// Copyright (c) 2013 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "gn/parse_tree.h" #include #include #include #include #include "base/json/string_escape.h" #include "base/stl_util.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "gn/functions.h" #include "gn/operators.h" #include "gn/scope.h" #include "gn/string_utils.h" // Dictionary keys used for JSON-formatted tree dump. const char kJsonNodeChild[] = "child"; const char kJsonNodeType[] = "type"; const char kJsonNodeValue[] = "value"; const char kJsonBeforeComment[] = "before_comment"; const char kJsonSuffixComment[] = "suffix_comment"; const char kJsonAfterComment[] = "after_comment"; const char kJsonLocation[] = "location"; const char kJsonLocationBeginLine[] = "begin_line"; const char kJsonLocationBeginColumn[] = "begin_column"; const char kJsonLocationEndLine[] = "end_line"; const char kJsonLocationEndColumn[] = "end_column"; // Used by Block and List. const char kJsonBeginToken[] = "begin_token"; const char kJsonEnd[] = "end"; namespace { enum DepsCategory { DEPS_CATEGORY_LOCAL, DEPS_CATEGORY_RELATIVE, DEPS_CATEGORY_ABSOLUTE, DEPS_CATEGORY_OTHER, }; DepsCategory GetDepsCategory(std::string_view deps) { if (deps.length() < 2 || deps[0] != '"' || deps[deps.size() - 1] != '"') return DEPS_CATEGORY_OTHER; if (deps[1] == ':') return DEPS_CATEGORY_LOCAL; if (deps[1] == '/') return DEPS_CATEGORY_ABSOLUTE; return DEPS_CATEGORY_RELATIVE; } std::tuple SplitAtFirst( std::string_view str, char c) { if (!base::starts_with(str, "\"") || !base::ends_with(str, "\"")) return std::make_tuple(str, std::string_view()); str = str.substr(1, str.length() - 2); size_t index_of_first = str.find(c); return std::make_tuple(str.substr(0, index_of_first), index_of_first != std::string_view::npos ? str.substr(index_of_first + 1) : std::string_view()); } bool IsSortRangeSeparator(const ParseNode* node, const ParseNode* prev) { // If it's a block comment, or has an attached comment with a blank line // before it, then we break the range at this point. return node->AsBlockComment() != nullptr || (prev && node->comments() && !node->comments()->before().empty() && (node->GetRange().begin().line_number() > prev->GetRange().end().line_number() + static_cast(node->comments()->before().size() + 1))); } std::string_view GetStringRepresentation(const ParseNode* node) { DCHECK(node->AsLiteral() || node->AsIdentifier() || node->AsAccessor()); if (node->AsLiteral()) return node->AsLiteral()->value().value(); else if (node->AsIdentifier()) return node->AsIdentifier()->value().value(); else if (node->AsAccessor()) return node->AsAccessor()->base().value(); return std::string_view(); } void AddLocationJSONNodes(base::Value* dict, LocationRange location) { base::Value loc(base::Value::Type::DICTIONARY); loc.SetKey(kJsonLocationBeginLine, base::Value(location.begin().line_number())); loc.SetKey(kJsonLocationBeginColumn, base::Value(location.begin().column_number())); loc.SetKey(kJsonLocationEndLine, base::Value(location.end().line_number())); loc.SetKey(kJsonLocationEndColumn, base::Value(location.end().column_number())); dict->SetKey(kJsonLocation, std::move(loc)); } Location GetBeginLocationFromJSON(const base::Value& value) { int line = value.FindKey(kJsonLocation)->FindKey(kJsonLocationBeginLine)->GetInt(); int column = value.FindKey(kJsonLocation)->FindKey(kJsonLocationBeginColumn)->GetInt(); return Location(nullptr, line, column); } void GetCommentsFromJSON(ParseNode* node, const base::Value& value) { Comments* comments = node->comments_mutable(); Location loc = GetBeginLocationFromJSON(value); auto loc_for = [&loc](int line) { return Location(nullptr, loc.line_number() + line, loc.column_number()); }; if (value.FindKey(kJsonBeforeComment)) { int line = 0; for (const auto& c : value.FindKey(kJsonBeforeComment)->GetList()) { comments->append_before( Token::ClassifyAndMake(loc_for(line), c.GetString())); ++line; } } if (value.FindKey(kJsonSuffixComment)) { int line = 0; for (const auto& c : value.FindKey(kJsonSuffixComment)->GetList()) { comments->append_suffix( Token::ClassifyAndMake(loc_for(line), c.GetString())); ++line; } } if (value.FindKey(kJsonAfterComment)) { int line = 0; for (const auto& c : value.FindKey(kJsonAfterComment)->GetList()) { comments->append_after( Token::ClassifyAndMake(loc_for(line), c.GetString())); ++line; } } } Token TokenFromValue(const base::Value& value) { return Token::ClassifyAndMake(GetBeginLocationFromJSON(value), value.FindKey(kJsonNodeValue)->GetString()); } } // namespace Comments::Comments() = default; Comments::~Comments() = default; void Comments::ReverseSuffix() { for (int i = 0, j = static_cast(suffix_.size() - 1); i < j; ++i, --j) std::swap(suffix_[i], suffix_[j]); } ParseNode::ParseNode() = default; ParseNode::~ParseNode() = default; const AccessorNode* ParseNode::AsAccessor() const { return nullptr; } const BinaryOpNode* ParseNode::AsBinaryOp() const { return nullptr; } const BlockCommentNode* ParseNode::AsBlockComment() const { return nullptr; } const BlockNode* ParseNode::AsBlock() const { return nullptr; } const ConditionNode* ParseNode::AsCondition() const { return nullptr; } const EndNode* ParseNode::AsEnd() const { return nullptr; } const FunctionCallNode* ParseNode::AsFunctionCall() const { return nullptr; } const IdentifierNode* ParseNode::AsIdentifier() const { return nullptr; } const ListNode* ParseNode::AsList() const { return nullptr; } const LiteralNode* ParseNode::AsLiteral() const { return nullptr; } const UnaryOpNode* ParseNode::AsUnaryOp() const { return nullptr; } Comments* ParseNode::comments_mutable() { if (!comments_) comments_ = std::make_unique(); return comments_.get(); } base::Value ParseNode::CreateJSONNode(const char* type, LocationRange location) const { base::Value dict(base::Value::Type::DICTIONARY); dict.SetKey(kJsonNodeType, base::Value(type)); AddLocationJSONNodes(&dict, location); AddCommentsJSONNodes(&dict); return dict; } base::Value ParseNode::CreateJSONNode(const char* type, std::string_view value, LocationRange location) const { base::Value dict(base::Value::Type::DICTIONARY); dict.SetKey(kJsonNodeType, base::Value(type)); dict.SetKey(kJsonNodeValue, base::Value(value)); AddLocationJSONNodes(&dict, location); AddCommentsJSONNodes(&dict); return dict; } void ParseNode::AddCommentsJSONNodes(base::Value* out_value) const { if (comments_) { if (comments_->before().size()) { base::Value comment_values(base::Value::Type::LIST); for (const auto& token : comments_->before()) comment_values.GetList().push_back(base::Value(token.value())); out_value->SetKey(kJsonBeforeComment, std::move(comment_values)); } if (comments_->suffix().size()) { base::Value comment_values(base::Value::Type::LIST); for (const auto& token : comments_->suffix()) comment_values.GetList().push_back(base::Value(token.value())); out_value->SetKey(kJsonSuffixComment, std::move(comment_values)); } if (comments_->after().size()) { base::Value comment_values(base::Value::Type::LIST); for (const auto& token : comments_->after()) comment_values.GetList().push_back(base::Value(token.value())); out_value->SetKey(kJsonAfterComment, std::move(comment_values)); } } } // static std::unique_ptr ParseNode::BuildFromJSON(const base::Value& value) { const std::string& str_type = value.FindKey(kJsonNodeType)->GetString(); #define RETURN_IF_MATCHES_NAME(t) \ do { \ if (str_type == t::kDumpNodeName) { \ return t::NewFromJSON(value); \ } \ } while (0) RETURN_IF_MATCHES_NAME(AccessorNode); RETURN_IF_MATCHES_NAME(BinaryOpNode); RETURN_IF_MATCHES_NAME(BlockCommentNode); RETURN_IF_MATCHES_NAME(BlockNode); RETURN_IF_MATCHES_NAME(ConditionNode); RETURN_IF_MATCHES_NAME(EndNode); RETURN_IF_MATCHES_NAME(FunctionCallNode); RETURN_IF_MATCHES_NAME(IdentifierNode); RETURN_IF_MATCHES_NAME(ListNode); RETURN_IF_MATCHES_NAME(LiteralNode); RETURN_IF_MATCHES_NAME(UnaryOpNode); #undef RETURN_IF_MATCHES_NAME NOTREACHED() << str_type; return std::unique_ptr(); } // AccessorNode --------------------------------------------------------------- AccessorNode::AccessorNode() = default; AccessorNode::~AccessorNode() = default; const AccessorNode* AccessorNode::AsAccessor() const { return this; } Value AccessorNode::Execute(Scope* scope, Err* err) const { if (subscript_) return ExecuteSubscriptAccess(scope, err); else if (member_) return ExecuteScopeAccess(scope, err); NOTREACHED(); return Value(); } LocationRange AccessorNode::GetRange() const { if (subscript_) return LocationRange(base_.location(), subscript_->GetRange().end()); else if (member_) return LocationRange(base_.location(), member_->GetRange().end()); NOTREACHED(); return LocationRange(); } Err AccessorNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(GetRange(), msg, help); } base::Value AccessorNode::GetJSONNode() const { base::Value dict(CreateJSONNode(kDumpNodeName, base_.value(), GetRange())); base::Value child(base::Value::Type::LIST); if (subscript_) { child.GetList().push_back(subscript_->GetJSONNode()); dict.SetKey(kDumpAccessorKind, base::Value(kDumpAccessorKindSubscript)); } else if (member_) { child.GetList().push_back(member_->GetJSONNode()); dict.SetKey(kDumpAccessorKind, base::Value(kDumpAccessorKindMember)); } dict.SetKey(kJsonNodeChild, std::move(child)); return dict; } #define DECLARE_CHILD_AS_LIST_OR_FAIL() \ const base::Value* child = value.FindKey(kJsonNodeChild); \ if (!child || !child->is_list()) { \ return nullptr; \ } \ (void)(0) // this is to supress extra semicolon warning. // static std::unique_ptr AccessorNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); DECLARE_CHILD_AS_LIST_OR_FAIL(); ret->base_ = TokenFromValue(value); const base::Value::ListStorage& children = child->GetList(); const std::string& kind = value.FindKey(kDumpAccessorKind)->GetString(); if (kind == kDumpAccessorKindSubscript) { ret->subscript_ = ParseNode::BuildFromJSON(children[0]); } else if (kind == kDumpAccessorKindMember) { ret->member_ = IdentifierNode::NewFromJSON(children[0]); } GetCommentsFromJSON(ret.get(), value); return ret; } Value AccessorNode::ExecuteSubscriptAccess(Scope* scope, Err* err) const { const Value* base_value = scope->GetValue(base_.value(), true); if (!base_value) { *err = MakeErrorDescribing("Undefined identifier."); return Value(); } if (base_value->type() == Value::LIST) { return ExecuteArrayAccess(scope, base_value, err); } else if (base_value->type() == Value::SCOPE) { return ExecuteScopeSubscriptAccess(scope, base_value, err); } else { *err = MakeErrorDescribing( std::string("Expecting either a list or a scope for subscript, got ") + Value::DescribeType(base_value->type()) + "."); return Value(); } } Value AccessorNode::ExecuteArrayAccess(Scope* scope, const Value* base_value, Err* err) const { size_t index = 0; if (!ComputeAndValidateListIndex(scope, base_value->list_value().size(), &index, err)) return Value(); return base_value->list_value()[index]; } Value AccessorNode::ExecuteScopeSubscriptAccess(Scope* scope, const Value* base_value, Err* err) const { Value key_value = subscript_->Execute(scope, err); if (err->has_error()) return Value(); if (!key_value.VerifyTypeIs(Value::STRING, err)) return Value(); const Value* result = ExecuteScopeAccessForMember(scope, key_value.string_value(), err); if (!result) { *err = Err(subscript_.get(), "No value named \"" + key_value.string_value() + "\" in scope \"" + base_.value() + "\""); return Value(); } return *result; } Value AccessorNode::ExecuteScopeAccess(Scope* scope, Err* err) const { const Value* result = ExecuteScopeAccessForMember(scope, member_->value().value(), err); if (!result) { *err = Err(member_.get(), "No value named \"" + member_->value().value() + "\" in scope \"" + base_.value() + "\""); return Value(); } return *result; } const Value* AccessorNode::ExecuteScopeAccessForMember( Scope* scope, std::string_view member_str, Err* err) const { // We jump through some hoops here since ideally a.b will count "b" as // accessed in the given scope. The value "a" might be in some normal nested // scope and we can modify it, but it might also be inherited from the // readonly root scope and we can't do used variable tracking on it. (It's // not legal to const cast it away since the root scope will be in readonly // mode and being accessed from multiple threads without locking.) So this // code handles both cases. const Value* result = nullptr; // Look up the value in the scope named by "base_". Value* mutable_base_value = scope->GetMutableValue(base_.value(), Scope::SEARCH_NESTED, true); if (mutable_base_value) { // Common case: base value is mutable so we can track variable accesses // for unused value warnings. if (!mutable_base_value->VerifyTypeIs(Value::SCOPE, err)) return nullptr; result = mutable_base_value->scope_value()->GetValue(member_str, true); } else { // Fall back to see if the value is on a read-only scope. const Value* const_base_value = scope->GetValue(base_.value(), true); if (const_base_value) { // Read only value, don't try to mark the value access as a "used" one. if (!const_base_value->VerifyTypeIs(Value::SCOPE, err)) return nullptr; result = const_base_value->scope_value()->GetValue(member_str); } else { *err = Err(base_, "Undefined identifier."); return nullptr; } } return result; } void AccessorNode::SetNewLocation(int line_number) { Location old = base_.location(); base_.set_location(Location(old.file(), line_number, old.column_number())); } bool AccessorNode::ComputeAndValidateListIndex(Scope* scope, size_t max_len, size_t* computed_index, Err* err) const { Value index_value = subscript_->Execute(scope, err); if (err->has_error()) return false; if (!index_value.VerifyTypeIs(Value::INTEGER, err)) return false; int64_t index_int = index_value.int_value(); if (index_int < 0) { *err = Err(subscript_->GetRange(), "Negative array subscript.", "You gave me " + base::Int64ToString(index_int) + "."); return false; } if (max_len == 0) { *err = Err(subscript_->GetRange(), "Array subscript out of range.", "You gave me " + base::Int64ToString(index_int) + " but the " + "array has no elements."); return false; } size_t index_sizet = static_cast(index_int); if (index_sizet >= max_len) { *err = Err(subscript_->GetRange(), "Array subscript out of range.", "You gave me " + base::Int64ToString(index_int) + " but I was expecting something from 0 to " + base::NumberToString(max_len - 1) + ", inclusive."); return false; } *computed_index = index_sizet; return true; } // BinaryOpNode --------------------------------------------------------------- BinaryOpNode::BinaryOpNode() = default; BinaryOpNode::~BinaryOpNode() = default; const BinaryOpNode* BinaryOpNode::AsBinaryOp() const { return this; } Value BinaryOpNode::Execute(Scope* scope, Err* err) const { return ExecuteBinaryOperator(scope, this, left_.get(), right_.get(), err); } LocationRange BinaryOpNode::GetRange() const { return left_->GetRange().Union(right_->GetRange()); } Err BinaryOpNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(op_, msg, help); } base::Value BinaryOpNode::GetJSONNode() const { base::Value dict(CreateJSONNode(kDumpNodeName, op_.value(), GetRange())); base::Value child(base::Value::Type::LIST); child.GetList().push_back(left_->GetJSONNode()); child.GetList().push_back(right_->GetJSONNode()); dict.SetKey(kJsonNodeChild, std::move(child)); return dict; } // static std::unique_ptr BinaryOpNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); DECLARE_CHILD_AS_LIST_OR_FAIL(); const base::Value::ListStorage& children = child->GetList(); ret->left_ = ParseNode::BuildFromJSON(children[0]); ret->right_ = ParseNode::BuildFromJSON(children[1]); ret->op_ = TokenFromValue(value); GetCommentsFromJSON(ret.get(), value); return ret; } // BlockNode ------------------------------------------------------------------ BlockNode::BlockNode(ResultMode result_mode) : result_mode_(result_mode) {} BlockNode::~BlockNode() = default; const BlockNode* BlockNode::AsBlock() const { return this; } Value BlockNode::Execute(Scope* enclosing_scope, Err* err) const { std::unique_ptr nested_scope; // May be null. Scope* execution_scope; // Either the enclosing_scope or nested_scope. if (result_mode_ == RETURNS_SCOPE) { // Create a nested scope to save the values for returning. nested_scope = std::make_unique(enclosing_scope); execution_scope = nested_scope.get(); } else { // Use the enclosing scope. Modifications will go into this also (for // example, if conditions and loops). execution_scope = enclosing_scope; } for (size_t i = 0; i < statements_.size() && !err->has_error(); i++) { // Check for trying to execute things with no side effects in a block. // // A BlockNode here means that somebody has a free-floating { }. // Technically this can have side effects since it could generated targets, // but we don't want to allow this since it creates ambiguity when // immediately following a function call that takes no block. By not // allowing free-floating blocks that aren't passed anywhere or assigned to // anything, this ambiguity is resolved. const ParseNode* cur = statements_[i].get(); if (cur->AsList() || cur->AsLiteral() || cur->AsUnaryOp() || cur->AsIdentifier() || cur->AsBlock()) { *err = cur->MakeErrorDescribing( "This statement has no effect.", "Either delete it or do something with the result."); return Value(); } cur->Execute(execution_scope, err); } if (result_mode_ == RETURNS_SCOPE) { // Clear the reference to the containing scope. This will be passed in // a value whose lifetime will not be related to the enclosing_scope passed // to this function. nested_scope->DetachFromContaining(); return Value(this, std::move(nested_scope)); } return Value(); } LocationRange BlockNode::GetRange() const { if (begin_token_.type() != Token::INVALID && end_->value().type() != Token::INVALID) { return begin_token_.range().Union(end_->value().range()); } else if (!statements_.empty()) { return statements_[0]->GetRange().Union( statements_[statements_.size() - 1]->GetRange()); } return LocationRange(); } Err BlockNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(GetRange(), msg, help); } base::Value BlockNode::GetJSONNode() const { base::Value dict(CreateJSONNode(kDumpNodeName, GetRange())); base::Value statements(base::Value::Type::LIST); for (const auto& statement : statements_) statements.GetList().push_back(statement->GetJSONNode()); if (end_) dict.SetKey(kJsonEnd, end_->GetJSONNode()); dict.SetKey(kJsonNodeChild, std::move(statements)); if (result_mode_ == BlockNode::RETURNS_SCOPE) { dict.SetKey(kDumpResultMode, base::Value(kDumpResultModeReturnsScope)); } else if (result_mode_ == BlockNode::DISCARDS_RESULT) { dict.SetKey(kDumpResultMode, base::Value(kDumpResultModeDiscardsResult)); } else { NOTREACHED(); } dict.SetKey(kJsonBeginToken, base::Value(begin_token_.value())); return dict; } // static std::unique_ptr BlockNode::NewFromJSON(const base::Value& value) { const std::string& result_mode = value.FindKey(kDumpResultMode)->GetString(); std::unique_ptr ret; if (result_mode == kDumpResultModeReturnsScope) { ret.reset(new BlockNode(BlockNode::RETURNS_SCOPE)); } else if (result_mode == kDumpResultModeDiscardsResult) { ret.reset(new BlockNode(BlockNode::DISCARDS_RESULT)); } else { NOTREACHED(); } DECLARE_CHILD_AS_LIST_OR_FAIL(); for (const auto& elem : child->GetList()) { ret->statements_.push_back(ParseNode::BuildFromJSON(elem)); } ret->begin_token_ = Token::ClassifyAndMake(GetBeginLocationFromJSON(value), value.FindKey(kJsonBeginToken)->GetString()); if (value.FindKey(kJsonEnd)) { ret->end_ = EndNode::NewFromJSON(*value.FindKey(kJsonEnd)); } GetCommentsFromJSON(ret.get(), value); return ret; } // ConditionNode -------------------------------------------------------------- ConditionNode::ConditionNode() = default; ConditionNode::~ConditionNode() = default; const ConditionNode* ConditionNode::AsCondition() const { return this; } Value ConditionNode::Execute(Scope* scope, Err* err) const { Value condition_result = condition_->Execute(scope, err); if (err->has_error()) return Value(); if (condition_result.type() != Value::BOOLEAN) { *err = condition_->MakeErrorDescribing( "Condition does not evaluate to a boolean value.", std::string("This is a value of type \"") + Value::DescribeType(condition_result.type()) + "\" instead."); err->AppendRange(if_token_.range()); return Value(); } if (condition_result.boolean_value()) { if_true_->Execute(scope, err); } else if (if_false_) { // The else block is optional. if_false_->Execute(scope, err); } return Value(); } LocationRange ConditionNode::GetRange() const { if (if_false_) return if_token_.range().Union(if_false_->GetRange()); return if_token_.range().Union(if_true_->GetRange()); } Err ConditionNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(if_token_, msg, help); } base::Value ConditionNode::GetJSONNode() const { base::Value dict = CreateJSONNode(kDumpNodeName, GetRange()); base::Value child(base::Value::Type::LIST); child.GetList().push_back(condition_->GetJSONNode()); child.GetList().push_back(if_true_->GetJSONNode()); if (if_false_) { child.GetList().push_back(if_false_->GetJSONNode()); } dict.SetKey(kJsonNodeChild, std::move(child)); return dict; } // static std::unique_ptr ConditionNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); DECLARE_CHILD_AS_LIST_OR_FAIL(); const base::Value::ListStorage& children = child->GetList(); ret->if_token_ = Token::ClassifyAndMake(GetBeginLocationFromJSON(value), "if"); ret->condition_ = ParseNode::BuildFromJSON(children[0]); ret->if_true_ = BlockNode::NewFromJSON(children[1]); if (children.size() > 2) { ret->if_false_ = ParseNode::BuildFromJSON(children[2]); } GetCommentsFromJSON(ret.get(), value); return ret; } // FunctionCallNode ----------------------------------------------------------- FunctionCallNode::FunctionCallNode() = default; FunctionCallNode::~FunctionCallNode() = default; const FunctionCallNode* FunctionCallNode::AsFunctionCall() const { return this; } Value FunctionCallNode::Execute(Scope* scope, Err* err) const { return functions::RunFunction(scope, this, args_.get(), block_.get(), err); } LocationRange FunctionCallNode::GetRange() const { if (function_.type() == Token::INVALID) return LocationRange(); // This will be null in some tests. if (block_) return function_.range().Union(block_->GetRange()); return function_.range().Union(args_->GetRange()); } Err FunctionCallNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(function_, msg, help); } base::Value FunctionCallNode::GetJSONNode() const { base::Value dict = CreateJSONNode(kDumpNodeName, function_.value(), GetRange()); base::Value child(base::Value::Type::LIST); child.GetList().push_back(args_->GetJSONNode()); if (block_) { child.GetList().push_back(block_->GetJSONNode()); } dict.SetKey(kJsonNodeChild, std::move(child)); return dict; } // static std::unique_ptr FunctionCallNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); DECLARE_CHILD_AS_LIST_OR_FAIL(); const base::Value::ListStorage& children = child->GetList(); ret->function_ = TokenFromValue(value); ret->args_ = ListNode::NewFromJSON(children[0]); if (children.size() > 1) ret->block_ = BlockNode::NewFromJSON(children[1]); GetCommentsFromJSON(ret.get(), value); return ret; } void FunctionCallNode::SetNewLocation(int line_number) { Location func_old_loc = function_.location(); Location func_new_loc = Location(func_old_loc.file(), line_number, func_old_loc.column_number()); function_.set_location(func_new_loc); Location args_old_loc = args_->Begin().location(); Location args_new_loc = Location(args_old_loc.file(), line_number, args_old_loc.column_number()); const_cast(args_->Begin()).set_location(args_new_loc); const_cast(args_->End()->value()).set_location(args_new_loc); } // IdentifierNode -------------------------------------------------------------- IdentifierNode::IdentifierNode() = default; IdentifierNode::IdentifierNode(const Token& token) : value_(token) {} IdentifierNode::~IdentifierNode() = default; const IdentifierNode* IdentifierNode::AsIdentifier() const { return this; } Value IdentifierNode::Execute(Scope* scope, Err* err) const { const Scope* found_in_scope = nullptr; const Value* value = scope->GetValueWithScope(value_.value(), true, &found_in_scope); Value result; if (!value) { *err = MakeErrorDescribing("Undefined identifier"); return result; } if (!EnsureNotReadingFromSameDeclareArgs(this, scope, found_in_scope, err)) return result; result = *value; result.set_origin(this); return result; } LocationRange IdentifierNode::GetRange() const { return value_.range(); } Err IdentifierNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(value_, msg, help); } base::Value IdentifierNode::GetJSONNode() const { return CreateJSONNode(kDumpNodeName, value_.value(), GetRange()); } // static std::unique_ptr IdentifierNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); ret->set_value(TokenFromValue(value)); GetCommentsFromJSON(ret.get(), value); return ret; } void IdentifierNode::SetNewLocation(int line_number) { Location old = value_.location(); value_.set_location(Location(old.file(), line_number, old.column_number())); } // ListNode ------------------------------------------------------------------- ListNode::ListNode() {} ListNode::~ListNode() = default; const ListNode* ListNode::AsList() const { return this; } Value ListNode::Execute(Scope* scope, Err* err) const { Value result_value(this, Value::LIST); std::vector& results = result_value.list_value(); results.reserve(contents_.size()); for (const auto& cur : contents_) { if (cur->AsBlockComment()) continue; results.push_back(cur->Execute(scope, err)); if (err->has_error()) return Value(); if (results.back().type() == Value::NONE) { *err = cur->MakeErrorDescribing("This does not evaluate to a value.", "I can't do something with nothing."); return Value(); } } return result_value; } LocationRange ListNode::GetRange() const { return LocationRange(begin_token_.location(), end_->value().location()); } Err ListNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(begin_token_, msg, help); } base::Value ListNode::GetJSONNode() const { base::Value dict(CreateJSONNode(kDumpNodeName, GetRange())); base::Value child(base::Value::Type::LIST); for (const auto& cur : contents_) { child.GetList().push_back(cur->GetJSONNode()); } if (end_) dict.SetKey(kJsonEnd, end_->GetJSONNode()); dict.SetKey(kJsonNodeChild, std::move(child)); dict.SetKey(kJsonBeginToken, base::Value(begin_token_.value())); return dict; } // static std::unique_ptr ListNode::NewFromJSON(const base::Value& value) { auto ret = std::make_unique(); DECLARE_CHILD_AS_LIST_OR_FAIL(); for (const auto& elem : child->GetList()) { ret->contents_.push_back(ParseNode::BuildFromJSON(elem)); } ret->begin_token_ = Token::ClassifyAndMake(GetBeginLocationFromJSON(value), value.FindKey(kJsonBeginToken)->GetString()); if (value.FindKey(kJsonEnd)) { ret->end_ = EndNode::NewFromJSON(*value.FindKey(kJsonEnd)); } GetCommentsFromJSON(ret.get(), value); return ret; } template void ListNode::SortList(Comparator comparator) { // Partitions first on BlockCommentNodes and sorts each partition separately. for (auto sr : GetSortRanges()) { bool skip = false; for (size_t i = sr.begin; i != sr.end; ++i) { // Bails out if any of the nodes are unsupported. const ParseNode* node = contents_[i].get(); if (!node->AsLiteral() && !node->AsIdentifier() && !node->AsAccessor()) { skip = true; continue; } } if (skip) continue; // Save the original line number so that we can re-assign ranges. We assume // they're contiguous lines because GetSortRanges() does so above. We need // to re-assign these line numbers primiarily because `gn format` uses them // to determine whether two nodes were initially separated by a blank line // or not. int start_line = contents_[sr.begin]->GetRange().begin().line_number(); const ParseNode* original_first = contents_[sr.begin].get(); std::sort(contents_.begin() + sr.begin, contents_.begin() + sr.end, [&comparator](const std::unique_ptr& a, const std::unique_ptr& b) { return comparator(a.get(), b.get()); }); // If the beginning of the range had before comments, and the first node // moved during the sort, then move its comments to the new head of the // range. if (original_first->comments() && contents_[sr.begin].get() != original_first) { for (const auto& hc : original_first->comments()->before()) { const_cast(contents_[sr.begin].get()) ->comments_mutable() ->append_before(hc); } const_cast(original_first) ->comments_mutable() ->clear_before(); } const ParseNode* prev = nullptr; for (size_t i = sr.begin; i != sr.end; ++i) { const ParseNode* node = contents_[i].get(); DCHECK(node->AsLiteral() || node->AsIdentifier() || node->AsAccessor()); int line_number = prev ? prev->GetRange().end().line_number() + 1 : start_line; if (node->AsLiteral()) { const_cast(node->AsLiteral()) ->SetNewLocation(line_number); } else if (node->AsIdentifier()) { const_cast(node->AsIdentifier()) ->SetNewLocation(line_number); } else if (node->AsAccessor()) { const_cast(node->AsAccessor()) ->SetNewLocation(line_number); } prev = node; } } } void ListNode::SortAsStringsList() { // Sorts alphabetically. SortList([](const ParseNode* a, const ParseNode* b) { std::string_view astr = GetStringRepresentation(a); std::string_view bstr = GetStringRepresentation(b); return astr < bstr; }); } void ListNode::SortAsTargetsList() { // Sorts first relative targets, then absolute, each group is sorted // alphabetically. SortList([](const ParseNode* a, const ParseNode* b) { std::string_view astr = GetStringRepresentation(a); std::string_view bstr = GetStringRepresentation(b); return std::make_pair(GetDepsCategory(astr), SplitAtFirst(astr, ':')) < std::make_pair(GetDepsCategory(bstr), SplitAtFirst(bstr, ':')); }); } // Breaks the ParseNodes of |contents| up by ranges that should be separately // sorted. In particular, we break at a block comment, or an item that has an // attached "before" comment and is separated by a blank line from the item // before it. The assumption is that both of these indicate a separate 'section' // of a sources block across which items should not be inter-sorted. std::vector ListNode::GetSortRanges() const { std::vector ranges; const ParseNode* prev = nullptr; size_t begin = 0; for (size_t i = begin; i < contents_.size(); prev = contents_[i++].get()) { if (IsSortRangeSeparator(contents_[i].get(), prev)) { if (i > begin) { ranges.push_back(SortRange(begin, i)); // If |i| is an item with an attached comment, then we start the next // range at that point, because we want to include it in the sort. // Otherwise, it's a block comment which we skip over entirely because // we don't want to move or include it in the sort. The two cases are: // // sources = [ // "a", // "b", // // # // # This is a block comment. // # // // "c", // "d", // ] // // which contains 5 elements, and for which the ranges would be { [0, // 2), [3, 5) } (notably excluding 2, the block comment), and: // // sources = [ // "a", // "b", // // # This is a header comment. // "c", // "d", // ] // // which contains 4 elements, index 2 containing an attached 'before' // comments, and the ranges should be { [0, 2), [2, 4) }. if (!contents_[i]->AsBlockComment()) begin = i; else begin = i + 1; } else { // If it was a one item range, just skip over it. begin = i + 1; } } } if (begin != contents_.size()) ranges.push_back(SortRange(begin, contents_.size())); return ranges; } // LiteralNode ----------------------------------------------------------------- LiteralNode::LiteralNode() = default; LiteralNode::LiteralNode(const Token& token) : value_(token) {} LiteralNode::~LiteralNode() = default; const LiteralNode* LiteralNode::AsLiteral() const { return this; } Value LiteralNode::Execute(Scope* scope, Err* err) const { switch (value_.type()) { case Token::TRUE_TOKEN: return Value(this, true); case Token::FALSE_TOKEN: return Value(this, false); case Token::INTEGER: { std::string_view s = value_.value(); if ((base::starts_with(s, "0") && s.size() > 1) || base::starts_with(s, "-0")) { if (s == "-0") *err = MakeErrorDescribing("Negative zero doesn't make sense"); else *err = MakeErrorDescribing("Leading zeros not allowed"); return Value(); } int64_t result_int; if (!base::StringToInt64(s, &result_int)) { *err = MakeErrorDescribing("This does not look like an integer"); return Value(); } return Value(this, result_int); } case Token::STRING: { Value v(this, Value::STRING); ExpandStringLiteral(scope, value_, &v, err); return v; } default: NOTREACHED(); return Value(); } } LocationRange LiteralNode::GetRange() const { return value_.range(); } Err LiteralNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(value_, msg, help); } base::Value LiteralNode::GetJSONNode() const { return CreateJSONNode(kDumpNodeName, value_.value(), GetRange()); } // static std::unique_ptr LiteralNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); ret->value_ = TokenFromValue(value); GetCommentsFromJSON(ret.get(), value); return ret; } void LiteralNode::SetNewLocation(int line_number) { Location old = value_.location(); value_.set_location(Location(old.file(), line_number, old.column_number())); } // UnaryOpNode ---------------------------------------------------------------- UnaryOpNode::UnaryOpNode() = default; UnaryOpNode::~UnaryOpNode() = default; const UnaryOpNode* UnaryOpNode::AsUnaryOp() const { return this; } Value UnaryOpNode::Execute(Scope* scope, Err* err) const { Value operand_value = operand_->Execute(scope, err); if (err->has_error()) return Value(); return ExecuteUnaryOperator(scope, this, operand_value, err); } LocationRange UnaryOpNode::GetRange() const { return op_.range().Union(operand_->GetRange()); } Err UnaryOpNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(op_, msg, help); } base::Value UnaryOpNode::GetJSONNode() const { base::Value dict = CreateJSONNode(kDumpNodeName, op_.value(), GetRange()); base::Value child(base::Value::Type::LIST); child.GetList().push_back(operand_->GetJSONNode()); dict.SetKey(kJsonNodeChild, std::move(child)); return dict; } // static std::unique_ptr UnaryOpNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); ret->op_ = TokenFromValue(value); DECLARE_CHILD_AS_LIST_OR_FAIL(); ret->operand_ = ParseNode::BuildFromJSON(child->GetList()[0]); GetCommentsFromJSON(ret.get(), value); return ret; } // BlockCommentNode ------------------------------------------------------------ BlockCommentNode::BlockCommentNode() = default; BlockCommentNode::~BlockCommentNode() = default; const BlockCommentNode* BlockCommentNode::AsBlockComment() const { return this; } Value BlockCommentNode::Execute(Scope* scope, Err* err) const { return Value(); } LocationRange BlockCommentNode::GetRange() const { return comment_.range(); } Err BlockCommentNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(comment_, msg, help); } base::Value BlockCommentNode::GetJSONNode() const { std::string escaped; return CreateJSONNode(kDumpNodeName, comment_.value(), GetRange()); } // static std::unique_ptr BlockCommentNode::NewFromJSON( const base::Value& value) { auto ret = std::make_unique(); ret->comment_ = Token(GetBeginLocationFromJSON(value), Token::BLOCK_COMMENT, value.FindKey(kJsonNodeValue)->GetString()); GetCommentsFromJSON(ret.get(), value); return ret; } // EndNode --------------------------------------------------------------------- EndNode::EndNode(const Token& token) : value_(token) {} EndNode::~EndNode() = default; const EndNode* EndNode::AsEnd() const { return this; } Value EndNode::Execute(Scope* scope, Err* err) const { return Value(); } LocationRange EndNode::GetRange() const { return value_.range(); } Err EndNode::MakeErrorDescribing(const std::string& msg, const std::string& help) const { return Err(value_, msg, help); } base::Value EndNode::GetJSONNode() const { return CreateJSONNode(kDumpNodeName, value_.value(), GetRange()); } // static std::unique_ptr EndNode::NewFromJSON(const base::Value& value) { auto ret = std::make_unique(TokenFromValue(value)); GetCommentsFromJSON(ret.get(), value); return ret; }