// sample drv interface #pragma clang diagnostic ignored "-Wgnu-anonymous-struct" #pragma clang diagnostic ignored "-Wmissing-prototypes" #pragma clang diagnostic ignored "-Wsign-compare" #include #include #include #include #ifdef _WIN32 # define WIN32_LEAN_AND_MEAN # ifndef NOMINMAX # define NOMINMAX # endif # include # include #else # include # include #endif #include "ggml-impl.h" #include "htp-drv.h" #include "libdl.h" #include // // Driver API types // typedef void * (*rpcmem_alloc_pfn_t)(int heapid, uint32_t flags, int size); typedef void * (*rpcmem_alloc2_pfn_t)(int heapid, uint32_t flags, size_t size); typedef void (*rpcmem_free_pfn_t)(void * po); typedef int (*rpcmem_to_fd_pfn_t)(void * po); typedef AEEResult (*dspqueue_create_pfn_t)(int domain, uint32_t flags, uint32_t req_queue_size, uint32_t resp_queue_size, dspqueue_callback_t packet_callback, dspqueue_callback_t error_callback, void * callback_context, dspqueue_t * queue); typedef AEEResult (*dspqueue_close_pfn_t)(dspqueue_t queue); typedef AEEResult (*dspqueue_export_pfn_t)(dspqueue_t queue, uint64_t *queue_id); typedef AEEResult (*dspqueue_write_pfn_t)(dspqueue_t queue, uint32_t flags, uint32_t num_buffers, struct dspqueue_buffer *buffers, uint32_t message_length, const uint8_t *message, uint32_t timeout_us); typedef AEEResult (*dspqueue_read_pfn_t)(dspqueue_t queue, uint32_t *flags, uint32_t max_buffers, uint32_t *num_buffers, struct dspqueue_buffer *buffers, uint32_t max_message_length, uint32_t *message_length, uint8_t *message, uint32_t timeout_us); typedef int (*fastrpc_mmap_pfn_t)(int domain, int fd, void *addr, int offset, size_t length, enum fastrpc_map_flags flags); typedef int (*fastrpc_munmap_pfn_t)(int domain, int fd, void *addr, size_t length); typedef int (*remote_handle64_open_pfn_t)(const char* name, remote_handle64 *ph); typedef int (*remote_handle64_invoke_pfn_t)(remote_handle64 h, uint32_t dwScalars, remote_arg *pra); typedef int (*remote_handle64_close_pfn_t)(remote_handle h); typedef int (*remote_handle_control_pfn_t)(uint32_t req, void* data, uint32_t datalen); typedef int (*remote_handle64_control_pfn_t)(remote_handle64 h, uint32_t req, void* data, uint32_t datalen); typedef int (*remote_session_control_pfn_t)(uint32_t req, void *data, uint32_t datalen); // // Driver API pfns // rpcmem_alloc_pfn_t rpcmem_alloc_pfn = nullptr; rpcmem_alloc2_pfn_t rpcmem_alloc2_pfn = nullptr; rpcmem_free_pfn_t rpcmem_free_pfn = nullptr; rpcmem_to_fd_pfn_t rpcmem_to_fd_pfn = nullptr; fastrpc_mmap_pfn_t fastrpc_mmap_pfn = nullptr; fastrpc_munmap_pfn_t fastrpc_munmap_pfn = nullptr; dspqueue_create_pfn_t dspqueue_create_pfn = nullptr; dspqueue_close_pfn_t dspqueue_close_pfn = nullptr; dspqueue_export_pfn_t dspqueue_export_pfn = nullptr; dspqueue_write_pfn_t dspqueue_write_pfn = nullptr; dspqueue_read_pfn_t dspqueue_read_pfn = nullptr; remote_handle64_open_pfn_t remote_handle64_open_pfn = nullptr; remote_handle64_invoke_pfn_t remote_handle64_invoke_pfn = nullptr; remote_handle64_close_pfn_t remote_handle64_close_pfn = nullptr; remote_handle_control_pfn_t remote_handle_control_pfn = nullptr; remote_handle64_control_pfn_t remote_handle64_control_pfn = nullptr; remote_session_control_pfn_t remote_session_control_pfn = nullptr; // // Driver API // void * rpcmem_alloc(int heapid, uint32_t flags, int size) { return rpcmem_alloc_pfn(heapid, flags, size); } void * rpcmem_alloc2(int heapid, uint32_t flags, size_t size) { if (rpcmem_alloc2_pfn) { return rpcmem_alloc2_pfn(heapid, flags, size); } else { GGML_LOG_INFO("ggml-hex: rpcmem_alloc2 not found, falling back to rpcmem_alloc\n"); return rpcmem_alloc_pfn(heapid, flags, size); } } void rpcmem_free(void * po) { return rpcmem_free_pfn(po); } int rpcmem_to_fd(void * po) { return rpcmem_to_fd_pfn(po); } HTPDRV_API int fastrpc_mmap(int domain, int fd, void * addr, int offset, size_t length, enum fastrpc_map_flags flags) { return fastrpc_mmap_pfn(domain, fd, addr, offset, length, flags); } HTPDRV_API int fastrpc_munmap(int domain, int fd, void * addr, size_t length) { return fastrpc_munmap_pfn(domain, fd, addr, length); } AEEResult dspqueue_create(int domain, uint32_t flags, uint32_t req_queue_size, uint32_t resp_queue_size, dspqueue_callback_t packet_callback, dspqueue_callback_t error_callback, void * callback_context, dspqueue_t * queue) { return dspqueue_create_pfn(domain, flags, req_queue_size, resp_queue_size, packet_callback, error_callback, callback_context, queue); } AEEResult dspqueue_close(dspqueue_t queue) { return dspqueue_close_pfn(queue); } AEEResult dspqueue_export(dspqueue_t queue, uint64_t * queue_id) { return dspqueue_export_pfn(queue, queue_id); } AEEResult dspqueue_write(dspqueue_t queue, uint32_t flags, uint32_t num_buffers, struct dspqueue_buffer * buffers, uint32_t message_length, const uint8_t * message, uint32_t timeout_us) { return dspqueue_write_pfn(queue, flags, num_buffers, buffers, message_length, message, timeout_us); } AEEResult dspqueue_read(dspqueue_t queue, uint32_t * flags, uint32_t max_buffers, uint32_t * num_buffers, struct dspqueue_buffer * buffers, uint32_t max_message_length, uint32_t * message_length, uint8_t * message, uint32_t timeout_us) { return dspqueue_read_pfn(queue, flags, max_buffers, num_buffers, buffers, max_message_length, message_length, message, timeout_us); } HTPDRV_API int remote_handle64_open(const char * name, remote_handle64 * ph) { return remote_handle64_open_pfn(name, ph); } HTPDRV_API int remote_handle64_invoke(remote_handle64 h, uint32_t dwScalars, remote_arg * pra) { return remote_handle64_invoke_pfn(h, dwScalars, pra); } HTPDRV_API int remote_handle64_close(remote_handle64 h) { return remote_handle64_close_pfn(h); } HTPDRV_API int remote_handle_control(uint32_t req, void * data, uint32_t datalen) { return remote_handle_control_pfn(req, data, datalen); } HTPDRV_API int remote_handle64_control(remote_handle64 h, uint32_t req, void * data, uint32_t datalen) { return remote_handle64_control_pfn(h, req, data, datalen); } HTPDRV_API int remote_session_control(uint32_t req, void * data, uint32_t datalen) { return remote_session_control_pfn(req, data, datalen); } #ifdef _WIN32 static std::string wstr_to_str(std::wstring_view wstr) { std::string result; if (wstr.empty()) { return result; } auto bytes_needed = WideCharToMultiByte(CP_UTF8, WC_ERR_INVALID_CHARS, wstr.data(), (int) wstr.size(), nullptr, 0, nullptr, nullptr); if (bytes_needed == 0) { GGML_LOG_ERROR("ggml-hex: WideCharToMultiByte failed. Error %lu\n", GetLastError()); throw std::runtime_error("Invalid wstring input"); } result.resize(bytes_needed, '\0'); int bytes_written = WideCharToMultiByte(CP_UTF8, WC_ERR_INVALID_CHARS, wstr.data(), (int) wstr.size(), result.data(), bytes_needed, nullptr, nullptr); if (bytes_written == 0) { GGML_LOG_ERROR("ggml-hex: WideCharToMultiByte failed. Error %lu\n", GetLastError()); throw std::runtime_error("Wstring conversion failed"); } return result; } static std::string get_driver_path() { std::wstring serviceName = L"qcnspmcdm"; std::string result; // Get a handle to the SCM database. SC_HANDLE schSCManager = OpenSCManagerW(NULL, NULL, STANDARD_RIGHTS_READ); if (nullptr == schSCManager) { GGML_LOG_ERROR("ggml-hex: Failed to open SCManager. Error: %lu\n", GetLastError()); return result; } // Get a handle to the service. SC_HANDLE schService = OpenServiceW(schSCManager, // SCM database serviceName.c_str(), // name of service SERVICE_QUERY_CONFIG); // need query config access if (nullptr == schService) { GGML_LOG_ERROR("ggml-hex: Failed to open qcnspmcdm service. Error: %lu\n", GetLastError()); CloseServiceHandle(schSCManager); return result; } // Store the size of buffer used as an output. DWORD bufferSize; if (!QueryServiceConfigW(schService, NULL, 0, &bufferSize) && (GetLastError() != ERROR_INSUFFICIENT_BUFFER)) { GGML_LOG_ERROR("ggml-hex: Failed to query service config. Error: %lu\n", GetLastError()); CloseServiceHandle(schService); CloseServiceHandle(schSCManager); return result; } // Get the configuration of the service. LPQUERY_SERVICE_CONFIGW serviceConfig = static_cast(LocalAlloc(LMEM_FIXED, bufferSize)); if (!QueryServiceConfigW(schService, serviceConfig, bufferSize, &bufferSize)) { fprintf(stderr, "ggml-hex: Failed to query service config. Error: %lu\n", GetLastError()); LocalFree(serviceConfig); CloseServiceHandle(schService); CloseServiceHandle(schSCManager); return result; } // Read the driver file path get its parent directory std::wstring driverPath = std::wstring(serviceConfig->lpBinaryPathName); driverPath = driverPath.substr(0, driverPath.find_last_of(L"\\")); // Clean up resources LocalFree(serviceConfig); CloseServiceHandle(schService); CloseServiceHandle(schSCManager); // Driver path would contain invalid path string, like: // \SystemRoot\System32\DriverStore\FileRepository\qcadsprpc8280.inf_arm64_c2b9460c9a072f37 // "\SystemRoot" should be replace with a correct one (e.g. C:\Windows) const std::wstring systemRootPlaceholder = L"\\SystemRoot"; if (0 != driverPath.compare(0, systemRootPlaceholder.length(), systemRootPlaceholder)) { GGML_LOG_ERROR("ggml-hex: String pattern not found in driver path.\n"); return result; } // Replace \SystemRoot with an absolute path from system ENV windir const std::wstring systemRootEnv = L"windir"; // Query the number of wide characters this variable requires DWORD numWords = GetEnvironmentVariableW(systemRootEnv.c_str(), NULL, 0); if (numWords == 0) { GGML_LOG_ERROR("ggml-hex: Failed get systemRoot environment variable\n"); return result; } // Query the actual system root name from environment variable std::vector systemRoot(numWords + 1); numWords = GetEnvironmentVariableW(systemRootEnv.c_str(), systemRoot.data(), numWords + 1); if (numWords == 0) { GGML_LOG_ERROR("ggml-hex: Failed to read windir environment variable\n"); return result; } driverPath.replace(0, systemRootPlaceholder.length(), std::wstring(systemRoot.data())); return wstr_to_str(driverPath); } #endif using dl_handle_ptr = std::unique_ptr; int htpdrv_init() { static dl_handle_ptr lib_cdsp_rpc_handle = nullptr; static bool initialized = false; #ifdef _WIN32 std::string drv_path = get_driver_path() + "\\" + "libcdsprpc.dll"; #else std::string drv_path = "libcdsprpc.so"; #endif if (initialized) { GGML_LOG_INFO("ggml-hex: Driver already loaded\n"); return AEE_SUCCESS; } GGML_LOG_INFO("ggml-hex: Loading driver %s\n", drv_path.c_str()); fs::path path{ drv_path.c_str() }; dl_handle_ptr handle { dl_load_library(path) }; if (!handle) { GGML_LOG_ERROR("ggml-hex: failed to load %s: %s\n", path.u8string().c_str(), dl_error()); return AEE_EUNABLETOLOAD; } #define dlsym(drv, type, pfn, symbol, ignore) \ do { \ pfn = (type) dl_get_sym(drv, #symbol); \ if (!ignore && nullptr == pfn) { \ GGML_LOG_ERROR("ggml-hex: failed to dlsym %s\n", #symbol); \ return AEE_EUNABLETOLOAD; \ } \ } while (0) dlsym(handle.get(), rpcmem_alloc_pfn_t, rpcmem_alloc_pfn, rpcmem_alloc, false); dlsym(handle.get(), rpcmem_alloc2_pfn_t, rpcmem_alloc2_pfn, rpcmem_alloc2, true); dlsym(handle.get(), rpcmem_free_pfn_t, rpcmem_free_pfn, rpcmem_free, false); dlsym(handle.get(), rpcmem_to_fd_pfn_t, rpcmem_to_fd_pfn, rpcmem_to_fd, false); dlsym(handle.get(), fastrpc_mmap_pfn_t, fastrpc_mmap_pfn, fastrpc_mmap, false); dlsym(handle.get(), fastrpc_munmap_pfn_t, fastrpc_munmap_pfn, fastrpc_munmap, false); dlsym(handle.get(), dspqueue_create_pfn_t, dspqueue_create_pfn, dspqueue_create, false); dlsym(handle.get(), dspqueue_close_pfn_t, dspqueue_close_pfn, dspqueue_close, false); dlsym(handle.get(), dspqueue_export_pfn_t, dspqueue_export_pfn, dspqueue_export, false); dlsym(handle.get(), dspqueue_write_pfn_t, dspqueue_write_pfn, dspqueue_write, false); dlsym(handle.get(), dspqueue_read_pfn_t, dspqueue_read_pfn, dspqueue_read, false); dlsym(handle.get(), remote_handle64_open_pfn_t, remote_handle64_open_pfn, remote_handle64_open, false); dlsym(handle.get(), remote_handle64_invoke_pfn_t, remote_handle64_invoke_pfn, remote_handle64_invoke, false); dlsym(handle.get(), remote_handle_control_pfn_t, remote_handle_control_pfn, remote_handle_control, false); dlsym(handle.get(), remote_handle64_control_pfn_t, remote_handle64_control_pfn, remote_handle64_control, false); dlsym(handle.get(), remote_session_control_pfn_t, remote_session_control_pfn, remote_session_control, false); dlsym(handle.get(), remote_handle64_close_pfn_t, remote_handle64_close_pfn, remote_handle64_close, false); lib_cdsp_rpc_handle = std::move(handle); initialized = true; return AEE_SUCCESS; } domain * get_domain(int domain_id) { int i = 0; int size = sizeof(supported_domains) / sizeof(domain); for (i = 0; i < size; i++) { if (supported_domains[i].id == domain_id) { return &supported_domains[i]; } } return NULL; } int get_hex_arch_ver(int domain, int * arch) { if (!remote_handle_control_pfn) { GGML_LOG_ERROR("ggml-hex: remote_handle_control is not supported on this device\n"); return AEE_EUNSUPPORTEDAPI; } struct remote_dsp_capability arch_ver; arch_ver.domain = (uint32_t) domain; arch_ver.attribute_ID = ARCH_VER; arch_ver.capability = (uint32_t) 0; int err = remote_handle_control(DSPRPC_GET_DSP_INFO, &arch_ver, sizeof(arch_ver)); if ((err & 0xff) == (AEE_EUNSUPPORTEDAPI & 0xff)) { GGML_LOG_ERROR("ggml-hex: FastRPC capability API is not supported on this device\n"); return AEE_EUNSUPPORTEDAPI; } if (err != AEE_SUCCESS) { GGML_LOG_ERROR("ggml-hex: FastRPC capability query failed (err %d)\n", err); return err; } switch (arch_ver.capability & 0xff) { case 0x68: *arch = 68; return 0; case 0x69: *arch = 69; return 0; case 0x73: *arch = 73; return 0; case 0x75: *arch = 75; return 0; case 0x79: *arch = 79; return 0; case 0x81: *arch = 81; return 0; } return -1; }