if (members->FunctionNameExists(*method->name, method->kind)) {
ErrorMsg(method->name_pos,
"field or method '%s' already defined", method->name->ToCString());
}
// Mangle the name for getter and setter functions and check function
// arity.
if (method->IsGetter() || method->IsSetter()) {
int expected_num_parameters = 0;
if (method->IsGetter()) {
expected_num_parameters = (method->has_static) ? 0 : 1;
method->name = &String::ZoneHandle(Field::GetterSymbol(*method->name));
} else {
ASSERT(method->IsSetter());
expected_num_parameters = (method->has_static) ? 1 : 2;
method->name = &String::ZoneHandle(Field::SetterSymbol(*method->name));
}
if ((method->params.num_fixed_parameters != expected_num_parameters) ||
(method->params.num_optional_parameters != 0)) {
ErrorMsg(method->name_pos, "illegal %s parameters",
method->IsGetter() ? "getter" : "setter");
}
}
// Parse redirecting factory constructor.
Type& redirection_type = Type::Handle();
String& redirection_identifier = String::Handle();
if (method->IsFactory() && (CurrentToken() == Token::kASSIGN)) {
ConsumeToken();
const intptr_t type_pos = TokenPos();
const AbstractType& type = AbstractType::Handle(
ParseType(ClassFinalizer::kTryResolve));
if (!type.IsMalformed() &&
(type.IsTypeParameter() || type.IsDynamicType())) {
// Replace the type with a malformed type and compile a throw when called.
redirection_type = ClassFinalizer::NewFinalizedMalformedType(
Error::Handle(), // No previous error.
current_class(),
type_pos,
ClassFinalizer::kTryResolve, // No compile-time error.
"factory '%s' may not redirect to %s'%s'",
method->name->ToCString(),
type.IsTypeParameter() ? "type parameter " : "",
type.IsTypeParameter() ?
String::Handle(type.UserVisibleName()).ToCString() : "dynamic");
} else {
redirection_type ^= type.raw();
}
if (CurrentToken() == Token::kPERIOD) {
// Named constructor or factory.
ConsumeToken();
redirection_identifier = ExpectIdentifier("identifier expected")->raw();
}
} else if (CurrentToken() == Token::kCOLON) {
// Parse initializers.
if (!method->IsConstructor()) {
ErrorMsg("initializers only allowed on constructors");
}
if ((LookaheadToken(1) == Token::kTHIS) &&
((LookaheadToken(2) == Token::kLPAREN) ||
LookaheadToken(4) == Token::kLPAREN)) {
// Redirected constructor: either this(...) or this.xxx(...).
if (method->params.has_field_initializer) {
// Constructors that redirect to another constructor must not
// initialize any fields using field initializer parameters.
ErrorMsg(formal_param_pos, "Redirecting constructor "
"may not use field initializer parameters");
}
ConsumeToken(); // Colon.
ExpectToken(Token::kTHIS);
String& redir_name = String::ZoneHandle(
String::Concat(members->class_name(), Symbols::Dot()));
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
redir_name = String::Concat(redir_name,
*ExpectIdentifier("constructor name expected"));
}
method->redirect_name = &redir_name;
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
SkipToMatchingParenthesis();
} else {
SkipInitializers();
}
}
// Only constructors can redirect to another method.
ASSERT((method->redirect_name == NULL) || method->IsConstructor());
intptr_t method_end_pos = method_pos;
if ((CurrentToken() == Token::kLBRACE) ||
(CurrentToken() == Token::kARROW)) {
if (method->has_abstract) {
ErrorMsg(method->name_pos,
"abstract method '%s' may not have a function body",
method->name->ToCString());
} else if (method->has_external) {
ErrorMsg(method->name_pos,
"external method '%s' may not have a function body",
method->name->ToCString());
} else if (method->IsFactoryOrConstructor() && method->has_const) {
ErrorMsg(method->name_pos,
"const constructor or factory '%s' may not have a function body",
method->name->ToCString());
}
if (method->redirect_name != NULL) {
ErrorMsg(method->name_pos,
"Constructor with redirection may not have a function body");
}
if (CurrentToken() == Token::kLBRACE) {
SkipBlock();
} else {
ConsumeToken();
SkipExpr();
ExpectSemicolon();
}
method_end_pos = TokenPos() - 1;
} else if (IsLiteral("native")) {
if (method->has_abstract) {
ErrorMsg(method->name_pos,
"abstract method '%s' may not have a function body",
method->name->ToCString());
} else if (method->IsFactoryOrConstructor() && method->has_const) {
ErrorMsg(method->name_pos,
"const constructor or factory '%s' may not be native",
method->name->ToCString());
}
if (method->redirect_name != NULL) {
ErrorMsg(method->name_pos,
"Constructor with redirection may not have a function body");
}
ParseNativeDeclaration();
} else {
// We haven't found a method body. Issue error if one is required.
const bool must_have_body =
method->has_static &&
!method->has_external &&
redirection_type.IsNull();
if (must_have_body) {
ErrorMsg(method->name_pos,
"function body expected for method '%s'",
method->name->ToCString());
}
if (CurrentToken() == Token::kSEMICOLON) {
ConsumeToken();
if (!method->has_static &&
!method->has_external &&
!method->IsConstructor()) {
// Methods, getters and setters without a body are
// implicitly abstract.
method->has_abstract = true;
}
} else {
// Signature is not followed by semicolon or body. Issue an
// appropriate error.
const bool must_have_semicolon =
(method->redirect_name != NULL) ||
(method->IsConstructor() && method->has_const) ||
method->has_external;
if (must_have_semicolon) {
ExpectSemicolon();
} else {
ErrorMsg(method->name_pos,
"function body or semicolon expected for method '%s'",
method->name->ToCString());
}
}
}
RawFunction::Kind function_kind;
if (method->IsFactoryOrConstructor()) {
function_kind = RawFunction::kConstructor;
} else if (method->IsGetter()) {
function_kind = RawFunction::kGetterFunction;
} else if (method->IsSetter()) {
function_kind = RawFunction::kSetterFunction;
} else {
function_kind = RawFunction::kRegularFunction;
}
Function& func = Function::Handle(
Function::New(*method->name,
function_kind,
method->has_static,
method->has_const,
method->has_abstract,
method->has_external,
current_class(),
method_pos));
func.set_result_type(*method->type);
func.set_end_token_pos(method_end_pos);
// If this method is a redirecting factory, set the redirection information.
if (!redirection_type.IsNull()) {
ASSERT(func.IsFactory());
func.SetRedirectionType(redirection_type);
if (!redirection_identifier.IsNull()) {
func.SetRedirectionIdentifier(redirection_identifier);
}
}
// No need to resolve parameter types yet, or add parameters to local scope.
ASSERT(is_top_level_);
AddFormalParamsToFunction(&method->params, func);
members->AddFunction(func);
}
void Parser::ParseFieldDefinition(ClassDesc* members, MemberDesc* field) {
TRACE_PARSER("ParseFieldDefinition");
// The parser has read the first field name and is now at the token
// after the field name.
ASSERT(CurrentToken() == Token::kSEMICOLON ||
CurrentToken() == Token::kCOMMA ||
CurrentToken() == Token::kASSIGN);
ASSERT(field->type != NULL);
ASSERT(field->name_pos > 0);
ASSERT(current_member_ == field);
// All const fields are also final.
ASSERT(!field->has_const || field->has_final);
if (field->has_abstract) {
ErrorMsg("keyword 'abstract' not allowed in field declaration");
}
if (field->has_external) {
ErrorMsg("keyword 'external' not allowed in field declaration");
}
if (field->has_factory) {
ErrorMsg("keyword 'factory' not allowed in field declaration");
}
if (members->FieldNameExists(*field->name, !field->has_final)) {
ErrorMsg(field->name_pos,
"'%s' field/method already defined\n", field->name->ToCString());
}
Function& getter = Function::Handle();
Function& setter = Function::Handle();
Field& class_field = Field::Handle();
Instance& init_value = Instance::Handle();
while (true) {
bool has_initializer = CurrentToken() == Token::kASSIGN;
bool has_simple_literal = false;
if (has_initializer) {
ConsumeToken();
init_value = Object::sentinel().raw();
// For static const fields, the initialization expression
// will be parsed through the kConstImplicitGetter method
// invocation/compilation.
// For instance fields, the expression is parsed when a constructor
// is compiled.
// For static fields with very simple initializer expressions
// (e.g. a literal number or string) we optimize away the
// kConstImplicitGetter and initialize the field here.
if (field->has_static && (field->has_final || field->has_const) &&
(LookaheadToken(1) == Token::kSEMICOLON)) {
has_simple_literal = IsSimpleLiteral(*field->type, &init_value);
}
SkipExpr();
} else {
if (field->has_const || (field->has_static && field->has_final)) {
ErrorMsg(field->name_pos,
"%s%s field '%s' must have an initializer expression",
field->has_static ? "static " : "",
field->has_const ? "const" : "final",
field->name->ToCString());
}
}
// Create the field object.
class_field = Field::New(*field->name,
field->has_static,
field->has_final,
field->has_const,
current_class(),
field->name_pos);
class_field.set_type(*field->type);
class_field.set_has_initializer(has_initializer);
members->AddField(class_field);
// For static const fields, set value to "uninitialized" and
// create a kConstImplicitGetter getter method.
if (field->has_static && has_initializer) {
class_field.set_value(init_value);
if (!has_simple_literal) {
String& getter_name = String::Handle(Field::GetterSymbol(*field->name));
getter = Function::New(getter_name,
RawFunction::kConstImplicitGetter,
field->has_static,
field->has_const,
/* is_abstract = */ false,
/* is_external = */ false,
current_class(),
field->name_pos);
getter.set_result_type(*field->type);
members->AddFunction(getter);
}
}
// For instance fields, we create implicit getter and setter methods.
if (!field->has_static) {
String& getter_name = String::Handle(Field::GetterSymbol(*field->name));
getter = Function::New(getter_name, RawFunction::kImplicitGetter,
field->has_static,
field->has_final,
/* is_abstract = */ false,
/* is_external = */ false,
current_class(),
field->name_pos);
ParamList params;
ASSERT(current_class().raw() == getter.Owner());
params.AddReceiver(ReceiverType(TokenPos()));
getter.set_result_type(*field->type);
AddFormalParamsToFunction(&params, getter);
members->AddFunction(getter);
if (!field->has_final) {
// Build a setter accessor for non-const fields.
String& setter_name = String::Handle(Field::SetterSymbol(*field->name));
setter = Function::New(setter_name, RawFunction::kImplicitSetter,
field->has_static,
field->has_final,
/* is_abstract = */ false,
/* is_external = */ false,
current_class(),
field->name_pos);
ParamList params;
ASSERT(current_class().raw() == setter.Owner());
params.AddReceiver(ReceiverType(TokenPos()));
params.AddFinalParameter(TokenPos(),
&Symbols::Value(),
field->type);
setter.set_result_type(Type::Handle(Type::VoidType()));
AddFormalParamsToFunction(&params, setter);
members->AddFunction(setter);
}
}
if (CurrentToken() != Token::kCOMMA) {
break;
}
ConsumeToken();
field->name_pos = this->TokenPos();
field->name = ExpectIdentifier("field name expected");
}
ExpectSemicolon();
}
void Parser::CheckOperatorArity(const MemberDesc& member) {
intptr_t expected_num_parameters; // Includes receiver.
Token::Kind op = member.operator_token;
if (op == Token::kASSIGN_INDEX) {
expected_num_parameters = 3;
} else if ((op == Token::kBIT_NOT) || (op == Token::kNEGATE)) {
expected_num_parameters = 1;
} else {
expected_num_parameters = 2;
}
if ((member.params.num_optional_parameters > 0) ||
member.params.has_optional_positional_parameters ||
member.params.has_optional_named_parameters ||
(member.params.num_fixed_parameters != expected_num_parameters)) {
// Subtract receiver when reporting number of expected arguments.
ErrorMsg(member.name_pos, "operator %s expects %"Pd" argument(s)",
member.name->ToCString(), (expected_num_parameters - 1));
}
}
void Parser::ParseClassMemberDefinition(ClassDesc* members) {
TRACE_PARSER("ParseClassMemberDefinition");
MemberDesc member;
current_member_ = &member;
if ((CurrentToken() == Token::kEXTERNAL) &&
(LookaheadToken(1) != Token::kLPAREN)) {
ConsumeToken();
member.has_external = true;
}
if ((CurrentToken() == Token::kSTATIC) &&
(LookaheadToken(1) != Token::kLPAREN)) {
ConsumeToken();
member.has_static = true;
}
if (CurrentToken() == Token::kCONST) {
ConsumeToken();
member.has_const = true;
} else if (CurrentToken() == Token::kFINAL) {
ConsumeToken();
member.has_final = true;
}
if (CurrentToken() == Token::kVAR) {
if (member.has_const) {
ErrorMsg("identifier expected after 'const'");
}
if (member.has_final) {
ErrorMsg("identifier expected after 'final'");
}
ConsumeToken();
member.has_var = true;
// The member type is the 'dynamic' type.
member.type = &Type::ZoneHandle(Type::DynamicType());
} else if (CurrentToken() == Token::kFACTORY) {
ConsumeToken();
if (member.has_static) {
ErrorMsg("factory method cannot be explicitly marked static");
}
member.has_factory = true;
member.has_static = true;
// The result type depends on the name of the factory method.
}
// Optionally parse a type.
if (CurrentToken() == Token::kVOID) {
if (member.has_var || member.has_factory) {
ErrorMsg("void not expected");
}
ConsumeToken();
ASSERT(member.type == NULL);
member.type = &Type::ZoneHandle(Type::VoidType());
} else if (CurrentToken() == Token::kIDENT) {
// This is either a type name or the name of a method/constructor/field.
if ((member.type == NULL) && !member.has_factory) {
// We have not seen a member type yet, so we check if the next
// identifier could represent a type before parsing it.
Token::Kind follower = LookaheadToken(1);
// We have an identifier followed by a 'follower' token.
// We either parse a type or assume that no type is specified.
if ((follower == Token::kLT) || // Parameterized type.
(follower == Token::kGET) || // Getter following a type.
(follower == Token::kSET) || // Setter following a type.
(follower == Token::kOPERATOR) || // Operator following a type.
(Token::IsIdentifier(follower)) || // Member name following a type.
((follower == Token::kPERIOD) && // Qualified class name of type,
(LookaheadToken(3) != Token::kLPAREN))) { // but not a named constr.
ASSERT(is_top_level_);
// The declared type of fields is never ignored, even in unchecked mode,
// because getters and setters could be closurized at some time (not
// supported yet).
member.type = &AbstractType::ZoneHandle(
ParseType(ClassFinalizer::kTryResolve));
}
}
}
// Optionally parse a (possibly named) constructor name or factory.
if (IsIdentifier() &&
(CurrentLiteral()->Equals(members->class_name()) || member.has_factory)) {
member.name_pos = TokenPos();
member.name = CurrentLiteral(); // Unqualified identifier.
ConsumeToken();
if (member.has_factory) {
// The factory name may be qualified, but the first identifier must match
// the name of the immediately enclosing class.
if (!member.name->Equals(members->class_name())) {
ErrorMsg(member.name_pos, "factory name must be '%s'",
members->class_name().ToCString());
}
// Do not bypass class resolution by using current_class() directly, since
// it may be a patch class.
const Object& result_type_class = Object::Handle(
UnresolvedClass::New(LibraryPrefix::Handle(),
*member.name,
member.name_pos));
// The type arguments of the result type are the type parameters of the
// current class. Note that in the case of a patch class, they are copied
// from the class being patched.
member.type = &Type::ZoneHandle(Type::New(
result_type_class,
TypeArguments::Handle(current_class().type_parameters()),
member.name_pos));
} else if (member.has_static) {
ErrorMsg(member.name_pos, "constructor cannot be static");
}
// We must be dealing with a constructor or named constructor.
member.kind = RawFunction::kConstructor;
*member.name = String::Concat(*member.name, Symbols::Dot());
if (CurrentToken() == Token::kPERIOD) {
// Named constructor.
ConsumeToken();
member.constructor_name = ExpectIdentifier("identifier expected");
*member.name = String::Concat(*member.name, *member.constructor_name);
}
// Ensure that names are symbols.
*member.name = Symbols::New(*member.name);
if (member.type == NULL) {
ASSERT(!member.has_factory);
// The body of the constructor cannot modify the type arguments of the
// constructed instance, which is passed in as a hidden parameter.
// Therefore, there is no need to set the result type to be checked.
member.type = &Type::ZoneHandle(Type::DynamicType());
} else {
// The type can only be already set in the factory case.
if (!member.has_factory) {
ErrorMsg(member.name_pos, "constructor must not specify return type");
}
}
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("left parenthesis expected");
}
} else if ((CurrentToken() == Token::kGET) && !member.has_var &&
(LookaheadToken(1) != Token::kLPAREN) &&
(LookaheadToken(1) != Token::kASSIGN) &&
(LookaheadToken(1) != Token::kCOMMA) &&
(LookaheadToken(1) != Token::kSEMICOLON)) {
ConsumeToken();
member.kind = RawFunction::kGetterFunction;
member.name_pos = this->TokenPos();
member.name = ExpectIdentifier("identifier expected");
// If the result type was not specified, it will be set to DynamicType.
} else if ((CurrentToken() == Token::kSET) && !member.has_var &&
(LookaheadToken(1) != Token::kLPAREN) &&
(LookaheadToken(1) != Token::kASSIGN) &&
(LookaheadToken(1) != Token::kCOMMA) &&
(LookaheadToken(1) != Token::kSEMICOLON)) {
ConsumeToken();
member.kind = RawFunction::kSetterFunction;
member.name_pos = this->TokenPos();
member.name = ExpectIdentifier("identifier expected");
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
// The grammar allows a return type, so member.type is not always NULL here.
// If no return type is specified, the return type of the setter is dynamic.
if (member.type == NULL) {
member.type = &Type::ZoneHandle(Type::DynamicType());
}
} else if ((CurrentToken() == Token::kOPERATOR) && !member.has_var &&
(LookaheadToken(1) != Token::kLPAREN) &&
(LookaheadToken(1) != Token::kASSIGN) &&
(LookaheadToken(1) != Token::kCOMMA) &&
(LookaheadToken(1) != Token::kSEMICOLON)) {
ConsumeToken();
if (!Token::CanBeOverloaded(CurrentToken())) {
ErrorMsg("invalid operator overloading");
}
if (member.has_static) {
ErrorMsg("operator overloading functions cannot be static");
}
member.operator_token = CurrentToken();
member.has_operator = true;
member.kind = RawFunction::kRegularFunction;
member.name_pos = this->TokenPos();
member.name =
&String::ZoneHandle(Symbols::New(Token::Str(member.operator_token)));
ConsumeToken();
} else if (IsIdentifier()) {
member.name = CurrentLiteral();
member.name_pos = TokenPos();
ConsumeToken();
} else {
ErrorMsg("identifier expected");
}
ASSERT(member.name != NULL);
if (CurrentToken() == Token::kLPAREN || member.IsGetter()) {
// Constructor or method.
if (member.type == NULL) {
member.type = &Type::ZoneHandle(Type::DynamicType());
}
ASSERT(member.IsFactory() == member.has_factory);
ParseMethodOrConstructor(members, &member);
} else if (CurrentToken() == Token::kSEMICOLON ||
CurrentToken() == Token::kCOMMA ||
CurrentToken() == Token::kASSIGN) {
// Field definition.
if (member.has_const) {
// const fields are implicitly final.
member.has_final = true;
}
if (member.type == NULL) {
if (member.has_final) {
member.type = &Type::ZoneHandle(Type::DynamicType());
} else {
ErrorMsg("missing 'var', 'final', 'const' or type"
" in field declaration");
}
}
ParseFieldDefinition(members, &member);
} else {
UnexpectedToken();
}
current_member_ = NULL;
members->AddMember(member);
}
void Parser::ParseClassDefinition(const GrowableObjectArray& pending_classes) {
TRACE_PARSER("ParseClassDefinition");
bool is_patch = false;
bool is_abstract = false;
if (is_patch_source() &&
(CurrentToken() == Token::kIDENT) &&
CurrentLiteral()->Equals("patch")) {
ConsumeToken();
is_patch = true;
} else if (CurrentToken() == Token::kABSTRACT) {
is_abstract = true;
ConsumeToken();
}
const intptr_t class_pos = TokenPos();
ExpectToken(Token::kCLASS);
const intptr_t classname_pos = TokenPos();
String& class_name = *ExpectUserDefinedTypeIdentifier("class name expected");
if (FLAG_trace_parser) {
OS::Print("TopLevel parsing class '%s'\n", class_name.ToCString());
}
Class& cls = Class::Handle();
TypeArguments& orig_type_parameters = TypeArguments::Handle();
Object& obj = Object::Handle(library_.LookupLocalObject(class_name));
if (obj.IsNull()) {
if (is_patch) {
ErrorMsg(classname_pos, "missing class '%s' cannot be patched",
class_name.ToCString());
}
cls = Class::New(class_name, script_, classname_pos);
library_.AddClass(cls);
} else {
if (!obj.IsClass()) {
ErrorMsg(classname_pos, "'%s' is already defined",
class_name.ToCString());
}
cls ^= obj.raw();
if (is_patch) {
// Preserve and reuse the original type parameters and bounds since the
// ones defined in the patch class will not be finalized.
orig_type_parameters = cls.type_parameters();
// A patch class must be given the same name as the class it is patching,
// otherwise the generic signature classes it defines will not match the
// patched generic signature classes. Therefore, new signature classes
// will be introduced and the original ones will not get finalized.
cls = Class::New(class_name, script_, classname_pos);
cls.set_library(library_);
} else {
// Not patching a class, but it has been found. This must be one of the
// pre-registered classes from object.cc or a duplicate definition.
if (cls.functions() != Object::empty_array().raw()) {
ErrorMsg(classname_pos, "class '%s' is already defined",
class_name.ToCString());
}
// Pre-registered classes need their scripts connected at this time.
cls.set_script(script_);
}
}
ASSERT(!cls.IsNull());
ASSERT(cls.functions() == Object::empty_array().raw());
set_current_class(cls);
ParseTypeParameters(cls);
if (is_patch) {
// Check that the new type parameters are identical to the original ones.
const TypeArguments& new_type_parameters =
TypeArguments::Handle(cls.type_parameters());
const int new_type_params_count =
new_type_parameters.IsNull() ? 0 : new_type_parameters.Length();
const int orig_type_params_count =
orig_type_parameters.IsNull() ? 0 : orig_type_parameters.Length();
if (new_type_params_count != orig_type_params_count) {
ErrorMsg(classname_pos,
"class '%s' must be patched with identical type parameters",
class_name.ToCString());
}
TypeParameter& new_type_param = TypeParameter::Handle();
TypeParameter& orig_type_param = TypeParameter::Handle();
String& new_name = String::Handle();
String& orig_name = String::Handle();
for (int i = 0; i < new_type_params_count; i++) {
new_type_param ^= new_type_parameters.TypeAt(i);
orig_type_param ^= orig_type_parameters.TypeAt(i);
new_name = new_type_param.name();
orig_name = orig_type_param.name();
if (!new_name.Equals(orig_name)) {
ErrorMsg(new_type_param.token_pos(),
"type parameter '%s' of patch class '%s' does not match "
"original type parameter '%s'",
new_name.ToCString(),
class_name.ToCString(),
orig_name.ToCString());
}
// We do not check that the bounds are repeated. We use the original ones.
// TODO(regis): Should we check?
}
cls.set_type_parameters(orig_type_parameters);
}
AbstractType& super_type = Type::Handle();
if (CurrentToken() == Token::kEXTENDS) {
ConsumeToken();
const intptr_t type_pos = TokenPos();
super_type = ParseType(ClassFinalizer::kTryResolve);
if (super_type.IsTypeParameter()) {
ErrorMsg(type_pos,
"class '%s' may not extend type parameter '%s'",
class_name.ToCString(),
String::Handle(super_type.UserVisibleName()).ToCString());
}
if (super_type.IsDynamicType()) {
ErrorMsg(type_pos,
"class '%s' may not extend 'dynamic'",
class_name.ToCString());
}
if (CurrentToken() == Token::kWITH) {
super_type = ParseMixins(super_type);
}
} else {
// No extends clause: implicitly extend Object.
super_type = Type::ObjectType();
}
ASSERT(!super_type.IsNull());
cls.set_super_type(super_type);
if (CurrentToken() == Token::kIMPLEMENTS) {
ParseInterfaceList(cls);
}
ExpectToken(Token::kLBRACE);
ClassDesc members(cls, class_name, false, class_pos);
while (CurrentToken() != Token::kRBRACE) {
SkipMetadata();
ParseClassMemberDefinition(&members);
}
ExpectToken(Token::kRBRACE);
if (is_abstract) {
cls.set_is_abstract();
}
CheckConstructors(&members);
// Need to compute this here since MakeArray() will clear the
// functions array in members.
const bool need_implicit_constructor =
!members.has_constructor() && !is_patch;
Array& array = Array::Handle();
array = Array::MakeArray(members.fields());
cls.SetFields(array);
// Creating a new array for functions marks the class as parsed.
array = Array::MakeArray(members.functions());
cls.SetFunctions(array);
// Add an implicit constructor if no explicit constructor is present.
// No implicit constructors are needed for patch classes.
if (need_implicit_constructor) {
AddImplicitConstructor(cls);
}
if (!is_patch) {
pending_classes.Add(cls, Heap::kOld);
} else {
// Apply the changes to the patched class looked up above.
ASSERT(obj.raw() == library_.LookupLocalObject(class_name));
// The patched class must not be finalized yet.
ASSERT(!Class::Cast(obj).is_finalized());
const char* err_msg = Class::Cast(obj).ApplyPatch(cls);
if (err_msg != NULL) {
ErrorMsg(classname_pos, "applying patch failed with '%s'", err_msg);
}
}
}
// Add an implicit constructor to the given class.
void Parser::AddImplicitConstructor(const Class& cls) {
// The implicit constructor is unnamed, has no explicit parameter.
String& ctor_name = String::ZoneHandle(cls.Name());
ctor_name = String::Concat(ctor_name, Symbols::Dot());
ctor_name = Symbols::New(ctor_name);
// To indicate that this is an implicit constructor, we set the
// token position is the same as the token position of the class.
Function& ctor = Function::Handle(
Function::New(ctor_name,
RawFunction::kConstructor,
/* is_static = */ false,
/* is_const = */ false,
/* is_abstract = */ false,
/* is_external = */ false,
cls,
cls.token_pos()));
ParamList params;
// Add implicit 'this' parameter. We don't care about the specific type
// and just specify dynamic.
const Type& receiver_type = Type::Handle(Type::DynamicType());
params.AddReceiver(&receiver_type);
// Add implicit parameter for construction phase.
params.AddFinalParameter(cls.token_pos(),
&Symbols::PhaseParameter(),
&Type::ZoneHandle(Type::SmiType()));
AddFormalParamsToFunction(&params, ctor);
// The body of the constructor cannot modify the type of the constructed
// instance, which is passed in as the receiver.
ctor.set_result_type(receiver_type);
cls.AddFunction(ctor);
}
// Check for cycles in constructor redirection. Also check whether a
// named constructor collides with the name of another class member.
void Parser::CheckConstructors(ClassDesc* class_desc) {
// Check for cycles in constructor redirection.
const GrowableArray<MemberDesc>& members = class_desc->members();
for (int i = 0; i < members.length(); i++) {
MemberDesc* member = &members[i];
if (member->constructor_name != NULL) {
// Check whether constructor name conflicts with a member name.
if (class_desc->FunctionNameExists(
*member->constructor_name, member->kind)) {
ErrorMsg(member->name_pos,
"Named constructor '%s' conflicts with method or field '%s'",
member->name->ToCString(),
member->constructor_name->ToCString());
}
}
GrowableArray<MemberDesc*> ctors;
while ((member != NULL) && (member->redirect_name != NULL)) {
ASSERT(member->IsConstructor());
// Check whether we have already seen this member.
for (int i = 0; i < ctors.length(); i++) {
if (ctors[i] == member) {
ErrorMsg(member->name_pos,
"cyclic reference in constructor redirection");
}
}
// We haven't seen this member. Add it to the list and follow
// the next redirection. If we can't find the constructor to
// which the current one redirects, we ignore the unresolved
// reference. We'll catch it later when the constructor gets
// compiled.
ctors.Add(member);
member = class_desc->LookupMember(*member->redirect_name);
}
}
}
void Parser::ParseMixinTypedef(const GrowableObjectArray& pending_classes) {
TRACE_PARSER("ParseMixinTypedef");
const intptr_t classname_pos = TokenPos();
String& class_name = *ExpectUserDefinedTypeIdentifier("class name expected");
if (FLAG_trace_parser) {
OS::Print("toplevel parsing typedef class '%s'\n", class_name.ToCString());
}
const Object& obj = Object::Handle(library_.LookupLocalObject(class_name));
if (!obj.IsNull()) {
ErrorMsg(classname_pos, "'%s' is already defined",
class_name.ToCString());
}
const Class& mixin_application =
Class::Handle(Class::New(class_name, script_, classname_pos));
library_.AddClass(mixin_application);
set_current_class(mixin_application);
ParseTypeParameters(mixin_application);
ExpectToken(Token::kASSIGN);
if (CurrentToken() == Token::kABSTRACT) {
mixin_application.set_is_abstract();
ConsumeToken();
}
const intptr_t type_pos = TokenPos();
AbstractType& type =
AbstractType::Handle(ParseType(ClassFinalizer::kTryResolve));
if (type.IsTypeParameter()) {
ErrorMsg(type_pos,
"class '%s' may not extend type parameter '%s'",
class_name.ToCString(),
String::Handle(type.UserVisibleName()).ToCString());
}
if (CurrentToken() != Token::kWITH) {
ErrorMsg("mixin application 'with Type' expected");
}
type = ParseMixins(type);
// TODO(hausner): treat the mixin application as an alias, not as a base
// class whose super class is the mixin application!
mixin_application.set_super_type(type);
AddImplicitConstructor(mixin_application);
if (CurrentToken() == Token::kIMPLEMENTS) {
ParseInterfaceList(mixin_application);
}
ExpectSemicolon();
pending_classes.Add(mixin_application, Heap::kOld);
}
// Look ahead to detect if we are seeing ident [ TypeParameters ] "(".
// We need this lookahead to distinguish between the optional return type
// and the alias name of a function type alias.
// Token position remains unchanged.
bool Parser::IsFunctionTypeAliasName() {
if (IsIdentifier() && (LookaheadToken(1) == Token::kLPAREN)) {
return true;
}
const intptr_t saved_pos = TokenPos();
bool is_alias_name = false;
if (IsIdentifier() && (LookaheadToken(1) == Token::kLT)) {
ConsumeToken();
if (TryParseTypeParameter() && (CurrentToken() == Token::kLPAREN)) {
is_alias_name = true;
}
}
SetPosition(saved_pos);
return is_alias_name;
}
// Look ahead to detect if we are seeing ident [ TypeParameters ] "=".
// Token position remains unchanged.
bool Parser::IsMixinTypedef() {
if (IsIdentifier() && (LookaheadToken(1) == Token::kASSIGN)) {
return true;
}
const intptr_t saved_pos = TokenPos();
bool is_mixin_def = false;
if (IsIdentifier() && (LookaheadToken(1) == Token::kLT)) {
ConsumeToken();
if (TryParseTypeParameter() && (CurrentToken() == Token::kASSIGN)) {
is_mixin_def = true;
}
}
SetPosition(saved_pos);
return is_mixin_def;
}
void Parser::ParseTypedef(const GrowableObjectArray& pending_classes) {
TRACE_PARSER("ParseTypedef");
ExpectToken(Token::kTYPEDEF);
if (IsMixinTypedef()) {
ParseMixinTypedef(pending_classes);
return;
}
// Parse the result type of the function type.
AbstractType& result_type = Type::Handle(Type::DynamicType());
if (CurrentToken() == Token::kVOID) {
ConsumeToken();
result_type = Type::VoidType();
} else if (!IsFunctionTypeAliasName()) {
// Type annotations in typedef are never ignored, even in unchecked mode.
// Wait until we have an owner class before resolving the result type.
result_type = ParseType(ClassFinalizer::kDoNotResolve);
}
const intptr_t alias_name_pos = TokenPos();
const String* alias_name =
ExpectUserDefinedTypeIdentifier("function alias name expected");
// Lookup alias name and report an error if it is already defined in
// the library scope.
const Object& obj = Object::Handle(library_.LookupLocalObject(*alias_name));
if (!obj.IsNull()) {
ErrorMsg(alias_name_pos,
"'%s' is already defined", alias_name->ToCString());
}
// Create the function type alias signature class. It will be linked to its
// signature function after it has been parsed. The type parameters, in order
// to be properly finalized, need to be associated to this signature class as
// they are parsed.
const Class& function_type_alias = Class::Handle(
Class::NewSignatureClass(*alias_name,
Function::Handle(),
script_,
alias_name_pos));
library_.AddClass(function_type_alias);
set_current_class(function_type_alias);
// Parse the type parameters of the function type.
ParseTypeParameters(function_type_alias);
// At this point, the type parameters have been parsed, so we can resolve the
// result type.
if (!result_type.IsNull()) {
ResolveTypeFromClass(function_type_alias,
ClassFinalizer::kTryResolve,
&result_type);
}
// Parse the formal parameters of the function type.
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("formal parameter list expected");
}
ParamList func_params;
// Add implicit closure object parameter.
func_params.AddFinalParameter(
TokenPos(),
&Symbols::ClosureParameter(),
&Type::ZoneHandle(Type::DynamicType()));
const bool no_explicit_default_values = false;
ParseFormalParameterList(no_explicit_default_values, &func_params);
ExpectSemicolon();
// The field 'is_static' has no meaning for signature functions.
Function& signature_function = Function::Handle(
Function::New(*alias_name,
RawFunction::kSignatureFunction,
/* is_static = */ false,
/* is_const = */ false,
/* is_abstract = */ false,
/* is_external = */ false,
function_type_alias,
alias_name_pos));
signature_function.set_result_type(result_type);
AddFormalParamsToFunction(&func_params, signature_function);
// Patch the signature function in the signature class.
function_type_alias.PatchSignatureFunction(signature_function);
const String& signature = String::Handle(signature_function.Signature());
if (FLAG_trace_parser) {
OS::Print("TopLevel parsing function type alias '%s'\n",
signature.ToCString());
}
// Lookup the signature class, i.e. the class whose name is the signature.
// We only lookup in the current library, but not in its imports, and only
// create a new canonical signature class if it does not exist yet.
Class& signature_class = Class::ZoneHandle(
library_.LookupLocalClass(signature));
if (signature_class.IsNull()) {
signature_class = Class::NewSignatureClass(signature,
signature_function,
script_,
alias_name_pos);
// Record the function signature class in the current library.
library_.AddClass(signature_class);
} else {
// Forget the just created signature function and use the existing one.
signature_function = signature_class.signature_function();
function_type_alias.PatchSignatureFunction(signature_function);
}
ASSERT(signature_function.signature_class() == signature_class.raw());
// The alias should not be marked as finalized yet, since it needs to be
// checked in the class finalizer for illegal self references.
ASSERT(!function_type_alias.IsCanonicalSignatureClass());
ASSERT(!function_type_alias.is_finalized());
pending_classes.Add(function_type_alias, Heap::kOld);
}
// Consumes exactly one right angle bracket. If the current token is a single
// bracket token, it is consumed normally. However, if it is a double or triple
// bracket, it is replaced by a single or double bracket token without
// incrementing the token index.
void Parser::ConsumeRightAngleBracket() {
if (token_kind_ == Token::kGT) {
ConsumeToken();
} else if (token_kind_ == Token::kSHR) {
token_kind_ = Token::kGT;
} else {
UNREACHABLE();
}
}
void Parser::SkipMetadata() {
while (CurrentToken() == Token::kAT) {
ConsumeToken();
ExpectIdentifier("identifier expected");
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("identifier expected");
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("identifier expected");
}
}
if (CurrentToken() == Token::kLPAREN) {
SkipToMatchingParenthesis();
}
}
}
void Parser::SkipTypeArguments() {
if (CurrentToken() == Token::kLT) {
do {
ConsumeToken();
SkipType(false);
} while (CurrentToken() == Token::kCOMMA);
Token::Kind token = CurrentToken();
if ((token == Token::kGT) || (token == Token::kSHR)) {
ConsumeRightAngleBracket();
} else {
ErrorMsg("right angle bracket expected");
}
}
}
void Parser::SkipType(bool allow_void) {
if (CurrentToken() == Token::kVOID) {
if (!allow_void) {
ErrorMsg("'void' not allowed here");
}
ConsumeToken();
} else {
ExpectIdentifier("type name expected");
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("name expected");
}
SkipTypeArguments();
}
}
void Parser::ParseTypeParameters(const Class& cls) {
TRACE_PARSER("ParseTypeParameters");
if (CurrentToken() == Token::kLT) {
Isolate* isolate = Isolate::Current();
const GrowableObjectArray& type_parameters_array =
GrowableObjectArray::Handle(GrowableObjectArray::New());
intptr_t index = 0;
TypeParameter& type_parameter = TypeParameter::Handle();
TypeParameter& existing_type_parameter = TypeParameter::Handle();
String& existing_type_parameter_name = String::Handle();
AbstractType& type_parameter_bound = Type::Handle();
do {
ConsumeToken();
SkipMetadata();
const intptr_t type_parameter_pos = TokenPos();
String& type_parameter_name =
*ExpectUserDefinedTypeIdentifier("type parameter expected");
// Check for duplicate type parameters.
for (intptr_t i = 0; i < index; i++) {
existing_type_parameter ^= type_parameters_array.At(i);
existing_type_parameter_name = existing_type_parameter.name();
if (existing_type_parameter_name.Equals(type_parameter_name)) {
ErrorMsg(type_parameter_pos, "duplicate type parameter '%s'",
type_parameter_name.ToCString());
}
}
if (CurrentToken() == Token::kEXTENDS) {
ConsumeToken();
// A bound may refer to the owner of the type parameter it applies to,
// i.e. to the class or interface currently being parsed.
// Postpone resolution in order to avoid resolving the class and its
// type parameters, as they are not fully parsed yet.
type_parameter_bound = ParseType(ClassFinalizer::kDoNotResolve);
} else {
type_parameter_bound = isolate->object_store()->object_type();
}
type_parameter = TypeParameter::New(cls,
index,
type_parameter_name,
type_parameter_bound,
type_parameter_pos);
type_parameters_array.Add(type_parameter);
index++;
} while (CurrentToken() == Token::kCOMMA);
Token::Kind token = CurrentToken();
if ((token == Token::kGT) || (token == Token::kSHR)) {
ConsumeRightAngleBracket();
} else {
ErrorMsg("right angle bracket expected");
}
const TypeArguments& type_parameters =
TypeArguments::Handle(NewTypeArguments(type_parameters_array));
cls.set_type_parameters(type_parameters);
// Try to resolve the upper bounds, which will at least resolve the
// referenced type parameters.
const intptr_t num_types = type_parameters.Length();
for (intptr_t i = 0; i < num_types; i++) {
type_parameter ^= type_parameters.TypeAt(i);
type_parameter_bound = type_parameter.bound();
ResolveTypeFromClass(cls,
ClassFinalizer::kTryResolve,
&type_parameter_bound);
type_parameter.set_bound(type_parameter_bound);
}
}
}
RawAbstractTypeArguments* Parser::ParseTypeArguments(
Error* malformed_error,
ClassFinalizer::FinalizationKind finalization) {
TRACE_PARSER("ParseTypeArguments");
if (CurrentToken() == Token::kLT) {
const GrowableObjectArray& types =
GrowableObjectArray::Handle(GrowableObjectArray::New());
AbstractType& type = AbstractType::Handle();
do {
ConsumeToken();
type = ParseType(finalization);
// Only keep the error for the first malformed type argument.
if (malformed_error->IsNull() && type.IsMalformed()) {
*malformed_error = type.malformed_error();
}
// Map a malformed type argument to dynamic, so that malformed types with
// a resolved type class are handled properly in production mode.
if (type.IsMalformed()) {
ASSERT(finalization < ClassFinalizer::kCanonicalizeWellFormed);
type = Type::DynamicType();
}
types.Add(type);
} while (CurrentToken() == Token::kCOMMA);
Token::Kind token = CurrentToken();
if ((token == Token::kGT) || (token == Token::kSHR)) {
ConsumeRightAngleBracket();
} else {
ErrorMsg("right angle bracket expected");
}
if (finalization != ClassFinalizer::kIgnore) {
return NewTypeArguments(types);
}
}
return TypeArguments::null();
}
// Parse interface list and add to class cls.
void Parser::ParseInterfaceList(const Class& cls) {
TRACE_PARSER("ParseInterfaceList");
ASSERT(CurrentToken() == Token::kIMPLEMENTS);
const GrowableObjectArray& all_interfaces =
GrowableObjectArray::Handle(GrowableObjectArray::New());
AbstractType& interface = AbstractType::Handle();
// First get all the interfaces already implemented by class.
Array& cls_interfaces = Array::Handle(cls.interfaces());
for (intptr_t i = 0; i < cls_interfaces.Length(); i++) {
interface ^= cls_interfaces.At(i);
all_interfaces.Add(interface);
}
// Now parse and add the new interfaces.
do {
ConsumeToken();
intptr_t interface_pos = TokenPos();
interface = ParseType(ClassFinalizer::kTryResolve);
if (interface.IsTypeParameter()) {
ErrorMsg(interface_pos,
"type parameter '%s' may not be used in interface list",
String::Handle(interface.UserVisibleName()).ToCString());
}
if (interface.IsDynamicType()) {
ErrorMsg(interface_pos, "'dynamic' may not be used in interface list");
}
all_interfaces.Add(interface);
} while (CurrentToken() == Token::kCOMMA);
cls_interfaces = Array::MakeArray(all_interfaces);
cls.set_interfaces(cls_interfaces);
}
RawAbstractType* Parser::ParseMixins(const AbstractType& super_type) {
TRACE_PARSER("ParseMixins");
ASSERT(CurrentToken() == Token::kWITH);
const GrowableObjectArray& mixin_apps =
GrowableObjectArray::Handle(GrowableObjectArray::New());
AbstractType& mixin_type = AbstractType::Handle();
AbstractTypeArguments& mixin_type_arguments =
AbstractTypeArguments::Handle();
Class& mixin_application = Class::Handle();
Type& mixin_application_type = Type::Handle();
Type& mixin_super_type = Type::Handle();
ASSERT(super_type.IsType());
mixin_super_type ^= super_type.raw();
Array& mixin_application_interfaces = Array::Handle();
do {
ConsumeToken();
const intptr_t mixin_pos = TokenPos();
mixin_type = ParseType(ClassFinalizer::kTryResolve);
if (mixin_type.IsTypeParameter()) {
ErrorMsg(mixin_pos,
"mixin type '%s' may not be a type parameter",
String::Handle(mixin_type.UserVisibleName()).ToCString());
}
// The name of the mixin application class is a combination of
// the superclass and mixin class.
String& mixin_app_name = String::Handle();
mixin_app_name = mixin_super_type.ClassName();
mixin_app_name = String::Concat(mixin_app_name, Symbols::Ampersand());
mixin_app_name = String::Concat(mixin_app_name,
String::Handle(mixin_type.ClassName()));
mixin_app_name = Symbols::New(mixin_app_name);
mixin_application = Class::New(mixin_app_name, script_, mixin_pos);
mixin_application.set_super_type(mixin_super_type);
mixin_application.set_mixin(Type::Cast(mixin_type));
mixin_application.set_library(library_);
AddImplicitConstructor(mixin_application);
// Add the mixin type to the interfaces that the mixin application
// class implements. This is necessary so that type tests work.
mixin_application_interfaces = Array::New(1);
mixin_application_interfaces.SetAt(0, mixin_type);
mixin_application.set_interfaces(mixin_application_interfaces);
// For the type arguments of the mixin application type, we need
// a copy of the type arguments to the mixin type. The simplest way
// to get the copy is to rewind the parser, parse the mixin type
// again and steal its type arguments.
SetPosition(mixin_pos);
mixin_type = ParseType(ClassFinalizer::kTryResolve);
mixin_type_arguments = mixin_type.arguments();
mixin_application_type = Type::New(mixin_application,
mixin_type_arguments,
mixin_pos);
mixin_super_type = mixin_application_type.raw();
mixin_apps.Add(mixin_application_type);
} while (CurrentToken() == Token::kCOMMA);
return MixinAppType::New(super_type,
Array::Handle(Array::MakeArray(mixin_apps)));
}
void Parser::ParseTopLevelVariable(TopLevel* top_level) {
TRACE_PARSER("ParseTopLevelVariable");
const bool is_const = (CurrentToken() == Token::kCONST);
// Const fields are implicitly final.
const bool is_final = is_const || (CurrentToken() == Token::kFINAL);
const bool is_static = true;
const AbstractType& type =
AbstractType::ZoneHandle(ParseConstFinalVarOrType(
FLAG_enable_type_checks ? ClassFinalizer::kTryResolve :
ClassFinalizer::kIgnore));
Field& field = Field::Handle();
Function& getter = Function::Handle();
while (true) {
const intptr_t name_pos = TokenPos();
String& var_name = *ExpectIdentifier("variable name expected");
if (library_.LookupLocalObject(var_name) != Object::null()) {
ErrorMsg(name_pos, "'%s' is already defined", var_name.ToCString());
}
String& accessor_name = String::Handle(Field::GetterName(var_name));
if (library_.LookupLocalObject(accessor_name) != Object::null()) {
ErrorMsg(name_pos, "getter for '%s' is already defined",
var_name.ToCString());
}
// A const or final variable does not define an implicit setter,
// so we only check setters for non-final variables.
if (!is_final) {
accessor_name = Field::SetterName(var_name);
if (library_.LookupLocalObject(accessor_name) != Object::null()) {
ErrorMsg(name_pos, "setter for '%s' is already defined",
var_name.ToCString());
}
}
field = Field::New(var_name, is_static, is_final, is_const,
current_class(), name_pos);
field.set_type(type);
field.set_value(Instance::Handle(Instance::null()));
top_level->fields.Add(field);
library_.AddObject(field, var_name);
if (CurrentToken() == Token::kASSIGN) {
ConsumeToken();
Instance& field_value = Instance::Handle(Object::sentinel().raw());
bool has_simple_literal = false;
if (is_final && (LookaheadToken(1) == Token::kSEMICOLON)) {
has_simple_literal = IsSimpleLiteral(type, &field_value);
}
SkipExpr();
field.set_value(field_value);
if (!has_simple_literal) {
// Create a static const getter.
String& getter_name = String::ZoneHandle(Field::GetterSymbol(var_name));
getter = Function::New(getter_name,
RawFunction::kConstImplicitGetter,
is_static,
is_const,
/* is_abstract = */ false,
/* is_external = */ false,
current_class(),
name_pos);
getter.set_result_type(type);
top_level->functions.Add(getter);
}
} else if (is_final) {
ErrorMsg(name_pos, "missing initializer for final or const variable");
}
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
} else if (CurrentToken() == Token::kSEMICOLON) {
ConsumeToken();
break;
} else {
ExpectSemicolon(); // Reports error.
}
}
}
void Parser::ParseTopLevelFunction(TopLevel* top_level) {
TRACE_PARSER("ParseTopLevelFunction");
AbstractType& result_type = Type::Handle(Type::DynamicType());
const bool is_static = true;
bool is_external = false;
bool is_patch = false;
if (is_patch_source() &&
(CurrentToken() == Token::kIDENT) &&
CurrentLiteral()->Equals("patch") &&
(LookaheadToken(1) != Token::kLPAREN)) {
ConsumeToken();
is_patch = true;
} else if (CurrentToken() == Token::kEXTERNAL) {
ConsumeToken();
is_external = true;
}
if (CurrentToken() == Token::kVOID) {
ConsumeToken();
result_type = Type::VoidType();
} else {
// Parse optional type.
if ((CurrentToken() == Token::kIDENT) &&
(LookaheadToken(1) != Token::kLPAREN)) {
result_type = ParseType(ClassFinalizer::kTryResolve);
}
}
const intptr_t name_pos = TokenPos();
const String& func_name = *ExpectIdentifier("function name expected");
bool found = library_.LookupLocalObject(func_name) != Object::null();
if (found && !is_patch) {
ErrorMsg(name_pos, "'%s' is already defined", func_name.ToCString());
} else if (!found && is_patch) {
ErrorMsg(name_pos, "missing '%s' cannot be patched", func_name.ToCString());
}
String& accessor_name = String::Handle(Field::GetterName(func_name));
if (library_.LookupLocalObject(accessor_name) != Object::null()) {
ErrorMsg(name_pos, "'%s' is already defined as getter",
func_name.ToCString());
}
// A setter named x= may co-exist with a function named x, thus we do
// not need to check setters.
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
const intptr_t function_pos = TokenPos();
ParamList params;
const bool allow_explicit_default_values = true;
ParseFormalParameterList(allow_explicit_default_values, &params);
intptr_t function_end_pos = function_pos;
if (is_external) {
ExpectSemicolon();
} else if (CurrentToken() == Token::kLBRACE) {
SkipBlock();
function_end_pos = TokenPos() - 1;
} else if (CurrentToken() == Token::kARROW) {
ConsumeToken();
SkipExpr();
ExpectSemicolon();
function_end_pos = TokenPos() - 1;
} else if (IsLiteral("native")) {
ParseNativeDeclaration();
} else {
ErrorMsg("function block expected");
}
Function& func = Function::Handle(
Function::New(func_name,
RawFunction::kRegularFunction,
is_static,
/* is_const = */ false,
/* is_abstract = */ false,
is_external,
current_class(),
function_pos));
func.set_result_type(result_type);
func.set_end_token_pos(function_end_pos);
AddFormalParamsToFunction(&params, func);
top_level->functions.Add(func);
if (!is_patch) {
library_.AddObject(func, func_name);
} else {
library_.ReplaceObject(func, func_name);
}
}
void Parser::ParseTopLevelAccessor(TopLevel* top_level) {
TRACE_PARSER("ParseTopLevelAccessor");
const bool is_static = true;
bool is_external = false;
bool is_patch = false;
AbstractType& result_type = AbstractType::Handle();
if (is_patch_source() &&
(CurrentToken() == Token::kIDENT) &&
CurrentLiteral()->Equals("patch")) {
ConsumeToken();
is_patch = true;
} else if (CurrentToken() == Token::kEXTERNAL) {
ConsumeToken();
is_external = true;
}
bool is_getter = (CurrentToken() == Token::kGET);
if (CurrentToken() == Token::kGET ||
CurrentToken() == Token::kSET) {
ConsumeToken();
result_type = Type::DynamicType();
} else {
if (CurrentToken() == Token::kVOID) {
ConsumeToken();
result_type = Type::VoidType();
} else {
result_type = ParseType(ClassFinalizer::kTryResolve);
}
is_getter = (CurrentToken() == Token::kGET);
if (CurrentToken() == Token::kGET || CurrentToken() == Token::kSET) {
ConsumeToken();
} else {
UnexpectedToken();
}
}
const intptr_t name_pos = TokenPos();
const String* field_name = ExpectIdentifier("accessor name expected");
const intptr_t accessor_pos = TokenPos();
ParamList params;
if (!is_getter) {
const bool allow_explicit_default_values = true;
ParseFormalParameterList(allow_explicit_default_values, &params);
}
String& accessor_name = String::ZoneHandle();
int expected_num_parameters = -1;
if (is_getter) {
expected_num_parameters = 0;
accessor_name = Field::GetterSymbol(*field_name);
} else {
expected_num_parameters = 1;
accessor_name = Field::SetterSymbol(*field_name);
}
if ((params.num_fixed_parameters != expected_num_parameters) ||
(params.num_optional_parameters != 0)) {
ErrorMsg(name_pos, "illegal %s parameters",
is_getter ? "getter" : "setter");
}
if (is_getter && library_.LookupLocalObject(*field_name) != Object::null()) {
ErrorMsg(name_pos, "'%s' is already defined in this library",
field_name->ToCString());
}
if (!is_getter) {
// Check whether there is a field with the same name that has an implicit
// setter.
const Field& field = Field::Handle(library_.LookupLocalField(*field_name));
if (!field.IsNull() && !field.is_final()) {
ErrorMsg(name_pos, "Variable '%s' is already defined in this library",
field_name->ToCString());
}
}
bool found = library_.LookupLocalObject(accessor_name) != Object::null();
if (found && !is_patch) {
ErrorMsg(name_pos, "%s for '%s' is already defined",
is_getter ? "getter" : "setter",
field_name->ToCString());
} else if (!found && is_patch) {
ErrorMsg(name_pos, "missing %s for '%s' cannot be patched",
is_getter ? "getter" : "setter",
field_name->ToCString());
}
intptr_t accessor_end_pos = accessor_pos;
if (is_external) {
ExpectSemicolon();
} else if (CurrentToken() == Token::kLBRACE) {
SkipBlock();
accessor_end_pos = TokenPos() - 1;
} else if (CurrentToken() == Token::kARROW) {
ConsumeToken();
SkipExpr();
ExpectSemicolon();
accessor_end_pos = TokenPos() - 1;
} else if (IsLiteral("native")) {
ParseNativeDeclaration();
} else {
ErrorMsg("function block expected");
}
Function& func = Function::Handle(
Function::New(accessor_name,
is_getter? RawFunction::kGetterFunction :
RawFunction::kSetterFunction,
is_static,
/* is_const = */ false,
/* is_abstract = */ false,
is_external,
current_class(),
accessor_pos));
func.set_result_type(result_type);
func.set_end_token_pos(accessor_end_pos);
AddFormalParamsToFunction(&params, func);
top_level->functions.Add(func);
if (!is_patch) {
library_.AddObject(func, accessor_name);
} else {
library_.ReplaceObject(func, accessor_name);
}
}
RawObject* Parser::CallLibraryTagHandler(Dart_LibraryTag tag,
intptr_t token_pos,
const String& url) {
Isolate* isolate = Isolate::Current();
Dart_LibraryTagHandler handler = isolate->library_tag_handler();
if (handler == NULL) {
if (url.StartsWith(Symbols::DartScheme())) {
if (tag == kCanonicalizeUrl) {
return url.raw();
}
return Object::null();
}
ErrorMsg(token_pos, "no library handler registered");
}
Dart_Handle result = handler(tag,
Api::NewHandle(isolate, library_.raw()),
Api::NewHandle(isolate, url.raw()));
if (Dart_IsError(result)) {
// In case of an error we append an explanatory error message to the
// error obtained from the library tag handler.
Error& prev_error = Error::Handle();
prev_error ^= Api::UnwrapHandle(result);
AppendErrorMsg(prev_error, token_pos, "library handler failed");
}
if (tag == kCanonicalizeUrl) {
if (!Dart_IsString(result)) {
ErrorMsg(token_pos, "library handler failed URI canonicalization");
}
}
return Api::UnwrapHandle(result);
}
void Parser::ParseLibraryName() {
ASSERT(CurrentToken() == Token::kLIBRARY);
ConsumeToken();
String& lib_name = *ExpectIdentifier("library name expected");
if (CurrentToken() == Token::kPERIOD) {
while (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
lib_name = String::Concat(lib_name, Symbols::Dot());
lib_name = String::Concat(lib_name,
*ExpectIdentifier("malformed library name"));
}
lib_name = Symbols::New(lib_name);
}
library_.SetName(lib_name);
ExpectSemicolon();
}
void Parser::ParseIdentList(GrowableObjectArray* names) {
if (!IsIdentifier()) {
ErrorMsg("identifier expected");
}
while (IsIdentifier()) {
names->Add(*CurrentLiteral());
ConsumeToken(); // Identifier.
if (CurrentToken() != Token::kCOMMA) {
return;
}
ConsumeToken(); // Comma.
}
}
void Parser::ParseLibraryImportExport() {
bool is_import = (CurrentToken() == Token::kIMPORT);
bool is_export = (CurrentToken() == Token::kEXPORT);
ASSERT(is_import || is_export);
const intptr_t import_pos = TokenPos();
ConsumeToken();
if (CurrentToken() != Token::kSTRING) {
ErrorMsg("library url expected");
}
const String& url = *CurrentLiteral();
if (url.Length() == 0) {
ErrorMsg("library url expected");
}
ConsumeToken();
String& prefix = String::Handle();
if (is_import && IsLiteral("as")) {
ConsumeToken();
prefix = ExpectIdentifier("prefix identifier expected")->raw();
}
Array& show_names = Array::Handle();
Array& hide_names = Array::Handle();
if (IsLiteral("show") || IsLiteral("hide")) {
GrowableObjectArray& show_list =
GrowableObjectArray::Handle(GrowableObjectArray::New());
GrowableObjectArray& hide_list =
GrowableObjectArray::Handle(GrowableObjectArray::New());
for (;;) {
if (IsLiteral("show")) {
ConsumeToken();
ParseIdentList(&show_list);
} else if (IsLiteral("hide")) {
ConsumeToken();
ParseIdentList(&hide_list);
} else {
break;
}
}
if (show_list.Length() > 0) {
show_names = Array::MakeArray(show_list);
}
if (hide_list.Length() > 0) {
hide_names = Array::MakeArray(hide_list);
}
}
ExpectSemicolon();
// Canonicalize library URL.
const String& canon_url = String::CheckedHandle(
CallLibraryTagHandler(kCanonicalizeUrl, import_pos, url));
// Lookup the library URL.
Library& library = Library::Handle(Library::LookupLibrary(canon_url));
if (library.IsNull()) {
// Call the library tag handler to load the library.
CallLibraryTagHandler(kImportTag, import_pos, canon_url);
// If the library tag handler succeded without registering the
// library we create an empty library to import.
library = Library::LookupLibrary(canon_url);
if (library.IsNull()) {
library = Library::New(canon_url);
library.Register();
}
}
const Namespace& ns =
Namespace::Handle(Namespace::New(library, show_names, hide_names));
if (is_import) {
// Ensure that private dart:_ libraries are only imported into dart:
// libraries.
const String& lib_url = String::Handle(library_.url());
if (canon_url.StartsWith(Symbols::DartSchemePrivate()) &&
!lib_url.StartsWith(Symbols::DartScheme())) {
ErrorMsg(import_pos, "private library is not accessible");
}
if (prefix.IsNull() || (prefix.Length() == 0)) {
library_.AddImport(ns);
} else {
LibraryPrefix& library_prefix = LibraryPrefix::Handle();
library_prefix = library_.LookupLocalLibraryPrefix(prefix);
if (!library_prefix.IsNull()) {
library_prefix.AddImport(ns);
} else {
library_prefix = LibraryPrefix::New(prefix, ns);
library_.AddObject(library_prefix, prefix);
}
}
} else {
ASSERT(is_export);
library_.AddExport(ns);
}
}
void Parser::ParseLibraryPart() {
const intptr_t source_pos = TokenPos();
ConsumeToken(); // Consume "part".
if (CurrentToken() != Token::kSTRING) {
ErrorMsg("url expected");
}
const String& url = *CurrentLiteral();
ConsumeToken();
ExpectSemicolon();
const String& canon_url = String::CheckedHandle(
CallLibraryTagHandler(kCanonicalizeUrl, source_pos, url));
CallLibraryTagHandler(kSourceTag, source_pos, canon_url);
}
void Parser::ParseLibraryDefinition() {
TRACE_PARSER("ParseLibraryDefinition");
// Handle the script tag.
if (CurrentToken() == Token::kSCRIPTTAG) {
// Nothing to do for script tags except to skip them.
ConsumeToken();
}
ASSERT(script_.kind() != RawScript::kSourceTag);
// We may read metadata tokens that are part of the toplevel
// declaration that follows the library definitions. Therefore, we
// need to remember the position of the last token that was
// successfully consumed.
intptr_t metadata_pos = TokenPos();
SkipMetadata();
if (CurrentToken() == Token::kLIBRARY) {
if (is_patch_source()) {
ErrorMsg("patch cannot override library name");
}
ParseLibraryName();
metadata_pos = TokenPos();
SkipMetadata();
}
while ((CurrentToken() == Token::kIMPORT) ||
(CurrentToken() == Token::kEXPORT)) {
ParseLibraryImportExport();
metadata_pos = TokenPos();
SkipMetadata();
}
// Core lib has not been explicitly imported, so we implicitly
// import it here.
if (!library_.ImportsCorelib()) {
Library& core_lib = Library::Handle(Library::CoreLibrary());
ASSERT(!core_lib.IsNull());
const Namespace& core_ns = Namespace::Handle(
Namespace::New(core_lib, Array::Handle(), Array::Handle()));
library_.AddImport(core_ns);
}
while (CurrentToken() == Token::kPART) {
ParseLibraryPart();
metadata_pos = TokenPos();
SkipMetadata();
}
SetPosition(metadata_pos);
}
void Parser::ParsePartHeader() {
intptr_t metadata_pos = TokenPos();
SkipMetadata();
// TODO(hausner): Once support for old #source directive is removed
// from the compiler, add an error message here if we don't find
// a 'part of' directive.
if (CurrentToken() == Token::kPART) {
ConsumeToken();
if (!IsLiteral("of")) {
ErrorMsg("'part of' expected");
}
ConsumeToken();
// The VM is not required to check that the library name matches the
// name of the current library, so we ignore it.
ExpectIdentifier("library name expected");
while (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("malformed library name");
}
ExpectSemicolon();
} else {
SetPosition(metadata_pos);
}
}
void Parser::ParseTopLevel() {
TRACE_PARSER("ParseTopLevel");
// Collect the classes found at the top level in this growable array.
// They need to be registered with class finalization after parsing
// has been completed.
Isolate* isolate = Isolate::Current();
ObjectStore* object_store = isolate->object_store();
const GrowableObjectArray& pending_classes =
GrowableObjectArray::Handle(isolate, object_store->pending_classes());
SetPosition(0);
is_top_level_ = true;
TopLevel top_level;
Class& toplevel_class = Class::Handle(
Class::New(Symbols::TopLevel(), script_, TokenPos()));
toplevel_class.set_library(library_);
if (is_library_source() || is_patch_source()) {
ParseLibraryDefinition();
} else if (is_part_source()) {
ParsePartHeader();
}
while (true) {
set_current_class(Class::Handle()); // No current class.
SkipMetadata();
if (CurrentToken() == Token::kCLASS) {
ParseClassDefinition(pending_classes);
} else if ((CurrentToken() == Token::kTYPEDEF) &&
(LookaheadToken(1) != Token::kLPAREN)) {
set_current_class(toplevel_class);
ParseTypedef(pending_classes);
} else if ((CurrentToken() == Token::kABSTRACT) &&
(LookaheadToken(1) == Token::kCLASS)) {
ParseClassDefinition(pending_classes);
} else if (is_patch_source() && IsLiteral("patch") &&
(LookaheadToken(1) == Token::kCLASS)) {
ParseClassDefinition(pending_classes);
} else {
set_current_class(toplevel_class);
if (IsVariableDeclaration()) {
ParseTopLevelVariable(&top_level);
} else if (IsFunctionDeclaration()) {
ParseTopLevelFunction(&top_level);
} else if (IsTopLevelAccessor()) {
ParseTopLevelAccessor(&top_level);
} else if (CurrentToken() == Token::kEOS) {
break;
} else {
UnexpectedToken();
}
}
}
if ((top_level.fields.Length() > 0) || (top_level.functions.Length() > 0)) {
Array& array = Array::Handle();
array = Array::MakeArray(top_level.fields);
toplevel_class.SetFields(array);
array = Array::MakeArray(top_level.functions);
toplevel_class.SetFunctions(array);
library_.AddAnonymousClass(toplevel_class);
pending_classes.Add(toplevel_class, Heap::kOld);
}
}
void Parser::ChainNewBlock(LocalScope* outer_scope) {
Block* block = new Block(current_block_,
outer_scope,
new SequenceNode(TokenPos(), outer_scope));
current_block_ = block;
}
void Parser::OpenBlock() {
ASSERT(current_block_ != NULL);
LocalScope* outer_scope = current_block_->scope;
ChainNewBlock(new LocalScope(outer_scope,
outer_scope->function_level(),
outer_scope->loop_level()));
}
void Parser::OpenLoopBlock() {
ASSERT(current_block_ != NULL);
LocalScope* outer_scope = current_block_->scope;
ChainNewBlock(new LocalScope(outer_scope,
outer_scope->function_level(),
outer_scope->loop_level() + 1));
}
void Parser::OpenFunctionBlock(const Function& func) {
LocalScope* outer_scope;
if (current_block_ == NULL) {
if (!func.IsLocalFunction()) {
// We are compiling a non-nested function.
outer_scope = new LocalScope(NULL, 0, 0);
} else {
// We are compiling the function of an invoked closure.
// Restore the outer scope containing all captured variables.
const ContextScope& context_scope =
ContextScope::Handle(func.context_scope());
ASSERT(!context_scope.IsNull());
outer_scope =
new LocalScope(LocalScope::RestoreOuterScope(context_scope), 0, 0);
}
} else {
// We are parsing a nested function while compiling the enclosing function.
outer_scope = new LocalScope(current_block_->scope,
current_block_->scope->function_level() + 1,
0);
}
ChainNewBlock(outer_scope);
}
SequenceNode* Parser::CloseBlock() {
SequenceNode* statements = current_block_->statements;
if (current_block_->scope != NULL) {
// Record the begin and end token index of the scope.
ASSERT(statements != NULL);
current_block_->scope->set_begin_token_pos(statements->token_pos());
current_block_->scope->set_end_token_pos(TokenPos());
}
current_block_ = current_block_->parent;
return statements;
}
// Set up default values for all optional parameters to the function.
void Parser::SetupDefaultsForOptionalParams(const ParamList* params,
Array& default_values) {
if (params->num_optional_parameters > 0) {
// Build array of default parameter values.
ParamDesc* param =
params->parameters->data() + params->num_fixed_parameters;
default_values = Array::New(params->num_optional_parameters);
for (int i = 0; i < params->num_optional_parameters; i++) {
ASSERT(param->default_value != NULL);
default_values.SetAt(i, *param->default_value);
param++;
}
}
}
// Populate the parameter type array and parameter name array of the function
// with the formal parameter types and names.
void Parser::AddFormalParamsToFunction(const ParamList* params,
const Function& func) {
ASSERT((params != NULL) && (params->parameters != NULL));
ASSERT((params->num_optional_parameters > 0) ==
(params->has_optional_positional_parameters ||
params->has_optional_named_parameters));
if (!Utils::IsInt(16, params->num_fixed_parameters) ||
!Utils::IsInt(16, params->num_optional_parameters)) {
ErrorMsg("too many formal parameters");
}
func.set_num_fixed_parameters(params->num_fixed_parameters);
func.SetNumOptionalParameters(params->num_optional_parameters,
params->has_optional_positional_parameters);
const int num_parameters = params->parameters->length();
ASSERT(num_parameters == func.NumParameters());
func.set_parameter_types(Array::Handle(Array::New(num_parameters,
Heap::kOld)));
func.set_parameter_names(Array::Handle(Array::New(num_parameters,
Heap::kOld)));
for (int i = 0; i < num_parameters; i++) {
ParamDesc& param_desc = (*params->parameters)[i];
ASSERT(is_top_level_ || param_desc.type->IsResolved());
func.SetParameterTypeAt(i, *param_desc.type);
func.SetParameterNameAt(i, *param_desc.name);
}
}
// Populate local scope with the formal parameters.
void Parser::AddFormalParamsToScope(const ParamList* params,
LocalScope* scope) {
ASSERT((params != NULL) && (params->parameters != NULL));
ASSERT(scope != NULL);
const int num_parameters = params->parameters->length();
for (int i = 0; i < num_parameters; i++) {
ParamDesc& param_desc = (*params->parameters)[i];
ASSERT(!is_top_level_ || param_desc.type->IsResolved());
const String* name = param_desc.name;
LocalVariable* parameter = new LocalVariable(
param_desc.name_pos, *name, *param_desc.type);
if (!scope->AddVariable(parameter)) {
ErrorMsg(param_desc.name_pos,
"name '%s' already exists in scope",
param_desc.name->ToCString());
}
if (param_desc.is_final) {
parameter->set_is_final();
}
}
}
// Builds ReturnNode/NativeBodyNode for a native function.
void Parser::ParseNativeFunctionBlock(const ParamList* params,
const Function& func) {
func.set_is_native(true);
TRACE_PARSER("ParseNativeFunctionBlock");
const Class& cls = Class::Handle(func.Owner());
ASSERT(func.NumParameters() == params->parameters->length());
// Parse the function name out.
const intptr_t native_pos = TokenPos();
const String& native_name = ParseNativeDeclaration();
// Now resolve the native function to the corresponding native entrypoint.
const int num_params = NativeArguments::ParameterCountForResolution(func);
NativeFunction native_function = NativeEntry::ResolveNative(
cls, native_name, num_params);
if (native_function == NULL) {
ErrorMsg(native_pos, "native function '%s' cannot be found",
native_name.ToCString());
}
// Now add the NativeBodyNode and return statement.
current_block_->statements->Add(
new ReturnNode(TokenPos(),
new NativeBodyNode(TokenPos(),
Function::ZoneHandle(func.raw()),
native_name,
native_function)));
}
LocalVariable* Parser::LookupReceiver(LocalScope* from_scope, bool test_only) {
ASSERT(!current_function().is_static());
return from_scope->LookupVariable(Symbols::This(), test_only);
}
LocalVariable* Parser::LookupTypeArgumentsParameter(LocalScope* from_scope,
bool test_only) {
ASSERT(current_function().IsInFactoryScope());
return from_scope->LookupVariable(Symbols::TypeArgumentsParameter(),
test_only);
}
LocalVariable* Parser::LookupPhaseParameter() {
const bool kTestOnly = false;
return current_block_->scope->LookupVariable(Symbols::PhaseParameter(),
kTestOnly);
}
void Parser::CaptureInstantiator() {
ASSERT(current_block_->scope->function_level() > 0);
const bool kTestOnly = false;
// Side effect of lookup captures the instantiator variable.
LocalVariable* instantiator = NULL;
if (current_function().IsInFactoryScope()) {
instantiator = LookupTypeArgumentsParameter(current_block_->scope,
kTestOnly);
} else {
instantiator = LookupReceiver(current_block_->scope, kTestOnly);
}
ASSERT(instantiator != NULL);
}
AstNode* Parser::LoadReceiver(intptr_t token_pos) {
// A nested function may access 'this', referring to the receiver of the
// outermost enclosing function.
const bool kTestOnly = false;
LocalVariable* receiver = LookupReceiver(current_block_->scope, kTestOnly);
if (receiver == NULL) {
ErrorMsg(token_pos, "illegal implicit access to receiver 'this'");
}
return new LoadLocalNode(TokenPos(), receiver);
}
AstNode* Parser::LoadTypeArgumentsParameter(intptr_t token_pos) {
// A nested function may access ':type_arguments' to use as instantiator,
// referring to the implicit first parameter of the outermost enclosing
// factory function.
const bool kTestOnly = false;
LocalVariable* param = LookupTypeArgumentsParameter(current_block_->scope,
kTestOnly);
ASSERT(param != NULL);
return new LoadLocalNode(TokenPos(), param);
}
AstNode* Parser::CallGetter(intptr_t token_pos,
AstNode* object,
const String& name) {
return new InstanceGetterNode(token_pos, object, name);
}
// Returns ast nodes of the variable initialization.
AstNode* Parser::ParseVariableDeclaration(const AbstractType& type,
bool is_final,
bool is_const) {
TRACE_PARSER("ParseVariableDeclaration");
ASSERT(IsIdentifier());
const intptr_t ident_pos = TokenPos();
LocalVariable* variable =
new LocalVariable(ident_pos, *CurrentLiteral(), type);
ASSERT(current_block_ != NULL);
ASSERT(current_block_->scope != NULL);
ConsumeToken(); // Variable identifier.
AstNode* initialization = NULL;
if (CurrentToken() == Token::kASSIGN) {
// Variable initialization.
const intptr_t assign_pos = TokenPos();
ConsumeToken();
AstNode* expr = ParseExpr(is_const, kConsumeCascades);
initialization = new StoreLocalNode(assign_pos, variable, expr);
if (is_const) {
ASSERT(expr->IsLiteralNode());
variable->SetConstValue(expr->AsLiteralNode()->literal());
}
} else if (is_final || is_const) {
ErrorMsg(ident_pos,
"missing initialization of 'final' or 'const' variable");
} else {
// Initialize variable with null.
AstNode* null_expr = new LiteralNode(ident_pos, Instance::ZoneHandle());
initialization = new StoreLocalNode(ident_pos, variable, null_expr);
}
// Add variable to scope after parsing the initalizer expression.
// The expression must not be able to refer to the variable.
if (!current_block_->scope->AddVariable(variable)) {
ErrorMsg(ident_pos, "identifier '%s' already defined",
variable->name().ToCString());
}
if (is_final || is_const) {
variable->set_is_final();
}
return initialization;
}
// Parses ('var' | 'final' [type] | 'const' [type] | type).
// The presence of 'final' or 'const' must be detected and remembered
// before the call. If a type is parsed, it may be resolved and finalized
// according to the given type finalization mode.
RawAbstractType* Parser::ParseConstFinalVarOrType(
ClassFinalizer::FinalizationKind finalization) {
TRACE_PARSER("ParseConstFinalVarOrType");
if (CurrentToken() == Token::kVAR) {
ConsumeToken();
return Type::DynamicType();
}
bool type_is_optional = false;
if ((CurrentToken() == Token::kFINAL) || (CurrentToken() == Token::kCONST)) {
ConsumeToken();
type_is_optional = true;
}
if (CurrentToken() != Token::kIDENT) {
if (type_is_optional) {
return Type::DynamicType();
} else {
ErrorMsg("type name expected");
}
}
if (type_is_optional) {
Token::Kind follower = LookaheadToken(1);
// We have an identifier followed by a 'follower' token.
// We either parse a type or return now.
if ((follower != Token::kLT) && // Parameterized type.
(follower != Token::kPERIOD) && // Qualified class name of type.
!Token::IsIdentifier(follower) && // Variable name following a type.
(follower != Token::kTHIS)) { // Field parameter following a type.
return Type::DynamicType();
}
}
return ParseType(finalization);
}
// Returns ast nodes of the variable initialization. Variables without an
// explicit initializer are initialized to null. If several variables are
// declared, the individual initializers are collected in a sequence node.
AstNode* Parser::ParseVariableDeclarationList() {
TRACE_PARSER("ParseVariableDeclarationList");
SkipMetadata();
bool is_final = (CurrentToken() == Token::kFINAL);
bool is_const = (CurrentToken() == Token::kCONST);
const AbstractType& type = AbstractType::ZoneHandle(ParseConstFinalVarOrType(
FLAG_enable_type_checks ? ClassFinalizer::kCanonicalize :
ClassFinalizer::kIgnore));
if (!IsIdentifier()) {
ErrorMsg("identifier expected");
}
AstNode* initializers = ParseVariableDeclaration(type, is_final, is_const);
ASSERT(initializers != NULL);
while (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
if (!IsIdentifier()) {
ErrorMsg("identifier expected after comma");
}
// We have a second initializer. Allocate a sequence node now.
// The sequence does not own the current scope. Set its own scope to NULL.
SequenceNode* sequence = NodeAsSequenceNode(initializers->token_pos(),
initializers,
NULL);
sequence->Add(ParseVariableDeclaration(type, is_final, is_const));
initializers = sequence;
}
return initializers;
}
AstNode* Parser::ParseFunctionStatement(bool is_literal) {
TRACE_PARSER("ParseFunctionStatement");
AbstractType& result_type = AbstractType::Handle();
const String* variable_name = NULL;
const String* function_name = NULL;
result_type = Type::DynamicType();
intptr_t ident_pos = TokenPos();
if (is_literal) {
ASSERT(CurrentToken() == Token::kLPAREN);
function_name = &Symbols::AnonymousClosure();
} else {
if (CurrentToken() == Token::kVOID) {
ConsumeToken();
result_type = Type::VoidType();
} else if ((CurrentToken() == Token::kIDENT) &&
(LookaheadToken(1) != Token::kLPAREN)) {
result_type = ParseType(ClassFinalizer::kCanonicalize);
}
ident_pos = TokenPos();
variable_name = ExpectIdentifier("function name expected");
function_name = variable_name;
}
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
intptr_t function_pos = TokenPos();
// Check whether we have parsed this closure function before, in a previous
// compilation. If so, reuse the function object, else create a new one
// and register it in the current class.
// Note that we cannot share the same closure function between the closurized
// and non-closurized versions of the same parent function.
Function& function = Function::ZoneHandle();
bool is_new_closure = false;
// TODO(hausner): There could be two different closures at the given
// function_pos, one enclosed in a closurized function and one enclosed in the
// non-closurized version of this same function.
function = current_class().LookupClosureFunction(function_pos);
if (function.IsNull() || (function.token_pos() != function_pos) ||
(function.parent_function() != innermost_function().raw())) {
is_new_closure = true;
function = Function::NewClosureFunction(*function_name,
innermost_function(),
function_pos);
function.set_result_type(result_type);
current_class().AddClosureFunction(function);
}
// The function type needs to be finalized at compile time, since the closure
// may be type checked at run time when assigned to a function variable,
// passed as a function argument, or returned as a function result.
LocalVariable* function_variable = NULL;
Type& function_type = Type::ZoneHandle();
if (variable_name != NULL) {
// Since the function type depends on the signature of the closure function,
// it cannot be determined before the formal parameter list of the closure
// function is parsed. Therefore, we set the function type to a new
// parameterized type to be patched after the actual type is known.
// We temporarily use the class of the Function interface.
const Class& unknown_signature_class = Class::Handle(
Type::Handle(Type::Function()).type_class());
function_type = Type::New(
unknown_signature_class, TypeArguments::Handle(), ident_pos);
function_type.SetIsFinalized(); // No finalization needed.
// Add the function variable to the scope before parsing the function in
// order to allow self reference from inside the function.
function_variable = new LocalVariable(ident_pos,
*variable_name,
function_type);
function_variable->set_is_final();
ASSERT(current_block_ != NULL);
ASSERT(current_block_->scope != NULL);
if (!current_block_->scope->AddVariable(function_variable)) {
ErrorMsg(ident_pos, "identifier '%s' already defined",
function_variable->name().ToCString());
}
}
// Parse the local function.
Array& default_parameter_values = Array::Handle();
SequenceNode* statements = Parser::ParseFunc(function,
default_parameter_values);
ASSERT(is_new_closure || (function.end_token_pos() == (TokenPos() - 1)));
function.set_end_token_pos(TokenPos() - 1);
// Now that the local function has formal parameters, lookup the signature
// class in the current library (but not in its imports) and only create a new
// canonical signature class if it does not exist yet.
const String& signature = String::Handle(function.Signature());
Class& signature_class = Class::ZoneHandle();
if (!is_new_closure) {
signature_class = function.signature_class();
}
if (signature_class.IsNull()) {
signature_class = library_.LookupLocalClass(signature);
}
if (signature_class.IsNull()) {
// If we don't have a signature class yet, this must be a closure we
// have not parsed before.
ASSERT(is_new_closure);
signature_class = Class::NewSignatureClass(signature,
function,
script_,
function.token_pos());
// Record the function signature class in the current library.
library_.AddClass(signature_class);
} else if (is_new_closure) {
function.set_signature_class(signature_class);
}
ASSERT(function.signature_class() == signature_class.raw());
// Local functions are registered in the enclosing class, but
// ignored during class finalization. The enclosing class has
// already been finalized.
ASSERT(current_class().is_finalized());
// Make sure that the instantiator is captured.
if ((signature_class.NumTypeParameters() > 0) &&
(current_block_->scope->function_level() > 0)) {
CaptureInstantiator();
}
// Since the signature type is cached by the signature class, it may have
// been finalized already.
Type& signature_type = Type::Handle(signature_class.SignatureType());
AbstractTypeArguments& signature_type_arguments =
AbstractTypeArguments::Handle(signature_type.arguments());
if (!signature_type.IsFinalized()) {
signature_type ^= ClassFinalizer::FinalizeType(
signature_class, signature_type, ClassFinalizer::kCanonicalize);
// The call to ClassFinalizer::FinalizeType may have
// extended the vector of type arguments.
signature_type_arguments = signature_type.arguments();
ASSERT(signature_type.IsMalformed() ||
signature_type_arguments.IsNull() ||
(signature_type_arguments.Length() ==
signature_class.NumTypeArguments()));
// The signature_class should not have changed.
ASSERT(signature_type.IsMalformed() ||
(signature_type.type_class() == signature_class.raw()));
}
if (variable_name != NULL) {
// Patch the function type of the variable now that the signature is known.
function_type.set_type_class(signature_class);
function_type.set_arguments(signature_type_arguments);
// Mark the function type as malformed if the signature type is malformed.
if (signature_type.IsMalformed()) {
const Error& error = Error::Handle(signature_type.malformed_error());
function_type.set_malformed_error(error);
}
// The function variable type should have been patched above.
ASSERT((function_variable == NULL) ||
(function_variable->type().raw() == function_type.raw()));
}
// The code generator does not compile the closure function when visiting
// a ClosureNode. The generated code allocates a new Closure object containing
// the current context. The type of the Closure object refers to the closure
// function, which will be compiled on first invocation of the closure object.
// Therefore, we ignore the parsed default_parameter_values and the
// node_sequence representing the body of the closure function, which will be
// parsed again when compiled later.
// The only purpose of parsing the function now (besides reporting obvious
// errors) is to mark referenced variables of the enclosing scopes as
// captured. The captured variables will be recorded along with their
// allocation information in a Scope object stored in the function object.
// This Scope object is then provided to the compiler when compiling the local
// function. It would be too early to record the captured variables here,
// since further closure functions may capture more variables.
// This Scope object is constructed after all variables have been allocated.
// The local scope of the parsed function can be pruned, since contained
// variables are not relevant for the compilation of the enclosing function.
// This pruning is done by omitting to hook the local scope in its parent
// scope in the constructor of LocalScope.
AstNode* closure =
new ClosureNode(ident_pos, function, NULL, statements->scope());
if (function_variable == NULL) {
ASSERT(is_literal);
return closure;
} else {
AstNode* initialization =
new StoreLocalNode(ident_pos, function_variable, closure);
return initialization;
}
}
// Returns true if the current and next tokens can be parsed as type
// parameters. Current token position is not saved and restored.
bool Parser::TryParseTypeParameter() {
if (CurrentToken() == Token::kLT) {
// We are possibly looking at type parameters. Find closing ">".
int nesting_level = 0;
do {
if (CurrentToken() == Token::kLT) {
nesting_level++;
} else if (CurrentToken() == Token::kGT) {
nesting_level--;
} else if (CurrentToken() == Token::kSHR) {
nesting_level -= 2;
} else if (CurrentToken() == Token::kIDENT) {
// Check to see if it is a qualified identifier.
if (LookaheadToken(1) == Token::kPERIOD) {
// Consume the identifier, the period will be consumed below.
ConsumeToken();
}
} else if (CurrentToken() != Token::kCOMMA &&
CurrentToken() != Token::kEXTENDS) {
// We are looking at something other than type parameters.
return false;
}
ConsumeToken();
} while (nesting_level > 0);
if (nesting_level < 0) {
return false;
}
}
return true;
}
bool Parser::IsSimpleLiteral(const AbstractType& type, Instance* value) {
bool no_check = type.IsDynamicType();
if ((CurrentToken() == Token::kINTEGER) &&
(no_check || type.IsIntType() || type.IsNumberType())) {
*value = CurrentIntegerLiteral();
return true;
} else if ((CurrentToken() == Token::kDOUBLE) &&
(no_check || type.IsDoubleType() || type.IsNumberType())) {
*value = CurrentDoubleLiteral();
return true;
} else if ((CurrentToken() == Token::kSTRING) &&
(no_check || type.IsStringType())) {
*value = CurrentLiteral()->raw();
return true;
} else if ((CurrentToken() == Token::kTRUE) &&
(no_check || type.IsBoolType())) {
*value = Bool::True().raw();
return true;
} else if ((CurrentToken() == Token::kFALSE) &&
(no_check || type.IsBoolType())) {
*value = Bool::False().raw();
return true;
} else if (CurrentToken() == Token::kNULL) {
*value = Instance::null();
return true;
}
return false;
}
// Returns true if the current token is kIDENT or a pseudo-keyword.
bool Parser::IsIdentifier() {
return Token::IsIdentifier(CurrentToken());
}
// Returns true if the next tokens can be parsed as a type with optional
// type parameters. Current token position is not restored.
bool Parser::TryParseOptionalType() {
if (CurrentToken() == Token::kIDENT) {
QualIdent type_name;
ParseQualIdent(&type_name);
if ((CurrentToken() == Token::kLT) && !TryParseTypeParameter()) {
return false;
}
}
return true;
}
// Returns true if the next tokens can be parsed as a type with optional
// type parameters, or keyword "void".
// Current token position is not restored.
bool Parser::TryParseReturnType() {
if (CurrentToken() == Token::kVOID) {
ConsumeToken();
return true;
} else if (CurrentToken() == Token::kIDENT) {
return TryParseOptionalType();
}
return false;
}
// Look ahead to detect whether the next tokens should be parsed as
// a variable declaration. Ignores optional metadata.
// Returns true if we detect the token pattern:
// 'var'
// | 'final'
// | const [type] ident (';' | '=' | ',')
// | type ident (';' | '=' | ',')
// Token position remains unchanged.
bool Parser::IsVariableDeclaration() {
if ((CurrentToken() == Token::kVAR) ||
(CurrentToken() == Token::kFINAL)) {
return true;
}
// Skip optional metadata.
if (CurrentToken() == Token::kAT) {
const intptr_t saved_pos = TokenPos();
SkipMetadata();
const bool is_var_decl = IsVariableDeclaration();
SetPosition(saved_pos);
return is_var_decl;
}
if ((CurrentToken() != Token::kIDENT) && (CurrentToken() != Token::kCONST)) {
// Not a legal type identifier or const keyword or metadata.
return false;
}
const intptr_t saved_pos = TokenPos();
bool is_var_decl = false;
bool have_type = false;
if (CurrentToken() == Token::kCONST) {
ConsumeToken();
have_type = true; // Type is dynamic.
}
if (IsIdentifier()) { // Type or variable name.
Token::Kind follower = LookaheadToken(1);
if ((follower == Token::kLT) || // Parameterized type.
(follower == Token::kPERIOD) || // Qualified class name of type.
Token::IsIdentifier(follower)) { // Variable name following a type.
// We see the beginning of something that could be a type.
const intptr_t type_pos = TokenPos();
if (TryParseOptionalType()) {
have_type = true;
} else {
SetPosition(type_pos);
}
}
if (have_type && IsIdentifier()) {
ConsumeToken();
if ((CurrentToken() == Token::kSEMICOLON) ||
(CurrentToken() == Token::kCOMMA) ||
(CurrentToken() == Token::kASSIGN)) {
is_var_decl = true;
}
}
}
SetPosition(saved_pos);
return is_var_decl;
}
// Look ahead to detect whether the next tokens should be parsed as
// a function declaration. Token position remains unchanged.
bool Parser::IsFunctionDeclaration() {
const intptr_t saved_pos = TokenPos();
bool is_external = false;
if (is_top_level_) {
if (is_patch_source() &&
(CurrentToken() == Token::kIDENT) &&
CurrentLiteral()->Equals("patch") &&
(LookaheadToken(1) != Token::kLPAREN)) {
// Skip over 'patch' for top-level function declarations in patch sources.
ConsumeToken();
} else if (CurrentToken() == Token::kEXTERNAL) {
// Skip over 'external' for top-level function declarations.
is_external = true;
ConsumeToken();
}
}
if (IsIdentifier() && (LookaheadToken(1) == Token::kLPAREN)) {
// Possibly a function without explicit return type.
ConsumeToken(); // Consume function identifier.
} else if (TryParseReturnType()) {
if (!IsIdentifier()) {
SetPosition(saved_pos);
return false;
}
ConsumeToken(); // Consume function identifier.
} else {
SetPosition(saved_pos);
return false;
}
// Check parameter list and the following token.
if (CurrentToken() == Token::kLPAREN) {
SkipToMatchingParenthesis();
if ((CurrentToken() == Token::kLBRACE) ||
(CurrentToken() == Token::kARROW) ||
(is_top_level_ && IsLiteral("native")) ||
is_external) {
SetPosition(saved_pos);
return true;
}
}
SetPosition(saved_pos);
return false;
}
bool Parser::IsTopLevelAccessor() {
const intptr_t saved_pos = TokenPos();
if (is_patch_source() &&
(CurrentToken() == Token::kIDENT) &&
(CurrentLiteral()->Equals("patch"))) {
ConsumeToken();
} else if (CurrentToken() == Token::kEXTERNAL) {
ConsumeToken();
}
if ((CurrentToken() == Token::kGET) || (CurrentToken() == Token::kSET)) {
SetPosition(saved_pos);
return true;
}
if (TryParseReturnType()) {
if ((CurrentToken() == Token::kGET) || (CurrentToken() == Token::kSET)) {
if (Token::IsIdentifier(LookaheadToken(1))) { // Accessor name.
SetPosition(saved_pos);
return true;
}
}
}
SetPosition(saved_pos);
return false;
}
bool Parser::IsFunctionLiteral() {
if (CurrentToken() != Token::kLPAREN || !allow_function_literals_) {
return false;
}
const intptr_t saved_pos = TokenPos();
bool is_function_literal = false;
SkipToMatchingParenthesis();
if ((CurrentToken() == Token::kLBRACE) ||
(CurrentToken() == Token::kARROW)) {
is_function_literal = true;
}
SetPosition(saved_pos);
return is_function_literal;
}
// Current token position is the token after the opening ( of the for
// statement. Returns true if we recognize a for ( .. in expr)
// statement.
bool Parser::IsForInStatement() {
const intptr_t saved_pos = TokenPos();
bool result = false;
// Allow const modifier as well when recognizing a for-in statement
// pattern. We will get an error later if the loop variable is
// declared with const.
if (CurrentToken() == Token::kVAR ||
CurrentToken() == Token::kFINAL ||
CurrentToken() == Token::kCONST) {
ConsumeToken();
}
if (IsIdentifier()) {
if (LookaheadToken(1) == Token::kIN) {
result = true;
} else if (TryParseOptionalType()) {
if (IsIdentifier()) {
ConsumeToken();
}
result = (CurrentToken() == Token::kIN);
}
}
SetPosition(saved_pos);
return result;
}
static bool ContainsAbruptCompletingStatement(SequenceNode* seq);
static bool IsAbruptCompleting(AstNode* statement) {
return statement->IsReturnNode() ||
statement->IsJumpNode() ||
statement->IsThrowNode() ||
(statement->IsSequenceNode() &&
ContainsAbruptCompletingStatement(statement->AsSequenceNode()));
}
static bool ContainsAbruptCompletingStatement(SequenceNode* seq) {
for (int i = 0; i < seq->length(); i++) {
if (IsAbruptCompleting(seq->NodeAt(i))) {
return true;
}
}
return false;
}
void Parser::ParseStatementSequence() {
TRACE_PARSER("ParseStatementSequence");
const bool dead_code_allowed = true;
bool abrupt_completing_seen = false;
while (CurrentToken() != Token::kRBRACE) {
const intptr_t statement_pos = TokenPos();
AstNode* statement = ParseStatement();
// Do not add statements with no effect (e.g., LoadLocalNode).
if ((statement != NULL) && statement->IsLoadLocalNode()) {
// Skip load local.
statement = statement->AsLoadLocalNode()->pseudo();
}
if (statement != NULL) {
if (!dead_code_allowed && abrupt_completing_seen) {
ErrorMsg(statement_pos, "dead code after abrupt completing statement");
}
current_block_->statements->Add(statement);
abrupt_completing_seen |= IsAbruptCompleting(statement);
}
}
}
// Parse nested statement of if, while, for, etc. We automatically generate
// a sequence of one statement if there are no curly braces.
// The argument 'parsing_loop_body' indicates the parsing of a loop statement.
SequenceNode* Parser::ParseNestedStatement(bool parsing_loop_body,
SourceLabel* label) {
TRACE_PARSER("ParseNestedStatement");
if (parsing_loop_body) {
OpenLoopBlock();
} else {
OpenBlock();
}
if (label != NULL) {
current_block_->scope->AddLabel(label);
}
if (CurrentToken() == Token::kLBRACE) {
ConsumeToken();
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
} else {
AstNode* statement = ParseStatement();
if (statement != NULL) {
current_block_->statements->Add(statement);
}
}
SequenceNode* sequence = CloseBlock();
return sequence;
}
AstNode* Parser::ParseIfStatement(String* label_name) {
TRACE_PARSER("ParseIfStatement");
ASSERT(CurrentToken() == Token::kIF);
const intptr_t if_pos = TokenPos();
SourceLabel* label = NULL;
if (label_name != NULL) {
label = SourceLabel::New(if_pos, label_name, SourceLabel::kStatement);
OpenBlock();
current_block_->scope->AddLabel(label);
}
ConsumeToken();
ExpectToken(Token::kLPAREN);
AstNode* cond_expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kRPAREN);
const bool parsing_loop_body = false;
SequenceNode* true_branch = ParseNestedStatement(parsing_loop_body, NULL);
SequenceNode* false_branch = NULL;
if (CurrentToken() == Token::kELSE) {
ConsumeToken();
false_branch = ParseNestedStatement(parsing_loop_body, NULL);
}
AstNode* if_node = new IfNode(if_pos, cond_expr, true_branch, false_branch);
if (label != NULL) {
current_block_->statements->Add(if_node);
SequenceNode* sequence = CloseBlock();
sequence->set_label(label);
if_node = sequence;
}
return if_node;
}
CaseNode* Parser::ParseCaseClause(LocalVariable* switch_expr_value,
SourceLabel* case_label) {
TRACE_PARSER("ParseCaseStatement");
bool default_seen = false;
const intptr_t case_pos = TokenPos();
// The case expressions node sequence does not own the enclosing scope.
SequenceNode* case_expressions = new SequenceNode(case_pos, NULL);
while (CurrentToken() == Token::kCASE || CurrentToken() == Token::kDEFAULT) {
if (CurrentToken() == Token::kCASE) {
if (default_seen) {
ErrorMsg("default clause must be last case");
}
ConsumeToken(); // Keyword case.
const intptr_t expr_pos = TokenPos();
AstNode* expr = ParseExpr(kAllowConst, kConsumeCascades);
AstNode* switch_expr_load = new LoadLocalNode(case_pos,
switch_expr_value);
AstNode* case_comparison = new ComparisonNode(expr_pos,
Token::kEQ,
expr,
switch_expr_load);
case_expressions->Add(case_comparison);
} else {
if (default_seen) {
ErrorMsg("only one default clause is allowed");
}
ConsumeToken(); // Keyword default.
default_seen = true;
// The default case always succeeds.
}
ExpectToken(Token::kCOLON);
}
OpenBlock();
bool abrupt_completing_seen = false;
while (true) {
// Check whether the next statement still belongs to the current case
// clause. If we see 'case' or 'default', optionally preceeded by
// a label, or closing brace, we stop parsing statements.
Token::Kind next_token;
if (IsIdentifier() && LookaheadToken(1) == Token::kCOLON) {
next_token = LookaheadToken(2);
} else {
next_token = CurrentToken();
}
if (next_token == Token::kRBRACE) {
// End of switch statement.
break;
}
if ((next_token == Token::kCASE) || (next_token == Token::kDEFAULT)) {
// End of this case clause. If there is a possible fall-through to
// the next case clause, throw an implicit FallThroughError.
if (!abrupt_completing_seen) {
ArgumentListNode* arguments = new ArgumentListNode(TokenPos());
arguments->Add(new LiteralNode(
TokenPos(), Integer::ZoneHandle(Integer::New(TokenPos()))));
current_block_->statements->Add(
MakeStaticCall(Symbols::FallThroughError(),
PrivateCoreLibName(Symbols::ThrowNew()),
arguments));
}
break;
}
// The next statement still belongs to this case.
AstNode* statement = ParseStatement();
if (statement != NULL) {
current_block_->statements->Add(statement);
abrupt_completing_seen |= IsAbruptCompleting(statement);
}
}
SequenceNode* statements = CloseBlock();
return new CaseNode(case_pos, case_label,
case_expressions, default_seen, switch_expr_value, statements);
}
AstNode* Parser::ParseSwitchStatement(String* label_name) {
TRACE_PARSER("ParseSwitchStatement");
ASSERT(CurrentToken() == Token::kSWITCH);
const intptr_t switch_pos = TokenPos();
SourceLabel* label =
SourceLabel::New(switch_pos, label_name, SourceLabel::kSwitch);
ConsumeToken();
const bool parens_are_mandatory = false;
bool paren_found = false;
if (CurrentToken() == Token::kLPAREN) {
paren_found = true;
ConsumeToken();
} else if (parens_are_mandatory) {
ErrorMsg("'(' expected");
}
const intptr_t expr_pos = TokenPos();
AstNode* switch_expr = ParseExpr(kAllowConst, kConsumeCascades);
if (paren_found) {
ExpectToken(Token::kRPAREN);
}
ExpectToken(Token::kLBRACE);
OpenBlock();
current_block_->scope->AddLabel(label);
// Store switch expression in temporary local variable.
LocalVariable* temp_variable =
new LocalVariable(expr_pos,
Symbols::SwitchExpr(),
Type::ZoneHandle(Type::DynamicType()));
current_block_->scope->AddVariable(temp_variable);
AstNode* save_switch_expr =
new StoreLocalNode(expr_pos, temp_variable, switch_expr);
current_block_->statements->Add(save_switch_expr);
// Parse case clauses
bool default_seen = false;
while (true) {
// Check for statement label
SourceLabel* case_label = NULL;
if (IsIdentifier() && LookaheadToken(1) == Token::kCOLON) {
// Case statements start with a label.
String* label_name = CurrentLiteral();
const intptr_t label_pos = TokenPos();
ConsumeToken(); // Consume label identifier.
ConsumeToken(); // Consume colon.
case_label = current_block_->scope->LocalLookupLabel(*label_name);
if (case_label == NULL) {
// Label does not exist yet. Add it to scope of switch statement.
case_label =
new SourceLabel(label_pos, *label_name, SourceLabel::kCase);
current_block_->scope->AddLabel(case_label);
} else if (case_label->kind() == SourceLabel::kForward) {
// We have seen a 'continue' with this label name. Resolve
// the forward reference.
case_label->ResolveForwardReference();
} else {
ErrorMsg(label_pos, "name '%s' already exists in scope",
label_name->ToCString());
}
ASSERT(case_label->kind() == SourceLabel::kCase);
}
if (CurrentToken() == Token::kCASE ||
CurrentToken() == Token::kDEFAULT) {
if (default_seen) {
ErrorMsg("no case clauses allowed after default clause");
}
CaseNode* case_clause = ParseCaseClause(temp_variable, case_label);
default_seen = case_clause->contains_default();
current_block_->statements->Add(case_clause);
} else if (CurrentToken() != Token::kRBRACE) {
ErrorMsg("'case' or '}' expected");
} else if (case_label != NULL) {
ErrorMsg("expecting at least one case clause after label");
} else {
break;
}
}
// Check for unresolved label references.
SourceLabel* unresolved_label =
current_block_->scope->CheckUnresolvedLabels();
if (unresolved_label != NULL) {
ErrorMsg("unresolved reference to label '%s'",
unresolved_label->name().ToCString());
}
SequenceNode* switch_body = CloseBlock();
ExpectToken(Token::kRBRACE);
return new SwitchNode(switch_pos, label, switch_body);
}
AstNode* Parser::ParseWhileStatement(String* label_name) {
TRACE_PARSER("ParseWhileStatement");
const intptr_t while_pos = TokenPos();
SourceLabel* label =
SourceLabel::New(while_pos, label_name, SourceLabel::kWhile);
ConsumeToken();
ExpectToken(Token::kLPAREN);
AstNode* cond_expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kRPAREN);
const bool parsing_loop_body = true;
SequenceNode* while_body = ParseNestedStatement(parsing_loop_body, label);
return new WhileNode(while_pos, label, cond_expr, while_body);
}
AstNode* Parser::ParseDoWhileStatement(String* label_name) {
TRACE_PARSER("ParseDoWhileStatement");
const intptr_t do_pos = TokenPos();
SourceLabel* label =
SourceLabel::New(do_pos, label_name, SourceLabel::kDoWhile);
ConsumeToken();
const bool parsing_loop_body = true;
SequenceNode* dowhile_body = ParseNestedStatement(parsing_loop_body, label);
ExpectToken(Token::kWHILE);
ExpectToken(Token::kLPAREN);
AstNode* cond_expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kRPAREN);
ExpectSemicolon();
return new DoWhileNode(do_pos, label, cond_expr, dowhile_body);
}
AstNode* Parser::ParseForInStatement(intptr_t forin_pos,
SourceLabel* label) {
TRACE_PARSER("ParseForInStatement");
bool is_final = (CurrentToken() == Token::kFINAL);
if (CurrentToken() == Token::kCONST) {
ErrorMsg("Loop variable cannot be 'const'");
}
const String* loop_var_name = NULL;
LocalVariable* loop_var = NULL;
intptr_t loop_var_pos = 0;
if (LookaheadToken(1) == Token::kIN) {
loop_var_pos = TokenPos();
loop_var_name = ExpectIdentifier("variable name expected");
} else {
// The case without a type is handled above, so require a type here.
const AbstractType& type =
AbstractType::ZoneHandle(ParseConstFinalVarOrType(
FLAG_enable_type_checks ? ClassFinalizer::kCanonicalize :
ClassFinalizer::kIgnore));
loop_var_pos = TokenPos();
loop_var_name = ExpectIdentifier("variable name expected");
loop_var = new LocalVariable(loop_var_pos, *loop_var_name, type);
if (is_final) {
loop_var->set_is_final();
}
}
ExpectToken(Token::kIN);
const intptr_t collection_pos = TokenPos();
AstNode* collection_expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kRPAREN);
OpenBlock(); // Implicit block around while loop.
// Generate implicit iterator variable and add to scope.
// We could set the type of the implicit iterator variable to Iterator<T>
// where T is the type of the for loop variable. However, the type error
// would refer to the compiler generated iterator and could confuse the user.
// It is better to leave the iterator untyped and postpone the type error
// until the loop variable is assigned to.
const AbstractType& iterator_type = Type::ZoneHandle(Type::DynamicType());
LocalVariable* iterator_var =
new LocalVariable(collection_pos, Symbols::ForInIter(), iterator_type);
current_block_->scope->AddVariable(iterator_var);
// Generate initialization of iterator variable.
ArgumentListNode* no_args = new ArgumentListNode(collection_pos);
AstNode* get_iterator = new InstanceGetterNode(
collection_pos, collection_expr, Symbols::GetIterator());
AstNode* iterator_init =
new StoreLocalNode(collection_pos, iterator_var, get_iterator);
current_block_->statements->Add(iterator_init);
// Generate while loop condition.
AstNode* iterator_moveNext = new InstanceCallNode(
collection_pos,
new LoadLocalNode(collection_pos, iterator_var),
Symbols::MoveNext(),
no_args);
// Parse the for loop body. Ideally, we would use ParseNestedStatement()
// here, but that does not work well because we have to insert an implicit
// variable assignment and potentially a variable declaration in the
// loop body.
OpenLoopBlock();
current_block_->scope->AddLabel(label);
AstNode* iterator_current = new InstanceGetterNode(
collection_pos,
new LoadLocalNode(collection_pos, iterator_var),
Symbols::Current());
// Generate assignment of next iterator value to loop variable.
AstNode* loop_var_assignment = NULL;
if (loop_var != NULL) {
// The for loop declares a new variable. Add it to the loop body scope.
current_block_->scope->AddVariable(loop_var);
loop_var_assignment =
new StoreLocalNode(loop_var_pos, loop_var, iterator_current);
} else {
AstNode* loop_var_primary =
ResolveIdent(loop_var_pos, *loop_var_name, false);
ASSERT(!loop_var_primary->IsPrimaryNode());
loop_var_assignment =
CreateAssignmentNode(loop_var_primary, iterator_current);
if (loop_var_assignment == NULL) {
ErrorMsg(loop_var_pos, "variable or field '%s' is not assignable",
loop_var_name->ToCString());
}
}
current_block_->statements->Add(loop_var_assignment);
// Now parse the for-in loop statement or block.
if (CurrentToken() == Token::kLBRACE) {
ConsumeToken();
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
} else {
AstNode* statement = ParseStatement();
if (statement != NULL) {
current_block_->statements->Add(statement);
}
}
SequenceNode* for_loop_statement = CloseBlock();
AstNode* while_statement =
new WhileNode(forin_pos, label, iterator_moveNext, for_loop_statement);
current_block_->statements->Add(while_statement);
return CloseBlock(); // Implicit block around while loop.
}
AstNode* Parser::ParseForStatement(String* label_name) {
TRACE_PARSER("ParseForStatement");
const intptr_t for_pos = TokenPos();
ConsumeToken();
ExpectToken(Token::kLPAREN);
SourceLabel* label = SourceLabel::New(for_pos, label_name, SourceLabel::kFor);
if (IsForInStatement()) {
return ParseForInStatement(for_pos, label);
}
// Open a block that contains the loop variable. Make it a loop block so
// that we allocate a new context if the loop variable is captured.
OpenLoopBlock();
AstNode* initializer = NULL;
const intptr_t init_pos = TokenPos();
LocalScope* init_scope = current_block_->scope;
if (CurrentToken() != Token::kSEMICOLON) {
if (IsVariableDeclaration()) {
initializer = ParseVariableDeclarationList();
} else {
initializer = ParseExpr(kAllowConst, kConsumeCascades);
}
}
ExpectSemicolon();
AstNode* condition = NULL;
if (CurrentToken() != Token::kSEMICOLON) {
condition = ParseExpr(kAllowConst, kConsumeCascades);
}
ExpectSemicolon();
AstNode* increment = NULL;
const intptr_t incr_pos = TokenPos();
if (CurrentToken() != Token::kRPAREN) {
increment = ParseExprList();
}
ExpectToken(Token::kRPAREN);
const bool parsing_loop_body = true;
SequenceNode* body = ParseNestedStatement(parsing_loop_body, label);
// Check whether any of the variables in the initializer part of
// the for statement are captured by a closure. If so, we insert a
// node that creates a new Context for the loop variable before
// the increment expression is evaluated.
for (int i = 0; i < init_scope->num_variables(); i++) {
if (init_scope->VariableAt(i)->is_captured() &&
(init_scope->VariableAt(i)->owner() == init_scope)) {
SequenceNode* incr_sequence = new SequenceNode(incr_pos, NULL);
incr_sequence->Add(new CloneContextNode(for_pos));
if (increment != NULL) {
incr_sequence->Add(increment);
}
increment = incr_sequence;
break;
}
}
AstNode* for_node =
new ForNode(for_pos,
label,
NodeAsSequenceNode(init_pos, initializer, NULL),
condition,
NodeAsSequenceNode(incr_pos, increment, NULL),
body);
current_block_->statements->Add(for_node);
return CloseBlock();
}
// Calling VM-internal helpers, uses implementation core library.
AstNode* Parser::MakeStaticCall(const String& cls_name,
const String& func_name,
ArgumentListNode* arguments) {
const Class& cls = Class::Handle(LookupCoreClass(cls_name));
ASSERT(!cls.IsNull());
const Function& func = Function::ZoneHandle(
Resolver::ResolveStatic(cls,
func_name,
arguments->length(),
arguments->names(),
Resolver::kIsQualified));
ASSERT(!func.IsNull());
return new StaticCallNode(arguments->token_pos(), func, arguments);
}
AstNode* Parser::MakeAssertCall(intptr_t begin, intptr_t end) {
ArgumentListNode* arguments = new ArgumentListNode(begin);
arguments->Add(new LiteralNode(begin,
Integer::ZoneHandle(Integer::New(begin))));
arguments->Add(new LiteralNode(end,
Integer::ZoneHandle(Integer::New(end))));
return MakeStaticCall(Symbols::AssertionError(),
PrivateCoreLibName(Symbols::ThrowNew()),
arguments);
}
AstNode* Parser::InsertClosureCallNodes(AstNode* condition) {
if (condition->IsClosureNode() ||
(condition->IsStoreLocalNode() &&
condition->AsStoreLocalNode()->value()->IsClosureNode())) {
EnsureSavedCurrentContext();
// Function literal in assert implies a call.
const intptr_t pos = condition->token_pos();
condition = new ClosureCallNode(pos, condition, new ArgumentListNode(pos));
} else if (condition->IsConditionalExprNode()) {
ConditionalExprNode* cond_expr = condition->AsConditionalExprNode();
cond_expr->set_true_expr(InsertClosureCallNodes(cond_expr->true_expr()));
cond_expr->set_false_expr(InsertClosureCallNodes(cond_expr->false_expr()));
}
return condition;
}
AstNode* Parser::ParseAssertStatement() {
TRACE_PARSER("ParseAssertStatement");
ConsumeToken(); // Consume assert keyword.
ExpectToken(Token::kLPAREN);
const intptr_t condition_pos = TokenPos();
if (!FLAG_enable_asserts && !FLAG_enable_type_checks) {
SkipExpr();
ExpectToken(Token::kRPAREN);
return NULL;
}
AstNode* condition = ParseExpr(kAllowConst, kConsumeCascades);
const intptr_t condition_end = TokenPos();
ExpectToken(Token::kRPAREN);
condition = InsertClosureCallNodes(condition);
condition = new UnaryOpNode(condition_pos, Token::kNOT, condition);
AstNode* assert_throw = MakeAssertCall(condition_pos, condition_end);
return new IfNode(condition_pos,
condition,
NodeAsSequenceNode(condition_pos, assert_throw, NULL),
NULL);
}
struct CatchParamDesc {
CatchParamDesc()
: token_pos(0), type(NULL), var(NULL) { }
intptr_t token_pos;
const AbstractType* type;
const String* var;
};
// Populate local scope of the catch block with the catch parameters.
void Parser::AddCatchParamsToScope(const CatchParamDesc& exception_param,
const CatchParamDesc& stack_trace_param,
LocalScope* scope) {
if (exception_param.var != NULL) {
LocalVariable* var = new LocalVariable(exception_param.token_pos,
*exception_param.var,
*exception_param.type);
var->set_is_final();
bool added_to_scope = scope->AddVariable(var);
ASSERT(added_to_scope);
}
if (stack_trace_param.var != NULL) {
LocalVariable* var = new LocalVariable(TokenPos(),
*stack_trace_param.var,
*stack_trace_param.type);
var->set_is_final();
bool added_to_scope = scope->AddVariable(var);
if (!added_to_scope) {
ErrorMsg(stack_trace_param.token_pos,
"name '%s' already exists in scope",
stack_trace_param.var->ToCString());
}
}
}
SequenceNode* Parser::ParseFinallyBlock() {
TRACE_PARSER("ParseFinallyBlock");
OpenBlock();
ExpectToken(Token::kLBRACE);
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
SequenceNode* finally_block = CloseBlock();
return finally_block;
}
void Parser::PushTryBlock(Block* try_block) {
TryBlocks* block = new TryBlocks(try_block, try_blocks_list_);
try_blocks_list_ = block;
}
Parser::TryBlocks* Parser::PopTryBlock() {
TryBlocks* innermost_try_block = try_blocks_list_;
try_blocks_list_ = try_blocks_list_->outer_try_block();
return innermost_try_block;
}
void Parser::AddNodeForFinallyInlining(AstNode* node) {
if (node == NULL) {
return;
}
ASSERT(node->IsReturnNode() || node->IsJumpNode());
TryBlocks* iterator = try_blocks_list_;
while (iterator != NULL) {
// For continue and break node check if the target label is in scope.
if (node->IsJumpNode()) {
SourceLabel* label = node->AsJumpNode()->label();
ASSERT(label != NULL);
LocalScope* try_scope = iterator->try_block()->scope;
// If the label is defined in a scope which is a child (nested scope)
// of the try scope then we are not breaking out of this try block
// so we do not need to inline the finally code. Otherwise we need
// to inline the finally code of this try block and then move on to the
// next outer try block.
if (label->owner()->IsNestedWithin(try_scope)) {
break;
}
}
iterator->AddNodeForFinallyInlining(node);
iterator = iterator->outer_try_block();
}
}
// Add the inlined finally block to the specified node.
void Parser::AddFinallyBlockToNode(AstNode* node,
InlinedFinallyNode* finally_node) {
if (node->IsReturnNode()) {
node->AsReturnNode()->AddInlinedFinallyNode(finally_node);
} else {
ASSERT(node->IsJumpNode());
node->AsJumpNode()->AddInlinedFinallyNode(finally_node);
}
}
AstNode* Parser::ParseTryStatement(String* label_name) {
TRACE_PARSER("ParseTryStatement");
// We create three stack slots for exceptions here:
// ':saved_try_context_var' - Used to save the context before start of the try
// block. The context register is restored from
// this slot before processing the catch block
// handler.
// ':exception_var' - Used to save the current exception object that was
// thrown.
// ':stacktrace_var' - Used to save the current stack trace object into which
// the stack trace was copied into when an exception was
// thrown.
// :exception_var and :stacktrace_var get set with the exception object
// and the stacktrace object when an exception is thrown.
// These three implicit variables can never be captured variables.
LocalVariable* context_var =
current_block_->scope->LocalLookupVariable(Symbols::SavedTryContextVar());
if (context_var == NULL) {
context_var = new LocalVariable(TokenPos(),
Symbols::SavedTryContextVar(),
Type::ZoneHandle(Type::DynamicType()));
current_block_->scope->AddVariable(context_var);
}
LocalVariable* catch_excp_var =
current_block_->scope->LocalLookupVariable(Symbols::ExceptionVar());
if (catch_excp_var == NULL) {
catch_excp_var = new LocalVariable(TokenPos(),
Symbols::ExceptionVar(),
Type::ZoneHandle(Type::DynamicType()));
current_block_->scope->AddVariable(catch_excp_var);
}
LocalVariable* catch_trace_var =
current_block_->scope->LocalLookupVariable(Symbols::StacktraceVar());
if (catch_trace_var == NULL) {
catch_trace_var = new LocalVariable(TokenPos(),
Symbols::StacktraceVar(),
Type::ZoneHandle(Type::DynamicType()));
current_block_->scope->AddVariable(catch_trace_var);
}
const intptr_t try_pos = TokenPos();
ConsumeToken(); // Consume the 'try'.
SourceLabel* try_label = NULL;
if (label_name != NULL) {
try_label = SourceLabel::New(try_pos, label_name, SourceLabel::kStatement);
OpenBlock();
current_block_->scope->AddLabel(try_label);
}
// Now parse the 'try' block.
OpenBlock();
Block* current_try_block = current_block_;
PushTryBlock(current_try_block);
ExpectToken(Token::kLBRACE);
ParseStatementSequence();
ExpectToken(Token::kRBRACE);
SequenceNode* try_block = CloseBlock();
// Now create a label for the end of catch block processing so that we can
// jump over the catch block code after executing the try block.
SourceLabel* end_catch_label =
SourceLabel::New(TokenPos(), NULL, SourceLabel::kCatch);
// Now parse the 'catch' blocks if any and merge all of them into
// an if-then sequence of the different types specified using the 'is'
// operator.
bool catch_seen = false;
bool generic_catch_seen = false;
SequenceNode* catch_handler_list = NULL;
const intptr_t handler_pos = TokenPos();
OpenBlock(); // Start the catch block sequence.
current_block_->scope->AddLabel(end_catch_label);
const GrowableObjectArray& handler_types =
GrowableObjectArray::Handle(GrowableObjectArray::New());
while ((CurrentToken() == Token::kCATCH) || IsLiteral("on")) {
const intptr_t catch_pos = TokenPos();
CatchParamDesc exception_param;
CatchParamDesc stack_trace_param;
catch_seen = true;
if (IsLiteral("on")) {
ConsumeToken();
// TODO(regis): The spec may change in the way a malformed 'on' type is
// treated. For now, we require the type to be wellformed.
exception_param.type = &AbstractType::ZoneHandle(
ParseType(ClassFinalizer::kCanonicalizeWellFormed));
} else {
exception_param.type =
&AbstractType::ZoneHandle(Type::DynamicType());
}
if (CurrentToken() == Token::kCATCH) {
ConsumeToken(); // Consume the 'catch'.
ExpectToken(Token::kLPAREN);
exception_param.token_pos = TokenPos();
exception_param.var = ExpectIdentifier("identifier expected");
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
// TODO(hausner): Make implicit type be StackTrace, not dynamic.
stack_trace_param.type =
&AbstractType::ZoneHandle(Type::DynamicType());
stack_trace_param.token_pos = TokenPos();
stack_trace_param.var = ExpectIdentifier("identifier expected");
}
ExpectToken(Token::kRPAREN);
}
// If a generic "catch all" statement has already been seen then all
// subsequent catch statements are dead. We issue an error for now,
// it might make sense to turn this into a warning.
if (generic_catch_seen) {
ErrorMsg("a generic 'catch all' statement already exists for this "
"try block. All subsequent catch statements are dead code");
}
OpenBlock();
AddCatchParamsToScope(exception_param,
stack_trace_param,
current_block_->scope);
// Parse the individual catch handler code and add an unconditional
// JUMP to the end of the try block.
ExpectToken(Token::kLBRACE);
OpenBlock();
if (exception_param.var != NULL) {
// Generate code to load the exception object (:exception_var) into
// the exception variable specified in this block.
LocalVariable* var = LookupLocalScope(*exception_param.var);
ASSERT(var != NULL);
ASSERT(catch_excp_var != NULL);
current_block_->statements->Add(
new StoreLocalNode(catch_pos, var,
new LoadLocalNode(catch_pos, catch_excp_var)));
}
if (stack_trace_param.var != NULL) {
// A stack trace variable is specified in this block, so generate code
// to load the stack trace object (:stacktrace_var) into the stack trace
// variable specified in this block.
ArgumentListNode* no_args = new ArgumentListNode(catch_pos);
LocalVariable* trace = LookupLocalScope(*stack_trace_param.var);
ASSERT(catch_trace_var != NULL);
current_block_->statements->Add(
new StoreLocalNode(catch_pos, trace,
new LoadLocalNode(catch_pos, catch_trace_var)));
current_block_->statements->Add(
new InstanceCallNode(
catch_pos,
new LoadLocalNode(catch_pos, trace),
PrivateCoreLibName(Symbols::_setupFullStackTrace()),
no_args));
}
ParseStatementSequence(); // Parse the catch handler code.
current_block_->statements->Add(
new JumpNode(catch_pos, Token::kCONTINUE, end_catch_label));
SequenceNode* catch_handler = CloseBlock();
ExpectToken(Token::kRBRACE);
if (!exception_param.type->IsDynamicType()) { // Has a type specification.
// Now form an 'if type check' as an exception type exists in
// the catch specifier.
if (!exception_param.type->IsInstantiated() &&
(current_block_->scope->function_level() > 0)) {
// Make sure that the instantiator is captured.
CaptureInstantiator();
}
TypeNode* exception_type = new TypeNode(catch_pos, *exception_param.type);
AstNode* exception_var = new LoadLocalNode(catch_pos, catch_excp_var);
if (!exception_type->type().IsInstantiated()) {
EnsureExpressionTemp();
}
AstNode* type_cond_expr = new ComparisonNode(
catch_pos, Token::kIS, exception_var, exception_type);
current_block_->statements->Add(
new IfNode(catch_pos, type_cond_expr, catch_handler, NULL));
// Do not add uninstantiated types (e.g. type parameter T or
// generic type List<T>), since the debugger won't be able to
// instantiate it when walking the stack.
// This means that the debugger is not able to determine whether
// an exception is caught if the catch clause uses generic types.
// It will report the exception as uncaught when in fact it might
// be caught and handled when we unwind the stack.
if (exception_param.type->IsInstantiated()) {
handler_types.Add(*exception_param.type);
}
} else {
// No exception type exists in the catch specifier so execute the
// catch handler code unconditionally.
current_block_->statements->Add(catch_handler);
generic_catch_seen = true;
// This catch clause will handle all exceptions. We can safely forget
// all previous catch clause types.
handler_types.SetLength(0);
handler_types.Add(*exception_param.type);
}
SequenceNode* catch_clause = CloseBlock();
// Add this individual catch handler to the catch handlers list.
current_block_->statements->Add(catch_clause);
}
catch_handler_list = CloseBlock();
TryBlocks* inner_try_block = PopTryBlock();
// Finally parse the 'finally' block.
SequenceNode* finally_block = NULL;
if (CurrentToken() == Token::kFINALLY) {
current_function().set_is_optimizable(false);
current_function().set_has_finally(true);
ConsumeToken(); // Consume the 'finally'.
const intptr_t finally_pos = TokenPos();
// Add the finally block to the exit points recorded so far.
intptr_t node_index = 0;
AstNode* node_to_inline =
inner_try_block->GetNodeToInlineFinally(node_index);
while (node_to_inline != NULL) {
finally_block = ParseFinallyBlock();
InlinedFinallyNode* node = new InlinedFinallyNode(finally_pos,
finally_block,
context_var);
AddFinallyBlockToNode(node_to_inline, node);
node_index += 1;
node_to_inline = inner_try_block->GetNodeToInlineFinally(node_index);
tokens_iterator_.SetCurrentPosition(finally_pos);
}
if (!generic_catch_seen) {
// No generic catch handler exists so execute this finally block
// before rethrowing the exception.
finally_block = ParseFinallyBlock();
catch_handler_list->Add(finally_block);
tokens_iterator_.SetCurrentPosition(finally_pos);
}
finally_block = ParseFinallyBlock();
} else {
if (!catch_seen) {
ErrorMsg("catch or finally clause expected");
}
}
if (!generic_catch_seen) {
// No generic catch handler exists so rethrow the exception so that
// the next catch handler can deal with it.
catch_handler_list->Add(
new ThrowNode(handler_pos,
new LoadLocalNode(handler_pos, catch_excp_var),
new LoadLocalNode(handler_pos, catch_trace_var)));
}
CatchClauseNode* catch_block =
new CatchClauseNode(handler_pos,
catch_handler_list,
Array::ZoneHandle(Array::MakeArray(handler_types)),
context_var,
catch_excp_var,
catch_trace_var);
// Now create the try/catch ast node and return it. If there is a label
// on the try/catch, close the block that's embedding the try statement
// and attach the label to it.
AstNode* try_catch_node =
new TryCatchNode(try_pos, try_block, end_catch_label,
context_var, catch_block, finally_block);
if (try_label != NULL) {
current_block_->statements->Add(try_catch_node);
SequenceNode* sequence = CloseBlock();
sequence->set_label(try_label);
try_catch_node = sequence;
}
return try_catch_node;
}
AstNode* Parser::ParseJump(String* label_name) {
TRACE_PARSER("ParseJump");
ASSERT(CurrentToken() == Token::kBREAK || CurrentToken() == Token::kCONTINUE);
Token::Kind jump_kind = CurrentToken();
const intptr_t jump_pos = TokenPos();
SourceLabel* target = NULL;
ConsumeToken();
if (IsIdentifier()) {
// Explicit label after break/continue.
const String& target_name = *CurrentLiteral();
ConsumeToken();
// Handle pathological cases first.
if (label_name != NULL && target_name.Equals(*label_name)) {
if (jump_kind == Token::kCONTINUE) {
ErrorMsg(jump_pos, "'continue' jump to label '%s' is illegal",
target_name.ToCString());
}
// L: break L; is a no-op.
return NULL;
}
target = current_block_->scope->LookupLabel(target_name);
if (target == NULL && jump_kind == Token::kCONTINUE) {
// Either a reference to a non-existent label, or a forward reference
// to a case label that we haven't seen yet. If we are inside a switch
// statement, create a "forward reference" label in the scope of
// the switch statement.
LocalScope* switch_scope = current_block_->scope->LookupSwitchScope();
if (switch_scope != NULL) {
// We found a switch scope. Enter a forward reference to the label.
target = new SourceLabel(
TokenPos(), target_name, SourceLabel::kForward);
switch_scope->AddLabel(target);
}
}
if (target == NULL) {
ErrorMsg(jump_pos, "label '%s' not found", target_name.ToCString());
}
} else {
target = current_block_->scope->LookupInnermostLabel(jump_kind);
if (target == NULL) {
ErrorMsg(jump_pos, "'%s' is illegal here", Token::Str(jump_kind));
}
}
ASSERT(target != NULL);
if (jump_kind == Token::kCONTINUE) {
if (target->kind() == SourceLabel::kSwitch) {
ErrorMsg(jump_pos, "'continue' jump to switch statement is illegal");
} else if (target->kind() == SourceLabel::kStatement) {
ErrorMsg(jump_pos, "'continue' jump to label '%s' is illegal",
target->name().ToCString());
}
}
if (jump_kind == Token::kBREAK && target->kind() == SourceLabel::kCase) {
ErrorMsg(jump_pos, "'break' to case clause label is illegal");
}
if (target->FunctionLevel() != current_block_->scope->function_level()) {
ErrorMsg(jump_pos, "'%s' target must be in same function context",
Token::Str(jump_kind));
}
return new JumpNode(jump_pos, jump_kind, target);
}
AstNode* Parser::ParseStatement() {
TRACE_PARSER("ParseStatement");
AstNode* statement = NULL;
intptr_t label_pos = 0;
String* label_name = NULL;
if (IsIdentifier()) {
if (LookaheadToken(1) == Token::kCOLON) {
// Statement starts with a label.
label_name = CurrentLiteral();
label_pos = TokenPos();
ASSERT(label_pos > 0);
ConsumeToken(); // Consume identifier.
ConsumeToken(); // Consume colon.
}
}
const intptr_t statement_pos = TokenPos();
if (CurrentToken() == Token::kWHILE) {
statement = ParseWhileStatement(label_name);
} else if (CurrentToken() == Token::kFOR) {
statement = ParseForStatement(label_name);
} else if (CurrentToken() == Token::kDO) {
statement = ParseDoWhileStatement(label_name);
} else if (CurrentToken() == Token::kSWITCH) {
statement = ParseSwitchStatement(label_name);
} else if (CurrentToken() == Token::kTRY) {
statement = ParseTryStatement(label_name);
} else if (CurrentToken() == Token::kRETURN) {
const intptr_t return_pos = TokenPos();
ConsumeToken();
if (CurrentToken() != Token::kSEMICOLON) {
if (current_function().IsConstructor() &&
(current_block_->scope->function_level() == 0)) {
ErrorMsg(return_pos, "return of a value not allowed in constructors");
}
AstNode* expr = ParseExpr(kAllowConst, kConsumeCascades);
statement = new ReturnNode(statement_pos, expr);
} else {
statement = new ReturnNode(statement_pos);
}
AddNodeForFinallyInlining(statement);
ExpectSemicolon();
} else if (CurrentToken() == Token::kIF) {
statement = ParseIfStatement(label_name);
} else if (CurrentToken() == Token::kASSERT) {
statement = ParseAssertStatement();
ExpectSemicolon();
} else if (IsVariableDeclaration()) {
statement = ParseVariableDeclarationList();
ExpectSemicolon();
} else if (IsFunctionDeclaration()) {
statement = ParseFunctionStatement(false);
} else if (CurrentToken() == Token::kLBRACE) {
SourceLabel* label = NULL;
OpenBlock();
if (label_name != NULL) {
label = SourceLabel::New(label_pos, label_name, SourceLabel::kStatement);
current_block_->scope->AddLabel(label);
}
ConsumeToken();
ParseStatementSequence();
statement = CloseBlock();
if (label != NULL) {
statement->AsSequenceNode()->set_label(label);
}
ExpectToken(Token::kRBRACE);
} else if (CurrentToken() == Token::kBREAK) {
statement = ParseJump(label_name);
AddNodeForFinallyInlining(statement);
ExpectSemicolon();
} else if (CurrentToken() == Token::kCONTINUE) {
statement = ParseJump(label_name);
AddNodeForFinallyInlining(statement);
ExpectSemicolon();
} else if (CurrentToken() == Token::kSEMICOLON) {
// Empty statement, nothing to do.
ConsumeToken();
} else if ((CurrentToken() == Token::kRETHROW) ||
((CurrentToken() == Token::kTHROW) &&
(LookaheadToken(1) == Token::kSEMICOLON))) {
// Rethrow of current exception. Throwing of an exception object
// is an expression and is handled in ParseExpr().
// TODO(hausner): remove support for 'throw;'.
ConsumeToken();
ExpectSemicolon();
// Check if it is ok to do a rethrow.
SourceLabel* label = current_block_->scope->LookupInnermostCatchLabel();
if (label == NULL ||
label->FunctionLevel() != current_block_->scope->function_level()) {
ErrorMsg(statement_pos, "rethrow of an exception is not valid here");
}
ASSERT(label->owner() != NULL);
LocalScope* scope = label->owner()->parent();
ASSERT(scope != NULL);
LocalVariable* excp_var =
scope->LocalLookupVariable(Symbols::ExceptionVar());
ASSERT(excp_var != NULL);
LocalVariable* trace_var =
scope->LocalLookupVariable(Symbols::StacktraceVar());
ASSERT(trace_var != NULL);
statement = new ThrowNode(statement_pos,
new LoadLocalNode(statement_pos, excp_var),
new LoadLocalNode(statement_pos, trace_var));
} else {
statement = ParseExpr(kAllowConst, kConsumeCascades);
ExpectSemicolon();
}
return statement;
}
RawError* Parser::FormatErrorWithAppend(const Error& prev_error,
const Script& script,
intptr_t token_pos,
const char* message_header,
const char* format,
va_list args) {
const String& msg1 = String::Handle(String::New(prev_error.ToErrorCString()));
const String& msg2 = String::Handle(
FormatMessage(script, token_pos, message_header, format, args));
return LanguageError::New(String::Handle(String::Concat(msg1, msg2)));
}
RawError* Parser::FormatError(const Script& script,
intptr_t token_pos,
const char* message_header,
const char* format,
va_list args) {
const String& msg = String::Handle(
FormatMessage(script, token_pos, message_header, format, args));
return LanguageError::New(msg);
}
RawError* Parser::FormatErrorMsg(const Script& script,
intptr_t token_pos,
const char* message_header,
const char* format, ...) {
va_list args;
va_start(args, format);
const Error& error = Error::Handle(
FormatError(script, token_pos, message_header, format, args));
va_end(args);
return error.raw();
}
RawString* Parser::FormatMessage(const Script& script,
intptr_t token_pos,
const char* message_header,
const char* format, va_list args) {
String& result = String::Handle();
const String& msg = String::Handle(String::NewFormattedV(format, args));
if (!script.IsNull()) {
const String& script_url = String::Handle(script.url());
if (token_pos >= 0) {
intptr_t line, column;
script.GetTokenLocation(token_pos, &line, &column);
result = String::NewFormatted("'%s': %s: line %"Pd" pos %"Pd": ",
script_url.ToCString(),
message_header,
line,
column);
// Append the formatted error or warning message.
result = String::Concat(result, msg);
const String& new_line = String::Handle(String::New("\n"));
// Append the source line.
const String& script_line = String::Handle(script.GetLine(line));
ASSERT(!script_line.IsNull());
result = String::Concat(result, new_line);
result = String::Concat(result, script_line);
result = String::Concat(result, new_line);
// Append the column marker.
const String& column_line = String::Handle(
String::NewFormatted("%*s\n", static_cast<int>(column), "^"));
result = String::Concat(result, column_line);
} else {
// Token position is unknown.
result = String::NewFormatted("'%s': %s: ",
script_url.ToCString(),
message_header);
result = String::Concat(result, msg);
}
} else {
// Script is unknown.
// Append the formatted error or warning message.
result = msg.raw();
}
return result.raw();
}
void Parser::PrintMessage(const Script& script,
intptr_t token_pos,
const char* message_header,
const char* format, ...) {
va_list args;
va_start(args, format);
const String& buf = String::Handle(
FormatMessage(script, token_pos, message_header, format, args));
va_end(args);
OS::Print("%s", buf.ToCString());
}
void Parser::ErrorMsg(intptr_t token_pos, const char* format, ...) {
va_list args;
va_start(args, format);
const Error& error = Error::Handle(
FormatError(script_, token_pos, "Error", format, args));
va_end(args);
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
}
void Parser::ErrorMsg(const char* format, ...) {
va_list args;
va_start(args, format);
const Error& error = Error::Handle(
FormatError(script_, TokenPos(), "Error", format, args));
va_end(args);
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
}
void Parser::ErrorMsg(const Error& error) {
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
}
void Parser::AppendErrorMsg(
const Error& prev_error, intptr_t token_pos, const char* format, ...) {
va_list args;
va_start(args, format);
const Error& error = Error::Handle(FormatErrorWithAppend(
prev_error, script_, token_pos, "Error", format, args));
va_end(args);
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
}
void Parser::Warning(intptr_t token_pos, const char* format, ...) {
if (FLAG_silent_warnings) return;
va_list args;
va_start(args, format);
const Error& error = Error::Handle(
FormatError(script_, token_pos, "Warning", format, args));
va_end(args);
if (FLAG_warning_as_error) {
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
} else {
OS::Print("%s", error.ToErrorCString());
}
}
void Parser::Warning(const char* format, ...) {
if (FLAG_silent_warnings) return;
va_list args;
va_start(args, format);
const Error& error = Error::Handle(
FormatError(script_, TokenPos(), "Warning", format, args));
va_end(args);
if (FLAG_warning_as_error) {
Isolate::Current()->long_jump_base()->Jump(1, error);
UNREACHABLE();
} else {
OS::Print("%s", error.ToErrorCString());
}
}
void Parser::Unimplemented(const char* msg) {
ErrorMsg(TokenPos(), "%s", msg);
}
void Parser::ExpectToken(Token::Kind token_expected) {
if (CurrentToken() != token_expected) {
ErrorMsg("'%s' expected", Token::Str(token_expected));
}
ConsumeToken();
}
void Parser::ExpectSemicolon() {
if (CurrentToken() != Token::kSEMICOLON) {
ErrorMsg("semicolon expected");
}
ConsumeToken();
}
void Parser::UnexpectedToken() {
ErrorMsg("unexpected token '%s'",
CurrentToken() == Token::kIDENT ?
CurrentLiteral()->ToCString() : Token::Str(CurrentToken()));
}
String* Parser::ExpectUserDefinedTypeIdentifier(const char* msg) {
if (CurrentToken() != Token::kIDENT) {
ErrorMsg("%s", msg);
}
String* ident = CurrentLiteral();
if (ident->Equals("dynamic")) {
ErrorMsg("%s", msg);
}
ConsumeToken();
return ident;
}
// Check whether current token is an identifier or a built-in identifier.
String* Parser::ExpectIdentifier(const char* msg) {
if (!IsIdentifier()) {
ErrorMsg("%s", msg);
}
String* ident = CurrentLiteral();
ConsumeToken();
return ident;
}
bool Parser::IsLiteral(const char* literal) {
return IsIdentifier() && CurrentLiteral()->Equals(literal);
}
static bool IsIncrementOperator(Token::Kind token) {
return token == Token::kINCR || token == Token::kDECR;
}
static bool IsPrefixOperator(Token::Kind token) {
return (token == Token::kTIGHTADD) || // Valid for literals only!
(token == Token::kSUB) ||
(token == Token::kNOT) ||
(token == Token::kBIT_NOT);
}
SequenceNode* Parser::NodeAsSequenceNode(intptr_t sequence_pos,
AstNode* node,
LocalScope* scope) {
if ((node == NULL) || !node->IsSequenceNode()) {
SequenceNode* sequence = new SequenceNode(sequence_pos, scope);
if (node != NULL) {
sequence->Add(node);
}
return sequence;
}
return node->AsSequenceNode();
}
AstNode* Parser::ThrowTypeError(intptr_t type_pos, const AbstractType& type) {
ASSERT(type.IsMalformed());
ArgumentListNode* arguments = new ArgumentListNode(type_pos);
// Location argument.
arguments->Add(new LiteralNode(
type_pos, Integer::ZoneHandle(Integer::New(type_pos))));
// Src value argument.
arguments->Add(new LiteralNode(type_pos, Instance::ZoneHandle()));
// Dst type name argument.
arguments->Add(new LiteralNode(type_pos, Symbols::Malformed()));
// Dst name argument.
arguments->Add(new LiteralNode(type_pos, Symbols::Empty()));
// Malformed type error.
const Error& error = Error::Handle(type.malformed_error());
arguments->Add(new LiteralNode(type_pos, String::ZoneHandle(
Symbols::New(error.ToErrorCString()))));
return MakeStaticCall(Symbols::TypeError(),
PrivateCoreLibName(Symbols::ThrowNew()),
arguments);
}
// TODO(regis): Providing the argument values is not always feasible, since
// evaluating them could throw an error.
// Should NoSuchMethodError reflect the argument count and names instead of
// argument values? Or should the spec specify a different evaluation order?
AstNode* Parser::ThrowNoSuchMethodError(intptr_t call_pos,
const Class& cls,
const String& function_name,
InvocationMirror::Call im_call,
InvocationMirror::Type im_type) {
ArgumentListNode* arguments = new ArgumentListNode(call_pos);
// Object receiver.
// TODO(regis): For now, we pass a class literal of the unresolved
// method's owner, but this is not specified and will probably change.
Type& type = Type::ZoneHandle(
Type::New(cls, TypeArguments::Handle(), call_pos, Heap::kOld));
type ^= ClassFinalizer::FinalizeType(
current_class(), type, ClassFinalizer::kCanonicalize);
arguments->Add(new LiteralNode(call_pos, type));
// String memberName.
arguments->Add(new LiteralNode(
call_pos, String::ZoneHandle(Symbols::New(function_name))));
// Smi invocation_type.
if (cls.IsTopLevel()) {
ASSERT(im_call == InvocationMirror::kStatic ||
im_call == InvocationMirror::kTopLevel);
im_call = InvocationMirror::kTopLevel;
}
arguments->Add(new LiteralNode(call_pos, Smi::ZoneHandle(
Smi::New(InvocationMirror::EncodeType(im_call, im_type)))));
// List arguments.
arguments->Add(new LiteralNode(call_pos, Array::ZoneHandle()));
// List argumentNames.
arguments->Add(new LiteralNode(call_pos, Array::ZoneHandle()));
// List existingArgumentNames.
// Check if there exists a function with the same name.
Function& function =
Function::Handle(cls.LookupStaticFunction(function_name));
if (function.IsNull()) {
// TODO(srdjan): Store argument values into the argument list.
arguments->Add(new LiteralNode(call_pos, Array::ZoneHandle()));
} else {
const int total_num_parameters = function.NumParameters();
Array& array = Array::ZoneHandle(Array::New(total_num_parameters));
array ^= array.Canonicalize();
// Skip receiver.
for (int i = 0; i < total_num_parameters; i++) {
array.SetAt(i, String::Handle(function.ParameterNameAt(i)));
}
arguments->Add(new LiteralNode(call_pos, array));
}
return MakeStaticCall(Symbols::NoSuchMethodError(),
PrivateCoreLibName(Symbols::ThrowNew()),
arguments);
}
AstNode* Parser::ParseBinaryExpr(int min_preced) {
TRACE_PARSER("ParseBinaryExpr");
ASSERT(min_preced >= 4);
AstNode* left_operand = ParseUnaryExpr();
if (left_operand->IsPrimaryNode() &&
(left_operand->AsPrimaryNode()->IsSuper())) {
ErrorMsg(left_operand->token_pos(), "illegal use of 'super'");
}
if (IsLiteral("as")) { // Not a reserved word.
token_kind_ = Token::kAS;
}
int current_preced = Token::Precedence(CurrentToken());
while (current_preced >= min_preced) {
while (Token::Precedence(CurrentToken()) == current_preced) {
Token::Kind op_kind = CurrentToken();
if (op_kind == Token::kTIGHTADD) {
op_kind = Token::kADD;
}
const intptr_t op_pos = TokenPos();
ConsumeToken();
AstNode* right_operand = NULL;
if ((op_kind != Token::kIS) && (op_kind != Token::kAS)) {
right_operand = ParseBinaryExpr(current_preced + 1);
} else {
// For 'is' and 'as' we expect the right operand to be a type.
if ((op_kind == Token::kIS) && (CurrentToken() == Token::kNOT)) {
ConsumeToken();
op_kind = Token::kISNOT;
}
const intptr_t type_pos = TokenPos();
const AbstractType& type = AbstractType::ZoneHandle(
ParseType(ClassFinalizer::kCanonicalizeExpression));
if (!type.IsInstantiated() &&
(current_block_->scope->function_level() > 0)) {
// Make sure that the instantiator is captured.
CaptureInstantiator();
}
right_operand = new TypeNode(type_pos, type);
if (((op_kind == Token::kIS) || (op_kind == Token::kISNOT)) &&
type.IsMalformed()) {
// Note that a type error is thrown even if the tested value is null
// in a type test. However, no cast exception is thrown if the value
// is null in a type cast.
return ThrowTypeError(type_pos, type);
}
}
if (Token::IsRelationalOperator(op_kind)
|| Token::IsTypeTestOperator(op_kind)
|| Token::IsTypeCastOperator(op_kind)
|| Token::IsEqualityOperator(op_kind)) {
if (Token::IsTypeTestOperator(op_kind) ||
Token::IsTypeCastOperator(op_kind)) {
if (!right_operand->AsTypeNode()->type().IsInstantiated()) {
EnsureExpressionTemp();
}
}
left_operand = new ComparisonNode(
op_pos, op_kind, left_operand, right_operand);
break; // Equality and relational operators cannot be chained.
} else {
left_operand = OptimizeBinaryOpNode(
op_pos, op_kind, left_operand, right_operand);
}
}
current_preced--;
}
return left_operand;
}
bool Parser::IsAssignableExpr(AstNode* expr) {
return (expr->IsLoadLocalNode() && !expr->AsLoadLocalNode()->HasPseudo()
&& (!expr->AsLoadLocalNode()->local().is_final()))
|| expr->IsLoadStaticFieldNode()
|| expr->IsStaticGetterNode()
|| expr->IsInstanceGetterNode()
|| expr->IsLoadIndexedNode()
|| (expr->IsPrimaryNode() && !expr->AsPrimaryNode()->IsSuper());
}
AstNode* Parser::ParseExprList() {
TRACE_PARSER("ParseExprList");
AstNode* expressions = ParseExpr(kAllowConst, kConsumeCascades);
if (CurrentToken() == Token::kCOMMA) {
// Collect comma-separated expressions in a non scope owning sequence node.
SequenceNode* list = new SequenceNode(TokenPos(), NULL);
list->Add(expressions);
while (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
AstNode* expr = ParseExpr(kAllowConst, kConsumeCascades);
list->Add(expr);
}
expressions = list;
}
return expressions;
}
const LocalVariable* Parser::GetIncrementTempLocal() {
if (!parsed_function()->has_expression_temp_var()) {
LocalVariable* temp = ParsedFunction::CreateExpressionTempVar(
current_function().token_pos());
ASSERT(temp != NULL);
parsed_function()->set_expression_temp_var(temp);
}
ASSERT(parsed_function()->has_expression_temp_var());
return parsed_function()->expression_temp_var();
}
void Parser::EnsureExpressionTemp() {
// Temporary used later by the flow_graph_builder.
GetIncrementTempLocal();
}
void Parser::EnsureSavedCurrentContext() {
// Used later by the flow_graph_builder to save current context.
if (!parsed_function()->has_saved_current_context_var()) {
LocalVariable* temp =
new LocalVariable(current_function().token_pos(),
Symbols::SavedCurrentContextVar(),
Type::ZoneHandle(Type::DynamicType()));
ASSERT(temp != NULL);
parsed_function()->set_saved_current_context_var(temp);
}
}
LocalVariable* Parser::CreateTempConstVariable(intptr_t token_pos,
const char* s) {
char name[64];
OS::SNPrint(name, 64, ":%s%"Pd, s, token_pos);
LocalVariable* temp =
new LocalVariable(token_pos,
String::ZoneHandle(Symbols::New(name)),
Type::ZoneHandle(Type::DynamicType()));
temp->set_is_final();
current_block_->scope->AddVariable(temp);
return temp;
}
// TODO(srdjan): Implement other optimizations.
AstNode* Parser::OptimizeBinaryOpNode(intptr_t op_pos,
Token::Kind binary_op,
AstNode* lhs,
AstNode* rhs) {
LiteralNode* lhs_literal = lhs->AsLiteralNode();
LiteralNode* rhs_literal = rhs->AsLiteralNode();
if ((lhs_literal != NULL) && (rhs_literal != NULL)) {
if (lhs_literal->literal().IsDouble() &&
rhs_literal->literal().IsDouble()) {
double left_double = Double::Cast(lhs_literal->literal()).value();
double right_double = Double::Cast(rhs_literal->literal()).value();
if (binary_op == Token::kDIV) {
const Double& dbl_obj = Double::ZoneHandle(
Double::NewCanonical((left_double / right_double)));
return new LiteralNode(op_pos, dbl_obj);
}
}
}
if ((binary_op == Token::kAND) || (binary_op == Token::kOR)) {
EnsureExpressionTemp();
}
return new BinaryOpNode(op_pos, binary_op, lhs, rhs);
}
AstNode* Parser::ExpandAssignableOp(intptr_t op_pos,
Token::Kind assignment_op,
AstNode* lhs,
AstNode* rhs) {
TRACE_PARSER("ExpandAssignableOp");
switch (assignment_op) {
case Token::kASSIGN:
return rhs;
case Token::kASSIGN_ADD:
return new BinaryOpNode(op_pos, Token::kADD, lhs, rhs);
case Token::kASSIGN_SUB:
return new BinaryOpNode(op_pos, Token::kSUB, lhs, rhs);
case Token::kASSIGN_MUL:
return new BinaryOpNode(op_pos, Token::kMUL, lhs, rhs);
case Token::kASSIGN_TRUNCDIV:
return new BinaryOpNode(op_pos, Token::kTRUNCDIV, lhs, rhs);
case Token::kASSIGN_DIV:
return new BinaryOpNode(op_pos, Token::kDIV, lhs, rhs);
case Token::kASSIGN_MOD:
return new BinaryOpNode(op_pos, Token::kMOD, lhs, rhs);
case Token::kASSIGN_SHR:
return new BinaryOpNode(op_pos, Token::kSHR, lhs, rhs);
case Token::kASSIGN_SHL:
return new BinaryOpNode(op_pos, Token::kSHL, lhs, rhs);
case Token::kASSIGN_OR:
return new BinaryOpNode(op_pos, Token::kBIT_OR, lhs, rhs);
case Token::kASSIGN_AND:
return new BinaryOpNode(op_pos, Token::kBIT_AND, lhs, rhs);
case Token::kASSIGN_XOR:
return new BinaryOpNode(op_pos, Token::kBIT_XOR, lhs, rhs);
default:
ErrorMsg(op_pos, "internal error: ExpandAssignableOp '%s' unimplemented",
Token::Name(assignment_op));
UNIMPLEMENTED();
return NULL;
}
}
// Evaluates the value of the compile time constant expression
// and returns a literal node for the value.
AstNode* Parser::FoldConstExpr(intptr_t expr_pos, AstNode* expr) {
if (expr->IsLiteralNode()) {
return expr;
}
if (expr->EvalConstExpr() == NULL) {
ErrorMsg(expr_pos, "expression must be a compile-time constant");
}
return new LiteralNode(expr_pos, EvaluateConstExpr(expr));
}
// A compound assignment consists of a store and a load part. In order
// to control inputs with potential side effects, the store part stores any
// side effect creating inputs into locals. The load part reads then from
// those locals. If expr may have side effects, it will be split into two new
// left and right nodes. 'expr' becomes the right node, left node is returned as
// result.
AstNode* Parser::PrepareCompoundAssignmentNodes(AstNode** expr) {
AstNode* node = *expr;
if (node->IsLoadIndexedNode()) {
LoadIndexedNode* left_node = node->AsLoadIndexedNode();
LoadIndexedNode* right_node = left_node;
intptr_t token_pos = node->token_pos();
node = NULL; // Do not use it.
if (!IsSimpleLocalOrLiteralNode(left_node->array())) {
LocalVariable* temp =
CreateTempConstVariable(token_pos, "lia");
StoreLocalNode* save =
new StoreLocalNode(token_pos, temp, left_node->array());
left_node = new LoadIndexedNode(token_pos,
save,
left_node->index_expr(),
left_node->super_class());
right_node = new LoadIndexedNode(token_pos,
new LoadLocalNode(token_pos, temp),
right_node->index_expr(),
right_node->super_class());
}
if (!IsSimpleLocalOrLiteralNode(left_node->index_expr())) {
LocalVariable* temp =
CreateTempConstVariable(token_pos, "lix");
StoreLocalNode* save =
new StoreLocalNode(token_pos, temp, left_node->index_expr());
left_node = new LoadIndexedNode(token_pos,
left_node->array(),
save,
left_node->super_class());
right_node = new LoadIndexedNode(token_pos,
right_node->array(),
new LoadLocalNode(token_pos, temp),
right_node->super_class());
}
*expr = right_node;
return left_node;
}
if (node->IsInstanceGetterNode()) {
InstanceGetterNode* left_node = node->AsInstanceGetterNode();
InstanceGetterNode* right_node = left_node;
intptr_t token_pos = node->token_pos();
node = NULL; // Do not use it.
if (!IsSimpleLocalOrLiteralNode(left_node->receiver())) {
LocalVariable* temp =
CreateTempConstVariable(token_pos, "igr");
StoreLocalNode* save =
new StoreLocalNode(token_pos, temp, left_node->receiver());
left_node = new InstanceGetterNode(token_pos,
save,
left_node->field_name());
right_node = new InstanceGetterNode(token_pos,
new LoadLocalNode(token_pos, temp),
right_node->field_name());
}
*expr = right_node;
return left_node;
}
return *expr;
}
// Ensure that the expression temp is allocated for nodes that may need it.
AstNode* Parser::CreateAssignmentNode(AstNode* original, AstNode* rhs) {
AstNode* result = original->MakeAssignmentNode(rhs);
if ((result == NULL) && original->IsTypeNode()) {
const String& type_name = String::ZoneHandle(
original->AsTypeNode()->type().ClassName());
// TODO(tball): determine whether NoSuchMethod should be called instead.
result = ThrowNoSuchMethodError(original->token_pos(),
current_class(),
type_name,
InvocationMirror::kStatic,
InvocationMirror::kSetter);
}
if ((result != NULL) &&
(result->IsStoreIndexedNode() ||
result->IsInstanceSetterNode() ||
result->IsStaticSetterNode() ||
result->IsStoreStaticFieldNode() ||
result->IsStoreLocalNode())) {
EnsureExpressionTemp();
}
return result;
}
AstNode* Parser::ParseCascades(AstNode* expr) {
intptr_t cascade_pos = TokenPos();
LocalVariable* cascade_receiver_var =
CreateTempConstVariable(cascade_pos, "casc");
SequenceNode* cascade = new SequenceNode(cascade_pos, NULL);
StoreLocalNode* save_cascade =
new StoreLocalNode(cascade_pos, cascade_receiver_var, expr);
cascade->Add(save_cascade);
while (CurrentToken() == Token::kCASCADE) {
cascade_pos = TokenPos();
LoadLocalNode* load_cascade_receiver =
new LoadLocalNode(cascade_pos, cascade_receiver_var);
if (Token::IsIdentifier(LookaheadToken(1))) {
// Replace .. with . for ParseSelectors().
token_kind_ = Token::kPERIOD;
} else if (LookaheadToken(1) == Token::kLBRACK) {
ConsumeToken();
} else {
ErrorMsg("identifier or [ expected after ..");
}
expr = ParseSelectors(load_cascade_receiver, true);
// Assignments after a cascade are part of the cascade. The
// assigned expression must not contain cascades.
if (Token::IsAssignmentOperator(CurrentToken())) {
Token::Kind assignment_op = CurrentToken();
const intptr_t assignment_pos = TokenPos();
ConsumeToken();
AstNode* right_expr = ParseExpr(kAllowConst, kNoCascades);
AstNode* left_expr = expr;
if (assignment_op != Token::kASSIGN) {
// Compound assignment: store inputs with side effects into
// temporary locals.
left_expr = PrepareCompoundAssignmentNodes(&expr);
}
right_expr =
ExpandAssignableOp(assignment_pos, assignment_op, expr, right_expr);
AstNode* assign_expr = CreateAssignmentNode(left_expr, right_expr);
if (assign_expr == NULL) {
ErrorMsg(assignment_pos,
"left hand side of '%s' is not assignable",
Token::Str(assignment_op));
}
expr = assign_expr;
}
cascade->Add(expr);
}
// The result is a pair of the (side effects of the) cascade sequence
// followed by the (value of the) receiver temp variable load.
return new LoadLocalNode(cascade_pos, cascade_receiver_var, cascade);
}
AstNode* Parser::ParseExpr(bool require_compiletime_const,
bool consume_cascades) {
TRACE_PARSER("ParseExpr");
const intptr_t expr_pos = TokenPos();
if (CurrentToken() == Token::kTHROW) {
ConsumeToken();
ASSERT(CurrentToken() != Token::kSEMICOLON);
AstNode* expr = ParseExpr(require_compiletime_const, consume_cascades);
return new ThrowNode(expr_pos, expr, NULL);
}
AstNode* expr = ParseConditionalExpr();
if (!Token::IsAssignmentOperator(CurrentToken())) {
if ((CurrentToken() == Token::kCASCADE) && consume_cascades) {
return ParseCascades(expr);
}
if (require_compiletime_const) {
expr = FoldConstExpr(expr_pos, expr);
}
return expr;
}
// Assignment expressions.
Token::Kind assignment_op = CurrentToken();
const intptr_t assignment_pos = TokenPos();
ConsumeToken();
const intptr_t right_expr_pos = TokenPos();
if (require_compiletime_const && (assignment_op != Token::kASSIGN)) {
ErrorMsg(right_expr_pos, "expression must be a compile-time constant");
}
AstNode* right_expr = ParseExpr(require_compiletime_const, consume_cascades);
AstNode* left_expr = expr;
if (assignment_op != Token::kASSIGN) {
// Compound assignment: store inputs with side effects into temp. locals.
left_expr = PrepareCompoundAssignmentNodes(&expr);
}
right_expr =
ExpandAssignableOp(assignment_pos, assignment_op, expr, right_expr);
AstNode* assign_expr = CreateAssignmentNode(left_expr, right_expr);
if (assign_expr == NULL) {
ErrorMsg(assignment_pos,
"left hand side of '%s' is not assignable",
Token::Str(assignment_op));
}
return assign_expr;
}
LiteralNode* Parser::ParseConstExpr() {
TRACE_PARSER("ParseConstExpr");
AstNode* expr = ParseExpr(kRequireConst, kNoCascades);
ASSERT(expr->IsLiteralNode());
return expr->AsLiteralNode();
}
AstNode* Parser::ParseConditionalExpr() {
TRACE_PARSER("ParseConditionalExpr");
const intptr_t expr_pos = TokenPos();
AstNode* expr = ParseBinaryExpr(Token::Precedence(Token::kOR));
if (CurrentToken() == Token::kCONDITIONAL) {
EnsureExpressionTemp();
ConsumeToken();
AstNode* expr1 = ParseExpr(kAllowConst, kNoCascades);
ExpectToken(Token::kCOLON);
AstNode* expr2 = ParseExpr(kAllowConst, kNoCascades);
expr = new ConditionalExprNode(expr_pos, expr, expr1, expr2);
}
return expr;
}
AstNode* Parser::ParseUnaryExpr() {
TRACE_PARSER("ParseUnaryExpr");
AstNode* expr = NULL;
const intptr_t op_pos = TokenPos();
if (IsPrefixOperator(CurrentToken())) {
Token::Kind unary_op = CurrentToken();
if (unary_op == Token::kSUB) {
unary_op = Token::kNEGATE;
}
ConsumeToken();
expr = ParseUnaryExpr();
if (unary_op == Token::kTIGHTADD) {
// kTIGHADD is added only in front of a number literal.
if (!expr->IsLiteralNode()) {
ErrorMsg(op_pos, "unexpected operator '+'");
}
// Expression is the literal itself.
} else if (expr->IsPrimaryNode() && (expr->AsPrimaryNode()->IsSuper())) {
expr = BuildUnarySuperOperator(unary_op, expr->AsPrimaryNode());
} else {
expr = UnaryOpNode::UnaryOpOrLiteral(op_pos, unary_op, expr);
}
} else if (IsIncrementOperator(CurrentToken())) {
Token::Kind incr_op = CurrentToken();
ConsumeToken();
expr = ParseUnaryExpr();
if (!IsAssignableExpr(expr)) {
ErrorMsg("expression is not assignable");
}
// Is prefix.
AstNode* left_expr = PrepareCompoundAssignmentNodes(&expr);
Token::Kind binary_op =
(incr_op == Token::kINCR) ? Token::kADD : Token::kSUB;
BinaryOpNode* add = new BinaryOpNode(
op_pos,
binary_op,
expr,
new LiteralNode(op_pos, Smi::ZoneHandle(Smi::New(1))));
AstNode* store = CreateAssignmentNode(left_expr, add);
ASSERT(store != NULL);
expr = store;
} else {
expr = ParsePostfixExpr();
}
return expr;
}
ArgumentListNode* Parser::ParseActualParameters(
ArgumentListNode* implicit_arguments,
bool require_const) {
TRACE_PARSER("ParseActualParameters");
ASSERT(CurrentToken() == Token::kLPAREN);
const bool saved_mode = SetAllowFunctionLiterals(true);
ArgumentListNode* arguments;
if (implicit_arguments == NULL) {
arguments = new ArgumentListNode(TokenPos());
} else {
arguments = implicit_arguments;
}
const GrowableObjectArray& names =
GrowableObjectArray::Handle(GrowableObjectArray::New());
bool named_argument_seen = false;
if (LookaheadToken(1) != Token::kRPAREN) {
String& arg_name = String::Handle();
do {
ASSERT((CurrentToken() == Token::kLPAREN) ||
(CurrentToken() == Token::kCOMMA));
ConsumeToken();
if (IsIdentifier() && (LookaheadToken(1) == Token::kCOLON)) {
named_argument_seen = true;
// The canonicalization of the arguments descriptor array built in
// the code generator requires that the names are symbols, i.e.
// canonicalized strings.
ASSERT(CurrentLiteral()->IsSymbol());
for (int i = 0; i < names.Length(); i++) {
arg_name ^= names.At(i);
if (CurrentLiteral()->Equals(arg_name)) {
ErrorMsg("duplicate named argument");
}
}
names.Add(*CurrentLiteral());
ConsumeToken(); // ident.
ConsumeToken(); // colon.
} else if (named_argument_seen) {
ErrorMsg("named argument expected");
}
arguments->Add(ParseExpr(require_const, kConsumeCascades));
} while (CurrentToken() == Token::kCOMMA);
} else {
ConsumeToken();
}
ExpectToken(Token::kRPAREN);
SetAllowFunctionLiterals(saved_mode);
if (named_argument_seen) {
arguments->set_names(Array::Handle(Array::MakeArray(names)));
}
return arguments;
}
AstNode* Parser::ParseStaticCall(const Class& cls,
const String& func_name,
intptr_t ident_pos) {
TRACE_PARSER("ParseStaticCall");
const intptr_t call_pos = TokenPos();
ASSERT(CurrentToken() == Token::kLPAREN);
ArgumentListNode* arguments = ParseActualParameters(NULL, kAllowConst);
const int num_arguments = arguments->length();
const Function& func = Function::ZoneHandle(
Resolver::ResolveStatic(cls,
func_name,
num_arguments,
arguments->names(),
Resolver::kIsQualified));
if (func.IsNull()) {
// Check if there is a static field of the same name, it could be a closure
// and so we try and invoke the closure.
AstNode* closure = NULL;
const Field& field = Field::ZoneHandle(cls.LookupStaticField(func_name));
Function& func = Function::ZoneHandle();
if (field.IsNull()) {
// No field, check if we have an explicit getter function.
const String& getter_name =
String::ZoneHandle(Field::GetterName(func_name));
const int kNumArguments = 0; // no arguments.
func = Resolver::ResolveStatic(cls,
getter_name,
kNumArguments,
Object::empty_array(),
Resolver::kIsQualified);
if (!func.IsNull()) {
ASSERT(func.kind() != RawFunction::kConstImplicitGetter);
EnsureSavedCurrentContext();
closure = new StaticGetterNode(call_pos,
NULL,
false,
Class::ZoneHandle(cls.raw()),
func_name);
return new ClosureCallNode(call_pos, closure, arguments);
}
} else {
EnsureSavedCurrentContext();
closure = GenerateStaticFieldLookup(field, call_pos);
return new ClosureCallNode(call_pos, closure, arguments);
}
// Could not resolve static method: throw a NoSuchMethodError.
return ThrowNoSuchMethodError(ident_pos,
cls,
func_name,
InvocationMirror::kStatic,
InvocationMirror::kMethod);
} else if (cls.IsTopLevel() &&
(cls.library() == Library::CoreLibrary()) &&
(func.name() == Symbols::Identical().raw())) {
// This is the predefined toplevel function identical(a,b). Create
// a comparison node instead.
ASSERT(num_arguments == 2);
return new ComparisonNode(ident_pos,
Token::kEQ_STRICT,
arguments->NodeAt(0),
arguments->NodeAt(1));
}
return new StaticCallNode(call_pos, func, arguments);
}
AstNode* Parser::ParseInstanceCall(AstNode* receiver, const String& func_name) {
TRACE_PARSER("ParseInstanceCall");
const intptr_t call_pos = TokenPos();
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg(call_pos, "left parenthesis expected");
}
ArgumentListNode* arguments = ParseActualParameters(NULL, kAllowConst);
return new InstanceCallNode(call_pos, receiver, func_name, arguments);
}
AstNode* Parser::ParseClosureCall(AstNode* closure) {
TRACE_PARSER("ParseClosureCall");
const intptr_t call_pos = TokenPos();
ASSERT(CurrentToken() == Token::kLPAREN);
EnsureSavedCurrentContext();
ArgumentListNode* arguments = ParseActualParameters(NULL, kAllowConst);
return new ClosureCallNode(call_pos, closure, arguments);
}
AstNode* Parser::GenerateStaticFieldLookup(const Field& field,
intptr_t ident_pos) {
// If the static field has an initializer, initialize the field at compile
// time, which is only possible if the field is const.
AstNode* initializing_getter = RunStaticFieldInitializer(field);
if (initializing_getter != NULL) {
// The field is not yet initialized and could not be initialized at compile
// time. The getter will initialize the field.
return initializing_getter;
}
// The field is initialized.
if (field.is_const()) {
ASSERT(field.value() != Object::sentinel().raw());
ASSERT(field.value() != Object::transition_sentinel().raw());
return new LiteralNode(ident_pos, Instance::ZoneHandle(field.value()));
}
// Access the field directly.
return new LoadStaticFieldNode(ident_pos, Field::ZoneHandle(field.raw()));
}
AstNode* Parser::ParseStaticFieldAccess(const Class& cls,
const String& field_name,
intptr_t ident_pos,
bool consume_cascades) {
TRACE_PARSER("ParseStaticFieldAccess");
AstNode* access = NULL;
const intptr_t call_pos = TokenPos();
const Field& field = Field::ZoneHandle(cls.LookupStaticField(field_name));
Function& func = Function::ZoneHandle();
if (Token::IsAssignmentOperator(CurrentToken())) {
// Make sure an assignment is legal.
if (field.IsNull()) {
// No field, check if we have an explicit setter function.
const String& setter_name =
String::ZoneHandle(Field::SetterName(field_name));
const int kNumArguments = 1; // value.
func = Resolver::ResolveStatic(cls,
setter_name,
kNumArguments,
Object::empty_array(),
Resolver::kIsQualified);
if (func.IsNull()) {
// No field or explicit setter function, throw a NoSuchMethodError.
return ThrowNoSuchMethodError(ident_pos,
cls,
field_name,
InvocationMirror::kStatic,
InvocationMirror::kField);
}
// Explicit setter function for the field found, field does not exist.
// Create a getter node first in case it is needed. If getter node
// is used as part of, e.g., "+=", and the explicit getter does not
// exist, and error will be reported by the code generator.
access = new StaticGetterNode(call_pos,
NULL,
false,
Class::ZoneHandle(cls.raw()),
String::ZoneHandle(field_name.raw()));
} else {
// Field exists.
if (field.is_final()) {
// Field has been marked as final, report an error as the field
// is not settable.
ErrorMsg(ident_pos,
"field '%s' is const static, cannot assign to it",
field_name.ToCString());
}
access = GenerateStaticFieldLookup(field, TokenPos());
}
} else { // Not Token::IsAssignmentOperator(CurrentToken()).
if (field.IsNull()) {
// No field, check if we have an explicit getter function.
const String& getter_name =
String::ZoneHandle(Field::GetterName(field_name));
const int kNumArguments = 0; // no arguments.
func = Resolver::ResolveStatic(cls,
getter_name,
kNumArguments,
Object::empty_array(),
Resolver::kIsQualified);
if (func.IsNull()) {
// We might be referring to an implicit closure, check to see if
// there is a function of the same name.
func = cls.LookupStaticFunction(field_name);
if (func.IsNull()) {
// No field or explicit getter function, throw a NoSuchMethodError.
return ThrowNoSuchMethodError(ident_pos,
cls,
field_name,
InvocationMirror::kStatic,
InvocationMirror::kGetter);
}
access = CreateImplicitClosureNode(func, call_pos, NULL);
} else {
ASSERT(func.kind() != RawFunction::kConstImplicitGetter);
access = new StaticGetterNode(call_pos,
NULL,
false,
Class::ZoneHandle(cls.raw()),
field_name);
}
} else {
access = GenerateStaticFieldLookup(field, TokenPos());
}
}
return access;
}
AstNode* Parser::LoadFieldIfUnresolved(AstNode* node) {
if (!node->IsPrimaryNode()) {
return node;
}
PrimaryNode* primary = node->AsPrimaryNode();
if (primary->primary().IsString()) {
if (primary->IsSuper()) {
return primary;
}
// In a static method, evaluation of an unresolved identifier causes a
// NoSuchMethodError to be thrown.
// In an instance method, we convert this into a getter call
// for a field (which may be defined in a subclass.)
String& name = String::CheckedZoneHandle(primary->primary().raw());
if (current_function().is_static() ||
current_function().IsInFactoryScope()) {
return ThrowNoSuchMethodError(primary->token_pos(),
current_class(),
name,
InvocationMirror::kStatic,
InvocationMirror::kField);
} else {
AstNode* receiver = LoadReceiver(primary->token_pos());
return CallGetter(node->token_pos(), receiver, name);
}
}
return primary;
}
AstNode* Parser::LoadClosure(PrimaryNode* primary) {
ASSERT(primary->primary().IsFunction());
AstNode* closure = NULL;
const Function& func =
Function::CheckedZoneHandle(primary->primary().raw());
const String& funcname = String::ZoneHandle(func.name());
if (func.is_static()) {
// Static function access.
closure = CreateImplicitClosureNode(func, primary->token_pos(), NULL);
} else {
// Instance function access.
if (current_function().is_static() ||
current_function().IsInFactoryScope()) {
ErrorMsg(primary->token_pos(),
"cannot access instance method '%s' from static method",
funcname.ToCString());
}
AstNode* receiver = LoadReceiver(primary->token_pos());
closure = CallGetter(primary->token_pos(), receiver, funcname);
}
return closure;
}
AstNode* Parser::ParseSelectors(AstNode* primary, bool is_cascade) {
AstNode* left = primary;
while (true) {
AstNode* selector = NULL;
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
if (left->IsPrimaryNode()) {
if (left->AsPrimaryNode()->primary().IsFunction()) {
left = LoadClosure(left->AsPrimaryNode());
} else {
// Super field access handled in ParseSuperFieldAccess(),
// super calls handled in ParseSuperCall().
ASSERT(!left->AsPrimaryNode()->IsSuper());
left = LoadFieldIfUnresolved(left);
}
}
const intptr_t ident_pos = TokenPos();
String* ident = ExpectIdentifier("identifier expected");
if (CurrentToken() == Token::kLPAREN) {
// Identifier followed by a opening paren: method call.
if (left->IsPrimaryNode() &&
left->AsPrimaryNode()->primary().IsClass()) {
// Static method call prefixed with class name.
const Class& cls = Class::Cast(left->AsPrimaryNode()->primary());
selector = ParseStaticCall(cls, *ident, ident_pos);
} else {
selector = ParseInstanceCall(left, *ident);
}
} else {
// Field access.
Class& cls = Class::Handle();
if (left->IsPrimaryNode()) {
PrimaryNode* primary_node = left->AsPrimaryNode();
if (primary_node->primary().IsClass()) {
// If the primary node referred to a class we are loading a
// qualified static field.
cls ^= primary_node->primary().raw();
}
}
if (cls.IsNull()) {
// Instance field access.
selector = CallGetter(ident_pos, left, *ident);
} else {
// Static field access.
selector =
ParseStaticFieldAccess(cls, *ident, ident_pos, !is_cascade);
}
}
} else if (CurrentToken() == Token::kLBRACK) {
// Super index operator handled in ParseSuperOperator().
ASSERT(!left->IsPrimaryNode() || !left->AsPrimaryNode()->IsSuper());
const intptr_t bracket_pos = TokenPos();
ConsumeToken();
left = LoadFieldIfUnresolved(left);
const bool saved_mode = SetAllowFunctionLiterals(true);
AstNode* index = ParseExpr(kAllowConst, kConsumeCascades);
SetAllowFunctionLiterals(saved_mode);
ExpectToken(Token::kRBRACK);
AstNode* array = left;
if (left->IsPrimaryNode()) {
PrimaryNode* primary = left->AsPrimaryNode();
if (primary->primary().IsFunction()) {
array = LoadClosure(primary);
} else if (primary->primary().IsClass()) {
ErrorMsg(bracket_pos, "cannot apply index operator to class");
} else {
UNREACHABLE(); // Internal parser error.
}
}
selector = new LoadIndexedNode(bracket_pos,
array,
index,
Class::ZoneHandle());
} else if (CurrentToken() == Token::kLPAREN) {
if (left->IsPrimaryNode()) {
PrimaryNode* primary = left->AsPrimaryNode();
const intptr_t primary_pos = primary->token_pos();
if (primary->primary().IsFunction()) {
const Function& func = Function::Cast(primary->primary());
const String& func_name = String::ZoneHandle(func.name());
if (func.is_static()) {
// Parse static function call.
Class& cls = Class::Handle(func.Owner());
selector = ParseStaticCall(cls, func_name, primary_pos);
} else {
// Dynamic function call on implicit "this" parameter.
if (current_function().is_static()) {
ErrorMsg(primary_pos,
"cannot access instance method '%s' "
"from static function",
func_name.ToCString());
}
selector = ParseInstanceCall(LoadReceiver(primary_pos), func_name);
}
} else if (primary->primary().IsString()) {
// Primary is an unresolved name.
if (primary->IsSuper()) {
ErrorMsg(primary->token_pos(), "illegal use of super");
}
String& name = String::CheckedZoneHandle(primary->primary().raw());
if (current_function().is_static()) {
selector = ThrowNoSuchMethodError(primary->token_pos(),
current_class(),
name,
InvocationMirror::kStatic,
InvocationMirror::kMethod);
} else {
// Treat as call to unresolved (instance) method.
AstNode* receiver = LoadReceiver(primary->token_pos());
selector = ParseInstanceCall(receiver, name);
}
} else if (primary->primary().IsClass()) {
ErrorMsg(left->token_pos(),
"must use 'new' or 'const' to construct new instance");
} else {
UNREACHABLE(); // Internal parser error.
}
} else {
// Left is not a primary node; this must be a closure call.
AstNode* closure = left;
selector = ParseClosureCall(closure);
}
} else {
// No (more) selectors to parse.
left = LoadFieldIfUnresolved(left);
if (left->IsPrimaryNode()) {
PrimaryNode* primary = left->AsPrimaryNode();
if (primary->primary().IsFunction()) {
// Treat as implicit closure.
left = LoadClosure(primary);
} else if (primary->primary().IsClass()) {
const Class& type_class = Class::Cast(primary->primary());
Type& type = Type::ZoneHandle(
Type::New(type_class, TypeArguments::Handle(),
primary->token_pos(), Heap::kOld));
type ^= ClassFinalizer::FinalizeType(
current_class(), type, ClassFinalizer::kCanonicalize);
left = new TypeNode(primary->token_pos(), type);
} else if (primary->IsSuper()) {
// Return "super" to handle unary super operator calls,
// or to report illegal use of "super" otherwise.
left = primary;
} else {
UNREACHABLE(); // Internal parser error.
}
}
// Done parsing selectors.
return left;
}
ASSERT(selector != NULL);
left = selector;
}
}
AstNode* Parser::ParsePostfixExpr() {
TRACE_PARSER("ParsePostfixExpr");
const intptr_t postfix_expr_pos = TokenPos();
AstNode* postfix_expr = ParsePrimary();
postfix_expr = ParseSelectors(postfix_expr, false);
if (IsIncrementOperator(CurrentToken())) {
TRACE_PARSER("IncrementOperator");
Token::Kind incr_op = CurrentToken();
if (!IsAssignableExpr(postfix_expr)) {
ErrorMsg("expression is not assignable");
}
ConsumeToken();
// Not prefix.
AstNode* left_expr = PrepareCompoundAssignmentNodes(&postfix_expr);
const LocalVariable* temp = GetIncrementTempLocal();
AstNode* save =
new StoreLocalNode(postfix_expr_pos, temp, postfix_expr);
Token::Kind binary_op =
(incr_op == Token::kINCR) ? Token::kADD : Token::kSUB;
BinaryOpNode* add = new BinaryOpNode(
postfix_expr_pos,
binary_op,
save,
new LiteralNode(postfix_expr_pos, Smi::ZoneHandle(Smi::New(1))));
AstNode* store = CreateAssignmentNode(left_expr, add);
// The result is a pair of the (side effects of the) store followed by
// the (value of the) initial value temp variable load.
LoadLocalNode* load_res =
new LoadLocalNode(postfix_expr_pos, temp, store);
return load_res;
}
return postfix_expr;
}
// Resolve the given type and its type arguments from the given scope class
// according to the given type finalization mode.
// If the given scope class is null, use the current library, but do not try to
// resolve type parameters.
// Not all involved type classes may get resolved yet, but at least the type
// parameters of the given class will get resolved, thereby relieving the class
// finalizer from resolving type parameters out of context.
void Parser::ResolveTypeFromClass(const Class& scope_class,
ClassFinalizer::FinalizationKind finalization,
AbstractType* type) {
ASSERT(finalization >= ClassFinalizer::kTryResolve);
ASSERT(type != NULL);
if (type->IsResolved()) {
return;
}
// Resolve class.
if (!type->HasResolvedTypeClass()) {
const UnresolvedClass& unresolved_class =
UnresolvedClass::Handle(type->unresolved_class());
const String& unresolved_class_name =
String::Handle(unresolved_class.ident());
Class& resolved_type_class = Class::Handle();
if (unresolved_class.library_prefix() == LibraryPrefix::null()) {
if (!scope_class.IsNull()) {
// First check if the type is a type parameter of the given scope class.
const TypeParameter& type_parameter = TypeParameter::Handle(
scope_class.LookupTypeParameter(unresolved_class_name,
type->token_pos()));
if (!type_parameter.IsNull()) {
// A type parameter is considered to be a malformed type when
// referenced by a static member.
if (ParsingStaticMember()) {
ASSERT(scope_class.raw() == current_class().raw());
*type = ClassFinalizer::NewFinalizedMalformedType(
Error::Handle(), // No previous error.
scope_class,
type->token_pos(),
finalization,
"type parameter '%s' cannot be referenced "
"from static member",
String::Handle(type_parameter.name()).ToCString());
return;
}
// A type parameter cannot be parameterized, so make the type
// malformed if type arguments have previously been parsed.
if (!AbstractTypeArguments::Handle(type->arguments()).IsNull()) {
*type = ClassFinalizer::NewFinalizedMalformedType(
Error::Handle(), // No previous error.
scope_class,
type_parameter.token_pos(),
finalization,
"type parameter '%s' cannot be parameterized",
String::Handle(type_parameter.name()).ToCString());
return;
}
*type = type_parameter.raw();
return;
}
}
// Resolve classname in the scope of the current library.
Error& error = Error::Handle();
// If we finalize a type expression, as opposed to a type annotation, we
// tell the resolver (by passing NULL) to immediately report an ambiguous
// type as a compile time error.
resolved_type_class = ResolveClassInCurrentLibraryScope(
unresolved_class.token_pos(),
unresolved_class_name,
finalization >= ClassFinalizer::kCanonicalizeExpression ?
NULL : &error);
if (!error.IsNull()) {
*type = ClassFinalizer::NewFinalizedMalformedType(
error,
scope_class,
unresolved_class.token_pos(),
finalization,
"cannot resolve class '%s'",
unresolved_class_name.ToCString());
return;
}
} else {
LibraryPrefix& lib_prefix =
LibraryPrefix::Handle(unresolved_class.library_prefix());
// Resolve class name in the scope of the library prefix.
Error& error = Error::Handle();
// If we finalize a type expression, as opposed to a type annotation, we
// tell the resolver (by passing NULL) to immediately report an ambiguous
// type as a compile time error.
resolved_type_class = ResolveClassInPrefixScope(
unresolved_class.token_pos(),
lib_prefix,
unresolved_class_name,
finalization >= ClassFinalizer::kCanonicalizeExpression ?
NULL : &error);
if (!error.IsNull()) {
*type = ClassFinalizer::NewFinalizedMalformedType(
error,
scope_class,
unresolved_class.token_pos(),
finalization,
"cannot resolve class '%s'",
unresolved_class_name.ToCString());
return;
}
}
// At this point, we can only have a parameterized_type.
Type& parameterized_type = Type::Handle();
parameterized_type ^= type->raw();
if (!resolved_type_class.IsNull()) {
// Replace unresolved class with resolved type class.
parameterized_type.set_type_class(resolved_type_class);
} else if (finalization >= ClassFinalizer::kCanonicalize) {
// The type is malformed.
ClassFinalizer::FinalizeMalformedType(
Error::Handle(), // No previous error.
current_class(), parameterized_type, finalization,
"type '%s' is not loaded",
String::Handle(parameterized_type.UserVisibleName()).ToCString());
}
}
// Resolve type arguments, if any.
const AbstractTypeArguments& arguments =
AbstractTypeArguments::Handle(type->arguments());
if (!arguments.IsNull()) {
const intptr_t num_arguments = arguments.Length();
for (intptr_t i = 0; i < num_arguments; i++) {
AbstractType& type_argument = AbstractType::Handle(arguments.TypeAt(i));
ResolveTypeFromClass(scope_class, finalization, &type_argument);
arguments.SetTypeAt(i, type_argument);
}
}
}
LocalVariable* Parser::LookupLocalScope(const String& ident) {
if (current_block_ == NULL) {
return NULL;
}
// A found name is treated as accessed and possibly marked as captured.
const bool kTestOnly = false;
return current_block_->scope->LookupVariable(ident, kTestOnly);
}
// Returns true if ident resolves to a formal parameter of the current function
// or of one of its enclosing functions.
// Make sure not to capture the formal parameter, since it is not accessed.
bool Parser::IsFormalParameter(const String& ident,
Function* owner_function,
LocalScope** owner_scope,
intptr_t* local_index) {
if (current_block_ == NULL) {
return false;
}
if (ident.Equals(Symbols::This())) {
// 'this' is not a formal parameter that can be tested with '?this'.
return false;
}
// Since an argument definition test does not use the value of the formal
// parameter, there is no reason to capture it.
const bool kTestOnly = true; // No capturing.
LocalVariable* local =
current_block_->scope->LookupVariable(ident, kTestOnly);
if ((local == NULL) ||
(local->owner()->HasContextLevel() &&
(local->owner()->context_level() < 1))) {
if ((local == NULL) && !current_function().IsLocalFunction()) {
// We are not generating code for a local function, so all locals,
// captured or not, are in scope. However, 'ident' was not found, so it
// does not exist.
return false;
}
// The formal parameter belongs to an enclosing function and may not have
// been captured, so it was not included in the context scope and it cannot
// be found by LookupVariable.
ASSERT((local == NULL) || local->is_captured());
// 'ident' necessarily refers to the formal parameter of one of the
// enclosing functions, or a compile error would have prevented the
// outermost enclosing function to be executed and we would not be compiling
// this local function.
// Therefore, look for ident directly in the formal parameter lists of the
// enclosing functions.
// There is no need to return the owner_scope, since the caller will not
// create the saved_arguments_descriptor variable, which already exists.
Function& function = Function::Handle(innermost_function().raw());
String& param_name = String::Handle();
do {
const int num_parameters = function.NumParameters();
for (intptr_t i = 0; i < num_parameters; i++) {
param_name = function.ParameterNameAt(i);
if (ident.Equals(param_name)) {
*owner_function = function.raw();
*owner_scope = NULL;
*local_index = i;
return true;
}
}
function = function.parent_function();
} while (!function.IsNull());
UNREACHABLE();
}
// Verify that local is a formal parameter of the current function or of one
// of its enclosing functions.
// Note that scopes are not yet associated to functions.
Function& function = Function::Handle(innermost_function().raw());
LocalScope* scope = current_block_->scope;
while (scope != NULL) {
ASSERT(!function.IsNull());
// Find the top scope for this function level.
while ((scope->parent() != NULL) &&
(scope->parent()->function_level() == scope->function_level())) {
scope = scope->parent();
}
if (scope == local->owner()) {
// Scope contains 'local' and the formal parameters of 'function'.
const int num_parameters = function.NumParameters();
for (intptr_t i = 0; i < num_parameters; i++) {
if (scope->VariableAt(i) == local) {
*owner_function = function.raw();
*owner_scope = scope;
*local_index = i;
return true;
}
}
// The variable 'local' is not a formal parameter.
return false;
}
scope = scope->parent();
function = function.parent_function();
}
// The variable 'local' does not belong to a function top scope.
return false;
}
void Parser::CheckInstanceFieldAccess(intptr_t field_pos,
const String& field_name) {
// Fields are not accessible from a static function, except from a
// constructor, which is considered as non-static by the compiler.
if (current_function().is_static()) {
ErrorMsg(field_pos,
"cannot access instance field '%s' from a static function",
field_name.ToCString());
}
}
bool Parser::ParsingStaticMember() const {
if (is_top_level_) {
return (current_member_ != NULL) &&
current_member_->has_static && !current_member_->has_factory;
}
ASSERT(!current_function().IsNull());
return
current_function().is_static() && !current_function().IsInFactoryScope();
}
const Type* Parser::ReceiverType(intptr_t type_pos) const {
ASSERT(!current_class().IsNull());
TypeArguments& type_arguments = TypeArguments::Handle();
if (current_class().NumTypeParameters() > 0) {
type_arguments = current_class().type_parameters();
}
Type& type = Type::ZoneHandle(
Type::New(current_class(), type_arguments, type_pos));
if (!is_top_level_) {
type ^= ClassFinalizer::FinalizeType(
current_class(), type, ClassFinalizer::kCanonicalizeWellFormed);
}
return &type;
}
bool Parser::IsInstantiatorRequired() const {
ASSERT(!current_function().IsNull());
if (current_function().is_static() &&
!current_function().IsInFactoryScope()) {
return false;
}
return current_class().NumTypeParameters() > 0;
}
// If the field is already initialized, return no ast (NULL).
// Otherwise, if the field is constant, initialize the field and return no ast.
// If the field is not initialized and not const, return the ast for the getter.
AstNode* Parser::RunStaticFieldInitializer(const Field& field) {
ASSERT(field.is_static());
const Instance& value = Instance::Handle(field.value());
if (value.raw() == Object::transition_sentinel().raw()) {
if (field.is_const()) {
ErrorMsg("circular dependency while initializing static field '%s'",
String::Handle(field.name()).ToCString());
} else {
// The implicit static getter will throw the exception if necessary.
return new StaticGetterNode(TokenPos(),
NULL,
false,
Class::ZoneHandle(field.owner()),
String::ZoneHandle(field.name()));
}
} else if (value.raw() == Object::sentinel().raw()) {
// This field has not been referenced yet and thus the value has
// not been evaluated. If the field is const, call the static getter method
// to evaluate the expression and canonicalize the value.
if (field.is_const()) {
field.set_value(Object::transition_sentinel());
const String& field_name = String::Handle(field.name());
const String& getter_name =
String::Handle(Field::GetterName(field_name));
const Class& cls = Class::Handle(field.owner());
const int kNumArguments = 0; // no arguments.
const Function& func =
Function::Handle(Resolver::ResolveStatic(cls,
getter_name,
kNumArguments,
Object::empty_array(),
Resolver::kIsQualified));
ASSERT(!func.IsNull());
ASSERT(func.kind() == RawFunction::kConstImplicitGetter);
Object& const_value = Object::Handle(
DartEntry::InvokeFunction(func, Object::empty_array()));
if (const_value.IsError()) {
const Error& error = Error::Cast(const_value);
if (error.IsUnhandledException()) {
field.set_value(Instance::Handle());
// It is a compile-time error if evaluation of a compile-time constant
// would raise an exception.
AppendErrorMsg(error, TokenPos(),
"error initializing const field '%s'",
String::Handle(field.name()).ToCString());
} else {
Isolate::Current()->long_jump_base()->Jump(1, error);
}
}
ASSERT(const_value.IsNull() || const_value.IsInstance());
Instance& instance = Instance::Handle();
instance ^= const_value.raw();
if (!instance.IsNull()) {
instance ^= instance.Canonicalize();
}
field.set_value(instance);
} else {
return new StaticGetterNode(TokenPos(),
NULL,
false,
Class::ZoneHandle(field.owner()),
String::ZoneHandle(field.name()));
}
}
return NULL;
}
RawObject* Parser::EvaluateConstConstructorCall(
const Class& type_class,
const AbstractTypeArguments& type_arguments,
const Function& constructor,
ArgumentListNode* arguments) {
const int kNumExtraArgs = 2; // implicit rcvr and construction phase args.
const int num_arguments = arguments->length() + kNumExtraArgs;
const Array& arg_values = Array::Handle(Array::New(num_arguments));
Instance& instance = Instance::Handle();
ASSERT(!constructor.IsFactory());
instance = Instance::New(type_class, Heap::kOld);
if (!type_arguments.IsNull()) {
if (!type_arguments.IsInstantiated()) {
ErrorMsg("type must be constant in const constructor");
}
instance.SetTypeArguments(
AbstractTypeArguments::Handle(type_arguments.Canonicalize()));
}
arg_values.SetAt(0, instance);
arg_values.SetAt(1, Smi::Handle(Smi::New(Function::kCtorPhaseAll)));
for (int i = 0; i < arguments->length(); i++) {
AstNode* arg = arguments->NodeAt(i);
// Arguments have been evaluated to a literal value already.
ASSERT(arg->IsLiteralNode());
arg_values.SetAt((i + kNumExtraArgs), arg->AsLiteralNode()->literal());
}
const Array& arg_descriptor =
Array::Handle(ArgumentsDescriptor::New(num_arguments,
arguments->names()));
const Object& result =
Object::Handle(DartEntry::InvokeFunction(constructor,
arg_values,
arg_descriptor));
if (result.IsError()) {
if (result.IsUnhandledException()) {
return result.raw();
} else {
Isolate::Current()->long_jump_base()->Jump(1, Error::Cast(result));
UNREACHABLE();
return Object::null();
}
} else {
if (!instance.IsNull()) {
instance ^= instance.Canonicalize();
}
return instance.raw();
}
}
// Do a lookup for the identifier in the block scope and the class scope
// return true if the identifier is found, false otherwise.
// If node is non NULL return an AST node corresponding to the identifier.
bool Parser::ResolveIdentInLocalScope(intptr_t ident_pos,
const String &ident,
AstNode** node) {
TRACE_PARSER("ResolveIdentInLocalScope");
Isolate* isolate = Isolate::Current();
// First try to find the identifier in the nested local scopes.
LocalVariable* local = LookupLocalScope(ident);
if (local != NULL) {
if (node != NULL) {
if (local->IsConst()) {
*node = new LiteralNode(ident_pos, *local->ConstValue());
} else {
*node = new LoadLocalNode(ident_pos, local);
}
}
return true;
}
// Try to find the identifier in the class scope of the current class.
// If the current class is the result of a mixin application, we must
// use the class scope of the class from which the function originates.
Class& cls = Class::Handle(isolate);
if (current_class().mixin() == Type::null()) {
cls = current_class().raw();
} else {
cls = parsed_function()->function().origin();
}
Function& func = Function::Handle(isolate, Function::null());
Field& field = Field::Handle(isolate, Field::null());
// First check if a field exists.
field = cls.LookupField(ident);
if (!field.IsNull()) {
if (node != NULL) {
if (!field.is_static()) {
CheckInstanceFieldAccess(ident_pos, ident);
*node = CallGetter(ident_pos, LoadReceiver(ident_pos), ident);
} else {
*node = GenerateStaticFieldLookup(field, ident_pos);
}
}
return true;
}
// Check if an instance/static function exists.
func = cls.LookupFunction(ident);
if (!func.IsNull() &&
(func.IsDynamicFunction() || func.IsStaticFunction())) {
if (node != NULL) {
*node = new PrimaryNode(ident_pos,
Function::ZoneHandle(isolate, func.raw()));
}
return true;
}
// Now check if a getter/setter method exists for it in which case
// it is still a field.
func = cls.LookupGetterFunction(ident);
if (!func.IsNull()) {
if (func.IsDynamicFunction()) {
if (node != NULL) {
CheckInstanceFieldAccess(ident_pos, ident);
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
*node = CallGetter(ident_pos, LoadReceiver(ident_pos), ident);
}
return true;
} else if (func.IsStaticFunction()) {
if (node != NULL) {
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
// The static getter may later be changed into a dynamically
// resolved instance setter if no static setter can
// be found.
AstNode* receiver = NULL;
const bool kTestOnly = true;
ASSERT(!current_function().IsInFactoryScope());
if (!current_function().is_static() &&
(LookupReceiver(current_block_->scope, kTestOnly) != NULL)) {
receiver = LoadReceiver(ident_pos);
}
*node = new StaticGetterNode(ident_pos,
receiver,
false,
Class::ZoneHandle(isolate, cls.raw()),
ident);
}
return true;
}
}
func = cls.LookupSetterFunction(ident);
if (!func.IsNull()) {
if (func.IsDynamicFunction()) {
if (node != NULL) {
// We create a getter node even though a getter doesn't exist as
// it could be followed by an assignment which will convert it to
// a setter node. If there is no assignment we will get an error
// when we try to invoke the getter.
CheckInstanceFieldAccess(ident_pos, ident);
ASSERT(AbstractType::Handle(func.result_type()).IsResolved());
*node = CallGetter(ident_pos, LoadReceiver(ident_pos), ident);
}
return true;
} else if (func.IsStaticFunction()) {
if (node != NULL) {
// We create a getter node even though a getter doesn't exist as
// it could be followed by an assignment which will convert it to
// a setter node. If there is no assignment we will get an error
// when we try to invoke the getter.
*node = new StaticGetterNode(ident_pos,
NULL,
false,
Class::ZoneHandle(isolate, cls.raw()),
ident);
}
return true;
}
}
// Nothing found in scope of current class.
if (node != NULL) {
*node = NULL;
}
return false; // Not an unqualified identifier.
}
static RawObject* LookupNameInLibrary(const Library& lib, const String& name) {
Object& obj = Object::Handle();
obj = lib.LookupLocalObject(name);
if (!obj.IsNull()) {
return obj.raw();
}
String& accessor_name = String::Handle(Field::GetterName(name));
obj = lib.LookupLocalObject(accessor_name);
if (!obj.IsNull()) {
return obj.raw();
}
accessor_name = Field::SetterName(name);
obj = lib.LookupLocalObject(accessor_name);
return obj.raw();
}
static RawObject* LookupNameInImport(const Namespace& ns, const String& name) {
Object& obj = Object::Handle();
obj = ns.Lookup(name);
if (!obj.IsNull()) {
return obj.raw();
}
// If the given name is filtered out by the import, don't look up the
// getter and setter names.
if (ns.HidesName(name)) {
return Object::null();
}
String& accessor_name = String::Handle(Field::GetterName(name));
obj = ns.Lookup(accessor_name);
if (!obj.IsNull()) {
return obj.raw();
}
accessor_name = Field::SetterName(name);
obj = ns.Lookup(accessor_name);
return obj.raw();
}
// Resolve a name by checking the global scope of the current
// library. If not found in the current library, then look in the scopes
// of all libraries that are imported without a library prefix.
// Issue an error if the name is not found in the global scope
// of the current library, but is defined in more than one imported
// library, i.e. if the name cannot be resolved unambiguously.
RawObject* Parser::ResolveNameInCurrentLibraryScope(intptr_t ident_pos,
const String& name,
Error* error) {
TRACE_PARSER("ResolveNameInCurrentLibraryScope");
Object& obj = Object::Handle(LookupNameInLibrary(library_, name));
if (obj.IsNull()) {
// Name is not found in current library. Check scope of all
// imported libraries.
String& first_lib_url = String::Handle();
Namespace& import = Namespace::Handle();
intptr_t num_imports = library_.num_imports();
Object& imported_obj = Object::Handle();
for (int i = 0; i < num_imports; i++) {
import = library_.ImportAt(i);
imported_obj = LookupNameInImport(import, name);
if (!imported_obj.IsNull()) {
const Library& lib = Library::Handle(import.library());
// TODO(8474): Remove the "Expect" special casing.
if (!first_lib_url.IsNull()
&& (strcmp(name.ToCString(), "Expect") != 0)
&& (strcmp(name.ToCString(), "ExpectException") != 0)) {
// Found duplicate definition.
Error& ambiguous_ref_error = Error::Handle();
if (first_lib_url.raw() == lib.url()) {
ambiguous_ref_error = FormatErrorMsg(
script_, ident_pos, "Error",
"ambiguous reference: "
"'%s' as library '%s' is imported multiple times",
name.ToCString(),
first_lib_url.ToCString());
} else {
ambiguous_ref_error = FormatErrorMsg(
script_, ident_pos, "Error",
"ambiguous reference: "
"'%s' is defined in library '%s' and also in '%s'",
name.ToCString(),
first_lib_url.ToCString(),
String::Handle(lib.url()).ToCString());
}
if (error == NULL) {
// Report a compile time error since the caller is not interested
// in the error.
ErrorMsg(ambiguous_ref_error);
}
*error = ambiguous_ref_error.raw();
return Object::null();
} else {
first_lib_url = lib.url();
obj = imported_obj.raw();
}
}
}
}
return obj.raw();
}
RawClass* Parser::ResolveClassInCurrentLibraryScope(intptr_t ident_pos,
const String& name,
Error* error) {
const Object& obj =
Object::Handle(ResolveNameInCurrentLibraryScope(ident_pos, name, error));
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
return Class::null();
}
// Resolve an identifier by checking the global scope of the current
// library. If not found in the current library, then look in the scopes
// of all libraries that are imported without a library prefix.
// Issue an error if the identifier is not found in the global scope
// of the current library, but is defined in more than one imported
// library, i.e. if the identifier cannot be resolved unambiguously.
AstNode* Parser::ResolveIdentInCurrentLibraryScope(intptr_t ident_pos,
const String& ident) {
TRACE_PARSER("ResolveIdentInCurrentLibraryScope");
const Object& obj =
Object::Handle(ResolveNameInCurrentLibraryScope(ident_pos, ident, NULL));
if (obj.IsClass()) {
const Class& cls = Class::Cast(obj);
return new PrimaryNode(ident_pos, Class::ZoneHandle(cls.raw()));
} else if (obj.IsField()) {
const Field& field = Field::Cast(obj);
ASSERT(field.is_static());
return GenerateStaticFieldLookup(field, ident_pos);
} else if (obj.IsFunction()) {
const Function& func = Function::Cast(obj);
ASSERT(func.is_static());
if (func.IsGetterFunction() || func.IsSetterFunction()) {
return new StaticGetterNode(ident_pos,
/* receiver */ NULL,
/* is_super_getter */ false,
Class::ZoneHandle(func.Owner()),
ident);
} else {
return new PrimaryNode(ident_pos, Function::ZoneHandle(func.raw()));
}
} else {
ASSERT(obj.IsNull() || obj.IsLibraryPrefix());
}
// Lexically unresolved primary identifiers are referenced by their name.
return new PrimaryNode(ident_pos, ident);
}
RawObject* Parser::ResolveNameInPrefixScope(intptr_t ident_pos,
const LibraryPrefix& prefix,
const String& name,
Error* error) {
TRACE_PARSER("ResolveNameInPrefixScope");
Namespace& import = Namespace::Handle();
String& first_lib_url = String::Handle();
Object& obj = Object::Handle();
Object& resolved_obj = Object::Handle();
const Array& imports = Array::Handle(prefix.imports());
for (intptr_t i = 0; i < prefix.num_imports(); i++) {
import ^= imports.At(i);
resolved_obj = LookupNameInImport(import, name);
if (!resolved_obj.IsNull()) {
obj = resolved_obj.raw();
const Library& lib = Library::Handle(import.library());
if (first_lib_url.IsNull()) {
first_lib_url = lib.url();
} else {
// Found duplicate definition.
Error& ambiguous_ref_error = Error::Handle();
if (first_lib_url.raw() == lib.url()) {
ambiguous_ref_error = FormatErrorMsg(
script_, ident_pos, "Error",
"ambiguous reference: '%s.%s' is imported multiple times",
String::Handle(prefix.name()).ToCString(),
name.ToCString());
} else {
ambiguous_ref_error = FormatErrorMsg(
script_, ident_pos, "Error",
"ambiguous reference: '%s.%s' is defined in '%s' and '%s'",
String::Handle(prefix.name()).ToCString(),
name.ToCString(),
first_lib_url.ToCString(),
String::Handle(lib.url()).ToCString());
}
if (error == NULL) {
// Report a compile time error since the caller is not interested
// in the error.
ErrorMsg(ambiguous_ref_error);
}
*error = ambiguous_ref_error.raw();
return Object::null();
}
}
}
return obj.raw();
}
RawClass* Parser::ResolveClassInPrefixScope(intptr_t ident_pos,
const LibraryPrefix& prefix,
const String& name,
Error* error) {
const Object& obj =
Object::Handle(ResolveNameInPrefixScope(ident_pos, prefix, name, error));
if (obj.IsClass()) {
return Class::Cast(obj).raw();
}
return Class::null();
}
// Do a lookup for the identifier in the scope of the specified
// library prefix. This means trying to resolve it locally in all of the
// libraries present in the library prefix. If there are multiple libraries
// with the name, issue an ambiguous reference error.
AstNode* Parser::ResolveIdentInPrefixScope(intptr_t ident_pos,
const LibraryPrefix& prefix,
const String& ident) {
TRACE_PARSER("ResolveIdentInPrefixScope");
Object& obj =
Object::Handle(ResolveNameInPrefixScope(ident_pos, prefix, ident, NULL));
if (obj.IsNull()) {
// Unresolved prefixed primary identifier.
ErrorMsg(ident_pos, "identifier '%s.%s' cannot be resolved",
String::Handle(prefix.name()).ToCString(),
ident.ToCString());
}
if (obj.IsClass()) {
const Class& cls = Class::Cast(obj);
return new PrimaryNode(ident_pos, Class::ZoneHandle(cls.raw()));
} else if (obj.IsField()) {
const Field& field = Field::Cast(obj);
ASSERT(field.is_static());
return GenerateStaticFieldLookup(field, ident_pos);
} else if (obj.IsFunction()) {
const Function& func = Function::Cast(obj);
ASSERT(func.is_static());
if (func.IsGetterFunction() || func.IsSetterFunction()) {
return new StaticGetterNode(ident_pos,
/* receiver */ NULL,
/* is_super_getter */ false,
Class::ZoneHandle(func.Owner()),
ident);
} else {
return new PrimaryNode(ident_pos, Function::ZoneHandle(func.raw()));
}
} else {
// TODO(hausner): Should this be an error? It is not meaningful to
// reference a library prefix defined in an imported library.
ASSERT(obj.IsLibraryPrefix());
}
// Lexically unresolved primary identifiers are referenced by their name.
return new PrimaryNode(ident_pos, ident);
}
// Resolve identifier, issue an error message if the name refers to
// a class/interface or a type parameter. Issue an error message if
// the ident refers to a method and allow_closure_names is false.
// If the name cannot be resolved, turn it into an instance field access
// if we're compiling an instance method, or issue an error message
// if we're compiling a static method.
AstNode* Parser::ResolveIdent(intptr_t ident_pos,
const String& ident,
bool allow_closure_names) {
TRACE_PARSER("ResolveIdent");
// First try to find the variable in the local scope (block scope or
// class scope).
AstNode* resolved = NULL;
ResolveIdentInLocalScope(ident_pos, ident, &resolved);
if (resolved == NULL) {
// Check whether the identifier is a type parameter. Type parameters
// can never be used in primary expressions.
if (!current_class().IsNull()) {
TypeParameter& type_param = TypeParameter::Handle(
current_class().LookupTypeParameter(ident, ident_pos));
if (!type_param.IsNull()) {
String& type_param_name = String::Handle(type_param.name());
ErrorMsg(ident_pos, "illegal use of type parameter %s",
type_param_name.ToCString());
}
}
// Not found in the local scope, and the name is not a type parameter.
// Try finding the variable in the library scope (current library
// and all libraries imported by it without a library prefix).
resolved = ResolveIdentInCurrentLibraryScope(ident_pos, ident);
}
if (resolved->IsPrimaryNode()) {
PrimaryNode* primary = resolved->AsPrimaryNode();
if (primary->primary().IsString()) {
// We got an unresolved name. If we are compiling a static
// method, evaluation of an unresolved identifier causes a
// NoSuchMethodError to be thrown. In an instance method, we convert
// the unresolved name to an instance field access, since a
// subclass might define a field with this name.
if (current_function().is_static()) {
resolved = ThrowNoSuchMethodError(ident_pos,
current_class(),
ident,
InvocationMirror::kStatic,
InvocationMirror::kField);
} else {
// Treat as call to unresolved instance field.
resolved = CallGetter(ident_pos, LoadReceiver(ident_pos), ident);
}
} else if (primary->primary().IsFunction()) {
if (allow_closure_names) {
resolved = LoadClosure(primary);
} else {
ErrorMsg(ident_pos, "illegal reference to method '%s'",
ident.ToCString());
}
} else {
ASSERT(primary->primary().IsClass());
ErrorMsg(ident_pos, "illegal reference to class or interface '%s'",
ident.ToCString());
}
}
return resolved;
}
// Parses type = [ident "."] ident ["<" type { "," type } ">"], then resolve and
// finalize it according to the given type finalization mode.
RawAbstractType* Parser::ParseType(
ClassFinalizer::FinalizationKind finalization) {
TRACE_PARSER("ParseType");
if (CurrentToken() != Token::kIDENT) {
ErrorMsg("type name expected");
}
QualIdent type_name;
if (finalization == ClassFinalizer::kIgnore) {
SkipQualIdent();
} else {
ParseQualIdent(&type_name);
// An identifier cannot be resolved in a local scope when top level parsing.
if (!is_top_level_ &&
(type_name.lib_prefix == NULL) &&
ResolveIdentInLocalScope(type_name.ident_pos, *type_name.ident, NULL)) {
ErrorMsg(type_name.ident_pos, "using '%s' in this context is invalid",
type_name.ident->ToCString());
}
}
Object& type_class = Object::Handle();
// Leave type_class as null if type finalization mode is kIgnore.
if (finalization != ClassFinalizer::kIgnore) {
LibraryPrefix& lib_prefix = LibraryPrefix::Handle();
if (type_name.lib_prefix != NULL) {
lib_prefix = type_name.lib_prefix->raw();
}
type_class = UnresolvedClass::New(lib_prefix,
*type_name.ident,
type_name.ident_pos);
}
Error& malformed_error = Error::Handle();
AbstractTypeArguments& type_arguments =
AbstractTypeArguments::Handle(ParseTypeArguments(&malformed_error,
finalization));
if (finalization == ClassFinalizer::kIgnore) {
return Type::DynamicType();
}
AbstractType& type = AbstractType::Handle(
Type::New(type_class, type_arguments, type_name.ident_pos));
// In production mode, malformed type arguments are mapped to dynamic.
// In checked mode, a type with malformed type arguments is malformed.
if (FLAG_enable_type_checks && !malformed_error.IsNull()) {
Type& parameterized_type = Type::Handle();
parameterized_type ^= type.raw();
parameterized_type.set_type_class(Class::Handle(Object::dynamic_class()));
parameterized_type.set_arguments(AbstractTypeArguments::Handle());
parameterized_type.set_malformed_error(malformed_error);
}
if (finalization >= ClassFinalizer::kTryResolve) {
ResolveTypeFromClass(current_class(), finalization, &type);
if (finalization >= ClassFinalizer::kCanonicalize) {
type ^= ClassFinalizer::FinalizeType(current_class(), type, finalization);
}
}
return type.raw();
}
void Parser::CheckConstructorCallTypeArguments(
intptr_t pos, Function& constructor,
const AbstractTypeArguments& type_arguments) {
if (!type_arguments.IsNull()) {
const Class& constructor_class = Class::Handle(constructor.Owner());
ASSERT(!constructor_class.IsNull());
ASSERT(constructor_class.is_finalized());
// Do not report the expected vs. actual number of type arguments, because
// the type argument vector is flattened and raw types are allowed.
if (type_arguments.Length() != constructor_class.NumTypeArguments()) {
ErrorMsg(pos, "wrong number of type arguments passed to constructor");
}
}
}
// Parse "[" [ expr { "," expr } ["," ] "]".
// Note: if the list literal is empty and the brackets have no whitespace
// between them, the scanner recognizes the opening and closing bracket
// as one token of type Token::kINDEX.
AstNode* Parser::ParseListLiteral(intptr_t type_pos,
bool is_const,
const AbstractTypeArguments& type_arguments) {
TRACE_PARSER("ParseListLiteral");
ASSERT(type_pos >= 0);
ASSERT(CurrentToken() == Token::kLBRACK || CurrentToken() == Token::kINDEX);
const intptr_t literal_pos = TokenPos();
bool is_empty_literal = CurrentToken() == Token::kINDEX;
ConsumeToken();
AbstractType& element_type = Type::ZoneHandle(Type::DynamicType());
// If no type argument vector is provided, leave it as null, which is
// equivalent to using dynamic as the type argument for the element type.
if (!type_arguments.IsNull()) {
ASSERT(type_arguments.Length() > 0);
// List literals take a single type argument.
element_type = type_arguments.TypeAt(0);
if (type_arguments.Length() != 1) {
ErrorMsg(type_pos,
"a list literal takes one type argument specifying "
"the element type");
}
if (is_const && !element_type.IsInstantiated()) {
ErrorMsg(type_pos,
"the type argument of a constant list literal cannot include "
"a type variable");
}
}
ASSERT(type_arguments.IsNull() || (type_arguments.Length() == 1));
const Class& array_class = Class::Handle(
Isolate::Current()->object_store()->array_class());
Type& type = Type::ZoneHandle(
Type::New(array_class, type_arguments, type_pos));
type ^= ClassFinalizer::FinalizeType(
current_class(), type, ClassFinalizer::kCanonicalize);
GrowableArray<AstNode*> element_list;
// Parse the list elements. Note: there may be an optional extra
// comma after the last element.
if (!is_empty_literal) {
const bool saved_mode = SetAllowFunctionLiterals(true);
while (CurrentToken() != Token::kRBRACK) {
const intptr_t element_pos = TokenPos();
AstNode* element = ParseExpr(is_const, kConsumeCascades);
if (FLAG_enable_type_checks &&
!is_const &&
!element_type.IsDynamicType()) {
element = new AssignableNode(element_pos,
element,
element_type,
Symbols::ListLiteralElement());
}
element_list.Add(element);
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
} else if (CurrentToken() != Token::kRBRACK) {
ErrorMsg("comma or ']' expected");
}
}
ExpectToken(Token::kRBRACK);
SetAllowFunctionLiterals(saved_mode);
}
if (is_const) {
// Allocate and initialize the const list at compile time.
Array& const_list =
Array::ZoneHandle(Array::New(element_list.length(), Heap::kOld));
const_list.SetTypeArguments(
AbstractTypeArguments::Handle(type_arguments.Canonicalize()));
Error& malformed_error = Error::Handle();
for (int i = 0; i < element_list.length(); i++) {
AstNode* elem = element_list[i];
// Arguments have been evaluated to a literal value already.
ASSERT(elem->IsLiteralNode());
if (FLAG_enable_type_checks &&
!element_type.IsDynamicType() &&
(!elem->AsLiteralNode()->literal().IsNull() &&
!elem->AsLiteralNode()->literal().IsInstanceOf(
element_type, TypeArguments::Handle(), &malformed_error))) {
// If the failure is due to a malformed type error, display it instead.
if (!malformed_error.IsNull()) {
ErrorMsg(malformed_error);
} else {
ErrorMsg(elem->AsLiteralNode()->token_pos(),
"list literal element at index %d must be "
"a constant of type '%s'",
i,
String::Handle(element_type.UserVisibleName()).ToCString());
}
}
const_list.SetAt(i, elem->AsLiteralNode()->literal());
}
const_list ^= const_list.Canonicalize();
const_list.MakeImmutable();
return new LiteralNode(literal_pos, const_list);
} else {
// Factory call at runtime.
const Class& factory_class =
Class::Handle(LookupCoreClass(Symbols::List()));
ASSERT(!factory_class.IsNull());
const Function& factory_method = Function::ZoneHandle(
factory_class.LookupFactory(
PrivateCoreLibName(Symbols::ListLiteralFactory())));
ASSERT(!factory_method.IsNull());
if (!type_arguments.IsNull() &&
!type_arguments.IsInstantiated() &&
(current_block_->scope->function_level() > 0)) {
// Make sure that the instantiator is captured.
CaptureInstantiator();
}
AbstractTypeArguments& factory_type_args =
AbstractTypeArguments::ZoneHandle(type_arguments.raw());
// If the factory class extends other parameterized classes, adjust the
// type argument vector.
if (!factory_type_args.IsNull() && (factory_class.NumTypeArguments() > 1)) {
ASSERT(factory_type_args.Length() == 1);
Type& factory_type = Type::Handle(Type::New(
factory_class, factory_type_args, type_pos, Heap::kNew));
factory_type ^= ClassFinalizer::FinalizeType(
current_class(), factory_type, ClassFinalizer::kFinalize);
factory_type_args = factory_type.arguments();
ASSERT(factory_type_args.Length() == factory_class.NumTypeArguments());
}
factory_type_args = factory_type_args.Canonicalize();
ArgumentListNode* factory_param = new ArgumentListNode(literal_pos);
if (element_list.length() == 0) {
// TODO(srdjan): Use Object::empty_array once issue 9871 has been fixed.
Array& empty_array = Array::ZoneHandle(Object::empty_array().raw());
LiteralNode* empty_array_literal =
new LiteralNode(TokenPos(), empty_array);
factory_param->Add(empty_array_literal);
} else {
const LocalVariable& temp_local = *BuildArrayTempLocal(type_pos);
ArrayNode* list =
new ArrayNode(TokenPos(), type, temp_local, element_list);
factory_param->Add(list);
}
return CreateConstructorCallNode(literal_pos,
factory_type_args,
factory_method,
factory_param);
}
}
ConstructorCallNode* Parser::CreateConstructorCallNode(
intptr_t token_pos,
const AbstractTypeArguments& type_arguments,
const Function& constructor,
ArgumentListNode* arguments) {
if (!type_arguments.IsNull() && !type_arguments.IsInstantiated()) {
EnsureExpressionTemp();
}
LocalVariable* allocated =
CreateTempConstVariable(token_pos, "alloc");
return new ConstructorCallNode(token_pos,
type_arguments,
constructor,
arguments,
allocated);
}
static void AddKeyValuePair(GrowableArray<AstNode*>* pairs,
bool is_const,
AstNode* key,
AstNode* value) {
if (is_const) {
ASSERT(key->IsLiteralNode());
ASSERT(key->AsLiteralNode()->literal().IsString());
const Instance& new_key = key->AsLiteralNode()->literal();
for (int i = 0; i < pairs->length(); i += 2) {
const Instance& key_i =
(*pairs)[i]->AsLiteralNode()->literal();
ASSERT(key_i.IsString());
if (new_key.Equals(key_i)) {
// Duplicate key found. The new value replaces the previously
// defined value.
(*pairs)[i + 1] = value;
return;
}
}
}
pairs->Add(key);
pairs->Add(value);
}
AstNode* Parser::ParseMapLiteral(intptr_t type_pos,
bool is_const,
const AbstractTypeArguments& type_arguments) {
TRACE_PARSER("ParseMapLiteral");
ASSERT(type_pos >= 0);
ASSERT(CurrentToken() == Token::kLBRACE);
const intptr_t literal_pos = TokenPos();
ConsumeToken();
AbstractType& value_type = Type::ZoneHandle(Type::DynamicType());
AbstractTypeArguments& map_type_arguments =
AbstractTypeArguments::ZoneHandle(type_arguments.raw());
// If no type argument vector is provided, leave it as null, which is
// equivalent to using dynamic as the type argument for the value type.
if (!map_type_arguments.IsNull()) {
ASSERT(map_type_arguments.Length() > 0);
// Map literals take two type arguments.
if (map_type_arguments.Length() != 2) {
ErrorMsg(type_pos,
"a map literal takes two type arguments specifying "
"the key type and the value type");
}
const AbstractType& key_type =
AbstractType::Handle(map_type_arguments.TypeAt(0));
value_type = map_type_arguments.TypeAt(1);
if (!key_type.IsStringType()) {
ErrorMsg(type_pos, "the key type of a map literal must be 'String'");
}
if (is_const && !value_type.IsInstantiated()) {
ErrorMsg(type_pos,
"the type argument of a constant map literal cannot include "
"a type variable");
}
}
ASSERT(map_type_arguments.IsNull() || (map_type_arguments.Length() == 2));
map_type_arguments ^= map_type_arguments.Canonicalize();
GrowableArray<AstNode*> kv_pairs_list;
// Parse the map entries. Note: there may be an optional extra
// comma after the last entry.
while (CurrentToken() != Token::kRBRACE) {
AstNode* key = NULL;
if (CurrentToken() == Token::kSTRING) {
key = ParseStringLiteral();
}
if (key == NULL) {
ErrorMsg("map entry key must be string literal");
} else if (is_const && !key->IsLiteralNode()) {
ErrorMsg("map entry key must be compile-time constant string");
}
ExpectToken(Token::kCOLON);
const bool saved_mode = SetAllowFunctionLiterals(true);
const intptr_t value_pos = TokenPos();
AstNode* value = ParseExpr(is_const, kConsumeCascades);
SetAllowFunctionLiterals(saved_mode);
if (FLAG_enable_type_checks &&
!is_const &&
!value_type.IsDynamicType()) {
value = new AssignableNode(value_pos,
value,
value_type,
Symbols::ListLiteralElement());
}
AddKeyValuePair(&kv_pairs_list, is_const, key, value);
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
} else if (CurrentToken() != Token::kRBRACE) {
ErrorMsg("comma or '}' expected");
}
}
ASSERT(kv_pairs_list.length() % 2 == 0);
ExpectToken(Token::kRBRACE);
if (is_const) {
// Create the key-value pair array, canonicalize it and then create
// the immutable map object with it. This all happens at compile time.
// The resulting immutable map object is returned as a literal.
// First, create the canonicalized key-value pair array.
Array& key_value_array =
Array::ZoneHandle(Array::New(kv_pairs_list.length(), Heap::kOld));
Error& malformed_error = Error::Handle();
for (int i = 0; i < kv_pairs_list.length(); i++) {
AstNode* arg = kv_pairs_list[i];
// Arguments have been evaluated to a literal value already.
ASSERT(arg->IsLiteralNode());
if (FLAG_enable_type_checks &&
((i % 2) == 1) && // Check values only, not keys.
!value_type.IsDynamicType() &&
(!arg->AsLiteralNode()->literal().IsNull() &&
!arg->AsLiteralNode()->literal().IsInstanceOf(
value_type, TypeArguments::Handle(), &malformed_error))) {
// If the failure is due to a malformed type error, display it instead.
if (!malformed_error.IsNull()) {
ErrorMsg(malformed_error);
} else {
ErrorMsg(arg->AsLiteralNode()->token_pos(),
"map literal value at index %d must be "
"a constant of type '%s'",
i >> 1,
String::Handle(value_type.UserVisibleName()).ToCString());
}
}
key_value_array.SetAt(i, arg->AsLiteralNode()->literal());
}
key_value_array ^= key_value_array.Canonicalize();
key_value_array.MakeImmutable();
// Construct the map object.
const Class& immutable_map_class =
Class::Handle(LookupCoreClass(Symbols::ImmutableMap()));
ASSERT(!immutable_map_class.IsNull());
// If the immutable map class extends other parameterized classes, we need
// to adjust the type argument vector. This is currently not the case.
ASSERT(immutable_map_class.NumTypeArguments() == 2);
ArgumentListNode* constr_args = new ArgumentListNode(TokenPos());
constr_args->Add(new LiteralNode(literal_pos, key_value_array));
const Function& map_constr =
Function::ZoneHandle(immutable_map_class.LookupConstructor(
PrivateCoreLibName(Symbols::ImmutableMapConstructor())));
ASSERT(!map_constr.IsNull());
const Object& constructor_result = Object::Handle(
EvaluateConstConstructorCall(immutable_map_class,
map_type_arguments,
map_constr,
constr_args));
if (constructor_result.IsUnhandledException()) {
return GenerateRethrow(literal_pos, constructor_result);
} else {
const Instance& const_instance = Instance::Cast(constructor_result);
return new LiteralNode(literal_pos,
Instance::ZoneHandle(const_instance.raw()));
}
} else {
// Factory call at runtime.
const Class& factory_class =
Class::Handle(LookupCoreClass(Symbols::Map()));
ASSERT(!factory_class.IsNull());
const Function& factory_method = Function::ZoneHandle(
factory_class.LookupFactory(
PrivateCoreLibName(Symbols::MapLiteralFactory())));
ASSERT(!factory_method.IsNull());
if (!map_type_arguments.IsNull() &&
!map_type_arguments.IsInstantiated() &&
(current_block_->scope->function_level() > 0)) {
// Make sure that the instantiator is captured.
CaptureInstantiator();
}
AbstractTypeArguments& factory_type_args =
AbstractTypeArguments::ZoneHandle(map_type_arguments.raw());
// If the factory class extends other parameterized classes, adjust the
// type argument vector.
if (!factory_type_args.IsNull() && (factory_class.NumTypeArguments() > 2)) {
ASSERT(factory_type_args.Length() == 2);
Type& factory_type = Type::Handle(Type::New(
factory_class, factory_type_args, type_pos, Heap::kNew));
factory_type ^= ClassFinalizer::FinalizeType(
current_class(), factory_type, ClassFinalizer::kFinalize);
factory_type_args = factory_type.arguments();
ASSERT(factory_type_args.Length() == factory_class.NumTypeArguments());
}
factory_type_args = factory_type_args.Canonicalize();
ArgumentListNode* factory_param = new ArgumentListNode(literal_pos);
// The kv_pair array is temporary and of element type dynamic. It is passed
// to the factory to initialize a properly typed map.
ArrayNode* kv_pairs = new ArrayNode(
TokenPos(),
Type::ZoneHandle(Type::ArrayType()),
*BuildArrayTempLocal(type_pos),
kv_pairs_list);
factory_param->Add(kv_pairs);
return CreateConstructorCallNode(literal_pos,
factory_type_args,
factory_method,
factory_param);
}
}
AstNode* Parser::ParseCompoundLiteral() {
TRACE_PARSER("ParseCompoundLiteral");
bool is_const = false;
if (CurrentToken() == Token::kCONST) {
is_const = true;
ConsumeToken();
}
const intptr_t type_pos = TokenPos();
Error& malformed_error = Error::Handle();
AbstractTypeArguments& type_arguments = AbstractTypeArguments::ZoneHandle(
ParseTypeArguments(&malformed_error,
ClassFinalizer::kCanonicalizeWellFormed));
// Map and List interfaces do not declare bounds on their type parameters, so
// we should never see a malformed type error here.
// Note that a bound error is the only possible malformed type error returned
// when requesting kCanonicalizeWellFormed type finalization.
ASSERT(malformed_error.IsNull());
AstNode* primary = NULL;
if ((CurrentToken() == Token::kLBRACK) ||
(CurrentToken() == Token::kINDEX)) {
primary = ParseListLiteral(type_pos, is_const, type_arguments);
} else if (CurrentToken() == Token::kLBRACE) {
primary = ParseMapLiteral(type_pos, is_const, type_arguments);
} else {
ErrorMsg("unexpected token %s", Token::Str(CurrentToken()));
}
return primary;
}
static const String& BuildConstructorName(const String& type_class_name,
const String* named_constructor) {
// By convention, the static function implementing a named constructor 'C'
// for class 'A' is labeled 'A.C', and the static function implementing the
// unnamed constructor for class 'A' is labeled 'A.'.
// This convention prevents users from explicitly calling constructors.
String& constructor_name =
String::Handle(String::Concat(type_class_name, Symbols::Dot()));
if (named_constructor != NULL) {
constructor_name = String::Concat(constructor_name, *named_constructor);
}
return constructor_name;
}
AstNode* Parser::ParseNewOperator() {
TRACE_PARSER("ParseNewOperator");
const intptr_t new_pos = TokenPos();
ASSERT((CurrentToken() == Token::kNEW) || (CurrentToken() == Token::kCONST));
bool is_const = (CurrentToken() == Token::kCONST);
ConsumeToken();
if (!IsIdentifier()) {
ErrorMsg("type name expected");
}
intptr_t type_pos = TokenPos();
AbstractType& type = AbstractType::Handle(
ParseType(ClassFinalizer::kCanonicalizeExpression));
// In case the type is malformed, throw a dynamic type error after finishing
// parsing the instance creation expression.
if (!type.IsMalformed() && (type.IsTypeParameter() || type.IsDynamicType())) {
// Replace the type with a malformed type.
type = ClassFinalizer::NewFinalizedMalformedType(
Error::Handle(), // No previous error.
current_class(),
type_pos,
ClassFinalizer::kTryResolve, // No compile-time error.
"%s'%s' cannot be instantiated",
type.IsTypeParameter() ? "type parameter " : "",
type.IsTypeParameter() ?
String::Handle(type.UserVisibleName()).ToCString() : "dynamic");
}
// The grammar allows for an optional ('.' identifier)? after the type, which
// is a named constructor. Note that ParseType(kMustResolve) above will not
// consume it as part of a misinterpreted qualified identifier, because only a
// valid library prefix is accepted as qualifier.
String* named_constructor = NULL;
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
named_constructor = ExpectIdentifier("name of constructor expected");
}
// Parse constructor parameters.
if (CurrentToken() != Token::kLPAREN) {
ErrorMsg("'(' expected");
}
intptr_t call_pos = TokenPos();
ArgumentListNode* arguments = ParseActualParameters(NULL, is_const);
// Parsing is complete, so we can return a throw in case of a malformed type
// or report a compile-time error if the constructor is const.
if (type.IsMalformed()) {
if (is_const) {
const Error& error = Error::Handle(type.malformed_error());
ErrorMsg(error);
}
return ThrowTypeError(type_pos, type);
}
// Resolve the type and optional identifier to a constructor or factory.
Class& type_class = Class::Handle(type.type_class());
const String& type_class_name = String::Handle(type_class.Name());
AbstractTypeArguments& type_arguments =
AbstractTypeArguments::ZoneHandle(type.arguments());
// A constructor has an implicit 'this' parameter (instance to construct)
// and a factory has an implicit 'this' parameter (type_arguments).
// A constructor has a second implicit 'phase' parameter.
intptr_t arguments_length = arguments->length() + 2;
// An additional type check of the result of a redirecting factory may be
// required.
AbstractType& type_bound = AbstractType::ZoneHandle();
// Make sure that an appropriate constructor exists.
const String& constructor_name =
BuildConstructorName(type_class_name, named_constructor);
Function& constructor = Function::ZoneHandle(
type_class.LookupConstructor(constructor_name));
if (constructor.IsNull()) {
constructor = type_class.LookupFactory(constructor_name);
if (constructor.IsNull()) {
const String& external_constructor_name =
(named_constructor ? constructor_name : type_class_name);
// Replace the type with a malformed type and compile a throw or report a
// compile-time error if the constructor is const.
if (is_const) {
type = ClassFinalizer::NewFinalizedMalformedType(
Error::Handle(), // No previous error.
current_class(),
call_pos,
ClassFinalizer::kTryResolve, // No compile-time error.
"class '%s' has no constructor or factory named '%s'",
String::Handle(type_class.Name()).ToCString(),
external_constructor_name.ToCString());
const Error& error = Error::Handle(type.malformed_error());
ErrorMsg(error);
}
return ThrowNoSuchMethodError(call_pos,
type_class,
external_constructor_name,
InvocationMirror::kConstructor,
InvocationMirror::kMethod);
} else if (constructor.IsRedirectingFactory()) {
Type& redirect_type = Type::Handle(constructor.RedirectionType());
if (!redirect_type.IsMalformed() && !redirect_type.IsInstantiated()) {
// The type arguments of the redirection type are instantiated from the
// type arguments of the parsed type of the 'new' or 'const' expression.
Error& malformed_error = Error::Handle();
redirect_type ^= redirect_type.InstantiateFrom(type_arguments,
&malformed_error);
if (!malformed_error.IsNull()) {
redirect_type.set_malformed_error(malformed_error);
}
}
if (redirect_type.IsMalformed()) {
if (is_const) {
ErrorMsg(Error::Handle(redirect_type.malformed_error()));
}
return ThrowTypeError(redirect_type.token_pos(), redirect_type);
}
if (FLAG_enable_type_checks && !redirect_type.IsSubtypeOf(type, NULL)) {
// Additional type checking of the result is necessary.
type_bound = type.raw();
}
type = redirect_type.raw();
type_class = type.type_class();
type_arguments = type.arguments();
constructor = constructor.RedirectionTarget();
ASSERT(!constructor.IsNull());
}
if (constructor.IsFactory()) {
// A factory does not have the implicit 'phase' parameter.
arguments_length -= 1;
}
}
// It is ok to call a factory method of an abstract class, but it is
// a dynamic error to instantiate an abstract class.
ASSERT(!constructor.IsNull());
if (type_class.is_abstract() && !constructor.IsFactory()) {
ArgumentListNode* arguments = new ArgumentListNode(type_pos);
arguments->Add(new LiteralNode(
TokenPos(), Integer::ZoneHandle(Integer::New(type_pos))));
arguments->Add(new LiteralNode(
TokenPos(), String::ZoneHandle(type_class_name.raw())));
return MakeStaticCall(Symbols::AbstractClassInstantiationError(),
PrivateCoreLibName(Symbols::ThrowNew()),
arguments);
}
String& error_message = String::Handle();
if (!constructor.AreValidArguments(arguments_length,
arguments->names(),
&error_message)) {
const String& external_constructor_name =
(named_constructor ? constructor_name : type_class_name);
if (is_const) {
ErrorMsg(call_pos,
"invalid arguments passed to constructor '%s' "
"for class '%s': %s",
external_constructor_name.ToCString(),
String::Handle(type_class.Name()).ToCString(),
error_message.ToCString());
}
return ThrowNoSuchMethodError(call_pos,
type_class,
external_constructor_name,
InvocationMirror::kConstructor,
InvocationMirror::kMethod);
}
// Return a throw in case of a malformed type or report a compile-time error
// if the constructor is const.
if (type.IsMalformed()) {
if (is_const) {
const Error& error = Error::Handle(type.malformed_error());
ErrorMsg(error);
}
return ThrowTypeError(type_pos, type);
}
type_arguments ^= type_arguments.Canonicalize();
// Make the constructor call.
AstNode* new_object = NULL;
if (is_const) {
if (!constructor.is_const()) {
ErrorMsg("'const' requires const constructor: '%s'",
String::Handle(constructor.name()).ToCString());
}
const Object& constructor_result = Object::Handle(
EvaluateConstConstructorCall(type_class,
type_arguments,
constructor,
arguments));
if (constructor_result.IsUnhandledException()) {
new_object = GenerateRethrow(new_pos, constructor_result);
} else {
const Instance& const_instance = Instance::Cast(constructor_result);
new_object = new LiteralNode(new_pos,
Instance::ZoneHandle(const_instance.raw()));
if (!type_bound.IsNull()) {
ASSERT(!type_bound.IsMalformed());
Error& malformed_error = Error::Handle();
if (!const_instance.IsInstanceOf(type_bound,
TypeArguments::Handle(),
&malformed_error)) {
type_bound = ClassFinalizer::NewFinalizedMalformedType(
malformed_error,
current_class(),
new_pos,
ClassFinalizer::kTryResolve, // No compile-time error.
"const factory result is not an instance of '%s'",
String::Handle(type_bound.UserVisibleName()).ToCString());
new_object = ThrowTypeError(new_pos, type_bound);
}
type_bound = AbstractType::null();
}
}
} else {
CheckConstructorCallTypeArguments(new_pos, constructor, type_arguments);
if (!type_arguments.IsNull() &&
!type_arguments.IsInstantiated() &&
(current_block_->scope->function_level() > 0)) {
// Make sure that the instantiator is captured.
CaptureInstantiator();
}
// If the type argument vector is not instantiated, we verify in checked
// mode at runtime that it is within its declared bounds.
new_object = CreateConstructorCallNode(
new_pos, type_arguments, constructor, arguments);
}
if (!type_bound.IsNull()) {
new_object = new AssignableNode(new_pos,
new_object,
type_bound,
Symbols::FactoryResult());
}
return new_object;
}
String& Parser::Interpolate(const GrowableArray<AstNode*>& values) {
const Class& cls = Class::Handle(LookupCoreClass(Symbols::StringBase()));
ASSERT(!cls.IsNull());
const Function& func =
Function::Handle(cls.LookupStaticFunction(
PrivateCoreLibName(Symbols::Interpolate())));
ASSERT(!func.IsNull());
// Build the array of literal values to interpolate.
const Array& value_arr = Array::Handle(Array::New(values.length()));
for (int i = 0; i < values.length(); i++) {
ASSERT(values[i]->IsLiteralNode());
value_arr.SetAt(i, values[i]->AsLiteralNode()->literal());
}
// Build argument array to pass to the interpolation function.
const Array& interpolate_arg = Array::Handle(Array::New(1));
interpolate_arg.SetAt(0, value_arr);
// Call interpolation function.
String& concatenated = String::ZoneHandle();
concatenated ^= DartEntry::InvokeFunction(func, interpolate_arg);
if (concatenated.IsUnhandledException()) {
ErrorMsg("Exception thrown in Parser::Interpolate");
}
concatenated = Symbols::New(concatenated);
return concatenated;
}
// A string literal consists of the concatenation of the next n tokens
// that satisfy the EBNF grammar:
// literal = kSTRING {{ interpol } kSTRING }
// interpol = kINTERPOL_VAR | (kINTERPOL_START expression kINTERPOL_END)
// In other words, the scanner breaks down interpolated strings so that
// a string literal always begins and ends with a kSTRING token.
AstNode* Parser::ParseStringLiteral() {
TRACE_PARSER("ParseStringLiteral");
AstNode* primary = NULL;
const intptr_t literal_start = TokenPos();
ASSERT(CurrentToken() == Token::kSTRING);
Token::Kind l1_token = LookaheadToken(1);
if ((l1_token != Token::kSTRING) &&
(l1_token != Token::kINTERPOL_VAR) &&
(l1_token != Token::kINTERPOL_START)) {
// Common case: no interpolation.
primary = new LiteralNode(literal_start, *CurrentLiteral());
ConsumeToken();
return primary;
}
// String interpolation needed.
bool is_compiletime_const = true;
GrowableArray<AstNode*> values_list;
while (CurrentToken() == Token::kSTRING) {
values_list.Add(new LiteralNode(TokenPos(), *CurrentLiteral()));
ConsumeToken();
while ((CurrentToken() == Token::kINTERPOL_VAR) ||
(CurrentToken() == Token::kINTERPOL_START)) {
AstNode* expr = NULL;
const intptr_t expr_pos = TokenPos();
if (CurrentToken() == Token::kINTERPOL_VAR) {
expr = ResolveIdent(TokenPos(), *CurrentLiteral(), true);
ConsumeToken();
} else {
ASSERT(CurrentToken() == Token::kINTERPOL_START);
ConsumeToken();
expr = ParseExpr(kAllowConst, kConsumeCascades);
ExpectToken(Token::kINTERPOL_END);
}
// Check if this interpolated string is still considered a compile time
// constant. If it is we need to evaluate if the current string part is
// a constant or not. Only stings, numbers, booleans and null values
// are allowed in compile time const interpolations.
if (is_compiletime_const) {
const Object* const_expr = expr->EvalConstExpr();
if ((const_expr != NULL) &&
(const_expr->IsNumber() ||
const_expr->IsString() ||
const_expr->IsBool() ||
const_expr->IsNull())) {
// Change expr into a literal.
expr = new LiteralNode(expr_pos, EvaluateConstExpr(expr));
} else {
is_compiletime_const = false;
}
}
values_list.Add(expr);
}
}
if (is_compiletime_const) {
primary = new LiteralNode(literal_start, Interpolate(values_list));
} else {
ArgumentListNode* interpolate_arg = new ArgumentListNode(TokenPos());
ArrayNode* values = new ArrayNode(
TokenPos(),
Type::ZoneHandle(Type::ArrayType()),
*BuildArrayTempLocal(TokenPos()),
values_list);
interpolate_arg->Add(values);
primary = MakeStaticCall(Symbols::StringBase(),
PrivateCoreLibName(Symbols::Interpolate()),
interpolate_arg);
}
return primary;
}
AstNode* Parser::ParseArgumentDefinitionTest() {
const intptr_t test_pos = TokenPos();
ConsumeToken();
const intptr_t ident_pos = TokenPos();
String* ident = ExpectIdentifier("parameter name expected");
Function& owner_function = Function::Handle();
LocalScope* owner_scope;
intptr_t param_index;
if (!IsFormalParameter(*ident, &owner_function, &owner_scope, &param_index)) {
ErrorMsg(ident_pos, "formal parameter name expected");
}
if (param_index < owner_function.num_fixed_parameters()) {
// The formal parameter is not optional, therefore the corresponding
// argument is always passed and defined.
return new LiteralNode(test_pos, Bool::True());
}
char name[64];
OS::SNPrint(name, 64, "%s_%"Pd"",
Symbols::Name(Symbols::kSavedArgDescVarPrefixId),
owner_function.token_pos());
const String& saved_args_desc_name = String::ZoneHandle(Symbols::New(name));
LocalVariable* saved_args_desc_var = LookupLocalScope(saved_args_desc_name);
if (saved_args_desc_var == NULL) {
ASSERT(owner_scope != NULL);
saved_args_desc_var =
new LocalVariable(owner_function.token_pos(),
saved_args_desc_name,
Type::ZoneHandle(Type::ArrayType()));
saved_args_desc_var->set_is_final();
// The saved arguments descriptor variable must be added just after the
// formal parameters. This simplifies the 2-step saving of a captured
// arguments descriptor.
// At this time, the owner scope should only contain formal parameters.
ASSERT(owner_scope->num_variables() == owner_function.NumParameters());
bool success = owner_scope->AddVariable(saved_args_desc_var);
ASSERT(success);
// Capture the saved arguments descriptor variable if necessary.
LocalVariable* local = LookupLocalScope(saved_args_desc_name);
ASSERT(local == saved_args_desc_var);
}
// If we currently generate code for the local function of an enclosing owner
// function, the saved arguments descriptor variable must have been captured
// by the above lookup.
ASSERT((owner_function.raw() == innermost_function().raw()) ||
saved_args_desc_var->is_captured());
const String& param_name = String::ZoneHandle(Symbols::New(*ident));
return new ArgumentDefinitionTestNode(
test_pos, param_index, param_name, saved_args_desc_var);
}
AstNode* Parser::ParsePrimary() {
TRACE_PARSER("ParsePrimary");
ASSERT(!is_top_level_);
AstNode* primary = NULL;
if (IsFunctionLiteral()) {
// The name of a literal function is visible from inside the function, but
// must not collide with names in the scope declaring the literal.
OpenBlock();
primary = ParseFunctionStatement(true);
CloseBlock();
} else if (IsIdentifier()) {
QualIdent qual_ident;
ParseQualIdent(&qual_ident);
if (qual_ident.lib_prefix == NULL) {
if (!ResolveIdentInLocalScope(qual_ident.ident_pos,
*qual_ident.ident,
&primary)) {
// Check whether the identifier is a type parameter. Type parameters
// can never be used as part of primary expressions.
if (!current_class().IsNull()) {
TypeParameter& type_param = TypeParameter::ZoneHandle(
current_class().LookupTypeParameter(*(qual_ident.ident),
TokenPos()));
if (!type_param.IsNull()) {
const String& type_param_name = String::Handle(type_param.name());
ErrorMsg(qual_ident.ident_pos,
"illegal use of type parameter %s",
type_param_name.ToCString());
}
}
// This is a non-local unqualified identifier so resolve the
// identifier locally in the main app library and all libraries
// imported by it.
primary = ResolveIdentInCurrentLibraryScope(qual_ident.ident_pos,
*qual_ident.ident);
}
} else {
// This is a qualified identifier with a library prefix so resolve
// the identifier locally in that library (we do not include the
// libraries imported by that library).
primary = ResolveIdentInPrefixScope(qual_ident.ident_pos,
*qual_ident.lib_prefix,
*qual_ident.ident);
}
ASSERT(primary != NULL);
} else if (CurrentToken() == Token::kTHIS) {
LocalVariable* local = LookupLocalScope(Symbols::This());
if (local == NULL) {
ErrorMsg("receiver 'this' is not in scope");
}
primary = new LoadLocalNode(TokenPos(), local);
ConsumeToken();
} else if (CurrentToken() == Token::kINTEGER) {
const Integer& literal = Integer::ZoneHandle(CurrentIntegerLiteral());
primary = new LiteralNode(TokenPos(), literal);
ConsumeToken();
} else if (CurrentToken() == Token::kTRUE) {
primary = new LiteralNode(TokenPos(), Bool::True());
ConsumeToken();
} else if (CurrentToken() == Token::kFALSE) {
primary = new LiteralNode(TokenPos(), Bool::False());
ConsumeToken();
} else if (CurrentToken() == Token::kNULL) {
primary = new LiteralNode(TokenPos(), Instance::ZoneHandle());
ConsumeToken();
} else if (CurrentToken() == Token::kLPAREN) {
ConsumeToken();
const bool saved_mode = SetAllowFunctionLiterals(true);
primary = ParseExpr(kAllowConst, kConsumeCascades);
SetAllowFunctionLiterals(saved_mode);
ExpectToken(Token::kRPAREN);
} else if (CurrentToken() == Token::kDOUBLE) {
Double& double_value = Double::ZoneHandle(CurrentDoubleLiteral());
if (double_value.IsNull()) {
ErrorMsg("invalid double literal");
}
primary = new LiteralNode(TokenPos(), double_value);
ConsumeToken();
} else if (CurrentToken() == Token::kSTRING) {
primary = ParseStringLiteral();
} else if (CurrentToken() == Token::kNEW) {
primary = ParseNewOperator();
} else if (CurrentToken() == Token::kCONST) {
if ((LookaheadToken(1) == Token::kLT) ||
(LookaheadToken(1) == Token::kLBRACK) ||
(LookaheadToken(1) == Token::kINDEX) ||
(LookaheadToken(1) == Token::kLBRACE)) {
primary = ParseCompoundLiteral();
} else {
primary = ParseNewOperator();
}
} else if (CurrentToken() == Token::kLT ||
CurrentToken() == Token::kLBRACK ||
CurrentToken() == Token::kINDEX ||
CurrentToken() == Token::kLBRACE) {
primary = ParseCompoundLiteral();
} else if (CurrentToken() == Token::kSUPER) {
if (current_function().is_static()) {
ErrorMsg("cannot access superclass from static method");
}
if (current_class().SuperClass() == Class::null()) {
ErrorMsg("class '%s' does not have a superclass",
String::Handle(current_class().Name()).ToCString());
}
if (current_class().mixin() != Type::null()) {
const Type& mixin_type = Type::Handle(current_class().mixin());
if (mixin_type.type_class() == current_function().origin()) {
ErrorMsg("class '%s' may not use super "
"because it is used as mixin class",
String::Handle(current_class().Name()).ToCString());
}
}
ConsumeToken();
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
const String& ident = *ExpectIdentifier("identifier expected");
if (CurrentToken() == Token::kLPAREN) {
primary = ParseSuperCall(ident);
} else {
primary = ParseSuperFieldAccess(ident);
}
} else if ((CurrentToken() == Token::kLBRACK) ||
Token::CanBeOverloaded(CurrentToken()) ||
(CurrentToken() == Token::kNE)) {
primary = ParseSuperOperator();
} else {
primary = new PrimaryNode(TokenPos(), Symbols::Super());
}
} else if (CurrentToken() == Token::kCONDITIONAL) {
primary = ParseArgumentDefinitionTest();
} else {
UnexpectedToken();
}
return primary;
}
// Evaluate expression in expr and return the value. The expression must
// be a compile time constant.
const Instance& Parser::EvaluateConstExpr(AstNode* expr) {
if (expr->IsLiteralNode()) {
return expr->AsLiteralNode()->literal();
} else if (expr->IsLoadLocalNode() &&
expr->AsLoadLocalNode()->local().IsConst()) {
return *expr->AsLoadLocalNode()->local().ConstValue();
} else {
ASSERT(expr->EvalConstExpr() != NULL);
ReturnNode* ret = new ReturnNode(expr->token_pos(), expr);
// Compile time constant expressions cannot reference anything from a
// local scope.
LocalScope* empty_scope = new LocalScope(NULL, 0, 0);
SequenceNode* seq = new SequenceNode(expr->token_pos(), empty_scope);
seq->Add(ret);
Object& result = Object::Handle(Compiler::ExecuteOnce(seq));
if (result.IsError()) {
// Propagate the compilation error.
Isolate::Current()->long_jump_base()->Jump(1, Error::Cast(result));
UNREACHABLE();
}
ASSERT(result.IsInstance());
Instance& value = Instance::ZoneHandle();
value ^= result.raw();
if (!value.IsNull()) {
value ^= value.Canonicalize();
}
return value;
}
}
void Parser::SkipFunctionLiteral() {
if (IsIdentifier()) {
if (LookaheadToken(1) != Token::kLPAREN) {
SkipType(true);
}
ExpectIdentifier("function name expected");
}
if (CurrentToken() == Token::kLPAREN) {
const bool allow_explicit_default_values = true;
ParamList params;
params.skipped = true;
ParseFormalParameterList(allow_explicit_default_values, &params);
}
if (CurrentToken() == Token::kLBRACE) {
SkipBlock();
} else if (CurrentToken() == Token::kARROW) {
ConsumeToken();
SkipExpr();
}
}
void Parser::SkipListLiteral() {
if (CurrentToken() == Token::kINDEX) {
// Empty list literal.
ConsumeToken();
return;
}
ExpectToken(Token::kLBRACK);
while (CurrentToken() != Token::kRBRACK) {
SkipNestedExpr();
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
}
}
ExpectToken(Token::kRBRACK);
}
void Parser::SkipMapLiteral() {
ExpectToken(Token::kLBRACE);
while (CurrentToken() == Token::kSTRING) {
SkipStringLiteral();
ExpectToken(Token::kCOLON);
SkipNestedExpr();
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
}
}
ExpectToken(Token::kRBRACE);
}
void Parser::SkipActualParameters() {
ExpectToken(Token::kLPAREN);
while (CurrentToken() != Token::kRPAREN) {
if (IsIdentifier() && (LookaheadToken(1) == Token::kCOLON)) {
// Named actual parameter.
ConsumeToken();
ConsumeToken();
}
SkipNestedExpr();
if (CurrentToken() == Token::kCOMMA) {
ConsumeToken();
}
}
ExpectToken(Token::kRPAREN);
}
void Parser::SkipCompoundLiteral() {
if (CurrentToken() == Token::kLT) {
SkipTypeArguments();
}
if ((CurrentToken() == Token::kLBRACK) ||
(CurrentToken() == Token::kINDEX)) {
SkipListLiteral();
} else if (CurrentToken() == Token::kLBRACE) {
SkipMapLiteral();
}
}
void Parser::SkipNewOperator() {
ConsumeToken(); // Skip new or const keyword.
if (IsIdentifier()) {
SkipType(false);
if (CurrentToken() == Token::kLPAREN) {
SkipActualParameters();
return;
}
}
}
void Parser::SkipStringLiteral() {
ASSERT(CurrentToken() == Token::kSTRING);
while (CurrentToken() == Token::kSTRING) {
ConsumeToken();
while (true) {
if (CurrentToken() == Token::kINTERPOL_VAR) {
ConsumeToken();
} else if (CurrentToken() == Token::kINTERPOL_START) {
ConsumeToken();
SkipExpr();
ExpectToken(Token::kINTERPOL_END);
} else {
break;
}
}
}
}
void Parser::SkipPrimary() {
if (IsFunctionLiteral()) {
SkipFunctionLiteral();
return;
}
switch (CurrentToken()) {
case Token::kTHIS:
case Token::kSUPER:
case Token::kNULL:
case Token::kTRUE:
case Token::kFALSE:
case Token::kINTEGER:
case Token::kDOUBLE:
ConsumeToken();
break;
case Token::kIDENT:
ConsumeToken();
break;
case Token::kSTRING:
SkipStringLiteral();
break;
case Token::kLPAREN:
ConsumeToken();
SkipNestedExpr();
ExpectToken(Token::kRPAREN);
break;
case Token::kNEW:
SkipNewOperator();
break;
case Token::kCONST:
if ((LookaheadToken(1) == Token::kLT) ||
(LookaheadToken(1) == Token::kLBRACE) ||
(LookaheadToken(1) == Token::kLBRACK) ||
(LookaheadToken(1) == Token::kINDEX)) {
ConsumeToken();
SkipCompoundLiteral();
} else {
SkipNewOperator();
}
break;
case Token::kLT:
case Token::kLBRACE:
case Token::kLBRACK:
case Token::kINDEX:
SkipCompoundLiteral();
break;
case Token::kCONDITIONAL:
ConsumeToken();
if (IsIdentifier()) {
ConsumeToken();
}
break;
default:
if (IsIdentifier()) {
ConsumeToken(); // Handle pseudo-keyword identifiers.
} else {
UnexpectedToken();
UNREACHABLE();
}
break;
}
}
void Parser::SkipSelectors() {
while (true) {
if (CurrentToken() == Token::kCASCADE) {
ConsumeToken();
if (CurrentToken() == Token::kLBRACK) {
continue; // Consume [ in next loop iteration.
} else {
ExpectIdentifier("identifier or [ expected after ..");
}
} else if (CurrentToken() == Token::kPERIOD) {
ConsumeToken();
ExpectIdentifier("identifier expected");
} else if (CurrentToken() == Token::kLBRACK) {
ConsumeToken();
SkipNestedExpr();
ExpectToken(Token::kRBRACK);
} else if (CurrentToken() == Token::kLPAREN) {
SkipActualParameters();
} else {
break;
}
}
}
void Parser::SkipPostfixExpr() {
SkipPrimary();
SkipSelectors();
if (IsIncrementOperator(CurrentToken())) {
ConsumeToken();
}
}
void Parser::SkipUnaryExpr() {
if (IsPrefixOperator(CurrentToken()) ||
IsIncrementOperator(CurrentToken())) {
ConsumeToken();
SkipUnaryExpr();
} else {
SkipPostfixExpr();
}
}
void Parser::SkipBinaryExpr() {
SkipUnaryExpr();
const int min_prec = Token::Precedence(Token::kOR);
const int max_prec = Token::Precedence(Token::kMUL);
while (((min_prec <= Token::Precedence(CurrentToken())) &&
(Token::Precedence(CurrentToken()) <= max_prec)) ||
IsLiteral("as")) {
Token::Kind last_token = IsLiteral("as") ? Token::kAS : CurrentToken();
ConsumeToken();
if (last_token == Token::kIS) {
if (CurrentToken() == Token::kNOT) {
ConsumeToken();
}
SkipType(false);
} else if (last_token == Token::kAS) {
SkipType(false);
} else {
SkipUnaryExpr();
}
}
}
void Parser::SkipConditionalExpr() {
SkipBinaryExpr();
if (CurrentToken() == Token::kCONDITIONAL) {
ConsumeToken();
SkipExpr();
ExpectToken(Token::kCOLON);
SkipExpr();
}
}
void Parser::SkipExpr() {
while (CurrentToken() == Token::kTHROW) {
ConsumeToken();
}
SkipConditionalExpr();
if (CurrentToken() == Token::kCASCADE) {
SkipSelectors();
}
if (Token::IsAssignmentOperator(CurrentToken())) {
ConsumeToken();
SkipExpr();
}
}
void Parser::SkipNestedExpr() {
const bool saved_mode = SetAllowFunctionLiterals(true);
SkipExpr();
SetAllowFunctionLiterals(saved_mode);
}
void Parser::SkipQualIdent() {
ASSERT(IsIdentifier());
ConsumeToken();
if (CurrentToken() == Token::kPERIOD) {
ConsumeToken(); // Consume the kPERIOD token.
ExpectIdentifier("identifier expected after '.'");
}
}
} // namespace dart