foomatic_shell/parser.cc - mirrors/cros/chromiumos/platform2 - Git at Google

 // Copyright 2020 The Chromium OS 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 "foomatic_shell/parser.h"

 #include <string>
 #include <vector>

 #include <base/logging.h>

 namespace foomatic_shell {

 namespace {

 // Returns true if |token| may be a prefix of PipeSegment.
 // Corresponding grammar rules:
 //  Command = {Variable,"=",StringAtom,Space}, Application, {Space,Parameter} ;
 //  Variable = NativeString ;
 //  Application = NativeString ;
 //  Parameter = StringAtom ;
 bool MatchAPrefixOfPipeSegment(const Token& token) {
   // Check if the token may be a prefix of: "(", Script, ")"
   if (token.type == Token::kByte && *token.begin == '(')
     return true;
   // Check if the token may be a prefix of a Command.
   if (token.type == Token::kNativeString)
     return true;
   // It cannot be a PipeSegment.
   return false;
 }

 }  // namespace

 // This class encapsulates an iterator representing the current position
 // (token) in the input sequence.
 class Parser::InputTokens {
  public:
   // Constructor. |tokens| is a reference to the input sequence. The input
   // sequence must remain constant and valid during the lifetime of the object.
   // The current position is set to the first element in the |tokens|. The last
   // token in the sequence must be of type EOF.
   explicit InputTokens(const std::vector<Token>& tokens)
       : tokens_(tokens), current_(tokens_.begin()) {
     DCHECK(!tokens.empty());
     DCHECK(tokens.back().type == Token::Type::kEOF);
   }

   InputTokens(const InputTokens&) = delete;
   InputTokens(InputTokens&&) = delete;

   // Returns the reference to the current token. It is always valid.
   const Token& GetCurrentToken() const { return *current_; }

   // Returns true <=> the current token is of type EOF.
   bool CurrentTokenIsEOF() const {
     return (current_->type == Token::Type::kEOF);
   }

   // Returns true <=> the current token is of type Space.
   bool CurrentTokenIsSpace() const {
     return (current_->type == Token::Type::kSpace);
   }

   // Returns true <=> the current token is of type NativeString.
   bool CurrentTokenIsNativeString() const {
     return (current_->type == Token::Type::kNativeString);
   }

   // Returns true <=> the current token is one of the types: LiteralString,
   // ExecutedString, InterpretedString, NativeString.
   bool CurrentTokenIsAnyString() const {
     return (current_->type == Token::Type::kExecutedString ||
             current_->type == Token::Type::kInterpretedString ||
             current_->type == Token::Type::kLiteralString ||
             current_->type == Token::Type::kNativeString);
   }

   // Returns true <=> the current token is of type Byte and its value equals
   // |c|.
   bool CurrentTokenIsByte(char c) const {
     return (current_->type == Token::Type::kByte && *(current_->begin) == c);
   }

   // Moves the current position to the next token. If the current token is of
   // type EOF, it does nothing.
   void MoveToNext() {
     if (current_->type != Token::Type::kEOF)
       ++current_;
   }

   // Moves the current position to the previous token. It the current position
   // points to the first token in the sequence, it does nothing.
   void ReturnToPrevious() {
     if (current_ != tokens_.begin())
       --current_;
   }

  private:
   const std::vector<Token>& tokens_;
   std::vector<Token>::const_iterator current_;
 };

 Parser::Parser(const std::vector<Token>& tokens)
     : tokens_(std::make_unique<InputTokens>(tokens)) {}

 Parser::~Parser() {}

 bool Parser::ParseWholeInput(Script* out) {
   DCHECK(out != nullptr);

   if (!ParseScript(out))
     return false;
   if (!tokens_->CurrentTokenIsEOF()) {
     message_ = "Not everything was parsed";
     return false;
   }
   return true;
 }

 std::string::const_iterator Parser::GetPosition() const {
   return tokens_->GetCurrentToken().begin;
 }

 // This is a wrapper around ParseScriptImpl(...) to limit the number of
 // recursive (...) operators (sub-shells invocations).
 bool Parser::ParseScript(Script* out) {
   if (script_recursion_level_ > 4) {
     message_ = "Too many recursive shells executions";
     return false;
   }

   ++script_recursion_level_;
   const bool result = ParseScriptImpl(out);
   --script_recursion_level_;
   return result;
 }

 // Parses the following (see grammar.h for details):
 //  Script = OptSpace, {SepP,OptSpace}, Pipeline,
 //           { {SepP,OptSpace}-, Pipeline }, {SepP,OptSpace} ;
 // or:
 //  Script = OptSpace , { SepP , OptSpace } ;
 // If succeed, the method shifts the current position to the first token after
 // the end of a whole Script. The resultant Script is saved in |out|. |out| must
 // contain a pointer to an empty Script structure. Returns false in case of an
 // error.
 bool Parser::ParseScriptImpl(Script* out) {
   DCHECK(out != nullptr);

   // Parsing: OptSpace
   if (tokens_->CurrentTokenIsSpace())
     tokens_->MoveToNext();

   // Parsing: { SepP , OptSpace }
   while (tokens_->CurrentTokenIsByte('\n') ||
          tokens_->CurrentTokenIsByte(';')) {
     tokens_->MoveToNext();
     if (tokens_->CurrentTokenIsSpace())
       tokens_->MoveToNext();
   }

   // If the next token matches a Pipeline prefix, we go forward with the first
   // Script definition. Otherwise, we match the second Script definition (the
   // shorter one) and finish here with success.
   if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()))
     return true;

   // Parsing: Pipeline
   out->pipelines.resize(1);
   if (!ParsePipeline(&out->pipelines.back()))
     return false;

   // Parsing: { {SepP,OptSpace}-, Pipeline }, {SepP,OptSpace}
   while (tokens_->CurrentTokenIsByte('\n') ||
          tokens_->CurrentTokenIsByte(';')) {
     // Parsing: {SepP,OptSpace}- or {SepP,OptSpace}
     do {
       tokens_->MoveToNext();
       if (tokens_->CurrentTokenIsSpace())
         tokens_->MoveToNext();
     } while (tokens_->CurrentTokenIsByte('\n') ||
              tokens_->CurrentTokenIsByte(';'));

     // If the next token is not a prefix of a Pipeline, we reach the end of
     // the Script.
     if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()))
       break;

     // Parsing: Pipeline
     out->pipelines.emplace_back();
     if (!ParsePipeline(&out->pipelines.back()))
       return false;
   }

   return true;
 }

 // Parses the following (see grammar.h for details):
 //  Pipeline = PipeSegment, OptSpace, {"|",OptSpace,PipeSegment,OptSpace} ;
 // The current token must be a first token of a Pipeline. If succeed, the
 // method shifts the current position to the first token after the end of a
 // whole Pipeline. The resultant Pipeline is saved in |out|. |out| must
 // contain a pointer to an empty Pipeline structure. Returns false in case
 // of an error.
 bool Parser::ParsePipeline(Pipeline* out) {
   DCHECK(out != nullptr);
   DCHECK(MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()));

   // Parsing: PipeSegment
   out->segments.resize(1);
   if (!ParsePipeSegment(&out->segments.back()))
     return false;

   // Parsing: OptSpace
   if (tokens_->CurrentTokenIsSpace())
     tokens_->MoveToNext();

   // Parsing: {"|",OptSpace,PipeSegment,OptSpace}
   while (tokens_->CurrentTokenIsByte('|')) {
     tokens_->MoveToNext();
     // Parsing: OptSpace
     if (tokens_->CurrentTokenIsSpace())
       tokens_->MoveToNext();
     // Parsing: PipeSegment
     if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken())) {
       message_ = "Missing Pipe Segment after |";
       return false;
     }
     out->segments.emplace_back();
     if (!ParsePipeSegment(&out->segments.back()))
       return false;
     // Parsing: OptSpace
     if (tokens_->CurrentTokenIsSpace())
       tokens_->MoveToNext();
   }

   return true;
 }

 // Parses the following (see grammar.h for details):
 //  PipeSegment = ("(",Script,")") | Command ;
 // The current token must be a first token of a PipeSegment. If succeed, the
 // method shifts the current position to the first token after the end of a
 // whole PipeSegment. The resultant PipeSegment is saved in |out|. |out| must
 // contain a pointer to an empty PipeSegment structure. Returns false in case
 // of an error.
 bool Parser::ParsePipeSegment(PipeSegment* out) {
   DCHECK(out != nullptr);
   DCHECK(MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()));

   if (tokens_->CurrentTokenIsByte('(')) {
     // Parsing: "(", Script, ")"
     tokens_->MoveToNext();
     out->script = std::make_unique<Script>();
     if (!ParseScript(out->script.get()))
       return false;
     if (!tokens_->CurrentTokenIsByte(')')) {
       message_ = "Missing closing parenthesis )";
       return false;
     }
     tokens_->MoveToNext();
     return true;
   }

   // Parsing: Command
   out->command = std::make_unique<Command>();
   return ParseCommand(out->command.get());
 }

 // Parses the following (see grammar.h for details):
 //  Command = {Variable,"=",StringAtom,Space}, Application, {Space,Parameter} ;
 // The current token must be of type NativeString. If succeed, the method
 // shifts the current position to the first token after the end of a whole
 // command statement. The resultant command is saved in |out|. |out| must
 // contain a pointer to an empty Command structure. Returns false in case of
 // an error.
 bool Parser::ParseCommand(Command* out) {
   DCHECK(out != nullptr);
   DCHECK(tokens_->CurrentTokenIsNativeString());

   // Parsing: {Variable,"=",StringAtom,Space}, Application
   while (true) {
     // Save the current token (NativeString) and check the next one.
     // If the next token is "=", we are inside variable definition:
     // Variable,"=",StringAtom,Space
     // Otherwise, we just parsed Application.
     const Token& first = tokens_->GetCurrentToken();
     tokens_->MoveToNext();
     if (tokens_->CurrentTokenIsByte('=')) {
       // The token |first| is a Variable.
       // Parsing: "=",StringAtom,Space
       tokens_->MoveToNext();
       if (!tokens_->CurrentTokenIsAnyString()) {
         message_ = "Variable assignment with missing value";
         return false;
       }
       // Save the variable and parse its value.
       out->variables_with_values.emplace_back();
       out->variables_with_values.back().variable = first;
       ParseString(&out->variables_with_values.back().new_value);
       // Now we expect Space.
       if (!tokens_->CurrentTokenIsSpace()) {
         message_ = "Unexpected token after variable assignment";
         return false;
       }
       tokens_->MoveToNext();
       // The next token must be a Variable or an Application.
       // Both are NativeString.
       if (!tokens_->CurrentTokenIsNativeString()) {
         message_ = "Missing command";
         return false;
       }
     } else {
       // The token |first| is an Application.
       out->application = first;
       // The current token is the first token after the Application.
       // Exit the loop and parse parameters.
       break;
     }
   }

   // Parsing: {Space,Parameter}
   while (true) {
     // If the current token is not a Space, it does not match.
     if (!tokens_->CurrentTokenIsSpace())
       break;
     // It is a Space, check the next token.
     tokens_->MoveToNext();
     // If the next token is a beginning of StringAtom, we have next parameter.
     // If not, we have to move back (to return a Space token) and exit.
     if (!tokens_->CurrentTokenIsAnyString() &&
         !tokens_->CurrentTokenIsByte('=')) {
       tokens_->ReturnToPrevious();
       break;
     }
     // It is a parameter, let's parse it.
     out->parameters.emplace_back();
     ParseString(&out->parameters.back());
   }

   return true;
 }

 // Parses the following (see grammar.h for details):
 //  StringAtom = { LiteralString | ExecutedString | InterpretedString
 //              | NativeString | "=" }- ;
 // The current token must be the first token of the string. The method shifts
 // the current position to the first token after the end of the string. The
 // resultant string is saved in |out|. |out| must contain pointer to the empty
 // StringAtom structure.
 void Parser::ParseString(StringAtom* out) {
   DCHECK(out != nullptr);
   DCHECK(tokens_->CurrentTokenIsAnyString() ||
          tokens_->CurrentTokenIsByte('='));

   while (tokens_->CurrentTokenIsAnyString() ||
          tokens_->CurrentTokenIsByte('=')) {
     out->components.push_back(tokens_->GetCurrentToken());
     tokens_->MoveToNext();
   }
 }

 }  // namespace foomatic_shell
	// Copyright 2020 The Chromium OS 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 "foomatic_shell/parser.h"

	#include <string>
	#include <vector>

	#include <base/logging.h>

	namespace foomatic_shell {

	namespace {

	// Returns true if \|token\| may be a prefix of PipeSegment.
	// Corresponding grammar rules:
	// Command = {Variable,"=",StringAtom,Space}, Application, {Space,Parameter} ;
	// Variable = NativeString ;
	// Application = NativeString ;
	// Parameter = StringAtom ;
	bool MatchAPrefixOfPipeSegment(const Token& token) {
	// Check if the token may be a prefix of: "(", Script, ")"
	if (token.type == Token::kByte && *token.begin == '(')
	return true;
	// Check if the token may be a prefix of a Command.
	if (token.type == Token::kNativeString)
	return true;
	// It cannot be a PipeSegment.
	return false;
	}

	} // namespace

	// This class encapsulates an iterator representing the current position
	// (token) in the input sequence.
	class Parser::InputTokens {
	public:
	// Constructor. \|tokens\| is a reference to the input sequence. The input
	// sequence must remain constant and valid during the lifetime of the object.
	// The current position is set to the first element in the \|tokens\|. The last
	// token in the sequence must be of type EOF.
	explicit InputTokens(const std::vector<Token>& tokens)
	: tokens_(tokens), current_(tokens_.begin()) {
	DCHECK(!tokens.empty());
	DCHECK(tokens.back().type == Token::Type::kEOF);
	}

	InputTokens(const InputTokens&) = delete;
	InputTokens(InputTokens&&) = delete;

	// Returns the reference to the current token. It is always valid.
	const Token& GetCurrentToken() const { return *current_; }

	// Returns true <=> the current token is of type EOF.
	bool CurrentTokenIsEOF() const {
	return (current_->type == Token::Type::kEOF);
	}

	// Returns true <=> the current token is of type Space.
	bool CurrentTokenIsSpace() const {
	return (current_->type == Token::Type::kSpace);
	}

	// Returns true <=> the current token is of type NativeString.
	bool CurrentTokenIsNativeString() const {
	return (current_->type == Token::Type::kNativeString);
	}

	// Returns true <=> the current token is one of the types: LiteralString,
	// ExecutedString, InterpretedString, NativeString.
	bool CurrentTokenIsAnyString() const {
	return (current_->type == Token::Type::kExecutedString \|\|
	current_->type == Token::Type::kInterpretedString \|\|
	current_->type == Token::Type::kLiteralString \|\|
	current_->type == Token::Type::kNativeString);
	}

	// Returns true <=> the current token is of type Byte and its value equals
	// \|c\|.
	bool CurrentTokenIsByte(char c) const {
	return (current_->type == Token::Type::kByte && *(current_->begin) == c);
	}

	// Moves the current position to the next token. If the current token is of
	// type EOF, it does nothing.
	void MoveToNext() {
	if (current_->type != Token::Type::kEOF)
	++current_;
	}

	// Moves the current position to the previous token. It the current position
	// points to the first token in the sequence, it does nothing.
	void ReturnToPrevious() {
	if (current_ != tokens_.begin())
	--current_;
	}

	private:
	const std::vector<Token>& tokens_;
	std::vector<Token>::const_iterator current_;
	};

	Parser::Parser(const std::vector<Token>& tokens)
	: tokens_(std::make_unique<InputTokens>(tokens)) {}

	Parser::~Parser() {}

	bool Parser::ParseWholeInput(Script* out) {
	DCHECK(out != nullptr);

	if (!ParseScript(out))
	return false;
	if (!tokens_->CurrentTokenIsEOF()) {
	message_ = "Not everything was parsed";
	return false;
	}
	return true;
	}

	std::string::const_iterator Parser::GetPosition() const {
	return tokens_->GetCurrentToken().begin;
	}

	// This is a wrapper around ParseScriptImpl(...) to limit the number of
	// recursive (...) operators (sub-shells invocations).
	bool Parser::ParseScript(Script* out) {
	if (script_recursion_level_ > 4) {
	message_ = "Too many recursive shells executions";
	return false;
	}

	++script_recursion_level_;
	const bool result = ParseScriptImpl(out);
	--script_recursion_level_;
	return result;
	}

	// Parses the following (see grammar.h for details):
	// Script = OptSpace, {SepP,OptSpace}, Pipeline,
	// { {SepP,OptSpace}-, Pipeline }, {SepP,OptSpace} ;
	// or:
	// Script = OptSpace , { SepP , OptSpace } ;
	// If succeed, the method shifts the current position to the first token after
	// the end of a whole Script. The resultant Script is saved in \|out\|. \|out\| must
	// contain a pointer to an empty Script structure. Returns false in case of an
	// error.
	bool Parser::ParseScriptImpl(Script* out) {
	DCHECK(out != nullptr);

	// Parsing: OptSpace
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();

	// Parsing: { SepP , OptSpace }
	while (tokens_->CurrentTokenIsByte('\n') \|\|
	tokens_->CurrentTokenIsByte(';')) {
	tokens_->MoveToNext();
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();
	}

	// If the next token matches a Pipeline prefix, we go forward with the first
	// Script definition. Otherwise, we match the second Script definition (the
	// shorter one) and finish here with success.
	if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()))
	return true;

	// Parsing: Pipeline
	out->pipelines.resize(1);
	if (!ParsePipeline(&out->pipelines.back()))
	return false;

	// Parsing: { {SepP,OptSpace}-, Pipeline }, {SepP,OptSpace}
	while (tokens_->CurrentTokenIsByte('\n') \|\|
	tokens_->CurrentTokenIsByte(';')) {
	// Parsing: {SepP,OptSpace}- or {SepP,OptSpace}
	do {
	tokens_->MoveToNext();
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();
	} while (tokens_->CurrentTokenIsByte('\n') \|\|
	tokens_->CurrentTokenIsByte(';'));

	// If the next token is not a prefix of a Pipeline, we reach the end of
	// the Script.
	if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()))
	break;

	// Parsing: Pipeline
	out->pipelines.emplace_back();
	if (!ParsePipeline(&out->pipelines.back()))
	return false;
	}

	return true;
	}

	// Parses the following (see grammar.h for details):
	// Pipeline = PipeSegment, OptSpace, {"\|",OptSpace,PipeSegment,OptSpace} ;
	// The current token must be a first token of a Pipeline. If succeed, the
	// method shifts the current position to the first token after the end of a
	// whole Pipeline. The resultant Pipeline is saved in \|out\|. \|out\| must
	// contain a pointer to an empty Pipeline structure. Returns false in case
	// of an error.
	bool Parser::ParsePipeline(Pipeline* out) {
	DCHECK(out != nullptr);
	DCHECK(MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()));

	// Parsing: PipeSegment
	out->segments.resize(1);
	if (!ParsePipeSegment(&out->segments.back()))
	return false;

	// Parsing: OptSpace
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();

	// Parsing: {"\|",OptSpace,PipeSegment,OptSpace}
	while (tokens_->CurrentTokenIsByte('\|')) {
	tokens_->MoveToNext();
	// Parsing: OptSpace
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();
	// Parsing: PipeSegment
	if (!MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken())) {
	message_ = "Missing Pipe Segment after \|";
	return false;
	}
	out->segments.emplace_back();
	if (!ParsePipeSegment(&out->segments.back()))
	return false;
	// Parsing: OptSpace
	if (tokens_->CurrentTokenIsSpace())
	tokens_->MoveToNext();
	}

	return true;
	}

	// Parses the following (see grammar.h for details):
	// PipeSegment = ("(",Script,")") \| Command ;
	// The current token must be a first token of a PipeSegment. If succeed, the
	// method shifts the current position to the first token after the end of a
	// whole PipeSegment. The resultant PipeSegment is saved in \|out\|. \|out\| must
	// contain a pointer to an empty PipeSegment structure. Returns false in case
	// of an error.
	bool Parser::ParsePipeSegment(PipeSegment* out) {
	DCHECK(out != nullptr);
	DCHECK(MatchAPrefixOfPipeSegment(tokens_->GetCurrentToken()));

	if (tokens_->CurrentTokenIsByte('(')) {
	// Parsing: "(", Script, ")"
	tokens_->MoveToNext();
	out->script = std::make_unique<Script>();
	if (!ParseScript(out->script.get()))
	return false;
	if (!tokens_->CurrentTokenIsByte(')')) {
	message_ = "Missing closing parenthesis )";
	return false;
	}
	tokens_->MoveToNext();
	return true;
	}

	// Parsing: Command
	out->command = std::make_unique<Command>();
	return ParseCommand(out->command.get());
	}

	// Parses the following (see grammar.h for details):
	// Command = {Variable,"=",StringAtom,Space}, Application, {Space,Parameter} ;
	// The current token must be of type NativeString. If succeed, the method
	// shifts the current position to the first token after the end of a whole
	// command statement. The resultant command is saved in \|out\|. \|out\| must
	// contain a pointer to an empty Command structure. Returns false in case of
	// an error.
	bool Parser::ParseCommand(Command* out) {
	DCHECK(out != nullptr);
	DCHECK(tokens_->CurrentTokenIsNativeString());

	// Parsing: {Variable,"=",StringAtom,Space}, Application
	while (true) {
	// Save the current token (NativeString) and check the next one.
	// If the next token is "=", we are inside variable definition:
	// Variable,"=",StringAtom,Space
	// Otherwise, we just parsed Application.
	const Token& first = tokens_->GetCurrentToken();
	tokens_->MoveToNext();
	if (tokens_->CurrentTokenIsByte('=')) {
	// The token \|first\| is a Variable.
	// Parsing: "=",StringAtom,Space
	tokens_->MoveToNext();
	if (!tokens_->CurrentTokenIsAnyString()) {
	message_ = "Variable assignment with missing value";
	return false;
	}
	// Save the variable and parse its value.
	out->variables_with_values.emplace_back();
	out->variables_with_values.back().variable = first;
	ParseString(&out->variables_with_values.back().new_value);
	// Now we expect Space.
	if (!tokens_->CurrentTokenIsSpace()) {
	message_ = "Unexpected token after variable assignment";
	return false;
	}
	tokens_->MoveToNext();
	// The next token must be a Variable or an Application.
	// Both are NativeString.
	if (!tokens_->CurrentTokenIsNativeString()) {
	message_ = "Missing command";
	return false;
	}
	} else {
	// The token \|first\| is an Application.
	out->application = first;
	// The current token is the first token after the Application.
	// Exit the loop and parse parameters.
	break;
	}
	}

	// Parsing: {Space,Parameter}
	while (true) {
	// If the current token is not a Space, it does not match.
	if (!tokens_->CurrentTokenIsSpace())
	break;
	// It is a Space, check the next token.
	tokens_->MoveToNext();
	// If the next token is a beginning of StringAtom, we have next parameter.
	// If not, we have to move back (to return a Space token) and exit.
	if (!tokens_->CurrentTokenIsAnyString() &&
	!tokens_->CurrentTokenIsByte('=')) {
	tokens_->ReturnToPrevious();
	break;
	}
	// It is a parameter, let's parse it.
	out->parameters.emplace_back();
	ParseString(&out->parameters.back());
	}

	return true;
	}

	// Parses the following (see grammar.h for details):
	// StringAtom = { LiteralString \| ExecutedString \| InterpretedString
	// \| NativeString \| "=" }- ;
	// The current token must be the first token of the string. The method shifts
	// the current position to the first token after the end of the string. The
	// resultant string is saved in \|out\|. \|out\| must contain pointer to the empty
	// StringAtom structure.
	void Parser::ParseString(StringAtom* out) {
	DCHECK(out != nullptr);
	DCHECK(tokens_->CurrentTokenIsAnyString() \|\|
	tokens_->CurrentTokenIsByte('='));

	while (tokens_->CurrentTokenIsAnyString() \|\|
	tokens_->CurrentTokenIsByte('=')) {
	out->components.push_back(tokens_->GetCurrentToken());
	tokens_->MoveToNext();
	}
	}

	} // namespace foomatic_shell