// Copyright 2016 Citra Emulator Project // Licensed under GPLv2 or any later version // Refer to the license.txt file included. #pragma once #include #include #include #include #include "core/hle/ipc.h" #include "core/hle/kernel/handle_table.h" #include "core/hle/kernel/hle_ipc.h" #include "core/hle/kernel/kernel.h" namespace IPC { class RequestHelperBase { protected: Kernel::HLERequestContext* context = nullptr; u32* cmdbuf; ptrdiff_t index = 1; Header header; public: RequestHelperBase(Kernel::HLERequestContext& context, Header desired_header) : context(&context), cmdbuf(context.CommandBuffer()), header(desired_header) {} RequestHelperBase(u32* command_buffer, Header command_header) : cmdbuf(command_buffer), header(command_header) {} /// Returns the total size of the request in words size_t TotalSize() const { return 1 /* command header */ + header.normal_params_size + header.translate_params_size; } void ValidateHeader() { DEBUG_ASSERT_MSG(index == TotalSize(), "Operations do not match the header (cmd 0x%x)", header.raw); } void Skip(unsigned size_in_words, bool set_to_null) { if (set_to_null) memset(cmdbuf + index, 0, size_in_words * sizeof(u32)); index += size_in_words; } /** * @brief Retrieves the address of a static buffer, used when a buffer is needed for output * @param buffer_id The index of the static buffer * @param data_size If non-null, will store the size of the buffer */ VAddr PeekStaticBuffer(u8 buffer_id, size_t* data_size = nullptr) const { u32* static_buffer = cmdbuf + Kernel::kStaticBuffersOffset / sizeof(u32) + buffer_id * 2; if (data_size) *data_size = StaticBufferDescInfo{static_buffer[0]}.size; return static_buffer[1]; } }; class RequestBuilder : public RequestHelperBase { public: RequestBuilder(Kernel::HLERequestContext& context, Header command_header) : RequestHelperBase(context, command_header) { // From this point we will start overwriting the existing command buffer, so it's safe to // release all previous incoming Object pointers since they won't be usable anymore. context.ClearIncomingObjects(); cmdbuf[0] = header.raw; } RequestBuilder(Kernel::HLERequestContext& context, u16 command_id, unsigned normal_params_size, unsigned translate_params_size) : RequestBuilder( context, Header{MakeHeader(command_id, normal_params_size, translate_params_size)}) {} RequestBuilder(u32* command_buffer, Header command_header) : RequestHelperBase(command_buffer, command_header) { cmdbuf[0] = header.raw; } explicit RequestBuilder(u32* command_buffer, u32 command_header) : RequestBuilder(command_buffer, Header{command_header}) {} RequestBuilder(u32* command_buffer, u16 command_id, unsigned normal_params_size, unsigned translate_params_size) : RequestBuilder(command_buffer, MakeHeader(command_id, normal_params_size, translate_params_size)) {} // Validate on destruction, as there shouldn't be any case where we don't want it ~RequestBuilder() { ValidateHeader(); } template void Push(T value); template void Push(const First& first_value, const Other&... other_values); /** * @brief Copies the content of the given trivially copyable class to the buffer as a normal * param * @note: The input class must be correctly packed/padded to fit hardware layout. */ template void PushRaw(const T& value); // TODO : ensure that translate params are added after all regular params template void PushCopyHandles(H... handles); template void PushMoveHandles(H... handles); template void PushObjects(Kernel::SharedPtr... pointers); void PushCurrentPIDHandle(); void PushStaticBuffer(VAddr buffer_vaddr, u32 size, u8 buffer_id); void PushMappedBuffer(VAddr buffer_vaddr, u32 size, MappedBufferPermissions perms); }; /// Push /// template <> inline void RequestBuilder::Push(u32 value) { cmdbuf[index++] = value; } template void RequestBuilder::PushRaw(const T& value) { static_assert(std::is_trivially_copyable(), "Raw types should be trivially copyable"); std::memcpy(cmdbuf + index, &value, sizeof(T)); index += (sizeof(T) + 3) / 4; // round up to word length } template <> inline void RequestBuilder::Push(u8 value) { PushRaw(value); } template <> inline void RequestBuilder::Push(u16 value) { PushRaw(value); } template <> inline void RequestBuilder::Push(u64 value) { Push(static_cast(value)); Push(static_cast(value >> 32)); } template <> inline void RequestBuilder::Push(bool value) { Push(static_cast(value)); } template <> inline void RequestBuilder::Push(ResultCode value) { Push(value.raw); } template void RequestBuilder::Push(const First& first_value, const Other&... other_values) { Push(first_value); Push(other_values...); } template inline void RequestBuilder::PushCopyHandles(H... handles) { Push(CopyHandleDesc(sizeof...(H))); Push(static_cast(handles)...); } template inline void RequestBuilder::PushMoveHandles(H... handles) { Push(MoveHandleDesc(sizeof...(H))); Push(static_cast(handles)...); } template inline void RequestBuilder::PushObjects(Kernel::SharedPtr... pointers) { PushMoveHandles(context->AddOutgoingHandle(std::move(pointers))...); } inline void RequestBuilder::PushCurrentPIDHandle() { Push(CallingPidDesc()); Push(u32(0)); } inline void RequestBuilder::PushStaticBuffer(VAddr buffer_vaddr, u32 size, u8 buffer_id) { Push(StaticBufferDesc(size, buffer_id)); Push(buffer_vaddr); } inline void RequestBuilder::PushMappedBuffer(VAddr buffer_vaddr, u32 size, MappedBufferPermissions perms) { Push(MappedBufferDesc(size, perms)); Push(buffer_vaddr); } class RequestParser : public RequestHelperBase { public: RequestParser(Kernel::HLERequestContext& context, Header desired_header) : RequestHelperBase(context, desired_header) {} RequestParser(Kernel::HLERequestContext& context, u16 command_id, unsigned normal_params_size, unsigned translate_params_size) : RequestParser(context, Header{MakeHeader(command_id, normal_params_size, translate_params_size)}) { } RequestParser(u32* command_buffer, Header command_header) : RequestHelperBase(command_buffer, command_header) {} explicit RequestParser(u32* command_buffer, u32 command_header) : RequestParser(command_buffer, Header{command_header}) {} RequestParser(u32* command_buffer, u16 command_id, unsigned normal_params_size, unsigned translate_params_size) : RequestParser(command_buffer, MakeHeader(command_id, normal_params_size, translate_params_size)) {} RequestBuilder MakeBuilder(u32 normal_params_size, u32 translate_params_size, bool validateHeader = true) { if (validateHeader) ValidateHeader(); Header builderHeader{ MakeHeader(header.command_id, normal_params_size, translate_params_size)}; if (context != nullptr) return {*context, builderHeader}; else return {cmdbuf, builderHeader}; } template T Pop(); template void Pop(T& value); template void Pop(First& first_value, Other&... other_values); /// Equivalent to calling `PopHandles<1>()[0]`. Kernel::Handle PopHandle(); /** * Pops a descriptor containing `N` handles. The handles are returned as an array. The * descriptor must contain exactly `N` handles, it is not permitted to, for example, call * PopHandles<1>() twice to read a multi-handle descriptor with 2 handles, or to make a single * PopHandles<2>() call to read 2 single-handle descriptors. */ template std::array PopHandles(); /// Convenience wrapper around PopHandles() which assigns the handles to the passed references. template void PopHandles(H&... handles) { std::tie(handles...) = PopHandles(); } /// Equivalent to calling `PopGenericObjects<1>()[0]`. Kernel::SharedPtr PopGenericObject(); /// Equivalent to calling `std::get<0>(PopObjects())`. template Kernel::SharedPtr PopObject(); /** * Pop a descriptor containing `N` handles and resolves them to Kernel::Object pointers. If a * handle is invalid, null is returned for that object instead. The same caveats from * PopHandles() apply regarding `N` matching the number of handles in the descriptor. */ template std::array, N> PopGenericObjects(); /** * Resolves handles to Kernel::Objects as in PopGenericsObjects(), but then also casts them to * the passed `T` types, while verifying that the cast is valid. If the type of an object does * not match, null is returned instead. */ template std::tuple...> PopObjects(); /// Convenience wrapper around PopObjects() which assigns the handles to the passed references. template void PopObjects(Kernel::SharedPtr&... pointers) { std::tie(pointers...) = PopObjects(); } /** * @brief Pops the static buffer vaddr * @return The virtual address of the buffer * @param[out] data_size If non-null, the pointed value will be set to the size of the data * @param[out] useStaticBuffersToGetVaddr Indicates if we should read the vaddr from the static * buffers (which is the correct thing to do, but no service presently implement it) instead of * using the same value as the process who sent the request * given by the source process * * Static buffers must be set up before any IPC request using those is sent. * It is the duty of the process (usually services) to allocate and set up the receiving static * buffer information * Please note that the setup uses virtual addresses. */ VAddr PopStaticBuffer(size_t* data_size = nullptr, bool useStaticBuffersToGetVaddr = false); /** * @brief Pops the mapped buffer vaddr * @return The virtual address of the buffer * @param[out] data_size If non-null, the pointed value will be set to the size of the data * given by the source process * @param[out] buffer_perms If non-null, the pointed value will be set to the permissions of the * buffer */ VAddr PopMappedBuffer(size_t* data_size = nullptr, MappedBufferPermissions* buffer_perms = nullptr); /** * @brief Reads the next normal parameters as a struct, by copying it * @note: The output class must be correctly packed/padded to fit hardware layout. */ template void PopRaw(T& value); /** * @brief Reads the next normal parameters as a struct, by copying it into a new value * @note: The output class must be correctly packed/padded to fit hardware layout. */ template T PopRaw(); }; /// Pop /// template <> inline u32 RequestParser::Pop() { return cmdbuf[index++]; } template void RequestParser::PopRaw(T& value) { static_assert(std::is_trivially_copyable(), "Raw types should be trivially copyable"); std::memcpy(&value, cmdbuf + index, sizeof(T)); index += (sizeof(T) + 3) / 4; // round up to word length } template T RequestParser::PopRaw() { T value; PopRaw(value); return value; } template <> inline u8 RequestParser::Pop() { return PopRaw(); } template <> inline u16 RequestParser::Pop() { return PopRaw(); } template <> inline u64 RequestParser::Pop() { const u64 lsw = Pop(); const u64 msw = Pop(); return msw << 32 | lsw; } template <> inline bool RequestParser::Pop() { return Pop() != 0; } template <> inline ResultCode RequestParser::Pop() { return ResultCode{Pop()}; } template void RequestParser::Pop(T& value) { value = Pop(); } template void RequestParser::Pop(First& first_value, Other&... other_values) { first_value = Pop(); Pop(other_values...); } inline Kernel::Handle RequestParser::PopHandle() { const u32 handle_descriptor = Pop(); DEBUG_ASSERT_MSG(IsHandleDescriptor(handle_descriptor), "Tried to pop handle(s) but the descriptor is not a handle descriptor"); DEBUG_ASSERT_MSG(HandleNumberFromDesc(handle_descriptor) == 1, "Descriptor indicates that there isn't exactly one handle"); return Pop(); } template std::array RequestParser::PopHandles() { u32 handle_descriptor = Pop(); ASSERT_MSG(IsHandleDescriptor(handle_descriptor), "Tried to pop handle(s) but the descriptor is not a handle descriptor"); ASSERT_MSG(N == HandleNumberFromDesc(handle_descriptor), "Number of handles doesn't match the descriptor"); std::array handles{}; for (Kernel::Handle& handle : handles) { handle = Pop(); } return handles; } inline Kernel::SharedPtr RequestParser::PopGenericObject() { Kernel::Handle handle = PopHandle(); return context->GetIncomingHandle(handle); } template Kernel::SharedPtr RequestParser::PopObject() { return Kernel::DynamicObjectCast(PopGenericObject()); } template inline std::array, N> RequestParser::PopGenericObjects() { std::array handles = PopHandles(); std::array, N> pointers; for (int i = 0; i < N; ++i) { pointers[i] = context->GetIncomingHandle(handles[i]); } return pointers; } namespace detail { template std::tuple...> PopObjectsHelper( std::array, sizeof...(T)>&& pointers, std::index_sequence) { return std::make_tuple(Kernel::DynamicObjectCast(std::move(pointers[I]))...); } } // namespace detail template inline std::tuple...> RequestParser::PopObjects() { return detail::PopObjectsHelper(PopGenericObjects(), std::index_sequence_for{}); } inline VAddr RequestParser::PopStaticBuffer(size_t* data_size, bool useStaticBuffersToGetVaddr) { const u32 sbuffer_descriptor = Pop(); StaticBufferDescInfo bufferInfo{sbuffer_descriptor}; if (data_size != nullptr) *data_size = bufferInfo.size; if (!useStaticBuffersToGetVaddr) return Pop(); else { ASSERT_MSG(0, "remove the assert if multiprocess/IPC translation are implemented."); // The buffer has already been copied to the static buffer by the kernel during // translation Pop(); // Pop the calling process buffer address // and get the vaddr from the static buffers return cmdbuf[(0x100 >> 2) + bufferInfo.buffer_id * 2 + 1]; } } inline VAddr RequestParser::PopMappedBuffer(size_t* data_size, MappedBufferPermissions* buffer_perms) { const u32 sbuffer_descriptor = Pop(); MappedBufferDescInfo bufferInfo{sbuffer_descriptor}; if (data_size != nullptr) *data_size = bufferInfo.size; if (buffer_perms != nullptr) *buffer_perms = bufferInfo.perms; return Pop(); } } // namespace IPC