third_party/perfetto/ui/src/controller/adb.ts - cobalt - Git at Google

 // Copyright (C) 2019 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.

 import {_TextDecoder, _TextEncoder} from 'custom_utils';

 import {assertExists} from '../base/logging';

 import {Adb, AdbMsg, AdbStream, CmdType} from './adb_interfaces';

 const textEncoder = new _TextEncoder();
 const textDecoder = new _TextDecoder();

 export const VERSION_WITH_CHECKSUM = 0x01000000;
 export const VERSION_NO_CHECKSUM = 0x01000001;
 export const DEFAULT_MAX_PAYLOAD_BYTES = 256 * 1024;

 export enum AdbState {
   DISCONNECTED = 0,
   // Authentication steps, see AdbOverWebUsb's handleAuthentication().
   AUTH_STEP1 = 1,
   AUTH_STEP2 = 2,
   AUTH_STEP3 = 3,

   CONNECTED = 2,
 }

 enum AuthCmd {
   TOKEN = 1,
   SIGNATURE = 2,
   RSAPUBLICKEY = 3,
 }

 const DEVICE_NOT_SET_ERROR = 'Device not set.';

 // This class is a basic TypeScript implementation of adb that only supports
 // shell commands. It is used to send the start tracing command to the connected
 // android device, and to automatically pull the trace after the end of the
 // recording. It works through the webUSB API. A brief description of how it
 // works is the following:
 // - The connection with the device is initiated by findAndConnect, which shows
 //   a dialog with a list of connected devices. Once one is selected the
 //   authentication begins. The authentication has to pass different steps, as
 //   described in the "handeAuthentication" method.
 // - AdbOverWebUsb tracks the state of the authentication via a state machine
 //   (see AdbState).
 // - A Message handler loop is executed to keep receiving the messages.
 // - All the messages received from the device are passed to "onMessage" that is
 //   implemented as a state machine.
 // - When a new shell is established, it becomes an AdbStream, and is kept in
 //   the "streams" map. Each time a message from the device is for a specific
 //   previously opened stream, the "onMessage" function will forward it to the
 //   stream (identified by a number).
 export class AdbOverWebUsb implements Adb {
   state: AdbState = AdbState.DISCONNECTED;
   streams = new Map<number, AdbStream>();
   devProps = '';
   maxPayload = DEFAULT_MAX_PAYLOAD_BYTES;
   key?: CryptoKeyPair;
   onConnected = () => {};

   // Devices after Dec 2017 don't use checksum. This will be auto-detected
   // during the connection.
   useChecksum = true;

   private lastStreamId = 0;
   private dev?: USBDevice;
   private usbInterfaceNumber?: number;
   private usbReadEndpoint = -1;
   private usbWriteEpEndpoint = -1;
   private filter = {
     classCode: 255,    // USB vendor specific code
     subclassCode: 66,  // Android vendor specific subclass
     protocolCode: 1,   // Adb protocol
   };

   async findDevice() {
     if (!('usb' in navigator)) {
       throw new Error('WebUSB not supported by the browser (requires HTTPS)');
     }
     return navigator.usb.requestDevice({filters: [this.filter]});
   }

   async getPairedDevices() {
     try {
       return navigator.usb.getDevices();
     } catch (e) {  // WebUSB not available.
       return Promise.resolve([]);
     }
   }

   async connect(device: USBDevice): Promise<void> {
     // If we are already connected, we are also already authenticated, so we can
     // skip doing the authentication again.
     if (this.state === AdbState.CONNECTED) {
       if (this.dev === device && device.opened) {
         this.onConnected();
         this.onConnected = () => {};
         return;
       }
       // Another device was connected.
       await this.disconnect();
     }

     this.dev = device;
     this.useChecksum = true;
     this.key = await AdbOverWebUsb.initKey();

     await this.dev.open();

     const {configValue, usbInterfaceNumber, endpoints} =
         this.findInterfaceAndEndpoint();
     this.usbInterfaceNumber = usbInterfaceNumber;

     this.usbReadEndpoint = this.findEndpointNumber(endpoints, 'in');
     this.usbWriteEpEndpoint = this.findEndpointNumber(endpoints, 'out');

     console.assert(this.usbReadEndpoint >= 0 && this.usbWriteEpEndpoint >= 0);

     await this.dev.selectConfiguration(configValue);
     await this.dev.claimInterface(usbInterfaceNumber);

     await this.startAuthentication();

     // This will start a message handler loop.
     this.receiveDeviceMessages();
     // The promise will be resolved after the handshake.
     return new Promise<void>((resolve, _) => this.onConnected = resolve);
   }

   async disconnect(): Promise<void> {
     if (this.state === AdbState.DISCONNECTED) {
       return;
     }
     this.state = AdbState.DISCONNECTED;

     if (!this.dev) return;

     new Map(this.streams).forEach((stream, _id) => stream.setClosed());
     console.assert(this.streams.size === 0);

     await this.dev.releaseInterface(assertExists(this.usbInterfaceNumber));
     this.dev = undefined;
     this.usbInterfaceNumber = undefined;
   }

   async startAuthentication() {
     // USB connected, now let's authenticate.
     const VERSION =
         this.useChecksum ? VERSION_WITH_CHECKSUM : VERSION_NO_CHECKSUM;
     this.state = AdbState.AUTH_STEP1;
     await this.send('CNXN', VERSION, this.maxPayload, 'host:1:UsbADB');
   }

   findInterfaceAndEndpoint() {
     if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
     for (const config of this.dev.configurations) {
       for (const interface_ of config.interfaces) {
         for (const alt of interface_.alternates) {
           if (alt.interfaceClass === this.filter.classCode &&
               alt.interfaceSubclass === this.filter.subclassCode &&
               alt.interfaceProtocol === this.filter.protocolCode) {
             return {
               configValue: config.configurationValue,
               usbInterfaceNumber: interface_.interfaceNumber,
               endpoints: alt.endpoints,
             };
           }  // if (alternate)
         }    // for (interface.alternates)
       }      // for (configuration.interfaces)
     }        // for (configurations)

     throw Error('Cannot find interfaces and endpoints');
   }

   findEndpointNumber(
       endpoints: USBEndpoint[], direction: 'out'|'in', type = 'bulk'): number {
     const ep =
         endpoints.find((ep) => ep.type === type && ep.direction === direction);

     if (ep) return ep.endpointNumber;

     throw Error(`Cannot find ${direction} endpoint`);
   }

   receiveDeviceMessages() {
     this.recv()
         .then((msg) => {
           this.onMessage(msg);
           this.receiveDeviceMessages();
         })
         .catch((e) => {
           // Ignore error with "DEVICE_NOT_SET_ERROR" message since it is always
           // thrown after the device disconnects.
           if (e.message !== DEVICE_NOT_SET_ERROR) {
             console.error(`Exception in recv: ${e.name}. error: ${e.message}`);
           }
           this.disconnect();
         });
   }

   async onMessage(msg: AdbMsg) {
     if (!this.key) throw Error('ADB key not initialized');

     if (msg.cmd === 'AUTH' && msg.arg0 === AuthCmd.TOKEN) {
       this.handleAuthentication(msg);
     } else if (msg.cmd === 'CNXN') {
       console.assert(
           [AdbState.AUTH_STEP2, AdbState.AUTH_STEP3].includes(this.state));
       this.state = AdbState.CONNECTED;
       this.handleConnectedMessage(msg);
     } else if (this.state === AdbState.CONNECTED && [
                  'OKAY',
                  'WRTE',
                  'CLSE',
                ].indexOf(msg.cmd) >= 0) {
       const stream = this.streams.get(msg.arg1);
       if (!stream) {
         console.warn(`Received message ${msg} for unknown stream ${msg.arg1}`);
         return;
       }
       stream.onMessage(msg);
     } else {
       console.error(`Unexpected message `, msg, ` in state ${this.state}`);
     }
   }

   async handleAuthentication(msg: AdbMsg) {
     if (!this.key) throw Error('ADB key not initialized');

     console.assert(msg.cmd === 'AUTH' && msg.arg0 === AuthCmd.TOKEN);
     const token = msg.data;

     if (this.state === AdbState.AUTH_STEP1) {
       // During this step, we send back the token received signed with our
       // private key. If the device has previously received our public key, the
       // dialog will not be displayed. Otherwise we will receive another message
       // ending up in AUTH_STEP3.
       this.state = AdbState.AUTH_STEP2;

       const signedToken =
           await signAdbTokenWithPrivateKey(this.key.privateKey, token);
       this.send('AUTH', AuthCmd.SIGNATURE, 0, new Uint8Array(signedToken));
       return;
     }

     console.assert(this.state === AdbState.AUTH_STEP2);

     // During this step, we send our public key. The dialog will appear, and
     // if the user chooses to remember our public key, it will be
     // saved, so that the next time we will only pass through AUTH_STEP1.
     this.state = AdbState.AUTH_STEP3;
     const encodedPubKey = await encodePubKey(this.key.publicKey);
     this.send('AUTH', AuthCmd.RSAPUBLICKEY, 0, encodedPubKey);
   }

   private handleConnectedMessage(msg: AdbMsg) {
     console.assert(msg.cmd === 'CNXN');

     this.maxPayload = msg.arg1;
     this.devProps = textDecoder.decode(msg.data);

     const deviceVersion = msg.arg0;

     if (![VERSION_WITH_CHECKSUM, VERSION_NO_CHECKSUM].includes(deviceVersion)) {
       console.error('Version ', msg.arg0, ' not really supported!');
     }
     this.useChecksum = deviceVersion === VERSION_WITH_CHECKSUM;
     this.state = AdbState.CONNECTED;

     // This will resolve the promise returned by "onConnect"
     this.onConnected();
     this.onConnected = () => {};
   }

   shell(cmd: string): Promise<AdbStream> {
     return this.openStream('shell:' + cmd);
   }

   socket(path: string): Promise<AdbStream> {
     return this.openStream('localfilesystem:' + path);
   }

   openStream(svc: string): Promise<AdbStream> {
     const stream = new AdbStreamImpl(this, ++this.lastStreamId);
     this.streams.set(stream.localStreamId, stream);
     this.send('OPEN', stream.localStreamId, 0, svc);

     //  The stream will resolve this promise once it receives the
     //  acknowledgement message from the device.
     return new Promise<AdbStream>((resolve, reject) => {
       stream.onConnect = () => {
         stream.onClose = () => {};
         resolve(stream);
       };
       stream.onClose = () =>
           reject(new Error(`Failed to openStream svc=${svc}`));
     });
   }

   async shellOutputAsString(cmd: string): Promise<string> {
     const shell = await this.shell(cmd);

     return new Promise<string>((resolve, _) => {
       const output: string[] = [];
       shell.onData = (raw) => output.push(textDecoder.decode(raw));
       shell.onClose = () => resolve(output.join());
     });
   }

   async send(
       cmd: CmdType, arg0: number, arg1: number, data?: Uint8Array|string) {
     await this.sendMsg(AdbMsgImpl.create(
         {cmd, arg0, arg1, data, useChecksum: this.useChecksum}));
   }

   //  The header and the message data must be sent consecutively. Using 2 awaits
   //  Another message can interleave after the first header has been sent,
   //  resulting in something like [header1] [header2] [data1] [data2];
   //  In this way we are waiting both promises to be resolved before continuing.
   async sendMsg(msg: AdbMsgImpl) {
     const sendPromises = [this.sendRaw(msg.encodeHeader())];
     if (msg.data.length > 0) sendPromises.push(this.sendRaw(msg.data));
     await Promise.all(sendPromises);
   }

   async recv(): Promise<AdbMsg> {
     const res = await this.recvRaw(ADB_MSG_SIZE);
     console.assert(res.status === 'ok');
     const msg = AdbMsgImpl.decodeHeader(res.data!);

     if (msg.dataLen > 0) {
       const resp = await this.recvRaw(msg.dataLen);
       msg.data = new Uint8Array(
           resp.data!.buffer, resp.data!.byteOffset, resp.data!.byteLength);
     }
     if (this.useChecksum) {
       console.assert(AdbOverWebUsb.checksum(msg.data) === msg.dataChecksum);
     }
     return msg;
   }

   static async initKey(): Promise<CryptoKeyPair> {
     const KEY_SIZE = 2048;

     const keySpec = {
       name: 'RSASSA-PKCS1-v1_5',
       modulusLength: KEY_SIZE,
       publicExponent: new Uint8Array([0x01, 0x00, 0x01]),
       hash: {name: 'SHA-1'},
     };

     const key = await crypto.subtle.generateKey(
         keySpec, /* extractable=*/ true, ['sign', 'verify']);
     return key;
   }

   static checksum(data: Uint8Array): number {
     let res = 0;
     for (let i = 0; i < data.byteLength; i++) res += data[i];
     return res & 0xFFFFFFFF;
   }

   sendRaw(buf: Uint8Array): Promise<USBOutTransferResult> {
     console.assert(buf.length <= this.maxPayload);
     if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
     return this.dev.transferOut(this.usbWriteEpEndpoint, buf.buffer);
   }

   recvRaw(dataLen: number): Promise<USBInTransferResult> {
     if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
     return this.dev.transferIn(this.usbReadEndpoint, dataLen);
   }
 }

 enum AdbStreamState {
   WAITING_INITIAL_OKAY = 0,
   CONNECTED = 1,
   CLOSED = 2
 }


 // An AdbStream is instantiated after the creation of a shell to the device.
 // Thanks to this, we can send commands and receive their output. Messages are
 // received in the main adb class, and are forwarded to an instance of this
 // class based on a stream id match. Also streams have an initialization flow:
 //   1. WAITING_INITIAL_OKAY: waiting for first "OKAY" message. Once received,
 //      the next state will be "CONNECTED".
 //   2. CONNECTED: ready to receive or send messages.
 //   3. WRITING: this is needed because we must receive an ack after sending
 //      each message (so, before sending the next one). For this reason, many
 //      subsequent "write" calls will result in different messages in the
 //      writeQueue. After each new acknowledgement ('OKAY') a new one will be
 //      sent. When the queue is empty, the state will return to CONNECTED.
 //   4. CLOSED: entered when the device closes the stream or close() is called.
 //      For shell commands, the stream is closed after the command completed.
 export class AdbStreamImpl implements AdbStream {
   private adb: AdbOverWebUsb;
   localStreamId: number;
   private remoteStreamId = -1;
   private state: AdbStreamState = AdbStreamState.WAITING_INITIAL_OKAY;
   private writeQueue: Uint8Array[] = [];

   private sendInProgress = false;

   onData: AdbStreamReadCallback = (_) => {};
   onConnect = () => {};
   onClose = () => {};

   constructor(adb: AdbOverWebUsb, localStreamId: number) {
     this.adb = adb;
     this.localStreamId = localStreamId;
   }

   close() {
     console.assert(this.state === AdbStreamState.CONNECTED);

     if (this.writeQueue.length > 0) {
       console.error(`Dropping ${
           this.writeQueue.length} queued messages due to stream closing.`);
       this.writeQueue = [];
     }

     this.adb.send('CLSE', this.localStreamId, this.remoteStreamId);
   }

   async write(msg: string|Uint8Array) {
     const raw = (typeof msg === 'string') ? textEncoder.encode(msg) : msg;
     if (this.sendInProgress ||
         this.state === AdbStreamState.WAITING_INITIAL_OKAY) {
       this.writeQueue.push(raw);
       return;
     }
     console.assert(this.state === AdbStreamState.CONNECTED);
     this.sendInProgress = true;
     await this.adb.send('WRTE', this.localStreamId, this.remoteStreamId, raw);
   }

   setClosed() {
     this.state = AdbStreamState.CLOSED;
     this.adb.streams.delete(this.localStreamId);
     this.onClose();
   }

   onMessage(msg: AdbMsgImpl) {
     console.assert(msg.arg1 === this.localStreamId);

     if (this.state === AdbStreamState.WAITING_INITIAL_OKAY &&
         msg.cmd === 'OKAY') {
       this.remoteStreamId = msg.arg0;
       this.state = AdbStreamState.CONNECTED;
       this.onConnect();
       return;
     }

     if (msg.cmd === 'WRTE') {
       this.adb.send('OKAY', this.localStreamId, this.remoteStreamId);
       this.onData(msg.data);
       return;
     }

     if (msg.cmd === 'OKAY') {
       console.assert(this.sendInProgress);
       this.sendInProgress = false;
       const queuedMsg = this.writeQueue.shift();
       if (queuedMsg !== undefined) this.write(queuedMsg);
       return;
     }

     if (msg.cmd === 'CLSE') {
       this.setClosed();
       return;
     }
     console.error(
         `Unexpected stream msg ${msg.toString()} in state ${this.state}`);
   }
 }

 interface AdbStreamReadCallback {
   (raw: Uint8Array): void;
 }

 const ADB_MSG_SIZE = 6 * 4;  // 6 * int32.

 export class AdbMsgImpl implements AdbMsg {
   cmd: CmdType;
   arg0: number;
   arg1: number;
   data: Uint8Array;
   dataLen: number;
   dataChecksum: number;

   useChecksum: boolean;

   constructor(
       cmd: CmdType, arg0: number, arg1: number, dataLen: number,
       dataChecksum: number, useChecksum = false) {
     console.assert(cmd.length === 4);
     this.cmd = cmd;
     this.arg0 = arg0;
     this.arg1 = arg1;
     this.dataLen = dataLen;
     this.data = new Uint8Array(dataLen);
     this.dataChecksum = dataChecksum;
     this.useChecksum = useChecksum;
   }


   static create({cmd, arg0, arg1, data, useChecksum = true}: {
     cmd: CmdType; arg0: number; arg1: number;
     data?: Uint8Array | string;
     useChecksum?: boolean;
   }): AdbMsgImpl {
     const encodedData = this.encodeData(data);
     const msg =
         new AdbMsgImpl(cmd, arg0, arg1, encodedData.length, 0, useChecksum);
     msg.data = encodedData;
     return msg;
   }

   get dataStr() {
     return textDecoder.decode(this.data);
   }

   toString() {
     return `${this.cmd} [${this.arg0},${this.arg1}] ${this.dataStr}`;
   }

   // A brief description of the message can be found here:
   // https://android.googlesource.com/platform/system/core/+/master/adb/protocol.txt
   //
   // struct amessage {
   //     uint32_t command;    // command identifier constant
   //     uint32_t arg0;       // first argument
   //     uint32_t arg1;       // second argument
   //     uint32_t data_length;// length of payload (0 is allowed)
   //     uint32_t data_check; // checksum of data payload
   //     uint32_t magic;      // command ^ 0xffffffff
   // };
   static decodeHeader(dv: DataView): AdbMsgImpl {
     console.assert(dv.byteLength === ADB_MSG_SIZE);
     const cmd = textDecoder.decode(dv.buffer.slice(0, 4)) as CmdType;
     const cmdNum = dv.getUint32(0, true);
     const arg0 = dv.getUint32(4, true);
     const arg1 = dv.getUint32(8, true);
     const dataLen = dv.getUint32(12, true);
     const dataChecksum = dv.getUint32(16, true);
     const cmdChecksum = dv.getUint32(20, true);
     console.assert(cmdNum === (cmdChecksum ^ 0xFFFFFFFF));
     return new AdbMsgImpl(cmd, arg0, arg1, dataLen, dataChecksum);
   }

   encodeHeader(): Uint8Array {
     const buf = new Uint8Array(ADB_MSG_SIZE);
     const dv = new DataView(buf.buffer);
     const cmdBytes: Uint8Array = textEncoder.encode(this.cmd);
     const rawMsg = AdbMsgImpl.encodeData(this.data);
     const checksum = this.useChecksum ? AdbOverWebUsb.checksum(rawMsg) : 0;
     for (let i = 0; i < 4; i++) dv.setUint8(i, cmdBytes[i]);

     dv.setUint32(4, this.arg0, true);
     dv.setUint32(8, this.arg1, true);
     dv.setUint32(12, rawMsg.byteLength, true);
     dv.setUint32(16, checksum, true);
     dv.setUint32(20, dv.getUint32(0, true) ^ 0xFFFFFFFF, true);

     return buf;
   }

   static encodeData(data?: Uint8Array|string): Uint8Array {
     if (data === undefined) return new Uint8Array([]);
     if (typeof data === 'string') return textEncoder.encode(data + '\0');
     return data;
   }
 }


 function base64StringToArray(s: string) {
   const decoded = atob(s.replace(/-/g, '+').replace(/_/g, '/'));
   return [...decoded].map((char) => char.charCodeAt(0));
 }

 const ANDROID_PUBKEY_MODULUS_SIZE = 2048;
 const MODULUS_SIZE_BYTES = ANDROID_PUBKEY_MODULUS_SIZE / 8;

 // RSA Public keys are encoded in a rather unique way. It's a base64 encoded
 // struct of 524 bytes in total as follows (see
 // libcrypto_utils/android_pubkey.c):
 //
 // typedef struct RSAPublicKey {
 //   // Modulus length. This must be ANDROID_PUBKEY_MODULUS_SIZE.
 //   uint32_t modulus_size_words;
 //
 //   // Precomputed montgomery parameter: -1 / n[0] mod 2^32
 //   uint32_t n0inv;
 //
 //   // RSA modulus as a little-endian array.
 //   uint8_t modulus[ANDROID_PUBKEY_MODULUS_SIZE];
 //
 //   // Montgomery parameter R^2 as a little-endian array of little-endian
 //   words. uint8_t rr[ANDROID_PUBKEY_MODULUS_SIZE];
 //
 //   // RSA modulus: 3 or 65537
 //   uint32_t exponent;
 // } RSAPublicKey;
 //
 // However, the Montgomery params (n0inv and rr) are not really used, see
 // comment in android_pubkey_decode() ("Note that we don't extract the
 // montgomery parameters...")
 async function encodePubKey(key: CryptoKey) {
   const expPubKey = await crypto.subtle.exportKey('jwk', key);
   const nArr = base64StringToArray(expPubKey.n as string).reverse();
   const eArr = base64StringToArray(expPubKey.e as string).reverse();

   const arr = new Uint8Array(3 * 4 + 2 * MODULUS_SIZE_BYTES);
   const dv = new DataView(arr.buffer);
   dv.setUint32(0, MODULUS_SIZE_BYTES / 4, true);

   // The Mongomery params (n0inv and rr) are not computed.
   dv.setUint32(4, 0 /* n0inv*/, true);
   // Modulus
   for (let i = 0; i < MODULUS_SIZE_BYTES; i++) dv.setUint8(8 + i, nArr[i]);

   // rr:
   for (let i = 0; i < MODULUS_SIZE_BYTES; i++) {
     dv.setUint8(8 + MODULUS_SIZE_BYTES + i, 0 /* rr*/);
   }
   // Exponent
   for (let i = 0; i < 4; i++) {
     dv.setUint8(8 + (2 * MODULUS_SIZE_BYTES) + i, eArr[i]);
   }
   return btoa(String.fromCharCode(...new Uint8Array(dv.buffer))) +
       ' perfetto@webusb';
 }

 // TODO(nicomazz): This token signature will be useful only when we save the
 // generated keys. So far, we are not doing so. As a consequence, a dialog is
 // displayed every time a tracing session is started.
 // The reason why it has not already been implemented is that the standard
 // crypto.subtle.sign function assumes that the input needs hashing, which is
 // not the case for ADB, where the 20 bytes token is already hashed.
 // A solution to this is implementing a custom private key signature with a js
 // implementation of big integers. Maybe, wrapping the key like in the following
 // CL can work:
 // https://android-review.googlesource.com/c/platform/external/perfetto/+/1105354/18
 async function signAdbTokenWithPrivateKey(
     _privateKey: CryptoKey, token: Uint8Array): Promise<ArrayBuffer> {
   // This function is not implemented.
   return token.buffer;
 }
	// Copyright (C) 2019 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.

	import {_TextDecoder, _TextEncoder} from 'custom_utils';

	import {assertExists} from '../base/logging';

	import {Adb, AdbMsg, AdbStream, CmdType} from './adb_interfaces';

	const textEncoder = new _TextEncoder();
	const textDecoder = new _TextDecoder();

	export const VERSION_WITH_CHECKSUM = 0x01000000;
	export const VERSION_NO_CHECKSUM = 0x01000001;
	export const DEFAULT_MAX_PAYLOAD_BYTES = 256 * 1024;

	export enum AdbState {
	DISCONNECTED = 0,
	// Authentication steps, see AdbOverWebUsb's handleAuthentication().
	AUTH_STEP1 = 1,
	AUTH_STEP2 = 2,
	AUTH_STEP3 = 3,

	CONNECTED = 2,
	}

	enum AuthCmd {
	TOKEN = 1,
	SIGNATURE = 2,
	RSAPUBLICKEY = 3,
	}

	const DEVICE_NOT_SET_ERROR = 'Device not set.';

	// This class is a basic TypeScript implementation of adb that only supports
	// shell commands. It is used to send the start tracing command to the connected
	// android device, and to automatically pull the trace after the end of the
	// recording. It works through the webUSB API. A brief description of how it
	// works is the following:
	// - The connection with the device is initiated by findAndConnect, which shows
	// a dialog with a list of connected devices. Once one is selected the
	// authentication begins. The authentication has to pass different steps, as
	// described in the "handeAuthentication" method.
	// - AdbOverWebUsb tracks the state of the authentication via a state machine
	// (see AdbState).
	// - A Message handler loop is executed to keep receiving the messages.
	// - All the messages received from the device are passed to "onMessage" that is
	// implemented as a state machine.
	// - When a new shell is established, it becomes an AdbStream, and is kept in
	// the "streams" map. Each time a message from the device is for a specific
	// previously opened stream, the "onMessage" function will forward it to the
	// stream (identified by a number).
	export class AdbOverWebUsb implements Adb {
	state: AdbState = AdbState.DISCONNECTED;
	streams = new Map<number, AdbStream>();
	devProps = '';
	maxPayload = DEFAULT_MAX_PAYLOAD_BYTES;
	key?: CryptoKeyPair;
	onConnected = () => {};

	// Devices after Dec 2017 don't use checksum. This will be auto-detected
	// during the connection.
	useChecksum = true;

	private lastStreamId = 0;
	private dev?: USBDevice;
	private usbInterfaceNumber?: number;
	private usbReadEndpoint = -1;
	private usbWriteEpEndpoint = -1;
	private filter = {
	classCode: 255, // USB vendor specific code
	subclassCode: 66, // Android vendor specific subclass
	protocolCode: 1, // Adb protocol
	};

	async findDevice() {
	if (!('usb' in navigator)) {
	throw new Error('WebUSB not supported by the browser (requires HTTPS)');
	}
	return navigator.usb.requestDevice({filters: [this.filter]});
	}

	async getPairedDevices() {
	try {
	return navigator.usb.getDevices();
	} catch (e) { // WebUSB not available.
	return Promise.resolve([]);
	}
	}

	async connect(device: USBDevice): Promise<void> {
	// If we are already connected, we are also already authenticated, so we can
	// skip doing the authentication again.
	if (this.state === AdbState.CONNECTED) {
	if (this.dev === device && device.opened) {
	this.onConnected();
	this.onConnected = () => {};
	return;
	}
	// Another device was connected.
	await this.disconnect();
	}

	this.dev = device;
	this.useChecksum = true;
	this.key = await AdbOverWebUsb.initKey();

	await this.dev.open();

	const {configValue, usbInterfaceNumber, endpoints} =
	this.findInterfaceAndEndpoint();
	this.usbInterfaceNumber = usbInterfaceNumber;

	this.usbReadEndpoint = this.findEndpointNumber(endpoints, 'in');
	this.usbWriteEpEndpoint = this.findEndpointNumber(endpoints, 'out');

	console.assert(this.usbReadEndpoint >= 0 && this.usbWriteEpEndpoint >= 0);

	await this.dev.selectConfiguration(configValue);
	await this.dev.claimInterface(usbInterfaceNumber);

	await this.startAuthentication();

	// This will start a message handler loop.
	this.receiveDeviceMessages();
	// The promise will be resolved after the handshake.
	return new Promise<void>((resolve, _) => this.onConnected = resolve);
	}

	async disconnect(): Promise<void> {
	if (this.state === AdbState.DISCONNECTED) {
	return;
	}
	this.state = AdbState.DISCONNECTED;

	if (!this.dev) return;

	new Map(this.streams).forEach((stream, _id) => stream.setClosed());
	console.assert(this.streams.size === 0);

	await this.dev.releaseInterface(assertExists(this.usbInterfaceNumber));
	this.dev = undefined;
	this.usbInterfaceNumber = undefined;
	}

	async startAuthentication() {
	// USB connected, now let's authenticate.
	const VERSION =
	this.useChecksum ? VERSION_WITH_CHECKSUM : VERSION_NO_CHECKSUM;
	this.state = AdbState.AUTH_STEP1;
	await this.send('CNXN', VERSION, this.maxPayload, 'host:1:UsbADB');
	}

	findInterfaceAndEndpoint() {
	if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
	for (const config of this.dev.configurations) {
	for (const interface_ of config.interfaces) {
	for (const alt of interface_.alternates) {
	if (alt.interfaceClass === this.filter.classCode &&
	alt.interfaceSubclass === this.filter.subclassCode &&
	alt.interfaceProtocol === this.filter.protocolCode) {
	return {
	configValue: config.configurationValue,
	usbInterfaceNumber: interface_.interfaceNumber,
	endpoints: alt.endpoints,
	};
	} // if (alternate)
	} // for (interface.alternates)
	} // for (configuration.interfaces)
	} // for (configurations)

	throw Error('Cannot find interfaces and endpoints');
	}

	findEndpointNumber(
	endpoints: USBEndpoint[], direction: 'out'\|'in', type = 'bulk'): number {
	const ep =
	endpoints.find((ep) => ep.type === type && ep.direction === direction);

	if (ep) return ep.endpointNumber;

	throw Error(`Cannot find ${direction} endpoint`);
	}

	receiveDeviceMessages() {
	this.recv()
	.then((msg) => {
	this.onMessage(msg);
	this.receiveDeviceMessages();
	})
	.catch((e) => {
	// Ignore error with "DEVICE_NOT_SET_ERROR" message since it is always
	// thrown after the device disconnects.
	if (e.message !== DEVICE_NOT_SET_ERROR) {
	console.error(`Exception in recv: ${e.name}. error: ${e.message}`);
	}
	this.disconnect();
	});
	}

	async onMessage(msg: AdbMsg) {
	if (!this.key) throw Error('ADB key not initialized');

	if (msg.cmd === 'AUTH' && msg.arg0 === AuthCmd.TOKEN) {
	this.handleAuthentication(msg);
	} else if (msg.cmd === 'CNXN') {
	console.assert(
	[AdbState.AUTH_STEP2, AdbState.AUTH_STEP3].includes(this.state));
	this.state = AdbState.CONNECTED;
	this.handleConnectedMessage(msg);
	} else if (this.state === AdbState.CONNECTED && [
	'OKAY',
	'WRTE',
	'CLSE',
	].indexOf(msg.cmd) >= 0) {
	const stream = this.streams.get(msg.arg1);
	if (!stream) {
	console.warn(`Received message ${msg} for unknown stream ${msg.arg1}`);
	return;
	}
	stream.onMessage(msg);
	} else {
	console.error(`Unexpected message `, msg, ` in state ${this.state}`);
	}
	}

	async handleAuthentication(msg: AdbMsg) {
	if (!this.key) throw Error('ADB key not initialized');

	console.assert(msg.cmd === 'AUTH' && msg.arg0 === AuthCmd.TOKEN);
	const token = msg.data;

	if (this.state === AdbState.AUTH_STEP1) {
	// During this step, we send back the token received signed with our
	// private key. If the device has previously received our public key, the
	// dialog will not be displayed. Otherwise we will receive another message
	// ending up in AUTH_STEP3.
	this.state = AdbState.AUTH_STEP2;

	const signedToken =
	await signAdbTokenWithPrivateKey(this.key.privateKey, token);
	this.send('AUTH', AuthCmd.SIGNATURE, 0, new Uint8Array(signedToken));
	return;
	}

	console.assert(this.state === AdbState.AUTH_STEP2);

	// During this step, we send our public key. The dialog will appear, and
	// if the user chooses to remember our public key, it will be
	// saved, so that the next time we will only pass through AUTH_STEP1.
	this.state = AdbState.AUTH_STEP3;
	const encodedPubKey = await encodePubKey(this.key.publicKey);
	this.send('AUTH', AuthCmd.RSAPUBLICKEY, 0, encodedPubKey);
	}

	private handleConnectedMessage(msg: AdbMsg) {
	console.assert(msg.cmd === 'CNXN');

	this.maxPayload = msg.arg1;
	this.devProps = textDecoder.decode(msg.data);

	const deviceVersion = msg.arg0;

	if (![VERSION_WITH_CHECKSUM, VERSION_NO_CHECKSUM].includes(deviceVersion)) {
	console.error('Version ', msg.arg0, ' not really supported!');
	}
	this.useChecksum = deviceVersion === VERSION_WITH_CHECKSUM;
	this.state = AdbState.CONNECTED;

	// This will resolve the promise returned by "onConnect"
	this.onConnected();
	this.onConnected = () => {};
	}

	shell(cmd: string): Promise<AdbStream> {
	return this.openStream('shell:' + cmd);
	}

	socket(path: string): Promise<AdbStream> {
	return this.openStream('localfilesystem:' + path);
	}

	openStream(svc: string): Promise<AdbStream> {
	const stream = new AdbStreamImpl(this, ++this.lastStreamId);
	this.streams.set(stream.localStreamId, stream);
	this.send('OPEN', stream.localStreamId, 0, svc);

	// The stream will resolve this promise once it receives the
	// acknowledgement message from the device.
	return new Promise<AdbStream>((resolve, reject) => {
	stream.onConnect = () => {
	stream.onClose = () => {};
	resolve(stream);
	};
	stream.onClose = () =>
	reject(new Error(`Failed to openStream svc=${svc}`));
	});
	}

	async shellOutputAsString(cmd: string): Promise<string> {
	const shell = await this.shell(cmd);

	return new Promise<string>((resolve, _) => {
	const output: string[] = [];
	shell.onData = (raw) => output.push(textDecoder.decode(raw));
	shell.onClose = () => resolve(output.join());
	});
	}

	async send(
	cmd: CmdType, arg0: number, arg1: number, data?: Uint8Array\|string) {
	await this.sendMsg(AdbMsgImpl.create(
	{cmd, arg0, arg1, data, useChecksum: this.useChecksum}));
	}

	// The header and the message data must be sent consecutively. Using 2 awaits
	// Another message can interleave after the first header has been sent,
	// resulting in something like [header1] [header2] [data1] [data2];
	// In this way we are waiting both promises to be resolved before continuing.
	async sendMsg(msg: AdbMsgImpl) {
	const sendPromises = [this.sendRaw(msg.encodeHeader())];
	if (msg.data.length > 0) sendPromises.push(this.sendRaw(msg.data));
	await Promise.all(sendPromises);
	}

	async recv(): Promise<AdbMsg> {
	const res = await this.recvRaw(ADB_MSG_SIZE);
	console.assert(res.status === 'ok');
	const msg = AdbMsgImpl.decodeHeader(res.data!);

	if (msg.dataLen > 0) {
	const resp = await this.recvRaw(msg.dataLen);
	msg.data = new Uint8Array(
	resp.data!.buffer, resp.data!.byteOffset, resp.data!.byteLength);
	}
	if (this.useChecksum) {
	console.assert(AdbOverWebUsb.checksum(msg.data) === msg.dataChecksum);
	}
	return msg;
	}

	static async initKey(): Promise<CryptoKeyPair> {
	const KEY_SIZE = 2048;

	const keySpec = {
	name: 'RSASSA-PKCS1-v1_5',
	modulusLength: KEY_SIZE,
	publicExponent: new Uint8Array([0x01, 0x00, 0x01]),
	hash: {name: 'SHA-1'},
	};

	const key = await crypto.subtle.generateKey(
	keySpec, /* extractable=*/ true, ['sign', 'verify']);
	return key;
	}

	static checksum(data: Uint8Array): number {
	let res = 0;
	for (let i = 0; i < data.byteLength; i++) res += data[i];
	return res & 0xFFFFFFFF;
	}

	sendRaw(buf: Uint8Array): Promise<USBOutTransferResult> {
	console.assert(buf.length <= this.maxPayload);
	if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
	return this.dev.transferOut(this.usbWriteEpEndpoint, buf.buffer);
	}

	recvRaw(dataLen: number): Promise<USBInTransferResult> {
	if (!this.dev) throw Error(DEVICE_NOT_SET_ERROR);
	return this.dev.transferIn(this.usbReadEndpoint, dataLen);
	}
	}

	enum AdbStreamState {
	WAITING_INITIAL_OKAY = 0,
	CONNECTED = 1,
	CLOSED = 2
	}


	// An AdbStream is instantiated after the creation of a shell to the device.
	// Thanks to this, we can send commands and receive their output. Messages are
	// received in the main adb class, and are forwarded to an instance of this
	// class based on a stream id match. Also streams have an initialization flow:
	// 1. WAITING_INITIAL_OKAY: waiting for first "OKAY" message. Once received,
	// the next state will be "CONNECTED".
	// 2. CONNECTED: ready to receive or send messages.
	// 3. WRITING: this is needed because we must receive an ack after sending
	// each message (so, before sending the next one). For this reason, many
	// subsequent "write" calls will result in different messages in the
	// writeQueue. After each new acknowledgement ('OKAY') a new one will be
	// sent. When the queue is empty, the state will return to CONNECTED.
	// 4. CLOSED: entered when the device closes the stream or close() is called.
	// For shell commands, the stream is closed after the command completed.
	export class AdbStreamImpl implements AdbStream {
	private adb: AdbOverWebUsb;
	localStreamId: number;
	private remoteStreamId = -1;
	private state: AdbStreamState = AdbStreamState.WAITING_INITIAL_OKAY;
	private writeQueue: Uint8Array[] = [];

	private sendInProgress = false;

	onData: AdbStreamReadCallback = (_) => {};
	onConnect = () => {};
	onClose = () => {};

	constructor(adb: AdbOverWebUsb, localStreamId: number) {
	this.adb = adb;
	this.localStreamId = localStreamId;
	}

	close() {
	console.assert(this.state === AdbStreamState.CONNECTED);

	if (this.writeQueue.length > 0) {
	console.error(`Dropping ${
	this.writeQueue.length} queued messages due to stream closing.`);
	this.writeQueue = [];
	}

	this.adb.send('CLSE', this.localStreamId, this.remoteStreamId);
	}

	async write(msg: string\|Uint8Array) {
	const raw = (typeof msg === 'string') ? textEncoder.encode(msg) : msg;
	if (this.sendInProgress \|\|
	this.state === AdbStreamState.WAITING_INITIAL_OKAY) {
	this.writeQueue.push(raw);
	return;
	}
	console.assert(this.state === AdbStreamState.CONNECTED);
	this.sendInProgress = true;
	await this.adb.send('WRTE', this.localStreamId, this.remoteStreamId, raw);
	}

	setClosed() {
	this.state = AdbStreamState.CLOSED;
	this.adb.streams.delete(this.localStreamId);
	this.onClose();
	}

	onMessage(msg: AdbMsgImpl) {
	console.assert(msg.arg1 === this.localStreamId);

	if (this.state === AdbStreamState.WAITING_INITIAL_OKAY &&
	msg.cmd === 'OKAY') {
	this.remoteStreamId = msg.arg0;
	this.state = AdbStreamState.CONNECTED;
	this.onConnect();
	return;
	}

	if (msg.cmd === 'WRTE') {
	this.adb.send('OKAY', this.localStreamId, this.remoteStreamId);
	this.onData(msg.data);
	return;
	}

	if (msg.cmd === 'OKAY') {
	console.assert(this.sendInProgress);
	this.sendInProgress = false;
	const queuedMsg = this.writeQueue.shift();
	if (queuedMsg !== undefined) this.write(queuedMsg);
	return;
	}

	if (msg.cmd === 'CLSE') {
	this.setClosed();
	return;
	}
	console.error(
	`Unexpected stream msg ${msg.toString()} in state ${this.state}`);
	}
	}

	interface AdbStreamReadCallback {
	(raw: Uint8Array): void;
	}

	const ADB_MSG_SIZE = 6 * 4; // 6 * int32.

	export class AdbMsgImpl implements AdbMsg {
	cmd: CmdType;
	arg0: number;
	arg1: number;
	data: Uint8Array;
	dataLen: number;
	dataChecksum: number;

	useChecksum: boolean;

	constructor(
	cmd: CmdType, arg0: number, arg1: number, dataLen: number,
	dataChecksum: number, useChecksum = false) {
	console.assert(cmd.length === 4);
	this.cmd = cmd;
	this.arg0 = arg0;
	this.arg1 = arg1;
	this.dataLen = dataLen;
	this.data = new Uint8Array(dataLen);
	this.dataChecksum = dataChecksum;
	this.useChecksum = useChecksum;
	}


	static create({cmd, arg0, arg1, data, useChecksum = true}: {
	cmd: CmdType; arg0: number; arg1: number;
	data?: Uint8Array \| string;
	useChecksum?: boolean;
	}): AdbMsgImpl {
	const encodedData = this.encodeData(data);
	const msg =
	new AdbMsgImpl(cmd, arg0, arg1, encodedData.length, 0, useChecksum);
	msg.data = encodedData;
	return msg;
	}

	get dataStr() {
	return textDecoder.decode(this.data);
	}

	toString() {
	return `${this.cmd} [${this.arg0},${this.arg1}] ${this.dataStr}`;
	}

	// A brief description of the message can be found here:
	// https://android.googlesource.com/platform/system/core/+/master/adb/protocol.txt
	//
	// struct amessage {
	// uint32_t command; // command identifier constant
	// uint32_t arg0; // first argument
	// uint32_t arg1; // second argument
	// uint32_t data_length;// length of payload (0 is allowed)
	// uint32_t data_check; // checksum of data payload
	// uint32_t magic; // command ^ 0xffffffff
	// };
	static decodeHeader(dv: DataView): AdbMsgImpl {
	console.assert(dv.byteLength === ADB_MSG_SIZE);
	const cmd = textDecoder.decode(dv.buffer.slice(0, 4)) as CmdType;
	const cmdNum = dv.getUint32(0, true);
	const arg0 = dv.getUint32(4, true);
	const arg1 = dv.getUint32(8, true);
	const dataLen = dv.getUint32(12, true);
	const dataChecksum = dv.getUint32(16, true);
	const cmdChecksum = dv.getUint32(20, true);
	console.assert(cmdNum === (cmdChecksum ^ 0xFFFFFFFF));
	return new AdbMsgImpl(cmd, arg0, arg1, dataLen, dataChecksum);
	}

	encodeHeader(): Uint8Array {
	const buf = new Uint8Array(ADB_MSG_SIZE);
	const dv = new DataView(buf.buffer);
	const cmdBytes: Uint8Array = textEncoder.encode(this.cmd);
	const rawMsg = AdbMsgImpl.encodeData(this.data);
	const checksum = this.useChecksum ? AdbOverWebUsb.checksum(rawMsg) : 0;
	for (let i = 0; i < 4; i++) dv.setUint8(i, cmdBytes[i]);

	dv.setUint32(4, this.arg0, true);
	dv.setUint32(8, this.arg1, true);
	dv.setUint32(12, rawMsg.byteLength, true);
	dv.setUint32(16, checksum, true);
	dv.setUint32(20, dv.getUint32(0, true) ^ 0xFFFFFFFF, true);

	return buf;
	}

	static encodeData(data?: Uint8Array\|string): Uint8Array {
	if (data === undefined) return new Uint8Array([]);
	if (typeof data === 'string') return textEncoder.encode(data + '\0');
	return data;
	}
	}


	function base64StringToArray(s: string) {
	const decoded = atob(s.replace(/-/g, '+').replace(/_/g, '/'));
	return [...decoded].map((char) => char.charCodeAt(0));
	}

	const ANDROID_PUBKEY_MODULUS_SIZE = 2048;
	const MODULUS_SIZE_BYTES = ANDROID_PUBKEY_MODULUS_SIZE / 8;

	// RSA Public keys are encoded in a rather unique way. It's a base64 encoded
	// struct of 524 bytes in total as follows (see
	// libcrypto_utils/android_pubkey.c):
	//
	// typedef struct RSAPublicKey {
	// // Modulus length. This must be ANDROID_PUBKEY_MODULUS_SIZE.
	// uint32_t modulus_size_words;
	//
	// // Precomputed montgomery parameter: -1 / n[0] mod 2^32
	// uint32_t n0inv;
	//
	// // RSA modulus as a little-endian array.
	// uint8_t modulus[ANDROID_PUBKEY_MODULUS_SIZE];
	//
	// // Montgomery parameter R^2 as a little-endian array of little-endian
	// words. uint8_t rr[ANDROID_PUBKEY_MODULUS_SIZE];
	//
	// // RSA modulus: 3 or 65537
	// uint32_t exponent;
	// } RSAPublicKey;
	//
	// However, the Montgomery params (n0inv and rr) are not really used, see
	// comment in android_pubkey_decode() ("Note that we don't extract the
	// montgomery parameters...")
	async function encodePubKey(key: CryptoKey) {
	const expPubKey = await crypto.subtle.exportKey('jwk', key);
	const nArr = base64StringToArray(expPubKey.n as string).reverse();
	const eArr = base64StringToArray(expPubKey.e as string).reverse();

	const arr = new Uint8Array(3 * 4 + 2 * MODULUS_SIZE_BYTES);
	const dv = new DataView(arr.buffer);
	dv.setUint32(0, MODULUS_SIZE_BYTES / 4, true);

	// The Mongomery params (n0inv and rr) are not computed.
	dv.setUint32(4, 0 /* n0inv*/, true);
	// Modulus
	for (let i = 0; i < MODULUS_SIZE_BYTES; i++) dv.setUint8(8 + i, nArr[i]);

	// rr:
	for (let i = 0; i < MODULUS_SIZE_BYTES; i++) {
	dv.setUint8(8 + MODULUS_SIZE_BYTES + i, 0 /* rr*/);
	}
	// Exponent
	for (let i = 0; i < 4; i++) {
	dv.setUint8(8 + (2 * MODULUS_SIZE_BYTES) + i, eArr[i]);
	}
	return btoa(String.fromCharCode(...new Uint8Array(dv.buffer))) +
	' perfetto@webusb';
	}

	// TODO(nicomazz): This token signature will be useful only when we save the
	// generated keys. So far, we are not doing so. As a consequence, a dialog is
	// displayed every time a tracing session is started.
	// The reason why it has not already been implemented is that the standard
	// crypto.subtle.sign function assumes that the input needs hashing, which is
	// not the case for ADB, where the 20 bytes token is already hashed.
	// A solution to this is implementing a custom private key signature with a js
	// implementation of big integers. Maybe, wrapping the key like in the following
	// CL can work:
	// https://android-review.googlesource.com/c/platform/external/perfetto/+/1105354/18
	async function signAdbTokenWithPrivateKey(
	_privateKey: CryptoKey, token: Uint8Array): Promise<ArrayBuffer> {
	// This function is not implemented.
	return token.buffer;
	}