/* * Copyright (C) 2007 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <windows.h> #include <winerror.h> #include <errno.h> #include <usb100.h> #include <adb_api.h> #include <stdio.h> #include "sysdeps.h" #define TRACE_TAG TRACE_USB #include "adb.h" /** Structure usb_handle describes our connection to the usb device via AdbWinApi.dll. This structure is returned from usb_open() routine and is expected in each subsequent call that is accessing the device. */ struct usb_handle { /// Previous entry in the list of opened usb handles usb_handle *prev; /// Next entry in the list of opened usb handles usb_handle *next; /// Handle to USB interface ADBAPIHANDLE adb_interface; /// Handle to USB read pipe (endpoint) ADBAPIHANDLE adb_read_pipe; /// Handle to USB write pipe (endpoint) ADBAPIHANDLE adb_write_pipe; /// Interface name char* interface_name; /// Mask for determining when to use zero length packets unsigned zero_mask; }; /// Class ID assigned to the device by androidusb.sys static const GUID usb_class_id = ANDROID_USB_CLASS_ID; /// List of opened usb handles static usb_handle handle_list = { .prev = &handle_list, .next = &handle_list, }; /// Locker for the list of opened usb handles ADB_MUTEX_DEFINE( usb_lock ); /// Checks if there is opened usb handle in handle_list for this device. int known_device(const char* dev_name); /// Checks if there is opened usb handle in handle_list for this device. /// usb_lock mutex must be held before calling this routine. int known_device_locked(const char* dev_name); /// Registers opened usb handle (adds it to handle_list). int register_new_device(usb_handle* handle); /// Checks if interface (device) matches certain criteria int recognized_device(usb_handle* handle); /// Enumerates present and available interfaces (devices), opens new ones and /// registers usb transport for them. void find_devices(); /// Entry point for thread that polls (every second) for new usb interfaces. /// This routine calls find_devices in infinite loop. void* device_poll_thread(void* unused); /// Initializes this module void usb_init(); /// Cleans up this module void usb_cleanup(); /// Opens usb interface (device) by interface (device) name. usb_handle* do_usb_open(const wchar_t* interface_name); /// Writes data to the opened usb handle int usb_write(usb_handle* handle, const void* data, int len); /// Reads data using the opened usb handle int usb_read(usb_handle *handle, void* data, int len); /// Cleans up opened usb handle void usb_cleanup_handle(usb_handle* handle); /// Cleans up (but don't close) opened usb handle void usb_kick(usb_handle* handle); /// Closes opened usb handle int usb_close(usb_handle* handle); /// Gets interface (device) name for an opened usb handle const char *usb_name(usb_handle* handle); int known_device_locked(const char* dev_name) { usb_handle* usb; if (NULL != dev_name) { // Iterate through the list looking for the name match. for(usb = handle_list.next; usb != &handle_list; usb = usb->next) { // In Windows names are not case sensetive! if((NULL != usb->interface_name) && (0 == stricmp(usb->interface_name, dev_name))) { return 1; } } } return 0; } int known_device(const char* dev_name) { int ret = 0; if (NULL != dev_name) { adb_mutex_lock(&usb_lock); ret = known_device_locked(dev_name); adb_mutex_unlock(&usb_lock); } return ret; } int register_new_device(usb_handle* handle) { if (NULL == handle) return 0; adb_mutex_lock(&usb_lock); // Check if device is already in the list if (known_device_locked(handle->interface_name)) { adb_mutex_unlock(&usb_lock); return 0; } // Not in the list. Add this handle to the list. handle->next = &handle_list; handle->prev = handle_list.prev; handle->prev->next = handle; handle->next->prev = handle; adb_mutex_unlock(&usb_lock); return 1; } void* device_poll_thread(void* unused) { D("Created device thread\n"); while(1) { find_devices(); adb_sleep_ms(1000); } return NULL; } void usb_init() { adb_thread_t tid; if(adb_thread_create(&tid, device_poll_thread, NULL)) { fatal_errno("cannot create input thread"); } } void usb_cleanup() { } usb_handle* do_usb_open(const wchar_t* interface_name) { // Allocate our handle usb_handle* ret = (usb_handle*)malloc(sizeof(usb_handle)); if (NULL == ret) return NULL; // Set linkers back to the handle ret->next = ret; ret->prev = ret; // Create interface. ret->adb_interface = AdbCreateInterfaceByName(interface_name); if (NULL == ret->adb_interface) { free(ret); errno = GetLastError(); return NULL; } // Open read pipe (endpoint) ret->adb_read_pipe = AdbOpenDefaultBulkReadEndpoint(ret->adb_interface, AdbOpenAccessTypeReadWrite, AdbOpenSharingModeReadWrite); if (NULL != ret->adb_read_pipe) { // Open write pipe (endpoint) ret->adb_write_pipe = AdbOpenDefaultBulkWriteEndpoint(ret->adb_interface, AdbOpenAccessTypeReadWrite, AdbOpenSharingModeReadWrite); if (NULL != ret->adb_write_pipe) { // Save interface name unsigned long name_len = 0; // First get expected name length AdbGetInterfaceName(ret->adb_interface, NULL, &name_len, true); if (0 != name_len) { ret->interface_name = (char*)malloc(name_len); if (NULL != ret->interface_name) { // Now save the name if (AdbGetInterfaceName(ret->adb_interface, ret->interface_name, &name_len, true)) { // We're done at this point return ret; } } else { SetLastError(ERROR_OUTOFMEMORY); } } } } // Something went wrong. int saved_errno = GetLastError(); usb_cleanup_handle(ret); free(ret); SetLastError(saved_errno); return NULL; } int usb_write(usb_handle* handle, const void* data, int len) { unsigned long time_out = 500 + len * 8; unsigned long written = 0; int ret; D("usb_write %d\n", len); if (NULL != handle) { // Perform write ret = AdbWriteEndpointSync(handle->adb_write_pipe, (void*)data, (unsigned long)len, &written, time_out); int saved_errno = GetLastError(); if (ret) { // Make sure that we've written what we were asked to write D("usb_write got: %ld, expected: %d\n", written, len); if (written == (unsigned long)len) { if(handle->zero_mask && (len & handle->zero_mask) == 0) { // Send a zero length packet AdbWriteEndpointSync(handle->adb_write_pipe, (void*)data, 0, &written, time_out); } return 0; } } else { // assume ERROR_INVALID_HANDLE indicates we are disconnected if (saved_errno == ERROR_INVALID_HANDLE) usb_kick(handle); } errno = saved_errno; } else { D("usb_write NULL handle\n"); SetLastError(ERROR_INVALID_HANDLE); } D("usb_write failed: %d\n", errno); return -1; } int usb_read(usb_handle *handle, void* data, int len) { unsigned long time_out = 500 + len * 8; unsigned long read = 0; int ret; D("usb_read %d\n", len); if (NULL != handle) { while (len > 0) { int xfer = (len > 4096) ? 4096 : len; ret = AdbReadEndpointSync(handle->adb_read_pipe, (void*)data, (unsigned long)xfer, &read, time_out); int saved_errno = GetLastError(); D("usb_write got: %ld, expected: %d, errno: %d\n", read, xfer, saved_errno); if (ret) { data += read; len -= read; if (len == 0) return 0; } else if (saved_errno != ERROR_SEM_TIMEOUT) { // assume ERROR_INVALID_HANDLE indicates we are disconnected if (saved_errno == ERROR_INVALID_HANDLE) usb_kick(handle); break; } errno = saved_errno; } } else { D("usb_read NULL handle\n"); SetLastError(ERROR_INVALID_HANDLE); } D("usb_read failed: %d\n", errno); return -1; } void usb_cleanup_handle(usb_handle* handle) { if (NULL != handle) { if (NULL != handle->interface_name) free(handle->interface_name); if (NULL != handle->adb_write_pipe) AdbCloseHandle(handle->adb_write_pipe); if (NULL != handle->adb_read_pipe) AdbCloseHandle(handle->adb_read_pipe); if (NULL != handle->adb_interface) AdbCloseHandle(handle->adb_interface); handle->interface_name = NULL; handle->adb_write_pipe = NULL; handle->adb_read_pipe = NULL; handle->adb_interface = NULL; } } void usb_kick(usb_handle* handle) { if (NULL != handle) { adb_mutex_lock(&usb_lock); usb_cleanup_handle(handle); adb_mutex_unlock(&usb_lock); } else { SetLastError(ERROR_INVALID_HANDLE); errno = ERROR_INVALID_HANDLE; } } int usb_close(usb_handle* handle) { D("usb_close\n"); if (NULL != handle) { // Remove handle from the list adb_mutex_lock(&usb_lock); if ((handle->next != handle) && (handle->prev != handle)) { handle->next->prev = handle->prev; handle->prev->next = handle->next; handle->prev = handle; handle->next = handle; } adb_mutex_unlock(&usb_lock); // Cleanup handle usb_cleanup_handle(handle); free(handle); } return 0; } const char *usb_name(usb_handle* handle) { if (NULL == handle) { SetLastError(ERROR_INVALID_HANDLE); errno = ERROR_INVALID_HANDLE; return NULL; } return (const char*)handle->interface_name; } int recognized_device(usb_handle* handle) { if (NULL == handle) return 0; // Check vendor and product id first USB_DEVICE_DESCRIPTOR device_desc; if (!AdbGetUsbDeviceDescriptor(handle->adb_interface, &device_desc)) { return 0; } // Then check interface properties USB_INTERFACE_DESCRIPTOR interf_desc; if (!AdbGetUsbInterfaceDescriptor(handle->adb_interface, &interf_desc)) { return 0; } // Must have two endpoints if (2 != interf_desc.bNumEndpoints) { return 0; } if (is_adb_interface(device_desc.idVendor, device_desc.idProduct, interf_desc.bInterfaceClass, interf_desc.bInterfaceSubClass, interf_desc.bInterfaceProtocol)) { if(interf_desc.bInterfaceProtocol == 0x01) { AdbEndpointInformation endpoint_info; // assuming zero is a valid bulk endpoint ID if (AdbGetEndpointInformation(handle->adb_interface, 0, &endpoint_info)) { handle->zero_mask = endpoint_info.max_packet_size - 1; } } return 1; } return 0; } void find_devices() { usb_handle* handle = NULL; char entry_buffer[2048]; char interf_name[2048]; AdbInterfaceInfo* next_interface = (AdbInterfaceInfo*)(&entry_buffer[0]); unsigned long entry_buffer_size = sizeof(entry_buffer); char* copy_name; // Enumerate all present and active interfaces. ADBAPIHANDLE enum_handle = AdbEnumInterfaces(usb_class_id, true, true, true); if (NULL == enum_handle) return; while (AdbNextInterface(enum_handle, next_interface, &entry_buffer_size)) { // TODO: FIXME - temp hack converting wchar_t into char. // It would be better to change AdbNextInterface so it will return // interface name as single char string. const wchar_t* wchar_name = next_interface->device_name; for(copy_name = interf_name; L'\0' != *wchar_name; wchar_name++, copy_name++) { *copy_name = (char)(*wchar_name); } *copy_name = '\0'; // Lets see if we already have this device in the list if (!known_device(interf_name)) { // This seems to be a new device. Open it! handle = do_usb_open(next_interface->device_name); if (NULL != handle) { // Lets see if this interface (device) belongs to us if (recognized_device(handle)) { D("adding a new device %s\n", interf_name); char serial_number[512]; unsigned long serial_number_len = sizeof(serial_number); if (AdbGetSerialNumber(handle->adb_interface, serial_number, &serial_number_len, true)) { // Lets make sure that we don't duplicate this device if (register_new_device(handle)) { register_usb_transport(handle, serial_number, 1); } else { D("register_new_device failed for %s\n", interf_name); usb_cleanup_handle(handle); free(handle); } } else { D("cannot get serial number\n"); usb_cleanup_handle(handle); free(handle); } } else { usb_cleanup_handle(handle); free(handle); } } } entry_buffer_size = sizeof(entry_buffer); } AdbCloseHandle(enum_handle); }