daemon/usb.cpp - SHIFTPHONES/android_packages_modules_adb - Gitiles

 /*
  * 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.
  */

 #define TRACE_TAG USB

 #include "sysdeps.h"

 #include <dirent.h>
 #include <errno.h>
 #include <linux/usb/ch9.h>
 #include <linux/usb/functionfs.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <sys/ioctl.h>
 #include <sys/types.h>
 #include <unistd.h>

 #include <algorithm>
 #include <atomic>
 #include <chrono>
 #include <condition_variable>
 #include <mutex>
 #include <thread>

 #include <android-base/logging.h>
 #include <android-base/properties.h>

 #include "adb.h"
 #include "daemon/usb.h"
 #include "transport.h"

 using namespace std::chrono_literals;

 #define MAX_PACKET_SIZE_FS 64
 #define MAX_PACKET_SIZE_HS 512
 #define MAX_PACKET_SIZE_SS 1024

 // Kernels before 3.3 have a 16KiB transfer limit  That limit was replaced
 // with a 16MiB global limit in 3.3, but each URB submitted required a
 // contiguous kernel allocation, so you would get ENOMEM if you tried to
 // send something larger than the biggest available contiguous kernel
 // memory region. Large contiguous allocations could be unreliable
 // on a device kernel that has been running for a while fragmenting its
 // memory so we start with a larger allocation, and shrink the amount if
 // necessary.
 #define USB_FFS_BULK_SIZE 16384

 #define cpu_to_le16(x) htole16(x)
 #define cpu_to_le32(x) htole32(x)

 #define FUNCTIONFS_ENDPOINT_ALLOC       _IOR('g', 231, __u32)

 static constexpr size_t ENDPOINT_ALLOC_RETRIES = 10;

 static int dummy_fd = -1;

 struct func_desc {
     struct usb_interface_descriptor intf;
     struct usb_endpoint_descriptor_no_audio source;
     struct usb_endpoint_descriptor_no_audio sink;
 } __attribute__((packed));

 struct ss_func_desc {
     struct usb_interface_descriptor intf;
     struct usb_endpoint_descriptor_no_audio source;
     struct usb_ss_ep_comp_descriptor source_comp;
     struct usb_endpoint_descriptor_no_audio sink;
     struct usb_ss_ep_comp_descriptor sink_comp;
 } __attribute__((packed));

 struct desc_v1 {
     struct usb_functionfs_descs_head_v1 {
         __le32 magic;
         __le32 length;
         __le32 fs_count;
         __le32 hs_count;
     } __attribute__((packed)) header;
     struct func_desc fs_descs, hs_descs;
 } __attribute__((packed));

 struct desc_v2 {
     struct usb_functionfs_descs_head_v2 header;
     // The rest of the structure depends on the flags in the header.
     __le32 fs_count;
     __le32 hs_count;
     __le32 ss_count;
     __le32 os_count;
     struct func_desc fs_descs, hs_descs;
     struct ss_func_desc ss_descs;
     struct usb_os_desc_header os_header;
     struct usb_ext_compat_desc os_desc;
 } __attribute__((packed));

 static struct func_desc fs_descriptors = {
     .intf = {
         .bLength = sizeof(fs_descriptors.intf),
         .bDescriptorType = USB_DT_INTERFACE,
         .bInterfaceNumber = 0,
         .bNumEndpoints = 2,
         .bInterfaceClass = ADB_CLASS,
         .bInterfaceSubClass = ADB_SUBCLASS,
         .bInterfaceProtocol = ADB_PROTOCOL,
         .iInterface = 1, /* first string from the provided table */
     },
     .source = {
         .bLength = sizeof(fs_descriptors.source),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 1 | USB_DIR_OUT,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_FS,
     },
     .sink = {
         .bLength = sizeof(fs_descriptors.sink),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 2 | USB_DIR_IN,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_FS,
     },
 };

 static struct func_desc hs_descriptors = {
     .intf = {
         .bLength = sizeof(hs_descriptors.intf),
         .bDescriptorType = USB_DT_INTERFACE,
         .bInterfaceNumber = 0,
         .bNumEndpoints = 2,
         .bInterfaceClass = ADB_CLASS,
         .bInterfaceSubClass = ADB_SUBCLASS,
         .bInterfaceProtocol = ADB_PROTOCOL,
         .iInterface = 1, /* first string from the provided table */
     },
     .source = {
         .bLength = sizeof(hs_descriptors.source),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 1 | USB_DIR_OUT,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_HS,
     },
     .sink = {
         .bLength = sizeof(hs_descriptors.sink),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 2 | USB_DIR_IN,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_HS,
     },
 };

 static struct ss_func_desc ss_descriptors = {
     .intf = {
         .bLength = sizeof(ss_descriptors.intf),
         .bDescriptorType = USB_DT_INTERFACE,
         .bInterfaceNumber = 0,
         .bNumEndpoints = 2,
         .bInterfaceClass = ADB_CLASS,
         .bInterfaceSubClass = ADB_SUBCLASS,
         .bInterfaceProtocol = ADB_PROTOCOL,
         .iInterface = 1, /* first string from the provided table */
     },
     .source = {
         .bLength = sizeof(ss_descriptors.source),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 1 | USB_DIR_OUT,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_SS,
     },
     .source_comp = {
         .bLength = sizeof(ss_descriptors.source_comp),
         .bDescriptorType = USB_DT_SS_ENDPOINT_COMP,
     },
     .sink = {
         .bLength = sizeof(ss_descriptors.sink),
         .bDescriptorType = USB_DT_ENDPOINT,
         .bEndpointAddress = 2 | USB_DIR_IN,
         .bmAttributes = USB_ENDPOINT_XFER_BULK,
         .wMaxPacketSize = MAX_PACKET_SIZE_SS,
     },
     .sink_comp = {
         .bLength = sizeof(ss_descriptors.sink_comp),
         .bDescriptorType = USB_DT_SS_ENDPOINT_COMP,
     },
 };

 struct usb_ext_compat_desc os_desc_compat = {
     .bFirstInterfaceNumber = 0,
     .Reserved1 = cpu_to_le32(1),
     .CompatibleID = {0},
     .SubCompatibleID = {0},
     .Reserved2 = {0},
 };

 static struct usb_os_desc_header os_desc_header = {
     .interface = cpu_to_le32(1),
     .dwLength = cpu_to_le32(sizeof(os_desc_header) + sizeof(os_desc_compat)),
     .bcdVersion = cpu_to_le32(1),
     .wIndex = cpu_to_le32(4),
     .bCount = cpu_to_le32(1),
     .Reserved = cpu_to_le32(0),
 };

 #define STR_INTERFACE_ "ADB Interface"

 static const struct {
     struct usb_functionfs_strings_head header;
     struct {
         __le16 code;
         const char str1[sizeof(STR_INTERFACE_)];
     } __attribute__((packed)) lang0;
 } __attribute__((packed)) strings = {
     .header = {
         .magic = cpu_to_le32(FUNCTIONFS_STRINGS_MAGIC),
         .length = cpu_to_le32(sizeof(strings)),
         .str_count = cpu_to_le32(1),
         .lang_count = cpu_to_le32(1),
     },
     .lang0 = {
         cpu_to_le16(0x0409), /* en-us */
         STR_INTERFACE_,
     },
 };

 bool init_functionfs(struct usb_handle* h) {
     ssize_t ret;
     struct desc_v1 v1_descriptor;
     struct desc_v2 v2_descriptor;
     size_t retries = 0;

     v2_descriptor.header.magic = cpu_to_le32(FUNCTIONFS_DESCRIPTORS_MAGIC_V2);
     v2_descriptor.header.length = cpu_to_le32(sizeof(v2_descriptor));
     v2_descriptor.header.flags = FUNCTIONFS_HAS_FS_DESC | FUNCTIONFS_HAS_HS_DESC |
                                  FUNCTIONFS_HAS_SS_DESC | FUNCTIONFS_HAS_MS_OS_DESC;
     v2_descriptor.fs_count = 3;
     v2_descriptor.hs_count = 3;
     v2_descriptor.ss_count = 5;
     v2_descriptor.os_count = 1;
     v2_descriptor.fs_descs = fs_descriptors;
     v2_descriptor.hs_descs = hs_descriptors;
     v2_descriptor.ss_descs = ss_descriptors;
     v2_descriptor.os_header = os_desc_header;
     v2_descriptor.os_desc = os_desc_compat;

     if (h->control < 0) { // might have already done this before
         D("OPENING %s", USB_FFS_ADB_EP0);
         h->control = adb_open(USB_FFS_ADB_EP0, O_RDWR);
         if (h->control < 0) {
             D("[ %s: cannot open control endpoint: errno=%d]", USB_FFS_ADB_EP0, errno);
             goto err;
         }

         ret = adb_write(h->control, &v2_descriptor, sizeof(v2_descriptor));
         if (ret < 0) {
             v1_descriptor.header.magic = cpu_to_le32(FUNCTIONFS_DESCRIPTORS_MAGIC);
             v1_descriptor.header.length = cpu_to_le32(sizeof(v1_descriptor));
             v1_descriptor.header.fs_count = 3;
             v1_descriptor.header.hs_count = 3;
             v1_descriptor.fs_descs = fs_descriptors;
             v1_descriptor.hs_descs = hs_descriptors;
             D("[ %s: Switching to V1_descriptor format errno=%d ]", USB_FFS_ADB_EP0, errno);
             ret = adb_write(h->control, &v1_descriptor, sizeof(v1_descriptor));
             if (ret < 0) {
                 D("[ %s: write descriptors failed: errno=%d ]", USB_FFS_ADB_EP0, errno);
                 goto err;
             }
         }

         ret = adb_write(h->control, &strings, sizeof(strings));
         if (ret < 0) {
             D("[ %s: writing strings failed: errno=%d]", USB_FFS_ADB_EP0, errno);
             goto err;
         }
     }

     h->bulk_out = adb_open(USB_FFS_ADB_OUT, O_RDWR);
     if (h->bulk_out < 0) {
         D("[ %s: cannot open bulk-out ep: errno=%d ]", USB_FFS_ADB_OUT, errno);
         goto err;
     }

     h->bulk_in = adb_open(USB_FFS_ADB_IN, O_RDWR);
     if (h->bulk_in < 0) {
         D("[ %s: cannot open bulk-in ep: errno=%d ]", USB_FFS_ADB_IN, errno);
         goto err;
     }

     h->max_rw = MAX_PAYLOAD;
     while (h->max_rw >= USB_FFS_BULK_SIZE && retries < ENDPOINT_ALLOC_RETRIES) {
         int ret_in = ioctl(h->bulk_in, FUNCTIONFS_ENDPOINT_ALLOC, static_cast<__u32>(h->max_rw));
         int errno_in = errno;
         int ret_out = ioctl(h->bulk_out, FUNCTIONFS_ENDPOINT_ALLOC, static_cast<__u32>(h->max_rw));
         int errno_out = errno;

         if (ret_in || ret_out) {
             if (errno_in == ENODEV || errno_out == ENODEV) {
                 std::this_thread::sleep_for(100ms);
                 retries += 1;
                 continue;
             }
             h->max_rw /= 2;
         } else {
             return true;
         }
     }

     D("[ adb: cannot call endpoint alloc: errno=%d ]", errno);
     // Kernel pre-allocation could have failed for recoverable reasons.
     // Continue running with a safe max rw size.
     h->max_rw *= 2;
     return true;

 err:
     if (h->bulk_in > 0) {
         adb_close(h->bulk_in);
         h->bulk_in = -1;
     }
     if (h->bulk_out > 0) {
         adb_close(h->bulk_out);
         h->bulk_out = -1;
     }
     if (h->control > 0) {
         adb_close(h->control);
         h->control = -1;
     }
     return false;
 }

 static void usb_ffs_open_thread(void* x) {
     struct usb_handle* usb = (struct usb_handle*)x;

     adb_thread_setname("usb ffs open");

     while (true) {
         // wait until the USB device needs opening
         std::unique_lock<std::mutex> lock(usb->lock);
         while (!usb->open_new_connection) {
             usb->notify.wait(lock);
         }
         usb->open_new_connection = false;
         lock.unlock();

         while (true) {
             if (init_functionfs(usb)) {
                 break;
             }
             std::this_thread::sleep_for(1s);
         }
         android::base::SetProperty("sys.usb.ffs.ready", "1");

         D("[ usb_thread - registering device ]");
         register_usb_transport(usb, 0, 0, 1);
     }

     // never gets here
     abort();
 }

 static int usb_ffs_write(usb_handle* h, const void* data, int len) {
     D("about to write (fd=%d, len=%d)", h->bulk_in, len);

     const char* buf = static_cast<const char*>(data);
     while (len > 0) {
         int write_len = std::min(h->max_rw, len);
         int n = adb_write(h->bulk_in, buf, write_len);
         if (n < 0) {
             D("ERROR: fd = %d, n = %d: %s", h->bulk_in, n, strerror(errno));
             return -1;
         }
         buf += n;
         len -= n;
     }

     D("[ done fd=%d ]", h->bulk_in);
     return 0;
 }

 static int usb_ffs_read(usb_handle* h, void* data, int len) {
     D("about to read (fd=%d, len=%d)", h->bulk_out, len);

     char* buf = static_cast<char*>(data);
     while (len > 0) {
         int read_len = std::min(h->max_rw, len);
         int n = adb_read(h->bulk_out, buf, read_len);
         if (n < 0) {
             D("ERROR: fd = %d, n = %d: %s", h->bulk_out, n, strerror(errno));
             return -1;
         }
         buf += n;
         len -= n;
     }

     D("[ done fd=%d ]", h->bulk_out);
     return 0;
 }

 static void usb_ffs_kick(usb_handle* h) {
     int err;

     err = ioctl(h->bulk_in, FUNCTIONFS_CLEAR_HALT);
     if (err < 0) {
         D("[ kick: source (fd=%d) clear halt failed (%d) ]", h->bulk_in, errno);
     }

     err = ioctl(h->bulk_out, FUNCTIONFS_CLEAR_HALT);
     if (err < 0) {
         D("[ kick: sink (fd=%d) clear halt failed (%d) ]", h->bulk_out, errno);
     }

     // don't close ep0 here, since we may not need to reinitialize it with
     // the same descriptors again. if however ep1/ep2 fail to re-open in
     // init_functionfs, only then would we close and open ep0 again.
     // Ditto the comment in usb_adb_kick.
     h->kicked = true;
     TEMP_FAILURE_RETRY(dup2(dummy_fd, h->bulk_out));
     TEMP_FAILURE_RETRY(dup2(dummy_fd, h->bulk_in));
 }

 static void usb_ffs_close(usb_handle* h) {
     h->kicked = false;
     adb_close(h->bulk_out);
     adb_close(h->bulk_in);
     // Notify usb_adb_open_thread to open a new connection.
     h->lock.lock();
     h->open_new_connection = true;
     h->lock.unlock();
     h->notify.notify_one();
 }

 static void usb_ffs_init() {
     D("[ usb_init - using FunctionFS ]");

     usb_handle* h = new usb_handle();

     h->write = usb_ffs_write;
     h->read = usb_ffs_read;
     h->kick = usb_ffs_kick;
     h->close = usb_ffs_close;

     D("[ usb_init - starting thread ]");
     if (!adb_thread_create(usb_ffs_open_thread, h)) {
         fatal_errno("[ cannot create usb thread ]\n");
     }
 }

 void usb_init() {
     dummy_fd = adb_open("/dev/null", O_WRONLY);
     CHECK_NE(dummy_fd, -1);
     usb_ffs_init();
 }

 int usb_write(usb_handle* h, const void* data, int len) {
     return h->write(h, data, len);
 }

 int usb_read(usb_handle* h, void* data, int len) {
     return h->read(h, data, len);
 }

 int usb_close(usb_handle* h) {
     h->close(h);
     return 0;
 }

 void usb_kick(usb_handle* h) {
     h->kick(h);
 }
	/*
	* 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.
	*/

	#define TRACE_TAG USB

	#include "sysdeps.h"

	#include <dirent.h>
	#include <errno.h>
	#include <linux/usb/ch9.h>
	#include <linux/usb/functionfs.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include <sys/ioctl.h>
	#include <sys/types.h>
	#include <unistd.h>

	#include <algorithm>
	#include <atomic>
	#include <chrono>
	#include <condition_variable>
	#include <mutex>
	#include <thread>

	#include <android-base/logging.h>
	#include <android-base/properties.h>

	#include "adb.h"
	#include "daemon/usb.h"
	#include "transport.h"

	using namespace std::chrono_literals;

	#define MAX_PACKET_SIZE_FS 64
	#define MAX_PACKET_SIZE_HS 512
	#define MAX_PACKET_SIZE_SS 1024

	// Kernels before 3.3 have a 16KiB transfer limit That limit was replaced
	// with a 16MiB global limit in 3.3, but each URB submitted required a
	// contiguous kernel allocation, so you would get ENOMEM if you tried to
	// send something larger than the biggest available contiguous kernel
	// memory region. Large contiguous allocations could be unreliable
	// on a device kernel that has been running for a while fragmenting its
	// memory so we start with a larger allocation, and shrink the amount if
	// necessary.
	#define USB_FFS_BULK_SIZE 16384

	#define cpu_to_le16(x) htole16(x)
	#define cpu_to_le32(x) htole32(x)

	#define FUNCTIONFS_ENDPOINT_ALLOC _IOR('g', 231, __u32)

	static constexpr size_t ENDPOINT_ALLOC_RETRIES = 10;

	static int dummy_fd = -1;

	struct func_desc {
	struct usb_interface_descriptor intf;
	struct usb_endpoint_descriptor_no_audio source;
	struct usb_endpoint_descriptor_no_audio sink;
	} __attribute__((packed));

	struct ss_func_desc {
	struct usb_interface_descriptor intf;
	struct usb_endpoint_descriptor_no_audio source;
	struct usb_ss_ep_comp_descriptor source_comp;
	struct usb_endpoint_descriptor_no_audio sink;
	struct usb_ss_ep_comp_descriptor sink_comp;
	} __attribute__((packed));

	struct desc_v1 {
	struct usb_functionfs_descs_head_v1 {
	__le32 magic;
	__le32 length;
	__le32 fs_count;
	__le32 hs_count;
	} __attribute__((packed)) header;
	struct func_desc fs_descs, hs_descs;
	} __attribute__((packed));

	struct desc_v2 {
	struct usb_functionfs_descs_head_v2 header;
	// The rest of the structure depends on the flags in the header.
	__le32 fs_count;
	__le32 hs_count;
	__le32 ss_count;
	__le32 os_count;
	struct func_desc fs_descs, hs_descs;
	struct ss_func_desc ss_descs;
	struct usb_os_desc_header os_header;
	struct usb_ext_compat_desc os_desc;
	} __attribute__((packed));

	static struct func_desc fs_descriptors = {
	.intf = {
	.bLength = sizeof(fs_descriptors.intf),
	.bDescriptorType = USB_DT_INTERFACE,
	.bInterfaceNumber = 0,
	.bNumEndpoints = 2,
	.bInterfaceClass = ADB_CLASS,
	.bInterfaceSubClass = ADB_SUBCLASS,
	.bInterfaceProtocol = ADB_PROTOCOL,
	.iInterface = 1, /* first string from the provided table */
	},
	.source = {
	.bLength = sizeof(fs_descriptors.source),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 1 \| USB_DIR_OUT,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_FS,
	},
	.sink = {
	.bLength = sizeof(fs_descriptors.sink),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 2 \| USB_DIR_IN,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_FS,
	},
	};

	static struct func_desc hs_descriptors = {
	.intf = {
	.bLength = sizeof(hs_descriptors.intf),
	.bDescriptorType = USB_DT_INTERFACE,
	.bInterfaceNumber = 0,
	.bNumEndpoints = 2,
	.bInterfaceClass = ADB_CLASS,
	.bInterfaceSubClass = ADB_SUBCLASS,
	.bInterfaceProtocol = ADB_PROTOCOL,
	.iInterface = 1, /* first string from the provided table */
	},
	.source = {
	.bLength = sizeof(hs_descriptors.source),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 1 \| USB_DIR_OUT,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_HS,
	},
	.sink = {
	.bLength = sizeof(hs_descriptors.sink),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 2 \| USB_DIR_IN,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_HS,
	},
	};

	static struct ss_func_desc ss_descriptors = {
	.intf = {
	.bLength = sizeof(ss_descriptors.intf),
	.bDescriptorType = USB_DT_INTERFACE,
	.bInterfaceNumber = 0,
	.bNumEndpoints = 2,
	.bInterfaceClass = ADB_CLASS,
	.bInterfaceSubClass = ADB_SUBCLASS,
	.bInterfaceProtocol = ADB_PROTOCOL,
	.iInterface = 1, /* first string from the provided table */
	},
	.source = {
	.bLength = sizeof(ss_descriptors.source),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 1 \| USB_DIR_OUT,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_SS,
	},
	.source_comp = {
	.bLength = sizeof(ss_descriptors.source_comp),
	.bDescriptorType = USB_DT_SS_ENDPOINT_COMP,
	},
	.sink = {
	.bLength = sizeof(ss_descriptors.sink),
	.bDescriptorType = USB_DT_ENDPOINT,
	.bEndpointAddress = 2 \| USB_DIR_IN,
	.bmAttributes = USB_ENDPOINT_XFER_BULK,
	.wMaxPacketSize = MAX_PACKET_SIZE_SS,
	},
	.sink_comp = {
	.bLength = sizeof(ss_descriptors.sink_comp),
	.bDescriptorType = USB_DT_SS_ENDPOINT_COMP,
	},
	};

	struct usb_ext_compat_desc os_desc_compat = {
	.bFirstInterfaceNumber = 0,
	.Reserved1 = cpu_to_le32(1),
	.CompatibleID = {0},
	.SubCompatibleID = {0},
	.Reserved2 = {0},
	};

	static struct usb_os_desc_header os_desc_header = {
	.interface = cpu_to_le32(1),
	.dwLength = cpu_to_le32(sizeof(os_desc_header) + sizeof(os_desc_compat)),
	.bcdVersion = cpu_to_le32(1),
	.wIndex = cpu_to_le32(4),
	.bCount = cpu_to_le32(1),
	.Reserved = cpu_to_le32(0),
	};

	#define STR_INTERFACE_ "ADB Interface"

	static const struct {
	struct usb_functionfs_strings_head header;
	struct {
	__le16 code;
	const char str1[sizeof(STR_INTERFACE_)];
	} __attribute__((packed)) lang0;
	} __attribute__((packed)) strings = {
	.header = {
	.magic = cpu_to_le32(FUNCTIONFS_STRINGS_MAGIC),
	.length = cpu_to_le32(sizeof(strings)),
	.str_count = cpu_to_le32(1),
	.lang_count = cpu_to_le32(1),
	},
	.lang0 = {
	cpu_to_le16(0x0409), /* en-us */
	STR_INTERFACE_,
	},
	};

	bool init_functionfs(struct usb_handle* h) {
	ssize_t ret;
	struct desc_v1 v1_descriptor;
	struct desc_v2 v2_descriptor;
	size_t retries = 0;

	v2_descriptor.header.magic = cpu_to_le32(FUNCTIONFS_DESCRIPTORS_MAGIC_V2);
	v2_descriptor.header.length = cpu_to_le32(sizeof(v2_descriptor));
	v2_descriptor.header.flags = FUNCTIONFS_HAS_FS_DESC \| FUNCTIONFS_HAS_HS_DESC \|
	FUNCTIONFS_HAS_SS_DESC \| FUNCTIONFS_HAS_MS_OS_DESC;
	v2_descriptor.fs_count = 3;
	v2_descriptor.hs_count = 3;
	v2_descriptor.ss_count = 5;
	v2_descriptor.os_count = 1;
	v2_descriptor.fs_descs = fs_descriptors;
	v2_descriptor.hs_descs = hs_descriptors;
	v2_descriptor.ss_descs = ss_descriptors;
	v2_descriptor.os_header = os_desc_header;
	v2_descriptor.os_desc = os_desc_compat;

	if (h->control < 0) { // might have already done this before
	D("OPENING %s", USB_FFS_ADB_EP0);
	h->control = adb_open(USB_FFS_ADB_EP0, O_RDWR);
	if (h->control < 0) {
	D("[ %s: cannot open control endpoint: errno=%d]", USB_FFS_ADB_EP0, errno);
	goto err;
	}

	ret = adb_write(h->control, &v2_descriptor, sizeof(v2_descriptor));
	if (ret < 0) {
	v1_descriptor.header.magic = cpu_to_le32(FUNCTIONFS_DESCRIPTORS_MAGIC);
	v1_descriptor.header.length = cpu_to_le32(sizeof(v1_descriptor));
	v1_descriptor.header.fs_count = 3;
	v1_descriptor.header.hs_count = 3;
	v1_descriptor.fs_descs = fs_descriptors;
	v1_descriptor.hs_descs = hs_descriptors;
	D("[ %s: Switching to V1_descriptor format errno=%d ]", USB_FFS_ADB_EP0, errno);
	ret = adb_write(h->control, &v1_descriptor, sizeof(v1_descriptor));
	if (ret < 0) {
	D("[ %s: write descriptors failed: errno=%d ]", USB_FFS_ADB_EP0, errno);
	goto err;
	}
	}

	ret = adb_write(h->control, &strings, sizeof(strings));
	if (ret < 0) {
	D("[ %s: writing strings failed: errno=%d]", USB_FFS_ADB_EP0, errno);
	goto err;
	}
	}

	h->bulk_out = adb_open(USB_FFS_ADB_OUT, O_RDWR);
	if (h->bulk_out < 0) {
	D("[ %s: cannot open bulk-out ep: errno=%d ]", USB_FFS_ADB_OUT, errno);
	goto err;
	}

	h->bulk_in = adb_open(USB_FFS_ADB_IN, O_RDWR);
	if (h->bulk_in < 0) {
	D("[ %s: cannot open bulk-in ep: errno=%d ]", USB_FFS_ADB_IN, errno);
	goto err;
	}

	h->max_rw = MAX_PAYLOAD;
	while (h->max_rw >= USB_FFS_BULK_SIZE && retries < ENDPOINT_ALLOC_RETRIES) {
	int ret_in = ioctl(h->bulk_in, FUNCTIONFS_ENDPOINT_ALLOC, static_cast<__u32>(h->max_rw));
	int errno_in = errno;
	int ret_out = ioctl(h->bulk_out, FUNCTIONFS_ENDPOINT_ALLOC, static_cast<__u32>(h->max_rw));
	int errno_out = errno;

	if (ret_in \|\| ret_out) {
	if (errno_in == ENODEV \|\| errno_out == ENODEV) {
	std::this_thread::sleep_for(100ms);
	retries += 1;
	continue;
	}
	h->max_rw /= 2;
	} else {
	return true;
	}
	}

	D("[ adb: cannot call endpoint alloc: errno=%d ]", errno);
	// Kernel pre-allocation could have failed for recoverable reasons.
	// Continue running with a safe max rw size.
	h->max_rw *= 2;
	return true;

	err:
	if (h->bulk_in > 0) {
	adb_close(h->bulk_in);
	h->bulk_in = -1;
	}
	if (h->bulk_out > 0) {
	adb_close(h->bulk_out);
	h->bulk_out = -1;
	}
	if (h->control > 0) {
	adb_close(h->control);
	h->control = -1;
	}
	return false;
	}

	static void usb_ffs_open_thread(void* x) {
	struct usb_handle* usb = (struct usb_handle*)x;

	adb_thread_setname("usb ffs open");

	while (true) {
	// wait until the USB device needs opening
	std::unique_lock<std::mutex> lock(usb->lock);
	while (!usb->open_new_connection) {
	usb->notify.wait(lock);
	}
	usb->open_new_connection = false;
	lock.unlock();

	while (true) {
	if (init_functionfs(usb)) {
	break;
	}
	std::this_thread::sleep_for(1s);
	}
	android::base::SetProperty("sys.usb.ffs.ready", "1");

	D("[ usb_thread - registering device ]");
	register_usb_transport(usb, 0, 0, 1);
	}

	// never gets here
	abort();
	}

	static int usb_ffs_write(usb_handle* h, const void* data, int len) {
	D("about to write (fd=%d, len=%d)", h->bulk_in, len);

	const char* buf = static_cast<const char*>(data);
	while (len > 0) {
	int write_len = std::min(h->max_rw, len);
	int n = adb_write(h->bulk_in, buf, write_len);
	if (n < 0) {
	D("ERROR: fd = %d, n = %d: %s", h->bulk_in, n, strerror(errno));
	return -1;
	}
	buf += n;
	len -= n;
	}

	D("[ done fd=%d ]", h->bulk_in);
	return 0;
	}

	static int usb_ffs_read(usb_handle* h, void* data, int len) {
	D("about to read (fd=%d, len=%d)", h->bulk_out, len);

	char* buf = static_cast<char*>(data);
	while (len > 0) {
	int read_len = std::min(h->max_rw, len);
	int n = adb_read(h->bulk_out, buf, read_len);
	if (n < 0) {
	D("ERROR: fd = %d, n = %d: %s", h->bulk_out, n, strerror(errno));
	return -1;
	}
	buf += n;
	len -= n;
	}

	D("[ done fd=%d ]", h->bulk_out);
	return 0;
	}

	static void usb_ffs_kick(usb_handle* h) {
	int err;

	err = ioctl(h->bulk_in, FUNCTIONFS_CLEAR_HALT);
	if (err < 0) {
	D("[ kick: source (fd=%d) clear halt failed (%d) ]", h->bulk_in, errno);
	}

	err = ioctl(h->bulk_out, FUNCTIONFS_CLEAR_HALT);
	if (err < 0) {
	D("[ kick: sink (fd=%d) clear halt failed (%d) ]", h->bulk_out, errno);
	}

	// don't close ep0 here, since we may not need to reinitialize it with
	// the same descriptors again. if however ep1/ep2 fail to re-open in
	// init_functionfs, only then would we close and open ep0 again.
	// Ditto the comment in usb_adb_kick.
	h->kicked = true;
	TEMP_FAILURE_RETRY(dup2(dummy_fd, h->bulk_out));
	TEMP_FAILURE_RETRY(dup2(dummy_fd, h->bulk_in));
	}

	static void usb_ffs_close(usb_handle* h) {
	h->kicked = false;
	adb_close(h->bulk_out);
	adb_close(h->bulk_in);
	// Notify usb_adb_open_thread to open a new connection.
	h->lock.lock();
	h->open_new_connection = true;
	h->lock.unlock();
	h->notify.notify_one();
	}

	static void usb_ffs_init() {
	D("[ usb_init - using FunctionFS ]");

	usb_handle* h = new usb_handle();

	h->write = usb_ffs_write;
	h->read = usb_ffs_read;
	h->kick = usb_ffs_kick;
	h->close = usb_ffs_close;

	D("[ usb_init - starting thread ]");
	if (!adb_thread_create(usb_ffs_open_thread, h)) {
	fatal_errno("[ cannot create usb thread ]\n");
	}
	}

	void usb_init() {
	dummy_fd = adb_open("/dev/null", O_WRONLY);
	CHECK_NE(dummy_fd, -1);
	usb_ffs_init();
	}

	int usb_write(usb_handle* h, const void* data, int len) {
	return h->write(h, data, len);
	}

	int usb_read(usb_handle* h, void* data, int len) {
	return h->read(h, data, len);
	}

	int usb_close(usb_handle* h) {
	h->close(h);
	return 0;
	}

	void usb_kick(usb_handle* h) {
	h->kick(h);
	}