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Quelle xptinfo.h Sprache: C |
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/* -*- 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 https://mozilla.org/MPL/2.0/. */ /** * Structures and methods with information about XPCOM interfaces for use by * XPConnect. The static backing data structures used by this file are generated * from xpidl interfaces by the jsonxpt.py and xptcodegen.py scripts. */ #ifndef xptinfo_h #define xptinfo_h #include <stdint.h> #include "nsID.h" #include "mozilla/Assertions.h" #include "jsapi.h" #include "js/Symbol.h" #include "js/Value.h" #include "nsString.h" #include "nsTArray.h" // Forward Declarations namespace mozilla { namespace dom { struct NativePropertyHooks; } // namespace dom } // namespace mozilla struct nsXPTInterfaceInfo; struct nsXPTType; struct nsXPTParamInfo; struct nsXPTMethodInfo; struct nsXPTConstantInfo; struct nsXPTDOMObjectInfo; enum class nsXPTInterface : uint16_t; // Internal helper methods. namespace xpt { namespace detail { inline const nsXPTInterfaceInfo* GetInterface(uint16_t aIndex); inline const nsXPTType& GetType(uint16_t aIndex); inline const nsXPTParamInfo& GetParam(uint16_t aIndex); inline const nsXPTMethodInfo& GetMethod(uint16_t aIndex); inline const nsXPTConstantInfo& GetConstant(uint16_t aIndex); inline const nsXPTDOMObjectInfo& GetDOMObjectInfo(uint16_t aIndex); inline const char* GetString(uint32_t aIndex); const nsXPTInterfaceInfo* InterfaceByIID(const nsIID& aIID); const nsXPTInterfaceInfo* InterfaceByName(const char* aName); extern const uint16_t sInterfacesSize; } // namespace detail } // namespace xpt /* * An Interface describes a single XPCOM interface, including all of its * methods. We don't record non-scriptable interfaces. */ struct nsXPTInterfaceInfo { // High efficiency getters for Interfaces based on perfect hashes. static const nsXPTInterfaceInfo* ByIID(const nsIID& aIID) { return xpt::detail::InterfaceByIID(aIID); } static const nsXPTInterfaceInfo* ByName(const char* aName) { return xpt::detail::InterfaceByName(aName); } static const nsXPTInterfaceInfo* Get(nsXPTInterface aID) { return ByIndex(uint16_t(aID)); } // These are only needed for Components_interfaces's enumerator. static const nsXPTInterfaceInfo* ByIndex(uint16_t aIndex) { // NOTE: We add 1 here, as the internal index 0 is reserved for null. return xpt::detail::GetInterface(aIndex + 1); } static uint16_t InterfaceCount() { return xpt::detail::sInterfacesSize; } // Interface flag getters bool IsFunction() const { return mFunction; } bool IsBuiltinClass() const { return mBuiltinClass; } bool IsMainProcessScriptableOnly() const { return mMainProcessScriptableOnly; } const char* Name() const { return xpt::detail::GetString(mName); } const nsIID& IID() const { return mIID; } // Get the parent interface, or null if this interface doesn't have a parent. const nsXPTInterfaceInfo* GetParent() const { return xpt::detail::GetInterface(mParent); } // Do we have an ancestor interface with the given IID? bool HasAncestor(const nsIID& aIID) const; // Get methods & constants uint16_t ConstantCount() const { return mNumConsts; } const nsXPTConstantInfo& Constant(uint16_t aIndex) const; uint16_t MethodCount() const { return mNumMethods; } const nsXPTMethodInfo& Method(uint16_t aIndex) const; nsresult GetMethodInfo(uint16_t aIndex, const nsXPTMethodInfo** aInfo) const; nsresult GetConstant(uint16_t aIndex, JS::MutableHandle<JS::Value> constant, char** aName) const; //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// nsID mIID; uint32_t mName; // Index into xpt::detail::sStrings uint16_t mParent : 14; uint16_t mBuiltinClass : 1; // XXX(nika): Do we need this if we don't have addons anymore? uint16_t mMainProcessScriptableOnly : 1; uint16_t mMethods; // Index into xpt::detail::sMethods uint16_t mConsts : 14; // Index into xpt::detail::sConsts uint16_t mFunction : 1; // uint16_t unused : 1; uint8_t mNumMethods; // NOTE(24/04/18): largest=nsIDocShell (193) uint8_t mNumConsts; // NOTE(24/04/18): largest=nsIAccessibleRole (175) }; // The fields in nsXPTInterfaceInfo were carefully ordered to minimize size. static_assert(sizeof(nsXPTInterfaceInfo) == 28, "wrong size?"); /* * The following enum represents contains the different tag types which * can be found in nsXPTTypeInfo::mTag. * * WARNING: mTag is 5 bits wide, supporting at most 32 tags. */ enum nsXPTTypeTag : uint8_t { // Arithmetic (POD) Types // - Do not require cleanup, // - All bit patterns are valid, // - Outparams may be uninitialized by caller, // - Directly supported in xptcall. // // NOTE: The name 'Arithmetic' comes from Harbison/Steele. Despite being a tad // unclear, it is used frequently in xptcall, so is unlikely to be changed. TD_INT8 = 0, TD_INT16 = 1, TD_INT32 = 2, TD_INT64 = 3, TD_UINT8 = 4, TD_UINT16 = 5, TD_UINT32 = 6, TD_UINT64 = 7, TD_FLOAT = 8, TD_DOUBLE = 9, TD_BOOL = 10, TD_CHAR = 11, TD_WCHAR = 12, _TD_LAST_ARITHMETIC = TD_WCHAR, // Pointer Types // - Require cleanup unless NULL, // - All-zeros (NULL) bit pattern is valid, // - Outparams may be uninitialized by caller, // - Supported in xptcall as raw pointer. TD_VOID = 13, TD_NSIDPTR = 14, TD_PSTRING = 15, TD_PWSTRING = 16, TD_INTERFACE_TYPE = 17, TD_INTERFACE_IS_TYPE = 18, TD_LEGACY_ARRAY = 19, TD_PSTRING_SIZE_IS = 20, TD_PWSTRING_SIZE_IS = 21, TD_DOMOBJECT = 22, TD_PROMISE = 23, _TD_LAST_POINTER = TD_PROMISE, // Complex Types // - Require cleanup, // - Always passed indirectly, // - Outparams must be initialized by caller, // - Supported in xptcall due to indirection. TD_UTF8STRING = 24, TD_CSTRING = 25, TD_ASTRING = 26, TD_NSID = 27, TD_JSVAL = 28, TD_ARRAY = 29, _TD_LAST_COMPLEX = TD_ARRAY }; static_assert(_TD_LAST_COMPLEX < 32, "nsXPTTypeTag must fit in 5 bits"); /* * A nsXPTType is a union used to identify the type of a method argument or * return value. The internal data is stored as an 5-bit tag, and two 8-bit * integers, to keep alignment requirements low. * * nsXPTType contains 3 extra bits, reserved for use by nsXPTParamInfo. */ struct nsXPTType { nsXPTTypeTag Tag() const { return static_cast<nsXPTTypeTag>(mTag); } // The index in the function argument list which should be used when // determining the iid_is or size_is properties of this dependent type. uint8_t ArgNum() const { MOZ_ASSERT(Tag() == TD_INTERFACE_IS_TYPE || Tag() == TD_PSTRING_SIZE_IS || Tag() == TD_PWSTRING_SIZE_IS || Tag() == TD_LEGACY_ARRAY); return mData1; } private: // Helper for reading 16-bit data values split between mData1 and mData2. uint16_t Data16() const { return static_cast<uint16_t>(mData1 << 8) | mData2; } public: // Get the type of the element in the current array or sequence. Arrays only // fit 8 bits of type data, while sequences support up to 16 bits of type data // due to not needing to store an ArgNum. const nsXPTType& ArrayElementType() const { if (Tag() == TD_LEGACY_ARRAY) { return xpt::detail::GetType(mData2); } MOZ_ASSERT(Tag() == TD_ARRAY); return xpt::detail::GetType(Data16()); } // We store the 16-bit iface value as two 8-bit values in order to // avoid 16-bit alignment requirements for XPTTypeDescriptor, which // reduces its size and also the size of XPTParamDescriptor. const nsXPTInterfaceInfo* GetInterface() const { MOZ_ASSERT(Tag() == TD_INTERFACE_TYPE); return xpt::detail::GetInterface(Data16()); } const nsXPTDOMObjectInfo& GetDOMObjectInfo() const { MOZ_ASSERT(Tag() == TD_DOMOBJECT); return xpt::detail::GetDOMObjectInfo(Data16()); } // See the comments in nsXPTTypeTag for an explanation as to what each of // these categories mean. bool IsArithmetic() const { return Tag() <= _TD_LAST_ARITHMETIC; } bool IsPointer() const { return !IsArithmetic() && Tag() <= _TD_LAST_POINTER; } bool IsComplex() const { return Tag() > _TD_LAST_POINTER; } bool IsInterfacePointer() const { return Tag() == TD_INTERFACE_TYPE || Tag() == TD_INTERFACE_IS_TYPE; } bool IsDependent() const { return (Tag() == TD_ARRAY && InnermostType().IsDependent()) || Tag() == TD_INTERFACE_IS_TYPE || Tag() == TD_LEGACY_ARRAY || Tag() == TD_PSTRING_SIZE_IS || Tag() == TD_PWSTRING_SIZE_IS; } // Unwrap a nested type to its innermost value (e.g. through arrays). const nsXPTType& InnermostType() const { if (Tag() == TD_LEGACY_ARRAY || Tag() == TD_ARRAY) { return ArrayElementType().InnermostType(); } return *this; } // In-memory size of native type in bytes. inline size_t Stride() const; // Offset the given base pointer to reference the element at the given index. void* ElementPtr(const void* aBase, uint32_t aIndex) const { return (char*)aBase + (aIndex * Stride()); } // Zero out a native value of the given type. The type must not be 'complex'. void ZeroValue(void* aValue) const { MOZ_RELEASE_ASSERT(!IsComplex(), "Cannot zero a complex value"); memset(aValue, 0, Stride()); } // Indexes into the extra types array of a small set of known types. enum class Idx : uint8_t { INT8 = 0, UINT8, INT16, UINT16, INT32, UINT32, INT64, UINT64, FLOAT, DOUBLE, BOOL, CHAR, WCHAR, NSIDPTR, PSTRING, PWSTRING, INTERFACE_IS_TYPE }; // Helper methods for fabricating nsXPTType values used by xpconnect. static nsXPTType MkArrayType(Idx aInner) { MOZ_ASSERT(aInner <= Idx::INTERFACE_IS_TYPE); return {TD_LEGACY_ARRAY, false, false, false, 0, (uint8_t)aInner}; } static const nsXPTType& Get(Idx aInner) { MOZ_ASSERT(aInner <= Idx::INTERFACE_IS_TYPE); return xpt::detail::GetType((uint8_t)aInner); } /////////////////////////////////////// // nsXPTType backwards compatibility // /////////////////////////////////////// nsXPTType& operator=(nsXPTTypeTag aPrefix) { mTag = aPrefix; return *this; } operator nsXPTTypeTag() const { return Tag(); } #define TD_ALIAS_(name_, value_) static constexpr nsXPTTypeTag name_ = value_ TD_ALIAS_(T_I8, TD_INT8); TD_ALIAS_(T_I16, TD_INT16); TD_ALIAS_(T_I32, TD_INT32); TD_ALIAS_(T_I64, TD_INT64); TD_ALIAS_(T_U8, TD_UINT8); TD_ALIAS_(T_U16, TD_UINT16); TD_ALIAS_(T_U32, TD_UINT32); TD_ALIAS_(T_U64, TD_UINT64); TD_ALIAS_(T_FLOAT, TD_FLOAT); TD_ALIAS_(T_DOUBLE, TD_DOUBLE); TD_ALIAS_(T_BOOL, TD_BOOL); TD_ALIAS_(T_CHAR, TD_CHAR); TD_ALIAS_(T_WCHAR, TD_WCHAR); TD_ALIAS_(T_VOID, TD_VOID); TD_ALIAS_(T_NSIDPTR, TD_NSIDPTR); TD_ALIAS_(T_CHAR_STR, TD_PSTRING); TD_ALIAS_(T_WCHAR_STR, TD_PWSTRING); TD_ALIAS_(T_INTERFACE, TD_INTERFACE_TYPE); TD_ALIAS_(T_INTERFACE_IS, TD_INTERFACE_IS_TYPE); TD_ALIAS_(T_LEGACY_ARRAY, TD_LEGACY_ARRAY); TD_ALIAS_(T_PSTRING_SIZE_IS, TD_PSTRING_SIZE_IS); TD_ALIAS_(T_PWSTRING_SIZE_IS, TD_PWSTRING_SIZE_IS); TD_ALIAS_(T_UTF8STRING, TD_UTF8STRING); TD_ALIAS_(T_CSTRING, TD_CSTRING); TD_ALIAS_(T_ASTRING, TD_ASTRING); TD_ALIAS_(T_NSID, TD_NSID); TD_ALIAS_(T_JSVAL, TD_JSVAL); TD_ALIAS_(T_DOMOBJECT, TD_DOMOBJECT); TD_ALIAS_(T_PROMISE, TD_PROMISE); TD_ALIAS_(T_ARRAY, TD_ARRAY); #undef TD_ALIAS_ //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// uint8_t mTag : 5; // Parameter bitflags are packed into the XPTTypeDescriptor to save space. // When the TypeDescriptor is not in a parameter, these flags are ignored. uint8_t mInParam : 1; uint8_t mOutParam : 1; uint8_t mOptionalParam : 1; // The data for the different variants is stored in these two data fields. // These should only be accessed via the getter methods above, which will // assert if the tag is invalid. uint8_t mData1; uint8_t mData2; }; // The fields in nsXPTType were carefully ordered to minimize size. static_assert(sizeof(nsXPTType) == 3, "wrong size"); /* * A nsXPTParamInfo is used to describe either a single argument to a method or * a method's result. It stores its flags in the type descriptor to save space. */ struct nsXPTParamInfo { bool IsIn() const { return mType.mInParam; } bool IsOut() const { return mType.mOutParam; } bool IsOptional() const { return mType.mOptionalParam; } bool IsShared() const { return false; } // XXX remove (backcompat) // Get the type of this parameter. const nsXPTType& Type() const { return mType; } const nsXPTType& GetType() const { return Type(); } // XXX remove (backcompat) // Whether this parameter is passed indirectly on the stack. All out/inout // params are passed indirectly, and complex types are always passed // indirectly. bool IsIndirect() const { return IsOut() || Type().IsComplex(); } //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// nsXPTType mType; }; // The fields in nsXPTParamInfo were carefully ordered to minimize size. static_assert(sizeof(nsXPTParamInfo) == 3, "wrong size"); /* * A nsXPTMethodInfo is used to describe a single interface method. */ struct nsXPTMethodInfo { bool IsGetter() const { return mGetter; } bool IsSetter() const { return mSetter; } bool IsReflectable() const { return mReflectable; } bool IsSymbol() const { return mIsSymbol; } bool WantsOptArgc() const { return mOptArgc; } bool WantsContext() const { return mContext; } uint8_t ParamCount() const { return mNumParams; } const char* Name() const { MOZ_ASSERT(!IsSymbol()); return xpt::detail::GetString(mName); } const nsXPTParamInfo& Param(uint8_t aIndex) const { MOZ_ASSERT(aIndex < mNumParams); return xpt::detail::GetParam(mParams + aIndex); } bool HasRetval() const { return mHasRetval; } const nsXPTParamInfo* GetRetval() const { return mHasRetval ? &Param(mNumParams - 1) : nullptr; } // If this is an [implicit_jscontext] method, returns the index of the // implicit JSContext* argument in the C++ method's argument list. // Otherwise returns UINT8_MAX. uint8_t IndexOfJSContext() const { if (!WantsContext()) { return UINT8_MAX; } if (IsGetter() || IsSetter()) { // Getters/setters always have the context as first argument. return 0; } // The context comes before the return value, if there is one. MOZ_ASSERT_IF(HasRetval(), ParamCount() > 0); return ParamCount() - uint8_t(HasRetval()); } JS::SymbolCode GetSymbolCode() const { MOZ_ASSERT(IsSymbol()); return JS::SymbolCode(mName); } JS::Symbol* GetSymbol(JSContext* aCx) const { return JS::GetWellKnownSymbol(aCx, GetSymbolCode()); } const char* SymbolDescription() const; const char* NameOrDescription() const { if (IsSymbol()) { return SymbolDescription(); } return Name(); } bool GetId(JSContext* aCx, jsid& aId) const; //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// uint32_t mName; // Index into xpt::detail::sStrings. uint16_t mParams; // Index into xpt::detail::sParams. uint8_t mNumParams; uint8_t mGetter : 1; uint8_t mSetter : 1; uint8_t mReflectable : 1; uint8_t mOptArgc : 1; uint8_t mContext : 1; uint8_t mHasRetval : 1; uint8_t mIsSymbol : 1; }; // The fields in nsXPTMethodInfo were carefully ordered to minimize size. static_assert(sizeof(nsXPTMethodInfo) == 8, "wrong size"); // This number is chosen to be no larger than the maximum number of parameters // any XPIDL-defined function needs; there is a static assert in the generated // code from xptcodegen.py to verify that decision. It is therefore also the // maximum number of stack allocated nsXPTCMiniVariant structures for argument // passing purposes in PrepareAndDispatch implementations. #if defined(MOZ_THUNDERBIRD) || defined(MOZ_SUITE) # define PARAM_BUFFER_COUNT 18 #else # define PARAM_BUFFER_COUNT 14 #endif /** * A nsXPTConstantInfo is used to describe a single interface constant. */ struct nsXPTConstantInfo { const char* Name() const { return xpt::detail::GetString(mName); } JS::Value JSValue() const { if (mSigned || mValue <= uint32_t(INT32_MAX)) { return JS::Int32Value(int32_t(mValue)); } return JS::DoubleValue(mValue); } //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// uint32_t mName : 31; // Index into xpt::detail::mStrings. // Whether the value should be interpreted as a int32_t or uint32_t. uint32_t mSigned : 1; uint32_t mValue; // The value stored as a u32 }; // The fields in nsXPTConstantInfo were carefully ordered to minimize size. static_assert(sizeof(nsXPTConstantInfo) == 8, "wrong size"); /** * Object representing the information required to wrap and unwrap DOMObjects. * * This object will not live in rodata as it contains relocations. */ struct nsXPTDOMObjectInfo { nsresult Unwrap(JS::Handle<JS::Value> aHandle, void** aObj, JSContext* aCx) const { return mUnwrap(aHandle, aObj, aCx); } bool Wrap(JSContext* aCx, void* aObj, JS::MutableHandle<JS::Value> aHandle) const { return mWrap(aCx, aObj, aHandle); } void Cleanup(void* aObj) const { return mCleanup(aObj); } //////////////////////////////////////////////////////////////// // Ensure these fields are in the same order as xptcodegen.py // //////////////////////////////////////////////////////////////// nsresult (*mUnwrap)(JS::Handle<JS::Value> aHandle, void** aObj, JSContext* aCx); bool (*mWrap)(JSContext* aCx, void* aObj, JS::MutableHandle<JS::Value> aHandle); void (*mCleanup)(void* aObj); }; namespace xpt { namespace detail { // The UntypedTArray type allows low-level access from XPConnect to nsTArray // internals without static knowledge of the array element type in question. class UntypedTArray : public nsTArray_base<nsTArrayFallibleAllocator, nsTArray_RelocateUsingMemutils> { public: void* Elements() const { return static_cast<void*>(Hdr() + 1); } // Changes the length and capacity to be at least large enough for aTo // elements. bool SetLength(const nsXPTType& aEltTy, uint32_t aTo) { if (!EnsureCapacity<nsTArrayFallibleAllocator>(aTo, aEltTy.Stride())) { return false; } if (mHdr != EmptyHdr()) { mHdr->mLength = aTo; } return true; } // Free backing memory for the nsTArray object. void Clear() { if (mHdr != EmptyHdr() && !UsesAutoArrayBuffer()) { nsTArrayFallibleAllocator::Free(mHdr); } mHdr = EmptyHdr(); } }; ////////////////////////////////////////////// // Raw typelib data stored in const statics // ////////////////////////////////////////////// // XPIDL information extern const nsXPTInterfaceInfo sInterfaces[]; extern const nsXPTType sTypes[]; extern const nsXPTParamInfo sParams[]; extern const nsXPTMethodInfo sMethods[]; extern const nsXPTConstantInfo sConsts[]; extern const nsXPTDOMObjectInfo sDOMObjects[]; extern const char sStrings[]; ////////////////////////////////////// // Helper Methods for fetching data // ////////////////////////////////////// inline const nsXPTInterfaceInfo* GetInterface(uint16_t aIndex) { if (aIndex > 0 && aIndex <= sInterfacesSize) { return &sInterfaces[aIndex - 1]; // 1-based as 0 is a marker. } return nullptr; } inline const nsXPTType& GetType(uint16_t aIndex) { return sTypes[aIndex]; } inline const nsXPTParamInfo& GetParam(uint16_t aIndex) { return sParams[aIndex]; } inline const nsXPTMethodInfo& GetMethod(uint16_t aIndex) { return sMethods[aIndex]; } inline const nsXPTConstantInfo& GetConstant(uint16_t aIndex) { return sConsts[aIndex]; } inline const nsXPTDOMObjectInfo& GetDOMObjectInfo(uint16_t aIndex) { return sDOMObjects[aIndex]; } inline const char* GetString(uint32_t aIndex) { return &sStrings[aIndex]; } } // namespace detail } // namespace xpt #define XPT_FOR_EACH_ARITHMETIC_TYPE(MACRO) \ MACRO(TD_INT8, int8_t) \ MACRO(TD_INT16, int16_t) \ MACRO(TD_INT32, int32_t) \ MACRO(TD_INT64, int64_t) \ MACRO(TD_UINT8, uint8_t) \ MACRO(TD_UINT16, uint16_t) \ MACRO(TD_UINT32, uint32_t) \ MACRO(TD_UINT64, uint64_t) \ MACRO(TD_FLOAT, float) \ MACRO(TD_DOUBLE, double) \ MACRO(TD_BOOL, bool) \ MACRO(TD_CHAR, char) \ MACRO(TD_WCHAR, char16_t) #define XPT_FOR_EACH_POINTER_TYPE(MACRO) \ MACRO(TD_VOID, void*) \ MACRO(TD_NSIDPTR, nsID*) \ MACRO(TD_PSTRING, char*) \ MACRO(TD_PWSTRING, wchar_t*) \ MACRO(TD_INTERFACE_TYPE, nsISupports*) \ MACRO(TD_INTERFACE_IS_TYPE, nsISupports*) \ MACRO(TD_LEGACY_ARRAY, void*) \ MACRO(TD_PSTRING_SIZE_IS, char*) \ MACRO(TD_PWSTRING_SIZE_IS, wchar_t*) \ MACRO(TD_DOMOBJECT, void*) \ MACRO(TD_PROMISE, mozilla::dom::Promise*) #define XPT_FOR_EACH_COMPLEX_TYPE(MACRO) \ MACRO(TD_UTF8STRING, nsCString) \ MACRO(TD_CSTRING, nsCString) \ MACRO(TD_ASTRING, nsString) \ MACRO(TD_NSID, nsID) \ MACRO(TD_JSVAL, JS::Value) \ MACRO(TD_ARRAY, xpt::detail::UntypedTArray) #define XPT_FOR_EACH_TYPE(MACRO) \ XPT_FOR_EACH_ARITHMETIC_TYPE(MACRO) \ XPT_FOR_EACH_POINTER_TYPE(MACRO) \ XPT_FOR_EACH_COMPLEX_TYPE(MACRO) inline size_t nsXPTType::Stride() const { // Compute the stride to use when walking an array of the given type. switch (Tag()) { #define XPT_TYPE_STRIDE(tag, type) \ case tag: \ return sizeof(type); XPT_FOR_EACH_TYPE(XPT_TYPE_STRIDE) #undef XPT_TYPE_STRIDE } MOZ_CRASH("Unknown type"); } #endif /* xptinfo_h */
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2026-04-04