tools/gn/scope.h - platform/external/chromium_org - Git at Google

 // 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.

 #ifndef TOOLS_GN_SCOPE_H_
 #define TOOLS_GN_SCOPE_H_

 #include <map>
 #include <set>

 #include "base/basictypes.h"
 #include "base/containers/hash_tables.h"
 #include "base/memory/ref_counted.h"
 #include "base/memory/scoped_ptr.h"
 #include "base/memory/scoped_vector.h"
 #include "tools/gn/err.h"
 #include "tools/gn/pattern.h"
 #include "tools/gn/source_dir.h"
 #include "tools/gn/value.h"

 class FunctionCallNode;
 class ImportManager;
 class Item;
 class ParseNode;
 class Settings;
 class TargetManager;
 class Template;

 // Scope for the script execution.
 //
 // Scopes are nested. Writing goes into the toplevel scope, reading checks
 // values resursively down the stack until a match is found or there are no
 // more containing scopes.
 //
 // A containing scope can be const or non-const. The const containing scope is
 // used primarily to refer to the master build config which is shared across
 // many invocations. A const containing scope, however, prevents us from
 // marking variables "used" which prevents us from issuing errors on unused
 // variables. So you should use a non-const containing scope whenever possible.
 class Scope {
  public:
   typedef base::hash_map<base::StringPiece, Value> KeyValueMap;
   // Holds an owning list of scoped_ptrs of Items (since we can't make a vector
   // of scoped_ptrs).
   typedef ScopedVector< scoped_ptr<Item> > ItemVector;

   // Allows code to provide values for built-in variables. This class will
   // automatically register itself on construction and deregister itself on
   // destruction.
   class ProgrammaticProvider {
    public:
     ProgrammaticProvider(Scope* scope) : scope_(scope) {
       scope_->AddProvider(this);
     }
     ~ProgrammaticProvider() {
       scope_->RemoveProvider(this);
     }

     // Returns a non-null value if the given value can be programmatically
     // generated, or NULL if there is none.
     virtual const Value* GetProgrammaticValue(
         const base::StringPiece& ident) = 0;

    protected:
     Scope* scope_;
   };

   // Options for configuring scope merges.
   struct MergeOptions {
     // Defaults to all false, which are the things least likely to cause errors.
     MergeOptions()
         : clobber_existing(false),
           skip_private_vars(false),
           mark_used(false) {
     }

     // When set, all existing avlues in the destination scope will be
     // overwritten.
     //
     // When false, it will be an error to merge a variable into another scope
     // where a variable with the same name is already set. The exception is
     // if both of the variables have the same value (which happens if you
     // somehow multiply import the same file, for example). This case will be
     // ignored since there is nothing getting lost.
     bool clobber_existing;

     // When true, private variables (names beginning with an underscore) will
     // be copied to the destination scope. When false, private values will be
     // skipped.
     bool skip_private_vars;

     // When set, values copied to the destination scope will be marked as used
     // so won't trigger an unused variable warning. You want this when doing an
     // import, for example, or files that don't need a variable from the .gni
     // file will throw an error.
     bool mark_used;
   };

   // Creates an empty toplevel scope.
   Scope(const Settings* settings);

   // Creates a dependent scope.
   Scope(Scope* parent);
   Scope(const Scope* parent);

   ~Scope();

   const Settings* settings() const { return settings_; }

   // See the const_/mutable_containing_ var declaraions below. Yes, it's a
   // bit weird that we can have a const pointer to the "mutable" one.
   Scope* mutable_containing() { return mutable_containing_; }
   const Scope* mutable_containing() const { return mutable_containing_; }
   const Scope* const_containing() const { return const_containing_; }
   const Scope* containing() const {
     return mutable_containing_ ? mutable_containing_ : const_containing_;
   }

   // Returns NULL if there's no such value.
   //
   // counts_as_used should be set if the variable is being read in a way that
   // should count for unused variable checking.
   const Value* GetValue(const base::StringPiece& ident,
                         bool counts_as_used);
   const Value* GetValue(const base::StringPiece& ident) const;

   // Returns the requested value as a mutable one if possible. If the value
   // is not found in a mutable scope, then returns null. Note that the value
   // could still exist in a const scope, so GetValue() could still return
   // non-null in this case.
   //
   // Say you have a local scope that then refers to the const root scope from
   // the master build config. You can't change the values from the master
   // build config (it's read-only so it can be read from multiple threads
   // without locking). Read-only operations would work on values from the root
   // scope, but write operations would only work on values in the derived
   // scope(s).
   //
   // Be careful when calling this. It's not normally correct to modify values,
   // but you should instead do a new Set each time.
   //
   // Consider this code:
   //   a = 5
   //    {
   //       a = 6
   //    }
   // The 6 should get set on the nested scope rather than modify the value
   // in the outer one.
   Value* GetMutableValue(const base::StringPiece& ident, bool counts_as_used);

   // Same as GetValue, but if the value exists in a parent scope, we'll copy
   // it to the current scope. If the return value is non-null, the value is
   // guaranteed to be set in the current scope. Generatlly this will be used
   // if the calling code is planning on modifying the value in-place.
   //
   // Since this is used when doing read-modifies, we never count this access
   // as reading the variable, since we assume it will be written to.
   Value* GetValueForcedToCurrentScope(const base::StringPiece& ident,
                                       const ParseNode* set_node);

   // The set_node indicates the statement that caused the set, for displaying
   // errors later. Returns a pointer to the value in the current scope (a copy
   // is made for storage).
   Value* SetValue(const base::StringPiece& ident,
                   const Value& v,
                   const ParseNode* set_node);

   // Removes the value with the given identifier if it exists on the current
   // scope. This does not search recursive scopes. Does nothing if not found.
   void RemoveIdentifier(const base::StringPiece& ident);

   // Removes from this scope all identifiers and templates that are considered
   // private.
   void RemovePrivateIdentifiers();

   // Templates associated with this scope. A template can only be set once, so
   // AddTemplate will fail and return false if a rule with that name already
   // exists. GetTemplate returns NULL if the rule doesn't exist, and it will
   // check all containing scoped rescursively.
   bool AddTemplate(const std::string& name, const Template* templ);
   const Template* GetTemplate(const std::string& name) const;

   // Marks the given identifier as (un)used in the current scope.
   void MarkUsed(const base::StringPiece& ident);
   void MarkUnused(const base::StringPiece& ident);

   // Checks to see if the scope has a var set that hasn't been used. This is
   // called before replacing the var with a different one. It does not check
   // containing scopes.
   //
   // If the identifier is present but hasnn't been used, return true.
   bool IsSetButUnused(const base::StringPiece& ident) const;

   // Checks the scope to see if any values were set but not used, and fills in
   // the error and returns false if they were.
   bool CheckForUnusedVars(Err* err) const;

   // Returns all values set in the current scope, without going to the parent
   // scopes.
   void GetCurrentScopeValues(KeyValueMap* output) const;

   // Copies this scope's values into the destination. Values from the
   // containing scope(s) (normally shadowed into the current one) will not be
   // copied, neither will the reference to the containing scope (this is why
   // it's "non-recursive").
   //
   // This is used in different contexts. When generating the error, the given
   // parse node will be blamed, and the given desc will be used to describe
   // the operation that doesn't support doing this. For example, desc_for_err
   // would be "import" when doing an import, and the error string would say
   // something like "The import contains...".
   bool NonRecursiveMergeTo(Scope* dest,
                            const MergeOptions& options,
                            const ParseNode* node_for_err,
                            const char* desc_for_err,
                            Err* err) const;

   // Constructs a scope that is a copy of the current one. Nested scopes will
   // be collapsed until we reach a const containing scope. Private values will
   // be included. The resulting closure will reference the const containing
   // scope as its containing scope (since we assume the const scope won't
   // change, we don't have to copy its values).
   scoped_ptr<Scope> MakeClosure() const;

   // Makes an empty scope with the given name. Returns NULL if the name is
   // already set.
   Scope* MakeTargetDefaults(const std::string& target_type);

   // Gets the scope associated with the given target name, or null if it hasn't
   // been set.
   const Scope* GetTargetDefaults(const std::string& target_type) const;

   // Filter to apply when the sources variable is assigned. May return NULL.
   const PatternList* GetSourcesAssignmentFilter() const;
   void set_sources_assignment_filter(
       scoped_ptr<PatternList> f) {
     sources_assignment_filter_ = f.Pass();
   }

   // Indicates if we're currently processing the build configuration file.
   // This is true when processing the config file for any toolchain.
   //
   // To set or clear the flag, it must currently be in the opposite state in
   // the current scope. Note that querying the state of the flag recursively
   // checks all containing scopes until it reaches the top or finds the flag
   // set.
   void SetProcessingBuildConfig();
   void ClearProcessingBuildConfig();
   bool IsProcessingBuildConfig() const;

   // Indicates if we're currently processing an import file.
   //
   // See SetProcessingBaseConfig for how flags work.
   void SetProcessingImport();
   void ClearProcessingImport();
   bool IsProcessingImport() const;

   // The source directory associated with this scope. This will check embedded
   // scopes until it finds a nonempty source directory. This will default to
   // an empty dir if no containing scope has a source dir set.
   const SourceDir& GetSourceDir() const;
   void set_source_dir(const SourceDir& d) { source_dir_ = d; }

   // The item collector is where Items (Targets, Configs, etc.) go that have
   // been defined. If a scope can generate items, this non-owning pointer will
   // point to the storage for such items. The creator of this scope will be
   // responsible for setting up the collector and then dealing with the
   // collected items once execution of the context is complete.
   //
   // The items in a scope are collected as we go and then dispatched at the end
   // of execution of a scope so that we can query the previously-generated
   // targets (like getting the outputs).
   //
   // This can be null if the current scope can not generate items (like for
   // imports and such).
   //
   // When retrieving the collector, the non-const scopes are recursively
   // queried. The collector is not copied for closures, etc.
   void set_item_collector(ItemVector* collector) {
     item_collector_ = collector;
   }
   ItemVector* GetItemCollector();

   // Properties are opaque pointers that code can use to set state on a Scope
   // that it can retrieve later.
   //
   // The key should be a pointer to some use-case-specific object (to avoid
   // collisions, otherwise it doesn't matter). Memory management is up to the
   // setter. Setting the value to NULL will delete the property.
   //
   // Getting a property recursively searches all scopes, and the optional
   // |found_on_scope| variable will be filled with the actual scope containing
   // the key (if the pointer is non-NULL).
   void SetProperty(const void* key, void* value);
   void* GetProperty(const void* key, const Scope** found_on_scope) const;

  private:
   friend class ProgrammaticProvider;

   struct Record {
     Record() : used(false) {}
     Record(const Value& v) : used(false), value(v) {}

     bool used;  // Set to true when the variable is used.
     Value value;
   };

   void AddProvider(ProgrammaticProvider* p);
   void RemoveProvider(ProgrammaticProvider* p);

   // Scopes can have no containing scope (both null), a mutable containing
   // scope, or a const containing scope. The reason is that when we're doing
   // a new target, we want to refer to the base_config scope which will be read
   // by multiple threads at the same time, so we REALLY want it to be const.
   // When you jsut do a nested {}, however, we sometimes want to be able to
   // change things (especially marking unused vars).
   const Scope* const_containing_;
   Scope* mutable_containing_;

   const Settings* settings_;

   // Bits set for different modes. See the flag definitions in the .cc file
   // for more.
   unsigned mode_flags_;

   typedef base::hash_map<base::StringPiece, Record> RecordMap;
   RecordMap values_;

   // Owning pointers. Note that this can't use string pieces since the names
   // are constructed from Values which might be deallocated before this goes
   // out of scope.
   typedef base::hash_map<std::string, Scope*> NamedScopeMap;
   NamedScopeMap target_defaults_;

   // Null indicates not set and that we should fallback to the containing
   // scope's filter.
   scoped_ptr<PatternList> sources_assignment_filter_;

   // Owning pointers, must be deleted.
   typedef std::map<std::string, scoped_refptr<const Template> > TemplateMap;
   TemplateMap templates_;

   ItemVector* item_collector_;

   // Opaque pointers. See SetProperty() above.
   typedef std::map<const void*, void*> PropertyMap;
   PropertyMap properties_;

   typedef std::set<ProgrammaticProvider*> ProviderSet;
   ProviderSet programmatic_providers_;

   SourceDir source_dir_;

   DISALLOW_COPY_AND_ASSIGN(Scope);
 };

 #endif  // TOOLS_GN_SCOPE_H_
	// 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.

	#ifndef TOOLS_GN_SCOPE_H_
	#define TOOLS_GN_SCOPE_H_

	#include <map>
	#include <set>

	#include "base/basictypes.h"
	#include "base/containers/hash_tables.h"
	#include "base/memory/ref_counted.h"
	#include "base/memory/scoped_ptr.h"
	#include "base/memory/scoped_vector.h"
	#include "tools/gn/err.h"
	#include "tools/gn/pattern.h"
	#include "tools/gn/source_dir.h"
	#include "tools/gn/value.h"

	class FunctionCallNode;
	class ImportManager;
	class Item;
	class ParseNode;
	class Settings;
	class TargetManager;
	class Template;

	// Scope for the script execution.
	//
	// Scopes are nested. Writing goes into the toplevel scope, reading checks
	// values resursively down the stack until a match is found or there are no
	// more containing scopes.
	//
	// A containing scope can be const or non-const. The const containing scope is
	// used primarily to refer to the master build config which is shared across
	// many invocations. A const containing scope, however, prevents us from
	// marking variables "used" which prevents us from issuing errors on unused
	// variables. So you should use a non-const containing scope whenever possible.
	class Scope {
	public:
	typedef base::hash_map<base::StringPiece, Value> KeyValueMap;
	// Holds an owning list of scoped_ptrs of Items (since we can't make a vector
	// of scoped_ptrs).
	typedef ScopedVector< scoped_ptr<Item> > ItemVector;

	// Allows code to provide values for built-in variables. This class will
	// automatically register itself on construction and deregister itself on
	// destruction.
	class ProgrammaticProvider {
	public:
	ProgrammaticProvider(Scope* scope) : scope_(scope) {
	scope_->AddProvider(this);
	}
	~ProgrammaticProvider() {
	scope_->RemoveProvider(this);
	}

	// Returns a non-null value if the given value can be programmatically
	// generated, or NULL if there is none.
	virtual const Value* GetProgrammaticValue(
	const base::StringPiece& ident) = 0;

	protected:
	Scope* scope_;
	};

	// Options for configuring scope merges.
	struct MergeOptions {
	// Defaults to all false, which are the things least likely to cause errors.
	MergeOptions()
	: clobber_existing(false),
	skip_private_vars(false),
	mark_used(false) {
	}

	// When set, all existing avlues in the destination scope will be
	// overwritten.
	//
	// When false, it will be an error to merge a variable into another scope
	// where a variable with the same name is already set. The exception is
	// if both of the variables have the same value (which happens if you
	// somehow multiply import the same file, for example). This case will be
	// ignored since there is nothing getting lost.
	bool clobber_existing;

	// When true, private variables (names beginning with an underscore) will
	// be copied to the destination scope. When false, private values will be
	// skipped.
	bool skip_private_vars;

	// When set, values copied to the destination scope will be marked as used
	// so won't trigger an unused variable warning. You want this when doing an
	// import, for example, or files that don't need a variable from the .gni
	// file will throw an error.
	bool mark_used;
	};

	// Creates an empty toplevel scope.
	Scope(const Settings* settings);

	// Creates a dependent scope.
	Scope(Scope* parent);
	Scope(const Scope* parent);

	~Scope();

	const Settings* settings() const { return settings_; }

	// See the const_/mutable_containing_ var declaraions below. Yes, it's a
	// bit weird that we can have a const pointer to the "mutable" one.
	Scope* mutable_containing() { return mutable_containing_; }
	const Scope* mutable_containing() const { return mutable_containing_; }
	const Scope* const_containing() const { return const_containing_; }
	const Scope* containing() const {
	return mutable_containing_ ? mutable_containing_ : const_containing_;
	}

	// Returns NULL if there's no such value.
	//
	// counts_as_used should be set if the variable is being read in a way that
	// should count for unused variable checking.
	const Value* GetValue(const base::StringPiece& ident,
	bool counts_as_used);
	const Value* GetValue(const base::StringPiece& ident) const;

	// Returns the requested value as a mutable one if possible. If the value
	// is not found in a mutable scope, then returns null. Note that the value
	// could still exist in a const scope, so GetValue() could still return
	// non-null in this case.
	//
	// Say you have a local scope that then refers to the const root scope from
	// the master build config. You can't change the values from the master
	// build config (it's read-only so it can be read from multiple threads
	// without locking). Read-only operations would work on values from the root
	// scope, but write operations would only work on values in the derived
	// scope(s).
	//
	// Be careful when calling this. It's not normally correct to modify values,
	// but you should instead do a new Set each time.
	//
	// Consider this code:
	// a = 5
	// {
	// a = 6
	// }
	// The 6 should get set on the nested scope rather than modify the value
	// in the outer one.
	Value* GetMutableValue(const base::StringPiece& ident, bool counts_as_used);

	// Same as GetValue, but if the value exists in a parent scope, we'll copy
	// it to the current scope. If the return value is non-null, the value is
	// guaranteed to be set in the current scope. Generatlly this will be used
	// if the calling code is planning on modifying the value in-place.
	//
	// Since this is used when doing read-modifies, we never count this access
	// as reading the variable, since we assume it will be written to.
	Value* GetValueForcedToCurrentScope(const base::StringPiece& ident,
	const ParseNode* set_node);

	// The set_node indicates the statement that caused the set, for displaying
	// errors later. Returns a pointer to the value in the current scope (a copy
	// is made for storage).
	Value* SetValue(const base::StringPiece& ident,
	const Value& v,
	const ParseNode* set_node);

	// Removes the value with the given identifier if it exists on the current
	// scope. This does not search recursive scopes. Does nothing if not found.
	void RemoveIdentifier(const base::StringPiece& ident);

	// Removes from this scope all identifiers and templates that are considered
	// private.
	void RemovePrivateIdentifiers();

	// Templates associated with this scope. A template can only be set once, so
	// AddTemplate will fail and return false if a rule with that name already
	// exists. GetTemplate returns NULL if the rule doesn't exist, and it will
	// check all containing scoped rescursively.
	bool AddTemplate(const std::string& name, const Template* templ);
	const Template* GetTemplate(const std::string& name) const;

	// Marks the given identifier as (un)used in the current scope.
	void MarkUsed(const base::StringPiece& ident);
	void MarkUnused(const base::StringPiece& ident);

	// Checks to see if the scope has a var set that hasn't been used. This is
	// called before replacing the var with a different one. It does not check
	// containing scopes.
	//
	// If the identifier is present but hasnn't been used, return true.
	bool IsSetButUnused(const base::StringPiece& ident) const;

	// Checks the scope to see if any values were set but not used, and fills in
	// the error and returns false if they were.
	bool CheckForUnusedVars(Err* err) const;

	// Returns all values set in the current scope, without going to the parent
	// scopes.
	void GetCurrentScopeValues(KeyValueMap* output) const;

	// Copies this scope's values into the destination. Values from the
	// containing scope(s) (normally shadowed into the current one) will not be
	// copied, neither will the reference to the containing scope (this is why
	// it's "non-recursive").
	//
	// This is used in different contexts. When generating the error, the given
	// parse node will be blamed, and the given desc will be used to describe
	// the operation that doesn't support doing this. For example, desc_for_err
	// would be "import" when doing an import, and the error string would say
	// something like "The import contains...".
	bool NonRecursiveMergeTo(Scope* dest,
	const MergeOptions& options,
	const ParseNode* node_for_err,
	const char* desc_for_err,
	Err* err) const;

	// Constructs a scope that is a copy of the current one. Nested scopes will
	// be collapsed until we reach a const containing scope. Private values will
	// be included. The resulting closure will reference the const containing
	// scope as its containing scope (since we assume the const scope won't
	// change, we don't have to copy its values).
	scoped_ptr<Scope> MakeClosure() const;

	// Makes an empty scope with the given name. Returns NULL if the name is
	// already set.
	Scope* MakeTargetDefaults(const std::string& target_type);

	// Gets the scope associated with the given target name, or null if it hasn't
	// been set.
	const Scope* GetTargetDefaults(const std::string& target_type) const;

	// Filter to apply when the sources variable is assigned. May return NULL.
	const PatternList* GetSourcesAssignmentFilter() const;
	void set_sources_assignment_filter(
	scoped_ptr<PatternList> f) {
	sources_assignment_filter_ = f.Pass();
	}

	// Indicates if we're currently processing the build configuration file.
	// This is true when processing the config file for any toolchain.
	//
	// To set or clear the flag, it must currently be in the opposite state in
	// the current scope. Note that querying the state of the flag recursively
	// checks all containing scopes until it reaches the top or finds the flag
	// set.
	void SetProcessingBuildConfig();
	void ClearProcessingBuildConfig();
	bool IsProcessingBuildConfig() const;

	// Indicates if we're currently processing an import file.
	//
	// See SetProcessingBaseConfig for how flags work.
	void SetProcessingImport();
	void ClearProcessingImport();
	bool IsProcessingImport() const;

	// The source directory associated with this scope. This will check embedded
	// scopes until it finds a nonempty source directory. This will default to
	// an empty dir if no containing scope has a source dir set.
	const SourceDir& GetSourceDir() const;
	void set_source_dir(const SourceDir& d) { source_dir_ = d; }

	// The item collector is where Items (Targets, Configs, etc.) go that have
	// been defined. If a scope can generate items, this non-owning pointer will
	// point to the storage for such items. The creator of this scope will be
	// responsible for setting up the collector and then dealing with the
	// collected items once execution of the context is complete.
	//
	// The items in a scope are collected as we go and then dispatched at the end
	// of execution of a scope so that we can query the previously-generated
	// targets (like getting the outputs).
	//
	// This can be null if the current scope can not generate items (like for
	// imports and such).
	//
	// When retrieving the collector, the non-const scopes are recursively
	// queried. The collector is not copied for closures, etc.
	void set_item_collector(ItemVector* collector) {
	item_collector_ = collector;
	}
	ItemVector* GetItemCollector();

	// Properties are opaque pointers that code can use to set state on a Scope
	// that it can retrieve later.
	//
	// The key should be a pointer to some use-case-specific object (to avoid
	// collisions, otherwise it doesn't matter). Memory management is up to the
	// setter. Setting the value to NULL will delete the property.
	//
	// Getting a property recursively searches all scopes, and the optional
	// \|found_on_scope\| variable will be filled with the actual scope containing
	// the key (if the pointer is non-NULL).
	void SetProperty(const void* key, void* value);
	void* GetProperty(const void* key, const Scope** found_on_scope) const;

	private:
	friend class ProgrammaticProvider;

	struct Record {
	Record() : used(false) {}
	Record(const Value& v) : used(false), value(v) {}

	bool used; // Set to true when the variable is used.
	Value value;
	};

	void AddProvider(ProgrammaticProvider* p);
	void RemoveProvider(ProgrammaticProvider* p);

	// Scopes can have no containing scope (both null), a mutable containing
	// scope, or a const containing scope. The reason is that when we're doing
	// a new target, we want to refer to the base_config scope which will be read
	// by multiple threads at the same time, so we REALLY want it to be const.
	// When you jsut do a nested {}, however, we sometimes want to be able to
	// change things (especially marking unused vars).
	const Scope* const_containing_;
	Scope* mutable_containing_;

	const Settings* settings_;

	// Bits set for different modes. See the flag definitions in the .cc file
	// for more.
	unsigned mode_flags_;

	typedef base::hash_map<base::StringPiece, Record> RecordMap;
	RecordMap values_;

	// Owning pointers. Note that this can't use string pieces since the names
	// are constructed from Values which might be deallocated before this goes
	// out of scope.
	typedef base::hash_map<std::string, Scope*> NamedScopeMap;
	NamedScopeMap target_defaults_;

	// Null indicates not set and that we should fallback to the containing
	// scope's filter.
	scoped_ptr<PatternList> sources_assignment_filter_;

	// Owning pointers, must be deleted.
	typedef std::map<std::string, scoped_refptr<const Template> > TemplateMap;
	TemplateMap templates_;

	ItemVector* item_collector_;

	// Opaque pointers. See SetProperty() above.
	typedef std::map<const void, void> PropertyMap;
	PropertyMap properties_;

	typedef std::set<ProgrammaticProvider*> ProviderSet;
	ProviderSet programmatic_providers_;

	SourceDir source_dir_;

	DISALLOW_COPY_AND_ASSIGN(Scope);
	};

	#endif // TOOLS_GN_SCOPE_H_