gecko-dev/layout/base/FrameProperties.h

495 строки
15 KiB
C++

/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifndef FRAMEPROPERTIES_H_
#define FRAMEPROPERTIES_H_
#include "mozilla/DebugOnly.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/TypeTraits.h"
#include "mozilla/Unused.h"
#include "nsTArray.h"
#include "nsThreadUtils.h"
class nsIFrame;
namespace mozilla {
struct FramePropertyDescriptorUntyped
{
/**
* mDestructor will be called if it's non-null.
*/
typedef void UntypedDestructor(void* aPropertyValue);
UntypedDestructor* mDestructor;
/**
* mDestructorWithFrame will be called if it's non-null and mDestructor
* is null. WARNING: The frame passed to mDestructorWithFrame may
* be a dangling frame pointer, if this is being called during
* presshell teardown. Do not use it except to compare against
* other frame pointers. No frame will have been allocated with
* the same address yet.
*/
typedef void UntypedDestructorWithFrame(const nsIFrame* aFrame,
void* aPropertyValue);
UntypedDestructorWithFrame* mDestructorWithFrame;
/**
* mDestructor and mDestructorWithFrame may both be null, in which case
* no value destruction is a no-op.
*/
protected:
/**
* At most one destructor should be passed in. In general, you should
* just use the static function FramePropertyDescriptor::New* below
* instead of using this constructor directly.
*/
constexpr FramePropertyDescriptorUntyped(
UntypedDestructor* aDtor, UntypedDestructorWithFrame* aDtorWithFrame)
: mDestructor(aDtor)
, mDestructorWithFrame(aDtorWithFrame)
{}
};
/**
* A pointer to a FramePropertyDescriptor serves as a unique property ID.
* The FramePropertyDescriptor stores metadata about the property.
* Currently the only metadata is a destructor function. The destructor
* function is called on property values when they are overwritten or
* deleted.
*
* To use this class, declare a global (i.e., file, class or function-scope
* static member) FramePropertyDescriptor and pass its address as
* aProperty in the FrameProperties methods.
*/
template<typename T>
struct FramePropertyDescriptor : public FramePropertyDescriptorUntyped
{
typedef void Destructor(T* aPropertyValue);
typedef void DestructorWithFrame(const nsIFrame* aaFrame,
T* aPropertyValue);
template<Destructor Dtor>
static constexpr const FramePropertyDescriptor<T> NewWithDestructor()
{
return { Destruct<Dtor>, nullptr };
}
template<DestructorWithFrame Dtor>
static constexpr
const FramePropertyDescriptor<T> NewWithDestructorWithFrame()
{
return { nullptr, DestructWithFrame<Dtor> };
}
static constexpr const FramePropertyDescriptor<T> NewWithoutDestructor()
{
return { nullptr, nullptr };
}
private:
constexpr FramePropertyDescriptor(
UntypedDestructor* aDtor, UntypedDestructorWithFrame* aDtorWithFrame)
: FramePropertyDescriptorUntyped(aDtor, aDtorWithFrame)
{}
template<Destructor Dtor>
static void Destruct(void* aPropertyValue)
{
Dtor(static_cast<T*>(aPropertyValue));
}
template<DestructorWithFrame Dtor>
static void DestructWithFrame(const nsIFrame* aFrame, void* aPropertyValue)
{
Dtor(aFrame, static_cast<T*>(aPropertyValue));
}
};
// SmallValueHolder<T> is a placeholder intended to be used as template
// argument of FramePropertyDescriptor for types which can fit into the
// size of a pointer directly. This class should never be defined, so
// that we won't use it for unexpected purpose by mistake.
template<typename T>
class SmallValueHolder;
namespace detail {
template<typename T>
struct FramePropertyTypeHelper
{
typedef T* Type;
};
template<typename T>
struct FramePropertyTypeHelper<SmallValueHolder<T>>
{
typedef T Type;
};
}
/**
* The FrameProperties class is optimized for storing 0 or 1 properties on
* a given frame. Storing very large numbers of properties on a single
* frame will not be efficient.
*
* Property values are passed as void* but do not actually have to be
* valid pointers. You can use NS_INT32_TO_PTR/NS_PTR_TO_INT32 to
* store int32_t values. Null/zero values can be stored and retrieved.
* Of course, the destructor function (if any) must handle such values
* correctly.
*/
class FrameProperties
{
public:
template<typename T>
using Descriptor = const FramePropertyDescriptor<T>*;
using UntypedDescriptor = const FramePropertyDescriptorUntyped*;
template<typename T>
using PropertyType = typename detail::FramePropertyTypeHelper<T>::Type;
explicit FrameProperties()
{
}
~FrameProperties()
{
MOZ_ASSERT(mProperties.Length() == 0, "forgot to delete properties");
}
/**
* Return true if we have no properties, otherwise return false.
*/
bool IsEmpty() const { return mProperties.IsEmpty(); }
/**
* Set a property value. This requires a linear search through
* the properties of the frame. Any existing value for the property
* is destroyed.
*/
template<typename T>
void Set(Descriptor<T> aProperty, PropertyType<T> aValue,
const nsIFrame* aFrame)
{
void* ptr = ReinterpretHelper<T>::ToPointer(aValue);
SetInternal(aProperty, ptr, aFrame);
}
/**
* Add a property value; the descriptor MUST NOT already be present.
*/
template<typename T>
void Add(Descriptor<T> aProperty, PropertyType<T> aValue)
{
MOZ_ASSERT(!Has(aProperty), "duplicate frame property");
void* ptr = ReinterpretHelper<T>::ToPointer(aValue);
AddInternal(aProperty, ptr);
}
/**
* @return true if @aProperty is set. This requires a linear search through the
* properties of the frame.
*
* In most cases, this shouldn't be used outside of assertions, because if
* you're doing a lookup anyway it would be far more efficient to call Get()
* or Remove() and check the aFoundResult outparam to find out whether the
* property is set. Legitimate non-assertion uses include:
*
* - Checking if a frame property is set in cases where that's all we want
* to know (i.e., we don't intend to read the actual value or remove the
* property).
*
* - Calling Has() before Set() in cases where we don't want to overwrite
* an existing value for the frame property.
*
* The HasSkippingBitCheck variant doesn't test NS_FRAME_HAS_PROPERTIES
* on aFrame, so it is safe to call after aFrame has been destroyed as
* long as, since that destruction happened, it isn't possible for a
* new frame to have been created and the same property added.
*/
template<typename T>
bool Has(Descriptor<T> aProperty) const
{
return mProperties.IndexOf(aProperty, 0, PropertyComparator())
!= nsTArray<PropertyValue>::NoIndex;
}
/**
* Get a property value. This requires a linear search through
* the properties of the frame. If the frame has no such property,
* returns zero-filled result, which means null for pointers and
* zero for integers and floating point types.
* @param aFoundResult if non-null, receives a value 'true' iff
* the frame has a value for the property. This lets callers
* disambiguate a null result, which can mean 'no such property' or
* 'property value is null'.
*/
template<typename T>
PropertyType<T> Get(Descriptor<T> aProperty,
bool* aFoundResult = nullptr) const
{
void* ptr = GetInternal(aProperty, aFoundResult);
return ReinterpretHelper<T>::FromPointer(ptr);
}
/**
* Remove a property value. This requires a linear search through
* the properties of the frame. The old property value is returned
* (and not destroyed). If the frame has no such property,
* returns zero-filled result, which means null for pointers and
* zero for integers and floating point types.
* @param aFoundResult if non-null, receives a value 'true' iff
* the frame had a value for the property. This lets callers
* disambiguate a null result, which can mean 'no such property' or
* 'property value is null'.
*/
template<typename T>
PropertyType<T> Remove(Descriptor<T> aProperty,
bool* aFoundResult = nullptr)
{
void* ptr = RemoveInternal(aProperty, aFoundResult);
return ReinterpretHelper<T>::FromPointer(ptr);
}
/**
* Remove and destroy a property value. This requires a linear search
* through the properties of the frame. If the frame has no such
* property, nothing happens.
*/
template<typename T>
void Delete(Descriptor<T> aProperty, const nsIFrame* aFrame)
{
DeleteInternal(aProperty, aFrame);
}
/**
* Call @aFunction for each property or until @aFunction returns false.
*/
template<class F>
void ForEach(F aFunction) const
{
#ifdef DEBUG
size_t len = mProperties.Length();
#endif
for (const auto& prop : mProperties) {
bool shouldContinue = aFunction(prop.mProperty, prop.mValue);
MOZ_ASSERT(len == mProperties.Length(),
"frame property list was modified by ForEach callback!");
if (!shouldContinue) {
return;
}
}
}
/**
* Remove and destroy all property values for the frame.
*/
void DeleteAll(const nsIFrame* aFrame) {
nsTArray<PropertyValue> toDelete;
toDelete.SwapElements(mProperties);
for (auto& prop : toDelete) {
prop.DestroyValueFor(aFrame);
}
MOZ_ASSERT(mProperties.IsEmpty(), "a property dtor added new properties");
}
size_t SizeOfExcludingThis(mozilla::MallocSizeOf aMallocSizeOf) const {
// We currently report only the shallow size of the mProperties array.
// As for the PropertyValue entries: we don't need to measure the mProperty
// field of because it always points to static memory, and we can't measure
// mValue because the type is opaque.
// XXX Can we do better, e.g. with a method on the descriptor?
return mProperties.ShallowSizeOfExcludingThis(aMallocSizeOf);
}
private:
// Prevent copying of FrameProperties; we should always return/pass around
// references to it, not copies!
FrameProperties(const FrameProperties&) = delete;
FrameProperties& operator=(const FrameProperties&) = delete;
inline void
SetInternal(UntypedDescriptor aProperty, void* aValue,
const nsIFrame* aFrame);
inline void
AddInternal(UntypedDescriptor aProperty, void* aValue);
inline void*
GetInternal(UntypedDescriptor aProperty, bool* aFoundResult) const;
inline void*
RemoveInternal(UntypedDescriptor aProperty, bool* aFoundResult);
inline void
DeleteInternal(UntypedDescriptor aProperty, const nsIFrame* aFrame);
template<typename T>
struct ReinterpretHelper
{
static_assert(sizeof(PropertyType<T>) <= sizeof(void*),
"size of the value must never be larger than a pointer");
static void* ToPointer(PropertyType<T> aValue)
{
void* ptr = nullptr;
memcpy(&ptr, &aValue, sizeof(aValue));
return ptr;
}
static PropertyType<T> FromPointer(void* aPtr)
{
PropertyType<T> value;
memcpy(&value, &aPtr, sizeof(value));
return value;
}
};
template<typename T>
struct ReinterpretHelper<T*>
{
static void* ToPointer(T* aValue)
{
return static_cast<void*>(aValue);
}
static T* FromPointer(void* aPtr)
{
return static_cast<T*>(aPtr);
}
};
/**
* Stores a property descriptor/value pair.
*/
struct PropertyValue {
PropertyValue() : mProperty(nullptr), mValue(nullptr) {}
PropertyValue(UntypedDescriptor aProperty, void* aValue)
: mProperty(aProperty), mValue(aValue) {}
void DestroyValueFor(const nsIFrame* aFrame) {
if (mProperty->mDestructor) {
mProperty->mDestructor(mValue);
} else if (mProperty->mDestructorWithFrame) {
mProperty->mDestructorWithFrame(aFrame, mValue);
}
}
UntypedDescriptor mProperty;
void* mValue;
};
/**
* Used with an array of PropertyValues to allow lookups that compare
* only on the FramePropertyDescriptor.
*/
class PropertyComparator {
public:
bool Equals(const PropertyValue& a, const PropertyValue& b) const {
return a.mProperty == b.mProperty;
}
bool Equals(UntypedDescriptor a, const PropertyValue& b) const {
return a == b.mProperty;
}
bool Equals(const PropertyValue& a, UntypedDescriptor b) const {
return a.mProperty == b;
}
};
nsTArray<PropertyValue> mProperties;
};
inline void*
FrameProperties::GetInternal(UntypedDescriptor aProperty,
bool* aFoundResult) const
{
MOZ_ASSERT(aProperty, "Null property?");
auto index = mProperties.IndexOf(aProperty, 0, PropertyComparator());
if (index == nsTArray<PropertyValue>::NoIndex) {
if (aFoundResult) {
*aFoundResult = false;
}
return nullptr;
}
if (aFoundResult) {
*aFoundResult = true;
}
return mProperties.ElementAt(index).mValue;
}
inline void
FrameProperties::SetInternal(UntypedDescriptor aProperty, void* aValue,
const nsIFrame* aFrame)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aProperty, "Null property?");
auto index = mProperties.IndexOf(aProperty, 0, PropertyComparator());
if (index != nsTArray<PropertyValue>::NoIndex) {
PropertyValue* pv = &mProperties.ElementAt(index);
pv->DestroyValueFor(aFrame);
pv->mValue = aValue;
return;
}
mProperties.AppendElement(PropertyValue(aProperty, aValue));
}
inline void
FrameProperties::AddInternal(UntypedDescriptor aProperty, void* aValue)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aProperty, "Null property?");
mProperties.AppendElement(PropertyValue(aProperty, aValue));
}
inline void*
FrameProperties::RemoveInternal(UntypedDescriptor aProperty, bool* aFoundResult)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aProperty, "Null property?");
auto index = mProperties.IndexOf(aProperty, 0, PropertyComparator());
if (index == nsTArray<PropertyValue>::NoIndex) {
if (aFoundResult) {
*aFoundResult = false;
}
return nullptr;
}
if (aFoundResult) {
*aFoundResult = true;
}
void* result = mProperties.ElementAt(index).mValue;
mProperties.RemoveElementAt(index);
return result;
}
inline void
FrameProperties::DeleteInternal(UntypedDescriptor aProperty,
const nsIFrame* aFrame)
{
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(aProperty, "Null property?");
auto index = mProperties.IndexOf(aProperty, 0, PropertyComparator());
if (index != nsTArray<PropertyValue>::NoIndex) {
mProperties.ElementAt(index).DestroyValueFor(aFrame);
mProperties.RemoveElementAt(index);
}
}
} // namespace mozilla
#endif /* FRAMEPROPERTIES_H_ */