1 /* 2 * Copyright (C) 2015 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17 #define TRACE_TAG SYSDEPS 18 19 #include "sysdeps.h" 20 21 #include <winsock2.h> /* winsock.h *must* be included before windows.h. */ 22 #include <windows.h> 23 24 #include <errno.h> 25 #include <stdio.h> 26 #include <stdlib.h> 27 28 #include <algorithm> 29 #include <memory> 30 #include <string> 31 #include <unordered_map> 32 #include <vector> 33 34 #include <cutils/sockets.h> 35 36 #include <android-base/errors.h> 37 #include <android-base/logging.h> 38 #include <android-base/stringprintf.h> 39 #include <android-base/strings.h> 40 #include <android-base/utf8.h> 41 42 #include "adb.h" 43 #include "adb_utils.h" 44 45 extern void fatal(const char *fmt, ...); 46 47 /* forward declarations */ 48 49 typedef const struct FHClassRec_* FHClass; 50 typedef struct FHRec_* FH; 51 typedef struct EventHookRec_* EventHook; 52 53 typedef struct FHClassRec_ { 54 void (*_fh_init)(FH); 55 int (*_fh_close)(FH); 56 int (*_fh_lseek)(FH, int, int); 57 int (*_fh_read)(FH, void*, int); 58 int (*_fh_write)(FH, const void*, int); 59 } FHClassRec; 60 61 static void _fh_file_init(FH); 62 static int _fh_file_close(FH); 63 static int _fh_file_lseek(FH, int, int); 64 static int _fh_file_read(FH, void*, int); 65 static int _fh_file_write(FH, const void*, int); 66 67 static const FHClassRec _fh_file_class = { 68 _fh_file_init, 69 _fh_file_close, 70 _fh_file_lseek, 71 _fh_file_read, 72 _fh_file_write, 73 }; 74 75 static void _fh_socket_init(FH); 76 static int _fh_socket_close(FH); 77 static int _fh_socket_lseek(FH, int, int); 78 static int _fh_socket_read(FH, void*, int); 79 static int _fh_socket_write(FH, const void*, int); 80 81 static const FHClassRec _fh_socket_class = { 82 _fh_socket_init, 83 _fh_socket_close, 84 _fh_socket_lseek, 85 _fh_socket_read, 86 _fh_socket_write, 87 }; 88 89 #define assert(cond) \ 90 do { \ 91 if (!(cond)) fatal("assertion failed '%s' on %s:%d\n", #cond, __FILE__, __LINE__); \ 92 } while (0) 93 94 void handle_deleter::operator()(HANDLE h) { 95 // CreateFile() is documented to return INVALID_HANDLE_FILE on error, 96 // implying that NULL is a valid handle, but this is probably impossible. 97 // Other APIs like CreateEvent() are documented to return NULL on error, 98 // implying that INVALID_HANDLE_VALUE is a valid handle, but this is also 99 // probably impossible. Thus, consider both NULL and INVALID_HANDLE_VALUE 100 // as invalid handles. std::unique_ptr won't call a deleter with NULL, so we 101 // only need to check for INVALID_HANDLE_VALUE. 102 if (h != INVALID_HANDLE_VALUE) { 103 if (!CloseHandle(h)) { 104 D("CloseHandle(%p) failed: %s", h, 105 android::base::SystemErrorCodeToString(GetLastError()).c_str()); 106 } 107 } 108 } 109 110 /**************************************************************************/ 111 /**************************************************************************/ 112 /***** *****/ 113 /***** replaces libs/cutils/load_file.c *****/ 114 /***** *****/ 115 /**************************************************************************/ 116 /**************************************************************************/ 117 118 void *load_file(const char *fn, unsigned *_sz) 119 { 120 HANDLE file; 121 char *data; 122 DWORD file_size; 123 124 std::wstring fn_wide; 125 if (!android::base::UTF8ToWide(fn, &fn_wide)) 126 return NULL; 127 128 file = CreateFileW( fn_wide.c_str(), 129 GENERIC_READ, 130 FILE_SHARE_READ, 131 NULL, 132 OPEN_EXISTING, 133 0, 134 NULL ); 135 136 if (file == INVALID_HANDLE_VALUE) 137 return NULL; 138 139 file_size = GetFileSize( file, NULL ); 140 data = NULL; 141 142 if (file_size > 0) { 143 data = (char*) malloc( file_size + 1 ); 144 if (data == NULL) { 145 D("load_file: could not allocate %ld bytes", file_size ); 146 file_size = 0; 147 } else { 148 DWORD out_bytes; 149 150 if ( !ReadFile( file, data, file_size, &out_bytes, NULL ) || 151 out_bytes != file_size ) 152 { 153 D("load_file: could not read %ld bytes from '%s'", file_size, fn); 154 free(data); 155 data = NULL; 156 file_size = 0; 157 } 158 } 159 } 160 CloseHandle( file ); 161 162 *_sz = (unsigned) file_size; 163 return data; 164 } 165 166 /**************************************************************************/ 167 /**************************************************************************/ 168 /***** *****/ 169 /***** common file descriptor handling *****/ 170 /***** *****/ 171 /**************************************************************************/ 172 /**************************************************************************/ 173 174 typedef struct FHRec_ 175 { 176 FHClass clazz; 177 int used; 178 int eof; 179 union { 180 HANDLE handle; 181 SOCKET socket; 182 } u; 183 184 int mask; 185 186 char name[32]; 187 188 } FHRec; 189 190 #define fh_handle u.handle 191 #define fh_socket u.socket 192 193 #define WIN32_FH_BASE 2048 194 #define WIN32_MAX_FHS 2048 195 196 static adb_mutex_t _win32_lock; 197 static FHRec _win32_fhs[ WIN32_MAX_FHS ]; 198 static int _win32_fh_next; // where to start search for free FHRec 199 200 static FH 201 _fh_from_int( int fd, const char* func ) 202 { 203 FH f; 204 205 fd -= WIN32_FH_BASE; 206 207 if (fd < 0 || fd >= WIN32_MAX_FHS) { 208 D( "_fh_from_int: invalid fd %d passed to %s", fd + WIN32_FH_BASE, 209 func ); 210 errno = EBADF; 211 return NULL; 212 } 213 214 f = &_win32_fhs[fd]; 215 216 if (f->used == 0) { 217 D( "_fh_from_int: invalid fd %d passed to %s", fd + WIN32_FH_BASE, 218 func ); 219 errno = EBADF; 220 return NULL; 221 } 222 223 return f; 224 } 225 226 227 static int 228 _fh_to_int( FH f ) 229 { 230 if (f && f->used && f >= _win32_fhs && f < _win32_fhs + WIN32_MAX_FHS) 231 return (int)(f - _win32_fhs) + WIN32_FH_BASE; 232 233 return -1; 234 } 235 236 static FH 237 _fh_alloc( FHClass clazz ) 238 { 239 FH f = NULL; 240 241 adb_mutex_lock( &_win32_lock ); 242 243 for (int i = _win32_fh_next; i < WIN32_MAX_FHS; ++i) { 244 if (_win32_fhs[i].clazz == NULL) { 245 f = &_win32_fhs[i]; 246 _win32_fh_next = i + 1; 247 goto Exit; 248 } 249 } 250 D( "_fh_alloc: no more free file descriptors" ); 251 errno = EMFILE; // Too many open files 252 Exit: 253 if (f) { 254 f->clazz = clazz; 255 f->used = 1; 256 f->eof = 0; 257 f->name[0] = '\0'; 258 clazz->_fh_init(f); 259 } 260 adb_mutex_unlock( &_win32_lock ); 261 return f; 262 } 263 264 265 static int 266 _fh_close( FH f ) 267 { 268 // Use lock so that closing only happens once and so that _fh_alloc can't 269 // allocate a FH that we're in the middle of closing. 270 adb_mutex_lock(&_win32_lock); 271 272 int offset = f - _win32_fhs; 273 if (_win32_fh_next > offset) { 274 _win32_fh_next = offset; 275 } 276 277 if (f->used) { 278 f->clazz->_fh_close( f ); 279 f->name[0] = '\0'; 280 f->eof = 0; 281 f->used = 0; 282 f->clazz = NULL; 283 } 284 adb_mutex_unlock(&_win32_lock); 285 return 0; 286 } 287 288 // Deleter for unique_fh. 289 class fh_deleter { 290 public: 291 void operator()(struct FHRec_* fh) { 292 // We're called from a destructor and destructors should not overwrite 293 // errno because callers may do: 294 // errno = EBLAH; 295 // return -1; // calls destructor, which should not overwrite errno 296 const int saved_errno = errno; 297 _fh_close(fh); 298 errno = saved_errno; 299 } 300 }; 301 302 // Like std::unique_ptr, but calls _fh_close() instead of operator delete(). 303 typedef std::unique_ptr<struct FHRec_, fh_deleter> unique_fh; 304 305 /**************************************************************************/ 306 /**************************************************************************/ 307 /***** *****/ 308 /***** file-based descriptor handling *****/ 309 /***** *****/ 310 /**************************************************************************/ 311 /**************************************************************************/ 312 313 static void _fh_file_init( FH f ) { 314 f->fh_handle = INVALID_HANDLE_VALUE; 315 } 316 317 static int _fh_file_close( FH f ) { 318 CloseHandle( f->fh_handle ); 319 f->fh_handle = INVALID_HANDLE_VALUE; 320 return 0; 321 } 322 323 static int _fh_file_read( FH f, void* buf, int len ) { 324 DWORD read_bytes; 325 326 if ( !ReadFile( f->fh_handle, buf, (DWORD)len, &read_bytes, NULL ) ) { 327 D( "adb_read: could not read %d bytes from %s", len, f->name ); 328 errno = EIO; 329 return -1; 330 } else if (read_bytes < (DWORD)len) { 331 f->eof = 1; 332 } 333 return (int)read_bytes; 334 } 335 336 static int _fh_file_write( FH f, const void* buf, int len ) { 337 DWORD wrote_bytes; 338 339 if ( !WriteFile( f->fh_handle, buf, (DWORD)len, &wrote_bytes, NULL ) ) { 340 D( "adb_file_write: could not write %d bytes from %s", len, f->name ); 341 errno = EIO; 342 return -1; 343 } else if (wrote_bytes < (DWORD)len) { 344 f->eof = 1; 345 } 346 return (int)wrote_bytes; 347 } 348 349 static int _fh_file_lseek( FH f, int pos, int origin ) { 350 DWORD method; 351 DWORD result; 352 353 switch (origin) 354 { 355 case SEEK_SET: method = FILE_BEGIN; break; 356 case SEEK_CUR: method = FILE_CURRENT; break; 357 case SEEK_END: method = FILE_END; break; 358 default: 359 errno = EINVAL; 360 return -1; 361 } 362 363 result = SetFilePointer( f->fh_handle, pos, NULL, method ); 364 if (result == INVALID_SET_FILE_POINTER) { 365 errno = EIO; 366 return -1; 367 } else { 368 f->eof = 0; 369 } 370 return (int)result; 371 } 372 373 374 /**************************************************************************/ 375 /**************************************************************************/ 376 /***** *****/ 377 /***** file-based descriptor handling *****/ 378 /***** *****/ 379 /**************************************************************************/ 380 /**************************************************************************/ 381 382 int adb_open(const char* path, int options) 383 { 384 FH f; 385 386 DWORD desiredAccess = 0; 387 DWORD shareMode = FILE_SHARE_READ | FILE_SHARE_WRITE; 388 389 switch (options) { 390 case O_RDONLY: 391 desiredAccess = GENERIC_READ; 392 break; 393 case O_WRONLY: 394 desiredAccess = GENERIC_WRITE; 395 break; 396 case O_RDWR: 397 desiredAccess = GENERIC_READ | GENERIC_WRITE; 398 break; 399 default: 400 D("adb_open: invalid options (0x%0x)", options); 401 errno = EINVAL; 402 return -1; 403 } 404 405 f = _fh_alloc( &_fh_file_class ); 406 if ( !f ) { 407 return -1; 408 } 409 410 std::wstring path_wide; 411 if (!android::base::UTF8ToWide(path, &path_wide)) { 412 return -1; 413 } 414 f->fh_handle = CreateFileW( path_wide.c_str(), desiredAccess, shareMode, 415 NULL, OPEN_EXISTING, 0, NULL ); 416 417 if ( f->fh_handle == INVALID_HANDLE_VALUE ) { 418 const DWORD err = GetLastError(); 419 _fh_close(f); 420 D( "adb_open: could not open '%s': ", path ); 421 switch (err) { 422 case ERROR_FILE_NOT_FOUND: 423 D( "file not found" ); 424 errno = ENOENT; 425 return -1; 426 427 case ERROR_PATH_NOT_FOUND: 428 D( "path not found" ); 429 errno = ENOTDIR; 430 return -1; 431 432 default: 433 D("unknown error: %s", android::base::SystemErrorCodeToString(err).c_str()); 434 errno = ENOENT; 435 return -1; 436 } 437 } 438 439 snprintf( f->name, sizeof(f->name), "%d(%s)", _fh_to_int(f), path ); 440 D( "adb_open: '%s' => fd %d", path, _fh_to_int(f) ); 441 return _fh_to_int(f); 442 } 443 444 /* ignore mode on Win32 */ 445 int adb_creat(const char* path, int mode) 446 { 447 FH f; 448 449 f = _fh_alloc( &_fh_file_class ); 450 if ( !f ) { 451 return -1; 452 } 453 454 std::wstring path_wide; 455 if (!android::base::UTF8ToWide(path, &path_wide)) { 456 return -1; 457 } 458 f->fh_handle = CreateFileW( path_wide.c_str(), GENERIC_WRITE, 459 FILE_SHARE_READ | FILE_SHARE_WRITE, 460 NULL, CREATE_ALWAYS, FILE_ATTRIBUTE_NORMAL, 461 NULL ); 462 463 if ( f->fh_handle == INVALID_HANDLE_VALUE ) { 464 const DWORD err = GetLastError(); 465 _fh_close(f); 466 D( "adb_creat: could not open '%s': ", path ); 467 switch (err) { 468 case ERROR_FILE_NOT_FOUND: 469 D( "file not found" ); 470 errno = ENOENT; 471 return -1; 472 473 case ERROR_PATH_NOT_FOUND: 474 D( "path not found" ); 475 errno = ENOTDIR; 476 return -1; 477 478 default: 479 D("unknown error: %s", android::base::SystemErrorCodeToString(err).c_str()); 480 errno = ENOENT; 481 return -1; 482 } 483 } 484 snprintf( f->name, sizeof(f->name), "%d(%s)", _fh_to_int(f), path ); 485 D( "adb_creat: '%s' => fd %d", path, _fh_to_int(f) ); 486 return _fh_to_int(f); 487 } 488 489 490 int adb_read(int fd, void* buf, int len) 491 { 492 FH f = _fh_from_int(fd, __func__); 493 494 if (f == NULL) { 495 return -1; 496 } 497 498 return f->clazz->_fh_read( f, buf, len ); 499 } 500 501 502 int adb_write(int fd, const void* buf, int len) 503 { 504 FH f = _fh_from_int(fd, __func__); 505 506 if (f == NULL) { 507 return -1; 508 } 509 510 return f->clazz->_fh_write(f, buf, len); 511 } 512 513 514 int adb_lseek(int fd, int pos, int where) 515 { 516 FH f = _fh_from_int(fd, __func__); 517 518 if (!f) { 519 return -1; 520 } 521 522 return f->clazz->_fh_lseek(f, pos, where); 523 } 524 525 526 int adb_close(int fd) 527 { 528 FH f = _fh_from_int(fd, __func__); 529 530 if (!f) { 531 return -1; 532 } 533 534 D( "adb_close: %s", f->name); 535 _fh_close(f); 536 return 0; 537 } 538 539 // Overrides strerror() to handle error codes not supported by the Windows C 540 // Runtime (MSVCRT.DLL). 541 char* adb_strerror(int err) { 542 // sysdeps.h defines strerror to adb_strerror, but in this function, we 543 // want to call the real C Runtime strerror(). 544 #pragma push_macro("strerror") 545 #undef strerror 546 const int saved_err = errno; // Save because we overwrite it later. 547 548 // Lookup the string for an unknown error. 549 char* errmsg = strerror(-1); 550 const std::string unknown_error = (errmsg == nullptr) ? "" : errmsg; 551 552 // Lookup the string for this error to see if the C Runtime has it. 553 errmsg = strerror(err); 554 if (errmsg != nullptr && unknown_error != errmsg) { 555 // The CRT returned an error message and it is different than the error 556 // message for an unknown error, so it is probably valid, so use it. 557 } else { 558 // Check if we have a string for this error code. 559 const char* custom_msg = nullptr; 560 switch (err) { 561 #pragma push_macro("ERR") 562 #undef ERR 563 #define ERR(errnum, desc) case errnum: custom_msg = desc; break 564 // These error strings are from AOSP bionic/libc/include/sys/_errdefs.h. 565 // Note that these cannot be longer than 94 characters because we 566 // pass this to _strerror() which has that requirement. 567 ERR(ECONNRESET, "Connection reset by peer"); 568 ERR(EHOSTUNREACH, "No route to host"); 569 ERR(ENETDOWN, "Network is down"); 570 ERR(ENETRESET, "Network dropped connection because of reset"); 571 ERR(ENOBUFS, "No buffer space available"); 572 ERR(ENOPROTOOPT, "Protocol not available"); 573 ERR(ENOTCONN, "Transport endpoint is not connected"); 574 ERR(ENOTSOCK, "Socket operation on non-socket"); 575 ERR(EOPNOTSUPP, "Operation not supported on transport endpoint"); 576 #pragma pop_macro("ERR") 577 } 578 579 if (custom_msg != nullptr) { 580 // Use _strerror() to write our string into the writable per-thread 581 // buffer used by strerror()/_strerror(). _strerror() appends the 582 // msg for the current value of errno, so set errno to a consistent 583 // value for every call so that our code-path is always the same. 584 errno = 0; 585 errmsg = _strerror(custom_msg); 586 const size_t custom_msg_len = strlen(custom_msg); 587 // Just in case _strerror() returned a read-only string, check if 588 // the returned string starts with our custom message because that 589 // implies that the string is not read-only. 590 if ((errmsg != nullptr) && 591 !strncmp(custom_msg, errmsg, custom_msg_len)) { 592 // _strerror() puts other text after our custom message, so 593 // remove that by terminating after our message. 594 errmsg[custom_msg_len] = '\0'; 595 } else { 596 // For some reason nullptr was returned or a pointer to a 597 // read-only string was returned, so fallback to whatever 598 // strerror() can muster (probably "Unknown error" or some 599 // generic CRT error string). 600 errmsg = strerror(err); 601 } 602 } else { 603 // We don't have a custom message, so use whatever strerror(err) 604 // returned earlier. 605 } 606 } 607 608 errno = saved_err; // restore 609 610 return errmsg; 611 #pragma pop_macro("strerror") 612 } 613 614 /**************************************************************************/ 615 /**************************************************************************/ 616 /***** *****/ 617 /***** socket-based file descriptors *****/ 618 /***** *****/ 619 /**************************************************************************/ 620 /**************************************************************************/ 621 622 #undef setsockopt 623 624 static void _socket_set_errno( const DWORD err ) { 625 // Because the Windows C Runtime (MSVCRT.DLL) strerror() does not support a 626 // lot of POSIX and socket error codes, some of the resulting error codes 627 // are mapped to strings by adb_strerror() above. 628 switch ( err ) { 629 case 0: errno = 0; break; 630 // Don't map WSAEINTR since that is only for Winsock 1.1 which we don't use. 631 // case WSAEINTR: errno = EINTR; break; 632 case WSAEFAULT: errno = EFAULT; break; 633 case WSAEINVAL: errno = EINVAL; break; 634 case WSAEMFILE: errno = EMFILE; break; 635 // Mapping WSAEWOULDBLOCK to EAGAIN is absolutely critical because 636 // non-blocking sockets can cause an error code of WSAEWOULDBLOCK and 637 // callers check specifically for EAGAIN. 638 case WSAEWOULDBLOCK: errno = EAGAIN; break; 639 case WSAENOTSOCK: errno = ENOTSOCK; break; 640 case WSAENOPROTOOPT: errno = ENOPROTOOPT; break; 641 case WSAEOPNOTSUPP: errno = EOPNOTSUPP; break; 642 case WSAENETDOWN: errno = ENETDOWN; break; 643 case WSAENETRESET: errno = ENETRESET; break; 644 // Map WSAECONNABORTED to EPIPE instead of ECONNABORTED because POSIX seems 645 // to use EPIPE for these situations and there are some callers that look 646 // for EPIPE. 647 case WSAECONNABORTED: errno = EPIPE; break; 648 case WSAECONNRESET: errno = ECONNRESET; break; 649 case WSAENOBUFS: errno = ENOBUFS; break; 650 case WSAENOTCONN: errno = ENOTCONN; break; 651 // Don't map WSAETIMEDOUT because we don't currently use SO_RCVTIMEO or 652 // SO_SNDTIMEO which would cause WSAETIMEDOUT to be returned. Future 653 // considerations: Reportedly send() can return zero on timeout, and POSIX 654 // code may expect EAGAIN instead of ETIMEDOUT on timeout. 655 // case WSAETIMEDOUT: errno = ETIMEDOUT; break; 656 case WSAEHOSTUNREACH: errno = EHOSTUNREACH; break; 657 default: 658 errno = EINVAL; 659 D( "_socket_set_errno: mapping Windows error code %lu to errno %d", 660 err, errno ); 661 } 662 } 663 664 extern int adb_poll(adb_pollfd* fds, size_t nfds, int timeout) { 665 // WSAPoll doesn't handle invalid/non-socket handles, so we need to handle them ourselves. 666 int skipped = 0; 667 std::vector<WSAPOLLFD> sockets; 668 std::vector<adb_pollfd*> original; 669 for (size_t i = 0; i < nfds; ++i) { 670 FH fh = _fh_from_int(fds[i].fd, __func__); 671 if (!fh || !fh->used || fh->clazz != &_fh_socket_class) { 672 D("adb_poll received bad FD %d", fds[i].fd); 673 fds[i].revents = POLLNVAL; 674 ++skipped; 675 } else { 676 WSAPOLLFD wsapollfd = { 677 .fd = fh->u.socket, 678 .events = static_cast<short>(fds[i].events) 679 }; 680 sockets.push_back(wsapollfd); 681 original.push_back(&fds[i]); 682 } 683 } 684 685 if (sockets.empty()) { 686 return skipped; 687 } 688 689 int result = WSAPoll(sockets.data(), sockets.size(), timeout); 690 if (result == SOCKET_ERROR) { 691 _socket_set_errno(WSAGetLastError()); 692 return -1; 693 } 694 695 // Map the results back onto the original set. 696 for (size_t i = 0; i < sockets.size(); ++i) { 697 original[i]->revents = sockets[i].revents; 698 } 699 700 // WSAPoll appears to return the number of unique FDs with avaiable events, instead of how many 701 // of the pollfd elements have a non-zero revents field, which is what it and poll are specified 702 // to do. Ignore its result and calculate the proper return value. 703 result = 0; 704 for (size_t i = 0; i < nfds; ++i) { 705 if (fds[i].revents != 0) { 706 ++result; 707 } 708 } 709 return result; 710 } 711 712 static void _fh_socket_init(FH f) { 713 f->fh_socket = INVALID_SOCKET; 714 f->mask = 0; 715 } 716 717 static int _fh_socket_close( FH f ) { 718 if (f->fh_socket != INVALID_SOCKET) { 719 /* gently tell any peer that we're closing the socket */ 720 if (shutdown(f->fh_socket, SD_BOTH) == SOCKET_ERROR) { 721 // If the socket is not connected, this returns an error. We want to 722 // minimize logging spam, so don't log these errors for now. 723 #if 0 724 D("socket shutdown failed: %s", 725 android::base::SystemErrorCodeToString(WSAGetLastError()).c_str()); 726 #endif 727 } 728 if (closesocket(f->fh_socket) == SOCKET_ERROR) { 729 // Don't set errno here, since adb_close will ignore it. 730 const DWORD err = WSAGetLastError(); 731 D("closesocket failed: %s", android::base::SystemErrorCodeToString(err).c_str()); 732 } 733 f->fh_socket = INVALID_SOCKET; 734 } 735 f->mask = 0; 736 return 0; 737 } 738 739 static int _fh_socket_lseek( FH f, int pos, int origin ) { 740 errno = EPIPE; 741 return -1; 742 } 743 744 static int _fh_socket_read(FH f, void* buf, int len) { 745 int result = recv(f->fh_socket, reinterpret_cast<char*>(buf), len, 0); 746 if (result == SOCKET_ERROR) { 747 const DWORD err = WSAGetLastError(); 748 // WSAEWOULDBLOCK is normal with a non-blocking socket, so don't trace 749 // that to reduce spam and confusion. 750 if (err != WSAEWOULDBLOCK) { 751 D("recv fd %d failed: %s", _fh_to_int(f), 752 android::base::SystemErrorCodeToString(err).c_str()); 753 } 754 _socket_set_errno(err); 755 result = -1; 756 } 757 return result; 758 } 759 760 static int _fh_socket_write(FH f, const void* buf, int len) { 761 int result = send(f->fh_socket, reinterpret_cast<const char*>(buf), len, 0); 762 if (result == SOCKET_ERROR) { 763 const DWORD err = WSAGetLastError(); 764 // WSAEWOULDBLOCK is normal with a non-blocking socket, so don't trace 765 // that to reduce spam and confusion. 766 if (err != WSAEWOULDBLOCK) { 767 D("send fd %d failed: %s", _fh_to_int(f), 768 android::base::SystemErrorCodeToString(err).c_str()); 769 } 770 _socket_set_errno(err); 771 result = -1; 772 } else { 773 // According to https://code.google.com/p/chromium/issues/detail?id=27870 774 // Winsock Layered Service Providers may cause this. 775 CHECK_LE(result, len) << "Tried to write " << len << " bytes to " 776 << f->name << ", but " << result 777 << " bytes reportedly written"; 778 } 779 return result; 780 } 781 782 /**************************************************************************/ 783 /**************************************************************************/ 784 /***** *****/ 785 /***** replacement for libs/cutils/socket_xxxx.c *****/ 786 /***** *****/ 787 /**************************************************************************/ 788 /**************************************************************************/ 789 790 #include <winsock2.h> 791 792 static int _winsock_init; 793 794 static void 795 _init_winsock( void ) 796 { 797 // TODO: Multiple threads calling this may potentially cause multiple calls 798 // to WSAStartup() which offers no real benefit. 799 if (!_winsock_init) { 800 WSADATA wsaData; 801 int rc = WSAStartup( MAKEWORD(2,2), &wsaData); 802 if (rc != 0) { 803 fatal("adb: could not initialize Winsock: %s", 804 android::base::SystemErrorCodeToString(rc).c_str()); 805 } 806 _winsock_init = 1; 807 808 // Note that we do not call atexit() to register WSACleanup to be called 809 // at normal process termination because: 810 // 1) When exit() is called, there are still threads actively using 811 // Winsock because we don't cleanly shutdown all threads, so it 812 // doesn't make sense to call WSACleanup() and may cause problems 813 // with those threads. 814 // 2) A deadlock can occur when exit() holds a C Runtime lock, then it 815 // calls WSACleanup() which tries to unload a DLL, which tries to 816 // grab the LoaderLock. This conflicts with the device_poll_thread 817 // which holds the LoaderLock because AdbWinApi.dll calls 818 // setupapi.dll which tries to load wintrust.dll which tries to load 819 // crypt32.dll which calls atexit() which tries to acquire the C 820 // Runtime lock that the other thread holds. 821 } 822 } 823 824 // Map a socket type to an explicit socket protocol instead of using the socket 825 // protocol of 0. Explicit socket protocols are used by most apps and we should 826 // do the same to reduce the chance of exercising uncommon code-paths that might 827 // have problems or that might load different Winsock service providers that 828 // have problems. 829 static int GetSocketProtocolFromSocketType(int type) { 830 switch (type) { 831 case SOCK_STREAM: 832 return IPPROTO_TCP; 833 case SOCK_DGRAM: 834 return IPPROTO_UDP; 835 default: 836 LOG(FATAL) << "Unknown socket type: " << type; 837 return 0; 838 } 839 } 840 841 int network_loopback_client(int port, int type, std::string* error) { 842 struct sockaddr_in addr; 843 SOCKET s; 844 845 unique_fh f(_fh_alloc(&_fh_socket_class)); 846 if (!f) { 847 *error = strerror(errno); 848 return -1; 849 } 850 851 if (!_winsock_init) _init_winsock(); 852 853 memset(&addr, 0, sizeof(addr)); 854 addr.sin_family = AF_INET; 855 addr.sin_port = htons(port); 856 addr.sin_addr.s_addr = htonl(INADDR_LOOPBACK); 857 858 s = socket(AF_INET, type, GetSocketProtocolFromSocketType(type)); 859 if (s == INVALID_SOCKET) { 860 const DWORD err = WSAGetLastError(); 861 *error = android::base::StringPrintf("cannot create socket: %s", 862 android::base::SystemErrorCodeToString(err).c_str()); 863 D("%s", error->c_str()); 864 _socket_set_errno(err); 865 return -1; 866 } 867 f->fh_socket = s; 868 869 if (connect(s, (struct sockaddr*)&addr, sizeof(addr)) == SOCKET_ERROR) { 870 // Save err just in case inet_ntoa() or ntohs() changes the last error. 871 const DWORD err = WSAGetLastError(); 872 *error = android::base::StringPrintf("cannot connect to %s:%u: %s", 873 inet_ntoa(addr.sin_addr), ntohs(addr.sin_port), 874 android::base::SystemErrorCodeToString(err).c_str()); 875 D("could not connect to %s:%d: %s", type != SOCK_STREAM ? "udp" : "tcp", port, 876 error->c_str()); 877 _socket_set_errno(err); 878 return -1; 879 } 880 881 const int fd = _fh_to_int(f.get()); 882 snprintf(f->name, sizeof(f->name), "%d(lo-client:%s%d)", fd, type != SOCK_STREAM ? "udp:" : "", 883 port); 884 D("port %d type %s => fd %d", port, type != SOCK_STREAM ? "udp" : "tcp", fd); 885 f.release(); 886 return fd; 887 } 888 889 #define LISTEN_BACKLOG 4 890 891 // interface_address is INADDR_LOOPBACK or INADDR_ANY. 892 static int _network_server(int port, int type, u_long interface_address, std::string* error) { 893 struct sockaddr_in addr; 894 SOCKET s; 895 int n; 896 897 unique_fh f(_fh_alloc(&_fh_socket_class)); 898 if (!f) { 899 *error = strerror(errno); 900 return -1; 901 } 902 903 if (!_winsock_init) _init_winsock(); 904 905 memset(&addr, 0, sizeof(addr)); 906 addr.sin_family = AF_INET; 907 addr.sin_port = htons(port); 908 addr.sin_addr.s_addr = htonl(interface_address); 909 910 // TODO: Consider using dual-stack socket that can simultaneously listen on 911 // IPv4 and IPv6. 912 s = socket(AF_INET, type, GetSocketProtocolFromSocketType(type)); 913 if (s == INVALID_SOCKET) { 914 const DWORD err = WSAGetLastError(); 915 *error = android::base::StringPrintf("cannot create socket: %s", 916 android::base::SystemErrorCodeToString(err).c_str()); 917 D("%s", error->c_str()); 918 _socket_set_errno(err); 919 return -1; 920 } 921 922 f->fh_socket = s; 923 924 // Note: SO_REUSEADDR on Windows allows multiple processes to bind to the 925 // same port, so instead use SO_EXCLUSIVEADDRUSE. 926 n = 1; 927 if (setsockopt(s, SOL_SOCKET, SO_EXCLUSIVEADDRUSE, (const char*)&n, sizeof(n)) == SOCKET_ERROR) { 928 const DWORD err = WSAGetLastError(); 929 *error = android::base::StringPrintf("cannot set socket option SO_EXCLUSIVEADDRUSE: %s", 930 android::base::SystemErrorCodeToString(err).c_str()); 931 D("%s", error->c_str()); 932 _socket_set_errno(err); 933 return -1; 934 } 935 936 if (bind(s, (struct sockaddr*)&addr, sizeof(addr)) == SOCKET_ERROR) { 937 // Save err just in case inet_ntoa() or ntohs() changes the last error. 938 const DWORD err = WSAGetLastError(); 939 *error = android::base::StringPrintf("cannot bind to %s:%u: %s", inet_ntoa(addr.sin_addr), 940 ntohs(addr.sin_port), 941 android::base::SystemErrorCodeToString(err).c_str()); 942 D("could not bind to %s:%d: %s", type != SOCK_STREAM ? "udp" : "tcp", port, error->c_str()); 943 _socket_set_errno(err); 944 return -1; 945 } 946 if (type == SOCK_STREAM) { 947 if (listen(s, LISTEN_BACKLOG) == SOCKET_ERROR) { 948 const DWORD err = WSAGetLastError(); 949 *error = android::base::StringPrintf( 950 "cannot listen on socket: %s", android::base::SystemErrorCodeToString(err).c_str()); 951 D("could not listen on %s:%d: %s", type != SOCK_STREAM ? "udp" : "tcp", port, 952 error->c_str()); 953 _socket_set_errno(err); 954 return -1; 955 } 956 } 957 const int fd = _fh_to_int(f.get()); 958 snprintf(f->name, sizeof(f->name), "%d(%s-server:%s%d)", fd, 959 interface_address == INADDR_LOOPBACK ? "lo" : "any", type != SOCK_STREAM ? "udp:" : "", 960 port); 961 D("port %d type %s => fd %d", port, type != SOCK_STREAM ? "udp" : "tcp", fd); 962 f.release(); 963 return fd; 964 } 965 966 int network_loopback_server(int port, int type, std::string* error) { 967 return _network_server(port, type, INADDR_LOOPBACK, error); 968 } 969 970 int network_inaddr_any_server(int port, int type, std::string* error) { 971 return _network_server(port, type, INADDR_ANY, error); 972 } 973 974 int network_connect(const std::string& host, int port, int type, int timeout, std::string* error) { 975 unique_fh f(_fh_alloc(&_fh_socket_class)); 976 if (!f) { 977 *error = strerror(errno); 978 return -1; 979 } 980 981 if (!_winsock_init) _init_winsock(); 982 983 struct addrinfo hints; 984 memset(&hints, 0, sizeof(hints)); 985 hints.ai_family = AF_UNSPEC; 986 hints.ai_socktype = type; 987 hints.ai_protocol = GetSocketProtocolFromSocketType(type); 988 989 char port_str[16]; 990 snprintf(port_str, sizeof(port_str), "%d", port); 991 992 struct addrinfo* addrinfo_ptr = nullptr; 993 994 #if (NTDDI_VERSION >= NTDDI_WINXPSP2) || (_WIN32_WINNT >= _WIN32_WINNT_WS03) 995 // TODO: When the Android SDK tools increases the Windows system 996 // requirements >= WinXP SP2, switch to android::base::UTF8ToWide() + GetAddrInfoW(). 997 #else 998 // Otherwise, keep using getaddrinfo(), or do runtime API detection 999 // with GetProcAddress("GetAddrInfoW"). 1000 #endif 1001 if (getaddrinfo(host.c_str(), port_str, &hints, &addrinfo_ptr) != 0) { 1002 const DWORD err = WSAGetLastError(); 1003 *error = android::base::StringPrintf("cannot resolve host '%s' and port %s: %s", 1004 host.c_str(), port_str, 1005 android::base::SystemErrorCodeToString(err).c_str()); 1006 1007 D("%s", error->c_str()); 1008 _socket_set_errno(err); 1009 return -1; 1010 } 1011 std::unique_ptr<struct addrinfo, decltype(freeaddrinfo)*> addrinfo(addrinfo_ptr, freeaddrinfo); 1012 addrinfo_ptr = nullptr; 1013 1014 // TODO: Try all the addresses if there's more than one? This just uses 1015 // the first. Or, could call WSAConnectByName() (Windows Vista and newer) 1016 // which tries all addresses, takes a timeout and more. 1017 SOCKET s = socket(addrinfo->ai_family, addrinfo->ai_socktype, addrinfo->ai_protocol); 1018 if (s == INVALID_SOCKET) { 1019 const DWORD err = WSAGetLastError(); 1020 *error = android::base::StringPrintf("cannot create socket: %s", 1021 android::base::SystemErrorCodeToString(err).c_str()); 1022 D("%s", error->c_str()); 1023 _socket_set_errno(err); 1024 return -1; 1025 } 1026 f->fh_socket = s; 1027 1028 // TODO: Implement timeouts for Windows. Seems like the default in theory 1029 // (according to http://serverfault.com/a/671453) and in practice is 21 sec. 1030 if (connect(s, addrinfo->ai_addr, addrinfo->ai_addrlen) == SOCKET_ERROR) { 1031 // TODO: Use WSAAddressToString or inet_ntop on address. 1032 const DWORD err = WSAGetLastError(); 1033 *error = android::base::StringPrintf("cannot connect to %s:%s: %s", host.c_str(), port_str, 1034 android::base::SystemErrorCodeToString(err).c_str()); 1035 D("could not connect to %s:%s:%s: %s", type != SOCK_STREAM ? "udp" : "tcp", host.c_str(), 1036 port_str, error->c_str()); 1037 _socket_set_errno(err); 1038 return -1; 1039 } 1040 1041 const int fd = _fh_to_int(f.get()); 1042 snprintf(f->name, sizeof(f->name), "%d(net-client:%s%d)", fd, type != SOCK_STREAM ? "udp:" : "", 1043 port); 1044 D("host '%s' port %d type %s => fd %d", host.c_str(), port, type != SOCK_STREAM ? "udp" : "tcp", 1045 fd); 1046 f.release(); 1047 return fd; 1048 } 1049 1050 #undef accept 1051 int adb_socket_accept(int serverfd, struct sockaddr* addr, socklen_t *addrlen) 1052 { 1053 FH serverfh = _fh_from_int(serverfd, __func__); 1054 1055 if ( !serverfh || serverfh->clazz != &_fh_socket_class ) { 1056 D("adb_socket_accept: invalid fd %d", serverfd); 1057 errno = EBADF; 1058 return -1; 1059 } 1060 1061 unique_fh fh(_fh_alloc( &_fh_socket_class )); 1062 if (!fh) { 1063 PLOG(ERROR) << "adb_socket_accept: failed to allocate accepted socket " 1064 "descriptor"; 1065 return -1; 1066 } 1067 1068 fh->fh_socket = accept( serverfh->fh_socket, addr, addrlen ); 1069 if (fh->fh_socket == INVALID_SOCKET) { 1070 const DWORD err = WSAGetLastError(); 1071 LOG(ERROR) << "adb_socket_accept: accept on fd " << serverfd << 1072 " failed: " + android::base::SystemErrorCodeToString(err); 1073 _socket_set_errno( err ); 1074 return -1; 1075 } 1076 1077 const int fd = _fh_to_int(fh.get()); 1078 snprintf( fh->name, sizeof(fh->name), "%d(accept:%s)", fd, serverfh->name ); 1079 D( "adb_socket_accept on fd %d returns fd %d", serverfd, fd ); 1080 fh.release(); 1081 return fd; 1082 } 1083 1084 1085 int adb_setsockopt( int fd, int level, int optname, const void* optval, socklen_t optlen ) 1086 { 1087 FH fh = _fh_from_int(fd, __func__); 1088 1089 if ( !fh || fh->clazz != &_fh_socket_class ) { 1090 D("adb_setsockopt: invalid fd %d", fd); 1091 errno = EBADF; 1092 return -1; 1093 } 1094 1095 // TODO: Once we can assume Windows Vista or later, if the caller is trying 1096 // to set SOL_SOCKET, SO_SNDBUF/SO_RCVBUF, ignore it since the OS has 1097 // auto-tuning. 1098 1099 int result = setsockopt( fh->fh_socket, level, optname, 1100 reinterpret_cast<const char*>(optval), optlen ); 1101 if ( result == SOCKET_ERROR ) { 1102 const DWORD err = WSAGetLastError(); 1103 D("adb_setsockopt: setsockopt on fd %d level %d optname %d failed: %s\n", 1104 fd, level, optname, android::base::SystemErrorCodeToString(err).c_str()); 1105 _socket_set_errno( err ); 1106 result = -1; 1107 } 1108 return result; 1109 } 1110 1111 int adb_getsockname(int fd, struct sockaddr* sockaddr, socklen_t* optlen) { 1112 FH fh = _fh_from_int(fd, __func__); 1113 1114 if (!fh || fh->clazz != &_fh_socket_class) { 1115 D("adb_getsockname: invalid fd %d", fd); 1116 errno = EBADF; 1117 return -1; 1118 } 1119 1120 int result = getsockname(fh->fh_socket, sockaddr, optlen); 1121 if (result == SOCKET_ERROR) { 1122 const DWORD err = WSAGetLastError(); 1123 D("adb_getsockname: setsockopt on fd %d failed: %s\n", fd, 1124 android::base::SystemErrorCodeToString(err).c_str()); 1125 _socket_set_errno(err); 1126 result = -1; 1127 } 1128 return result; 1129 } 1130 1131 int adb_shutdown(int fd) 1132 { 1133 FH f = _fh_from_int(fd, __func__); 1134 1135 if (!f || f->clazz != &_fh_socket_class) { 1136 D("adb_shutdown: invalid fd %d", fd); 1137 errno = EBADF; 1138 return -1; 1139 } 1140 1141 D( "adb_shutdown: %s", f->name); 1142 if (shutdown(f->fh_socket, SD_BOTH) == SOCKET_ERROR) { 1143 const DWORD err = WSAGetLastError(); 1144 D("socket shutdown fd %d failed: %s", fd, 1145 android::base::SystemErrorCodeToString(err).c_str()); 1146 _socket_set_errno(err); 1147 return -1; 1148 } 1149 return 0; 1150 } 1151 1152 // Emulate socketpair(2) by binding and connecting to a socket. 1153 int adb_socketpair(int sv[2]) { 1154 int server = -1; 1155 int client = -1; 1156 int accepted = -1; 1157 sockaddr_storage addr_storage; 1158 socklen_t addr_len = sizeof(addr_storage); 1159 sockaddr_in* addr = nullptr; 1160 std::string error; 1161 1162 server = network_loopback_server(0, SOCK_STREAM, &error); 1163 if (server < 0) { 1164 D("adb_socketpair: failed to create server: %s", error.c_str()); 1165 goto fail; 1166 } 1167 1168 if (adb_getsockname(server, reinterpret_cast<sockaddr*>(&addr_storage), &addr_len) < 0) { 1169 D("adb_socketpair: adb_getsockname failed: %s", strerror(errno)); 1170 goto fail; 1171 } 1172 1173 if (addr_storage.ss_family != AF_INET) { 1174 D("adb_socketpair: unknown address family received: %d", addr_storage.ss_family); 1175 errno = ECONNABORTED; 1176 goto fail; 1177 } 1178 1179 addr = reinterpret_cast<sockaddr_in*>(&addr_storage); 1180 D("adb_socketpair: bound on port %d", ntohs(addr->sin_port)); 1181 client = network_loopback_client(ntohs(addr->sin_port), SOCK_STREAM, &error); 1182 if (client < 0) { 1183 D("adb_socketpair: failed to connect client: %s", error.c_str()); 1184 goto fail; 1185 } 1186 1187 accepted = adb_socket_accept(server, nullptr, nullptr); 1188 if (accepted < 0) { 1189 D("adb_socketpair: failed to accept: %s", strerror(errno)); 1190 goto fail; 1191 } 1192 adb_close(server); 1193 sv[0] = client; 1194 sv[1] = accepted; 1195 return 0; 1196 1197 fail: 1198 if (server >= 0) { 1199 adb_close(server); 1200 } 1201 if (client >= 0) { 1202 adb_close(client); 1203 } 1204 if (accepted >= 0) { 1205 adb_close(accepted); 1206 } 1207 return -1; 1208 } 1209 1210 bool set_file_block_mode(int fd, bool block) { 1211 FH fh = _fh_from_int(fd, __func__); 1212 1213 if (!fh || !fh->used) { 1214 errno = EBADF; 1215 return false; 1216 } 1217 1218 if (fh->clazz == &_fh_socket_class) { 1219 u_long x = !block; 1220 if (ioctlsocket(fh->u.socket, FIONBIO, &x) != 0) { 1221 _socket_set_errno(WSAGetLastError()); 1222 return false; 1223 } 1224 return true; 1225 } else { 1226 errno = ENOTSOCK; 1227 return false; 1228 } 1229 } 1230 1231 bool set_tcp_keepalive(int fd, int interval_sec) { 1232 FH fh = _fh_from_int(fd, __func__); 1233 1234 if (!fh || fh->clazz != &_fh_socket_class) { 1235 D("set_tcp_keepalive(%d) failed: invalid fd", fd); 1236 errno = EBADF; 1237 return false; 1238 } 1239 1240 tcp_keepalive keepalive; 1241 keepalive.onoff = (interval_sec > 0); 1242 keepalive.keepalivetime = interval_sec * 1000; 1243 keepalive.keepaliveinterval = interval_sec * 1000; 1244 1245 DWORD bytes_returned = 0; 1246 if (WSAIoctl(fh->fh_socket, SIO_KEEPALIVE_VALS, &keepalive, sizeof(keepalive), nullptr, 0, 1247 &bytes_returned, nullptr, nullptr) != 0) { 1248 const DWORD err = WSAGetLastError(); 1249 D("set_tcp_keepalive(%d) failed: %s", fd, 1250 android::base::SystemErrorCodeToString(err).c_str()); 1251 _socket_set_errno(err); 1252 return false; 1253 } 1254 1255 return true; 1256 } 1257 1258 static adb_mutex_t g_console_output_buffer_lock; 1259 1260 void 1261 adb_sysdeps_init( void ) 1262 { 1263 #define ADB_MUTEX(x) InitializeCriticalSection( & x ); 1264 #include "mutex_list.h" 1265 InitializeCriticalSection( &_win32_lock ); 1266 InitializeCriticalSection( &g_console_output_buffer_lock ); 1267 } 1268 1269 /**************************************************************************/ 1270 /**************************************************************************/ 1271 /***** *****/ 1272 /***** Console Window Terminal Emulation *****/ 1273 /***** *****/ 1274 /**************************************************************************/ 1275 /**************************************************************************/ 1276 1277 // This reads input from a Win32 console window and translates it into Unix 1278 // terminal-style sequences. This emulates mostly Gnome Terminal (in Normal 1279 // mode, not Application mode), which itself emulates xterm. Gnome Terminal 1280 // is emulated instead of xterm because it is probably more popular than xterm: 1281 // Ubuntu's default Ctrl-Alt-T shortcut opens Gnome Terminal, Gnome Terminal 1282 // supports modern fonts, etc. It seems best to emulate the terminal that most 1283 // Android developers use because they'll fix apps (the shell, etc.) to keep 1284 // working with that terminal's emulation. 1285 // 1286 // The point of this emulation is not to be perfect or to solve all issues with 1287 // console windows on Windows, but to be better than the original code which 1288 // just called read() (which called ReadFile(), which called ReadConsoleA()) 1289 // which did not support Ctrl-C, tab completion, shell input line editing 1290 // keys, server echo, and more. 1291 // 1292 // This implementation reconfigures the console with SetConsoleMode(), then 1293 // calls ReadConsoleInput() to get raw input which it remaps to Unix 1294 // terminal-style sequences which is returned via unix_read() which is used 1295 // by the 'adb shell' command. 1296 // 1297 // Code organization: 1298 // 1299 // * _get_console_handle() and unix_isatty() provide console information. 1300 // * stdin_raw_init() and stdin_raw_restore() reconfigure the console. 1301 // * unix_read() detects console windows (as opposed to pipes, files, etc.). 1302 // * _console_read() is the main code of the emulation. 1303 1304 // Returns a console HANDLE if |fd| is a console, otherwise returns nullptr. 1305 // If a valid HANDLE is returned and |mode| is not null, |mode| is also filled 1306 // with the console mode. Requires GENERIC_READ access to the underlying HANDLE. 1307 static HANDLE _get_console_handle(int fd, DWORD* mode=nullptr) { 1308 // First check isatty(); this is very fast and eliminates most non-console 1309 // FDs, but returns 1 for both consoles and character devices like NUL. 1310 #pragma push_macro("isatty") 1311 #undef isatty 1312 if (!isatty(fd)) { 1313 return nullptr; 1314 } 1315 #pragma pop_macro("isatty") 1316 1317 // To differentiate between character devices and consoles we need to get 1318 // the underlying HANDLE and use GetConsoleMode(), which is what requires 1319 // GENERIC_READ permissions. 1320 const intptr_t intptr_handle = _get_osfhandle(fd); 1321 if (intptr_handle == -1) { 1322 return nullptr; 1323 } 1324 const HANDLE handle = reinterpret_cast<const HANDLE>(intptr_handle); 1325 DWORD temp_mode = 0; 1326 if (!GetConsoleMode(handle, mode ? mode : &temp_mode)) { 1327 return nullptr; 1328 } 1329 1330 return handle; 1331 } 1332 1333 // Returns a console handle if |stream| is a console, otherwise returns nullptr. 1334 static HANDLE _get_console_handle(FILE* const stream) { 1335 // Save and restore errno to make it easier for callers to prevent from overwriting errno. 1336 android::base::ErrnoRestorer er; 1337 const int fd = fileno(stream); 1338 if (fd < 0) { 1339 return nullptr; 1340 } 1341 return _get_console_handle(fd); 1342 } 1343 1344 int unix_isatty(int fd) { 1345 return _get_console_handle(fd) ? 1 : 0; 1346 } 1347 1348 // Get the next KEY_EVENT_RECORD that should be processed. 1349 static bool _get_key_event_record(const HANDLE console, INPUT_RECORD* const input_record) { 1350 for (;;) { 1351 DWORD read_count = 0; 1352 memset(input_record, 0, sizeof(*input_record)); 1353 if (!ReadConsoleInputA(console, input_record, 1, &read_count)) { 1354 D("_get_key_event_record: ReadConsoleInputA() failed: %s\n", 1355 android::base::SystemErrorCodeToString(GetLastError()).c_str()); 1356 errno = EIO; 1357 return false; 1358 } 1359 1360 if (read_count == 0) { // should be impossible 1361 fatal("ReadConsoleInputA returned 0"); 1362 } 1363 1364 if (read_count != 1) { // should be impossible 1365 fatal("ReadConsoleInputA did not return one input record"); 1366 } 1367 1368 // If the console window is resized, emulate SIGWINCH by breaking out 1369 // of read() with errno == EINTR. Note that there is no event on 1370 // vertical resize because we don't give the console our own custom 1371 // screen buffer (with CreateConsoleScreenBuffer() + 1372 // SetConsoleActiveScreenBuffer()). Instead, we use the default which 1373 // supports scrollback, but doesn't seem to raise an event for vertical 1374 // window resize. 1375 if (input_record->EventType == WINDOW_BUFFER_SIZE_EVENT) { 1376 errno = EINTR; 1377 return false; 1378 } 1379 1380 if ((input_record->EventType == KEY_EVENT) && 1381 (input_record->Event.KeyEvent.bKeyDown)) { 1382 if (input_record->Event.KeyEvent.wRepeatCount == 0) { 1383 fatal("ReadConsoleInputA returned a key event with zero repeat" 1384 " count"); 1385 } 1386 1387 // Got an interesting INPUT_RECORD, so return 1388 return true; 1389 } 1390 } 1391 } 1392 1393 static __inline__ bool _is_shift_pressed(const DWORD control_key_state) { 1394 return (control_key_state & SHIFT_PRESSED) != 0; 1395 } 1396 1397 static __inline__ bool _is_ctrl_pressed(const DWORD control_key_state) { 1398 return (control_key_state & (LEFT_CTRL_PRESSED | RIGHT_CTRL_PRESSED)) != 0; 1399 } 1400 1401 static __inline__ bool _is_alt_pressed(const DWORD control_key_state) { 1402 return (control_key_state & (LEFT_ALT_PRESSED | RIGHT_ALT_PRESSED)) != 0; 1403 } 1404 1405 static __inline__ bool _is_numlock_on(const DWORD control_key_state) { 1406 return (control_key_state & NUMLOCK_ON) != 0; 1407 } 1408 1409 static __inline__ bool _is_capslock_on(const DWORD control_key_state) { 1410 return (control_key_state & CAPSLOCK_ON) != 0; 1411 } 1412 1413 static __inline__ bool _is_enhanced_key(const DWORD control_key_state) { 1414 return (control_key_state & ENHANCED_KEY) != 0; 1415 } 1416 1417 // Constants from MSDN for ToAscii(). 1418 static const BYTE TOASCII_KEY_OFF = 0x00; 1419 static const BYTE TOASCII_KEY_DOWN = 0x80; 1420 static const BYTE TOASCII_KEY_TOGGLED_ON = 0x01; // for CapsLock 1421 1422 // Given a key event, ignore a modifier key and return the character that was 1423 // entered without the modifier. Writes to *ch and returns the number of bytes 1424 // written. 1425 static size_t _get_char_ignoring_modifier(char* const ch, 1426 const KEY_EVENT_RECORD* const key_event, const DWORD control_key_state, 1427 const WORD modifier) { 1428 // If there is no character from Windows, try ignoring the specified 1429 // modifier and look for a character. Note that if AltGr is being used, 1430 // there will be a character from Windows. 1431 if (key_event->uChar.AsciiChar == '\0') { 1432 // Note that we read the control key state from the passed in argument 1433 // instead of from key_event since the argument has been normalized. 1434 if (((modifier == VK_SHIFT) && 1435 _is_shift_pressed(control_key_state)) || 1436 ((modifier == VK_CONTROL) && 1437 _is_ctrl_pressed(control_key_state)) || 1438 ((modifier == VK_MENU) && _is_alt_pressed(control_key_state))) { 1439 1440 BYTE key_state[256] = {0}; 1441 key_state[VK_SHIFT] = _is_shift_pressed(control_key_state) ? 1442 TOASCII_KEY_DOWN : TOASCII_KEY_OFF; 1443 key_state[VK_CONTROL] = _is_ctrl_pressed(control_key_state) ? 1444 TOASCII_KEY_DOWN : TOASCII_KEY_OFF; 1445 key_state[VK_MENU] = _is_alt_pressed(control_key_state) ? 1446 TOASCII_KEY_DOWN : TOASCII_KEY_OFF; 1447 key_state[VK_CAPITAL] = _is_capslock_on(control_key_state) ? 1448 TOASCII_KEY_TOGGLED_ON : TOASCII_KEY_OFF; 1449 1450 // cause this modifier to be ignored 1451 key_state[modifier] = TOASCII_KEY_OFF; 1452 1453 WORD translated = 0; 1454 if (ToAscii(key_event->wVirtualKeyCode, 1455 key_event->wVirtualScanCode, key_state, &translated, 0) == 1) { 1456 // Ignoring the modifier, we found a character. 1457 *ch = (CHAR)translated; 1458 return 1; 1459 } 1460 } 1461 } 1462 1463 // Just use whatever Windows told us originally. 1464 *ch = key_event->uChar.AsciiChar; 1465 1466 // If the character from Windows is NULL, return a size of zero. 1467 return (*ch == '\0') ? 0 : 1; 1468 } 1469 1470 // If a Ctrl key is pressed, lookup the character, ignoring the Ctrl key, 1471 // but taking into account the shift key. This is because for a sequence like 1472 // Ctrl-Alt-0, we want to find the character '0' and for Ctrl-Alt-Shift-0, 1473 // we want to find the character ')'. 1474 // 1475 // Note that Windows doesn't seem to pass bKeyDown for Ctrl-Shift-NoAlt-0 1476 // because it is the default key-sequence to switch the input language. 1477 // This is configurable in the Region and Language control panel. 1478 static __inline__ size_t _get_non_control_char(char* const ch, 1479 const KEY_EVENT_RECORD* const key_event, const DWORD control_key_state) { 1480 return _get_char_ignoring_modifier(ch, key_event, control_key_state, 1481 VK_CONTROL); 1482 } 1483 1484 // Get without Alt. 1485 static __inline__ size_t _get_non_alt_char(char* const ch, 1486 const KEY_EVENT_RECORD* const key_event, const DWORD control_key_state) { 1487 return _get_char_ignoring_modifier(ch, key_event, control_key_state, 1488 VK_MENU); 1489 } 1490 1491 // Ignore the control key, find the character from Windows, and apply any 1492 // Control key mappings (for example, Ctrl-2 is a NULL character). Writes to 1493 // *pch and returns number of bytes written. 1494 static size_t _get_control_character(char* const pch, 1495 const KEY_EVENT_RECORD* const key_event, const DWORD control_key_state) { 1496 const size_t len = _get_non_control_char(pch, key_event, 1497 control_key_state); 1498 1499 if ((len == 1) && _is_ctrl_pressed(control_key_state)) { 1500 char ch = *pch; 1501 switch (ch) { 1502 case '2': 1503 case '@': 1504 case '`': 1505 ch = '\0'; 1506 break; 1507 case '3': 1508 case '[': 1509 case '{': 1510 ch = '\x1b'; 1511 break; 1512 case '4': 1513 case '\\': 1514 case '|': 1515 ch = '\x1c'; 1516 break; 1517 case '5': 1518 case ']': 1519 case '}': 1520 ch = '\x1d'; 1521 break; 1522 case '6': 1523 case '^': 1524 case '~': 1525 ch = '\x1e'; 1526 break; 1527 case '7': 1528 case '-': 1529 case '_': 1530 ch = '\x1f'; 1531 break; 1532 case '8': 1533 ch = '\x7f'; 1534 break; 1535 case '/': 1536 if (!_is_alt_pressed(control_key_state)) { 1537 ch = '\x1f'; 1538 } 1539 break; 1540 case '?': 1541 if (!_is_alt_pressed(control_key_state)) { 1542 ch = '\x7f'; 1543 } 1544 break; 1545 } 1546 *pch = ch; 1547 } 1548 1549 return len; 1550 } 1551 1552 static DWORD _normalize_altgr_control_key_state( 1553 const KEY_EVENT_RECORD* const key_event) { 1554 DWORD control_key_state = key_event->dwControlKeyState; 1555 1556 // If we're in an AltGr situation where the AltGr key is down (depending on 1557 // the keyboard layout, that might be the physical right alt key which 1558 // produces a control_key_state where Right-Alt and Left-Ctrl are down) or 1559 // AltGr-equivalent keys are down (any Ctrl key + any Alt key), and we have 1560 // a character (which indicates that there was an AltGr mapping), then act 1561 // as if alt and control are not really down for the purposes of modifiers. 1562 // This makes it so that if the user with, say, a German keyboard layout 1563 // presses AltGr-] (which we see as Right-Alt + Left-Ctrl + key), we just 1564 // output the key and we don't see the Alt and Ctrl keys. 1565 if (_is_ctrl_pressed(control_key_state) && 1566 _is_alt_pressed(control_key_state) 1567 && (key_event->uChar.AsciiChar != '\0')) { 1568 // Try to remove as few bits as possible to improve our chances of 1569 // detecting combinations like Left-Alt + AltGr, Right-Ctrl + AltGr, or 1570 // Left-Alt + Right-Ctrl + AltGr. 1571 if ((control_key_state & RIGHT_ALT_PRESSED) != 0) { 1572 // Remove Right-Alt. 1573 control_key_state &= ~RIGHT_ALT_PRESSED; 1574 // If uChar is set, a Ctrl key is pressed, and Right-Alt is 1575 // pressed, Left-Ctrl is almost always set, except if the user 1576 // presses Right-Ctrl, then AltGr (in that specific order) for 1577 // whatever reason. At any rate, make sure the bit is not set. 1578 control_key_state &= ~LEFT_CTRL_PRESSED; 1579 } else if ((control_key_state & LEFT_ALT_PRESSED) != 0) { 1580 // Remove Left-Alt. 1581 control_key_state &= ~LEFT_ALT_PRESSED; 1582 // Whichever Ctrl key is down, remove it from the state. We only 1583 // remove one key, to improve our chances of detecting the 1584 // corner-case of Left-Ctrl + Left-Alt + Right-Ctrl. 1585 if ((control_key_state & LEFT_CTRL_PRESSED) != 0) { 1586 // Remove Left-Ctrl. 1587 control_key_state &= ~LEFT_CTRL_PRESSED; 1588 } else if ((control_key_state & RIGHT_CTRL_PRESSED) != 0) { 1589 // Remove Right-Ctrl. 1590 control_key_state &= ~RIGHT_CTRL_PRESSED; 1591 } 1592 } 1593 1594 // Note that this logic isn't 100% perfect because Windows doesn't 1595 // allow us to detect all combinations because a physical AltGr key 1596 // press shows up as two bits, plus some combinations are ambiguous 1597 // about what is actually physically pressed. 1598 } 1599 1600 return control_key_state; 1601 } 1602 1603 // If NumLock is on and Shift is pressed, SHIFT_PRESSED is not set in 1604 // dwControlKeyState for the following keypad keys: period, 0-9. If we detect 1605 // this scenario, set the SHIFT_PRESSED bit so we can add modifiers 1606 // appropriately. 1607 static DWORD _normalize_keypad_control_key_state(const WORD vk, 1608 const DWORD control_key_state) { 1609 if (!_is_numlock_on(control_key_state)) { 1610 return control_key_state; 1611 } 1612 if (!_is_enhanced_key(control_key_state)) { 1613 switch (vk) { 1614 case VK_INSERT: // 0 1615 case VK_DELETE: // . 1616 case VK_END: // 1 1617 case VK_DOWN: // 2 1618 case VK_NEXT: // 3 1619 case VK_LEFT: // 4 1620 case VK_CLEAR: // 5 1621 case VK_RIGHT: // 6 1622 case VK_HOME: // 7 1623 case VK_UP: // 8 1624 case VK_PRIOR: // 9 1625 return control_key_state | SHIFT_PRESSED; 1626 } 1627 } 1628 1629 return control_key_state; 1630 } 1631 1632 static const char* _get_keypad_sequence(const DWORD control_key_state, 1633 const char* const normal, const char* const shifted) { 1634 if (_is_shift_pressed(control_key_state)) { 1635 // Shift is pressed and NumLock is off 1636 return shifted; 1637 } else { 1638 // Shift is not pressed and NumLock is off, or, 1639 // Shift is pressed and NumLock is on, in which case we want the 1640 // NumLock and Shift to neutralize each other, thus, we want the normal 1641 // sequence. 1642 return normal; 1643 } 1644 // If Shift is not pressed and NumLock is on, a different virtual key code 1645 // is returned by Windows, which can be taken care of by a different case 1646 // statement in _console_read(). 1647 } 1648 1649 // Write sequence to buf and return the number of bytes written. 1650 static size_t _get_modifier_sequence(char* const buf, const WORD vk, 1651 DWORD control_key_state, const char* const normal) { 1652 // Copy the base sequence into buf. 1653 const size_t len = strlen(normal); 1654 memcpy(buf, normal, len); 1655 1656 int code = 0; 1657 1658 control_key_state = _normalize_keypad_control_key_state(vk, 1659 control_key_state); 1660 1661 if (_is_shift_pressed(control_key_state)) { 1662 code |= 0x1; 1663 } 1664 if (_is_alt_pressed(control_key_state)) { // any alt key pressed 1665 code |= 0x2; 1666 } 1667 if (_is_ctrl_pressed(control_key_state)) { // any control key pressed 1668 code |= 0x4; 1669 } 1670 // If some modifier was held down, then we need to insert the modifier code 1671 if (code != 0) { 1672 if (len == 0) { 1673 // Should be impossible because caller should pass a string of 1674 // non-zero length. 1675 return 0; 1676 } 1677 size_t index = len - 1; 1678 const char lastChar = buf[index]; 1679 if (lastChar != '~') { 1680 buf[index++] = '1'; 1681 } 1682 buf[index++] = ';'; // modifier separator 1683 // 2 = shift, 3 = alt, 4 = shift & alt, 5 = control, 1684 // 6 = shift & control, 7 = alt & control, 8 = shift & alt & control 1685 buf[index++] = '1' + code; 1686 buf[index++] = lastChar; // move ~ (or other last char) to the end 1687 return index; 1688 } 1689 return len; 1690 } 1691 1692 // Write sequence to buf and return the number of bytes written. 1693 static size_t _get_modifier_keypad_sequence(char* const buf, const WORD vk, 1694 const DWORD control_key_state, const char* const normal, 1695 const char shifted) { 1696 if (_is_shift_pressed(control_key_state)) { 1697 // Shift is pressed and NumLock is off 1698 if (shifted != '\0') { 1699 buf[0] = shifted; 1700 return sizeof(buf[0]); 1701 } else { 1702 return 0; 1703 } 1704 } else { 1705 // Shift is not pressed and NumLock is off, or, 1706 // Shift is pressed and NumLock is on, in which case we want the 1707 // NumLock and Shift to neutralize each other, thus, we want the normal 1708 // sequence. 1709 return _get_modifier_sequence(buf, vk, control_key_state, normal); 1710 } 1711 // If Shift is not pressed and NumLock is on, a different virtual key code 1712 // is returned by Windows, which can be taken care of by a different case 1713 // statement in _console_read(). 1714 } 1715 1716 // The decimal key on the keypad produces a '.' for U.S. English and a ',' for 1717 // Standard German. Figure this out at runtime so we know what to output for 1718 // Shift-VK_DELETE. 1719 static char _get_decimal_char() { 1720 return (char)MapVirtualKeyA(VK_DECIMAL, MAPVK_VK_TO_CHAR); 1721 } 1722 1723 // Prefix the len bytes in buf with the escape character, and then return the 1724 // new buffer length. 1725 size_t _escape_prefix(char* const buf, const size_t len) { 1726 // If nothing to prefix, don't do anything. We might be called with 1727 // len == 0, if alt was held down with a dead key which produced nothing. 1728 if (len == 0) { 1729 return 0; 1730 } 1731 1732 memmove(&buf[1], buf, len); 1733 buf[0] = '\x1b'; 1734 return len + 1; 1735 } 1736 1737 // Internal buffer to satisfy future _console_read() calls. 1738 static auto& g_console_input_buffer = *new std::vector<char>(); 1739 1740 // Writes to buffer buf (of length len), returning number of bytes written or -1 on error. Never 1741 // returns zero on console closure because Win32 consoles are never 'closed' (as far as I can tell). 1742 static int _console_read(const HANDLE console, void* buf, size_t len) { 1743 for (;;) { 1744 // Read of zero bytes should not block waiting for something from the console. 1745 if (len == 0) { 1746 return 0; 1747 } 1748 1749 // Flush as much as possible from input buffer. 1750 if (!g_console_input_buffer.empty()) { 1751 const int bytes_read = std::min(len, g_console_input_buffer.size()); 1752 memcpy(buf, g_console_input_buffer.data(), bytes_read); 1753 const auto begin = g_console_input_buffer.begin(); 1754 g_console_input_buffer.erase(begin, begin + bytes_read); 1755 return bytes_read; 1756 } 1757 1758 // Read from the actual console. This may block until input. 1759 INPUT_RECORD input_record; 1760 if (!_get_key_event_record(console, &input_record)) { 1761 return -1; 1762 } 1763 1764 KEY_EVENT_RECORD* const key_event = &input_record.Event.KeyEvent; 1765 const WORD vk = key_event->wVirtualKeyCode; 1766 const CHAR ch = key_event->uChar.AsciiChar; 1767 const DWORD control_key_state = _normalize_altgr_control_key_state( 1768 key_event); 1769 1770 // The following emulation code should write the output sequence to 1771 // either seqstr or to seqbuf and seqbuflen. 1772 const char* seqstr = NULL; // NULL terminated C-string 1773 // Enough space for max sequence string below, plus modifiers and/or 1774 // escape prefix. 1775 char seqbuf[16]; 1776 size_t seqbuflen = 0; // Space used in seqbuf. 1777 1778 #define MATCH(vk, normal) \ 1779 case (vk): \ 1780 { \ 1781 seqstr = (normal); \ 1782 } \ 1783 break; 1784 1785 // Modifier keys should affect the output sequence. 1786 #define MATCH_MODIFIER(vk, normal) \ 1787 case (vk): \ 1788 { \ 1789 seqbuflen = _get_modifier_sequence(seqbuf, (vk), \ 1790 control_key_state, (normal)); \ 1791 } \ 1792 break; 1793 1794 // The shift key should affect the output sequence. 1795 #define MATCH_KEYPAD(vk, normal, shifted) \ 1796 case (vk): \ 1797 { \ 1798 seqstr = _get_keypad_sequence(control_key_state, (normal), \ 1799 (shifted)); \ 1800 } \ 1801 break; 1802 1803 // The shift key and other modifier keys should affect the output 1804 // sequence. 1805 #define MATCH_MODIFIER_KEYPAD(vk, normal, shifted) \ 1806 case (vk): \ 1807 { \ 1808 seqbuflen = _get_modifier_keypad_sequence(seqbuf, (vk), \ 1809 control_key_state, (normal), (shifted)); \ 1810 } \ 1811 break; 1812 1813 #define ESC "\x1b" 1814 #define CSI ESC "[" 1815 #define SS3 ESC "O" 1816 1817 // Only support normal mode, not application mode. 1818 1819 // Enhanced keys: 1820 // * 6-pack: insert, delete, home, end, page up, page down 1821 // * cursor keys: up, down, right, left 1822 // * keypad: divide, enter 1823 // * Undocumented: VK_PAUSE (Ctrl-NumLock), VK_SNAPSHOT, 1824 // VK_CANCEL (Ctrl-Pause/Break), VK_NUMLOCK 1825 if (_is_enhanced_key(control_key_state)) { 1826 switch (vk) { 1827 case VK_RETURN: // Enter key on keypad 1828 if (_is_ctrl_pressed(control_key_state)) { 1829 seqstr = "\n"; 1830 } else { 1831 seqstr = "\r"; 1832 } 1833 break; 1834 1835 MATCH_MODIFIER(VK_PRIOR, CSI "5~"); // Page Up 1836 MATCH_MODIFIER(VK_NEXT, CSI "6~"); // Page Down 1837 1838 // gnome-terminal currently sends SS3 "F" and SS3 "H", but that 1839 // will be fixed soon to match xterm which sends CSI "F" and 1840 // CSI "H". https://bugzilla.redhat.com/show_bug.cgi?id=1119764 1841 MATCH(VK_END, CSI "F"); 1842 MATCH(VK_HOME, CSI "H"); 1843 1844 MATCH_MODIFIER(VK_LEFT, CSI "D"); 1845 MATCH_MODIFIER(VK_UP, CSI "A"); 1846 MATCH_MODIFIER(VK_RIGHT, CSI "C"); 1847 MATCH_MODIFIER(VK_DOWN, CSI "B"); 1848 1849 MATCH_MODIFIER(VK_INSERT, CSI "2~"); 1850 MATCH_MODIFIER(VK_DELETE, CSI "3~"); 1851 1852 MATCH(VK_DIVIDE, "/"); 1853 } 1854 } else { // Non-enhanced keys: 1855 switch (vk) { 1856 case VK_BACK: // backspace 1857 if (_is_alt_pressed(control_key_state)) { 1858 seqstr = ESC "\x7f"; 1859 } else { 1860 seqstr = "\x7f"; 1861 } 1862 break; 1863 1864 case VK_TAB: 1865 if (_is_shift_pressed(control_key_state)) { 1866 seqstr = CSI "Z"; 1867 } else { 1868 seqstr = "\t"; 1869 } 1870 break; 1871 1872 // Number 5 key in keypad when NumLock is off, or if NumLock is 1873 // on and Shift is down. 1874 MATCH_KEYPAD(VK_CLEAR, CSI "E", "5"); 1875 1876 case VK_RETURN: // Enter key on main keyboard 1877 if (_is_alt_pressed(control_key_state)) { 1878 seqstr = ESC "\n"; 1879 } else if (_is_ctrl_pressed(control_key_state)) { 1880 seqstr = "\n"; 1881 } else { 1882 seqstr = "\r"; 1883 } 1884 break; 1885 1886 // VK_ESCAPE: Don't do any special handling. The OS uses many 1887 // of the sequences with Escape and many of the remaining 1888 // sequences don't produce bKeyDown messages, only !bKeyDown 1889 // for whatever reason. 1890 1891 case VK_SPACE: 1892 if (_is_alt_pressed(control_key_state)) { 1893 seqstr = ESC " "; 1894 } else if (_is_ctrl_pressed(control_key_state)) { 1895 seqbuf[0] = '\0'; // NULL char 1896 seqbuflen = 1; 1897 } else { 1898 seqstr = " "; 1899 } 1900 break; 1901 1902 MATCH_MODIFIER_KEYPAD(VK_PRIOR, CSI "5~", '9'); // Page Up 1903 MATCH_MODIFIER_KEYPAD(VK_NEXT, CSI "6~", '3'); // Page Down 1904 1905 MATCH_KEYPAD(VK_END, CSI "4~", "1"); 1906 MATCH_KEYPAD(VK_HOME, CSI "1~", "7"); 1907 1908 MATCH_MODIFIER_KEYPAD(VK_LEFT, CSI "D", '4'); 1909 MATCH_MODIFIER_KEYPAD(VK_UP, CSI "A", '8'); 1910 MATCH_MODIFIER_KEYPAD(VK_RIGHT, CSI "C", '6'); 1911 MATCH_MODIFIER_KEYPAD(VK_DOWN, CSI "B", '2'); 1912 1913 MATCH_MODIFIER_KEYPAD(VK_INSERT, CSI "2~", '0'); 1914 MATCH_MODIFIER_KEYPAD(VK_DELETE, CSI "3~", 1915 _get_decimal_char()); 1916 1917 case 0x30: // 0 1918 case 0x31: // 1 1919 case 0x39: // 9 1920 case VK_OEM_1: // ;: 1921 case VK_OEM_PLUS: // =+ 1922 case VK_OEM_COMMA: // ,< 1923 case VK_OEM_PERIOD: // .> 1924 case VK_OEM_7: // '" 1925 case VK_OEM_102: // depends on keyboard, could be <> or \| 1926 case VK_OEM_2: // /? 1927 case VK_OEM_3: // `~ 1928 case VK_OEM_4: // [{ 1929 case VK_OEM_5: // \| 1930 case VK_OEM_6: // ]} 1931 { 1932 seqbuflen = _get_control_character(seqbuf, key_event, 1933 control_key_state); 1934 1935 if (_is_alt_pressed(control_key_state)) { 1936 seqbuflen = _escape_prefix(seqbuf, seqbuflen); 1937 } 1938 } 1939 break; 1940 1941 case 0x32: // 2 1942 case 0x33: // 3 1943 case 0x34: // 4 1944 case 0x35: // 5 1945 case 0x36: // 6 1946 case 0x37: // 7 1947 case 0x38: // 8 1948 case VK_OEM_MINUS: // -_ 1949 { 1950 seqbuflen = _get_control_character(seqbuf, key_event, 1951 control_key_state); 1952 1953 // If Alt is pressed and it isn't Ctrl-Alt-ShiftUp, then 1954 // prefix with escape. 1955 if (_is_alt_pressed(control_key_state) && 1956 !(_is_ctrl_pressed(control_key_state) && 1957 !_is_shift_pressed(control_key_state))) { 1958 seqbuflen = _escape_prefix(seqbuf, seqbuflen); 1959 } 1960 } 1961 break; 1962 1963 case 0x41: // a 1964 case 0x42: // b 1965 case 0x43: // c 1966 case 0x44: // d 1967 case 0x45: // e 1968 case 0x46: // f 1969 case 0x47: // g 1970 case 0x48: // h 1971 case 0x49: // i 1972 case 0x4a: // j 1973 case 0x4b: // k 1974 case 0x4c: // l 1975 case 0x4d: // m 1976 case 0x4e: // n 1977 case 0x4f: // o 1978 case 0x50: // p 1979 case 0x51: // q 1980 case 0x52: // r 1981 case 0x53: // s 1982 case 0x54: // t 1983 case 0x55: // u 1984 case 0x56: // v 1985 case 0x57: // w 1986 case 0x58: // x 1987 case 0x59: // y 1988 case 0x5a: // z 1989 { 1990 seqbuflen = _get_non_alt_char(seqbuf, key_event, 1991 control_key_state); 1992 1993 // If Alt is pressed, then prefix with escape. 1994 if (_is_alt_pressed(control_key_state)) { 1995 seqbuflen = _escape_prefix(seqbuf, seqbuflen); 1996 } 1997 } 1998 break; 1999 2000 // These virtual key codes are generated by the keys on the 2001 // keypad *when NumLock is on* and *Shift is up*. 2002 MATCH(VK_NUMPAD0, "0"); 2003 MATCH(VK_NUMPAD1, "1"); 2004 MATCH(VK_NUMPAD2, "2"); 2005 MATCH(VK_NUMPAD3, "3"); 2006 MATCH(VK_NUMPAD4, "4"); 2007 MATCH(VK_NUMPAD5, "5"); 2008 MATCH(VK_NUMPAD6, "6"); 2009 MATCH(VK_NUMPAD7, "7"); 2010 MATCH(VK_NUMPAD8, "8"); 2011 MATCH(VK_NUMPAD9, "9"); 2012 2013 MATCH(VK_MULTIPLY, "*"); 2014 MATCH(VK_ADD, "+"); 2015 MATCH(VK_SUBTRACT, "-"); 2016 // VK_DECIMAL is generated by the . key on the keypad *when 2017 // NumLock is on* and *Shift is up* and the sequence is not 2018 // Ctrl-Alt-NoShift-. (which causes Ctrl-Alt-Del and the 2019 // Windows Security screen to come up). 2020 case VK_DECIMAL: 2021 // U.S. English uses '.', Germany German uses ','. 2022 seqbuflen = _get_non_control_char(seqbuf, key_event, 2023 control_key_state); 2024 break; 2025 2026 MATCH_MODIFIER(VK_F1, SS3 "P"); 2027 MATCH_MODIFIER(VK_F2, SS3 "Q"); 2028 MATCH_MODIFIER(VK_F3, SS3 "R"); 2029 MATCH_MODIFIER(VK_F4, SS3 "S"); 2030 MATCH_MODIFIER(VK_F5, CSI "15~"); 2031 MATCH_MODIFIER(VK_F6, CSI "17~"); 2032 MATCH_MODIFIER(VK_F7, CSI "18~"); 2033 MATCH_MODIFIER(VK_F8, CSI "19~"); 2034 MATCH_MODIFIER(VK_F9, CSI "20~"); 2035 MATCH_MODIFIER(VK_F10, CSI "21~"); 2036 MATCH_MODIFIER(VK_F11, CSI "23~"); 2037 MATCH_MODIFIER(VK_F12, CSI "24~"); 2038 2039 MATCH_MODIFIER(VK_F13, CSI "25~"); 2040 MATCH_MODIFIER(VK_F14, CSI "26~"); 2041 MATCH_MODIFIER(VK_F15, CSI "28~"); 2042 MATCH_MODIFIER(VK_F16, CSI "29~"); 2043 MATCH_MODIFIER(VK_F17, CSI "31~"); 2044 MATCH_MODIFIER(VK_F18, CSI "32~"); 2045 MATCH_MODIFIER(VK_F19, CSI "33~"); 2046 MATCH_MODIFIER(VK_F20, CSI "34~"); 2047 2048 // MATCH_MODIFIER(VK_F21, ???); 2049 // MATCH_MODIFIER(VK_F22, ???); 2050 // MATCH_MODIFIER(VK_F23, ???); 2051 // MATCH_MODIFIER(VK_F24, ???); 2052 } 2053 } 2054 2055 #undef MATCH 2056 #undef MATCH_MODIFIER 2057 #undef MATCH_KEYPAD 2058 #undef MATCH_MODIFIER_KEYPAD 2059 #undef ESC 2060 #undef CSI 2061 #undef SS3 2062 2063 const char* out; 2064 size_t outlen; 2065 2066 // Check for output in any of: 2067 // * seqstr is set (and strlen can be used to determine the length). 2068 // * seqbuf and seqbuflen are set 2069 // Fallback to ch from Windows. 2070 if (seqstr != NULL) { 2071 out = seqstr; 2072 outlen = strlen(seqstr); 2073 } else if (seqbuflen > 0) { 2074 out = seqbuf; 2075 outlen = seqbuflen; 2076 } else if (ch != '\0') { 2077 // Use whatever Windows told us it is. 2078 seqbuf[0] = ch; 2079 seqbuflen = 1; 2080 out = seqbuf; 2081 outlen = seqbuflen; 2082 } else { 2083 // No special handling for the virtual key code and Windows isn't 2084 // telling us a character code, then we don't know how to translate 2085 // the key press. 2086 // 2087 // Consume the input and 'continue' to cause us to get a new key 2088 // event. 2089 D("_console_read: unknown virtual key code: %d, enhanced: %s", 2090 vk, _is_enhanced_key(control_key_state) ? "true" : "false"); 2091 continue; 2092 } 2093 2094 // put output wRepeatCount times into g_console_input_buffer 2095 while (key_event->wRepeatCount-- > 0) { 2096 g_console_input_buffer.insert(g_console_input_buffer.end(), out, out + outlen); 2097 } 2098 2099 // Loop around and try to flush g_console_input_buffer 2100 } 2101 } 2102 2103 static DWORD _old_console_mode; // previous GetConsoleMode() result 2104 static HANDLE _console_handle; // when set, console mode should be restored 2105 2106 void stdin_raw_init() { 2107 const HANDLE in = _get_console_handle(STDIN_FILENO, &_old_console_mode); 2108 if (in == nullptr) { 2109 return; 2110 } 2111 2112 // Disable ENABLE_PROCESSED_INPUT so that Ctrl-C is read instead of 2113 // calling the process Ctrl-C routine (configured by 2114 // SetConsoleCtrlHandler()). 2115 // Disable ENABLE_LINE_INPUT so that input is immediately sent. 2116 // Disable ENABLE_ECHO_INPUT to disable local echo. Disabling this 2117 // flag also seems necessary to have proper line-ending processing. 2118 DWORD new_console_mode = _old_console_mode & ~(ENABLE_PROCESSED_INPUT | 2119 ENABLE_LINE_INPUT | 2120 ENABLE_ECHO_INPUT); 2121 // Enable ENABLE_WINDOW_INPUT to get window resizes. 2122 new_console_mode |= ENABLE_WINDOW_INPUT; 2123 2124 if (!SetConsoleMode(in, new_console_mode)) { 2125 // This really should not fail. 2126 D("stdin_raw_init: SetConsoleMode() failed: %s", 2127 android::base::SystemErrorCodeToString(GetLastError()).c_str()); 2128 } 2129 2130 // Once this is set, it means that stdin has been configured for 2131 // reading from and that the old console mode should be restored later. 2132 _console_handle = in; 2133 2134 // Note that we don't need to configure C Runtime line-ending 2135 // translation because _console_read() does not call the C Runtime to 2136 // read from the console. 2137 } 2138 2139 void stdin_raw_restore() { 2140 if (_console_handle != NULL) { 2141 const HANDLE in = _console_handle; 2142 _console_handle = NULL; // clear state 2143 2144 if (!SetConsoleMode(in, _old_console_mode)) { 2145 // This really should not fail. 2146 D("stdin_raw_restore: SetConsoleMode() failed: %s", 2147 android::base::SystemErrorCodeToString(GetLastError()).c_str()); 2148 } 2149 } 2150 } 2151 2152 // Called by 'adb shell' and 'adb exec-in' (via unix_read()) to read from stdin. 2153 int unix_read_interruptible(int fd, void* buf, size_t len) { 2154 if ((fd == STDIN_FILENO) && (_console_handle != NULL)) { 2155 // If it is a request to read from stdin, and stdin_raw_init() has been 2156 // called, and it successfully configured the console, then read from 2157 // the console using Win32 console APIs and partially emulate a unix 2158 // terminal. 2159 return _console_read(_console_handle, buf, len); 2160 } else { 2161 // On older versions of Windows (definitely 7, definitely not 10), 2162 // ReadConsole() with a size >= 31367 fails, so if |fd| is a console 2163 // we need to limit the read size. 2164 if (len > 4096 && unix_isatty(fd)) { 2165 len = 4096; 2166 } 2167 // Just call into C Runtime which can read from pipes/files and which 2168 // can do LF/CR translation (which is overridable with _setmode()). 2169 // Undefine the macro that is set in sysdeps.h which bans calls to 2170 // plain read() in favor of unix_read() or adb_read(). 2171 #pragma push_macro("read") 2172 #undef read 2173 return read(fd, buf, len); 2174 #pragma pop_macro("read") 2175 } 2176 } 2177 2178 /**************************************************************************/ 2179 /**************************************************************************/ 2180 /***** *****/ 2181 /***** Unicode support *****/ 2182 /***** *****/ 2183 /**************************************************************************/ 2184 /**************************************************************************/ 2185 2186 // This implements support for using files with Unicode filenames and for 2187 // outputting Unicode text to a Win32 console window. This is inspired from 2188 // http://utf8everywhere.org/. 2189 // 2190 // Background 2191 // ---------- 2192 // 2193 // On POSIX systems, to deal with files with Unicode filenames, just pass UTF-8 2194 // filenames to APIs such as open(). This works because filenames are largely 2195 // opaque 'cookies' (perhaps excluding path separators). 2196 // 2197 // On Windows, the native file APIs such as CreateFileW() take 2-byte wchar_t 2198 // UTF-16 strings. There is an API, CreateFileA() that takes 1-byte char 2199 // strings, but the strings are in the ANSI codepage and not UTF-8. (The 2200 // CreateFile() API is really just a macro that adds the W/A based on whether 2201 // the UNICODE preprocessor symbol is defined). 2202 // 2203 // Options 2204 // ------- 2205 // 2206 // Thus, to write a portable program, there are a few options: 2207 // 2208 // 1. Write the program with wchar_t filenames (wchar_t path[256];). 2209 // For Windows, just call CreateFileW(). For POSIX, write a wrapper openW() 2210 // that takes a wchar_t string, converts it to UTF-8 and then calls the real 2211 // open() API. 2212 // 2213 // 2. Write the program with a TCHAR typedef that is 2 bytes on Windows and 2214 // 1 byte on POSIX. Make T-* wrappers for various OS APIs and call those, 2215 // potentially touching a lot of code. 2216 // 2217 // 3. Write the program with a 1-byte char filenames (char path[256];) that are 2218 // UTF-8. For POSIX, just call open(). For Windows, write a wrapper that 2219 // takes a UTF-8 string, converts it to UTF-16 and then calls the real OS 2220 // or C Runtime API. 2221 // 2222 // The Choice 2223 // ---------- 2224 // 2225 // The code below chooses option 3, the UTF-8 everywhere strategy. It uses 2226 // android::base::WideToUTF8() which converts UTF-16 to UTF-8. This is used by the 2227 // NarrowArgs helper class that is used to convert wmain() args into UTF-8 2228 // args that are passed to main() at the beginning of program startup. We also use 2229 // android::base::UTF8ToWide() which converts from UTF-8 to UTF-16. This is used to 2230 // implement wrappers below that call UTF-16 OS and C Runtime APIs. 2231 // 2232 // Unicode console output 2233 // ---------------------- 2234 // 2235 // The way to output Unicode to a Win32 console window is to call 2236 // WriteConsoleW() with UTF-16 text. (The user must also choose a proper font 2237 // such as Lucida Console or Consolas, and in the case of East Asian languages 2238 // (such as Chinese, Japanese, Korean), the user must go to the Control Panel 2239 // and change the "system locale" to Chinese, etc., which allows a Chinese, etc. 2240 // font to be used in console windows.) 2241 // 2242 // The problem is getting the C Runtime to make fprintf and related APIs call 2243 // WriteConsoleW() under the covers. The C Runtime API, _setmode() sounds 2244 // promising, but the various modes have issues: 2245 // 2246 // 1. _setmode(_O_TEXT) (the default) does not use WriteConsoleW() so UTF-8 and 2247 // UTF-16 do not display properly. 2248 // 2. _setmode(_O_BINARY) does not use WriteConsoleW() and the text comes out 2249 // totally wrong. 2250 // 3. _setmode(_O_U8TEXT) seems to cause the C Runtime _invalid_parameter 2251 // handler to be called (upon a later I/O call), aborting the process. 2252 // 4. _setmode(_O_U16TEXT) and _setmode(_O_WTEXT) cause non-wide printf/fprintf 2253 // to output nothing. 2254 // 2255 // So the only solution is to write our own adb_fprintf() that converts UTF-8 2256 // to UTF-16 and then calls WriteConsoleW(). 2257 2258 2259 // Constructor for helper class to convert wmain() UTF-16 args to UTF-8 to 2260 // be passed to main(). 2261 NarrowArgs::NarrowArgs(const int argc, wchar_t** const argv) { 2262 narrow_args = new char*[argc + 1]; 2263 2264 for (int i = 0; i < argc; ++i) { 2265 std::string arg_narrow; 2266 if (!android::base::WideToUTF8(argv[i], &arg_narrow)) { 2267 fatal_errno("cannot convert argument from UTF-16 to UTF-8"); 2268 } 2269 narrow_args[i] = strdup(arg_narrow.c_str()); 2270 } 2271 narrow_args[argc] = nullptr; // terminate 2272 } 2273 2274 NarrowArgs::~NarrowArgs() { 2275 if (narrow_args != nullptr) { 2276 for (char** argp = narrow_args; *argp != nullptr; ++argp) { 2277 free(*argp); 2278 } 2279 delete[] narrow_args; 2280 narrow_args = nullptr; 2281 } 2282 } 2283 2284 int unix_open(const char* path, int options, ...) { 2285 std::wstring path_wide; 2286 if (!android::base::UTF8ToWide(path, &path_wide)) { 2287 return -1; 2288 } 2289 if ((options & O_CREAT) == 0) { 2290 return _wopen(path_wide.c_str(), options); 2291 } else { 2292 int mode; 2293 va_list args; 2294 va_start(args, options); 2295 mode = va_arg(args, int); 2296 va_end(args); 2297 return _wopen(path_wide.c_str(), options, mode); 2298 } 2299 } 2300 2301 // Version of opendir() that takes a UTF-8 path. 2302 DIR* adb_opendir(const char* path) { 2303 std::wstring path_wide; 2304 if (!android::base::UTF8ToWide(path, &path_wide)) { 2305 return nullptr; 2306 } 2307 2308 // Just cast _WDIR* to DIR*. This doesn't work if the caller reads any of 2309 // the fields, but right now all the callers treat the structure as 2310 // opaque. 2311 return reinterpret_cast<DIR*>(_wopendir(path_wide.c_str())); 2312 } 2313 2314 // Version of readdir() that returns UTF-8 paths. 2315 struct dirent* adb_readdir(DIR* dir) { 2316 _WDIR* const wdir = reinterpret_cast<_WDIR*>(dir); 2317 struct _wdirent* const went = _wreaddir(wdir); 2318 if (went == nullptr) { 2319 return nullptr; 2320 } 2321 2322 // Convert from UTF-16 to UTF-8. 2323 std::string name_utf8; 2324 if (!android::base::WideToUTF8(went->d_name, &name_utf8)) { 2325 return nullptr; 2326 } 2327 2328 // Cast the _wdirent* to dirent* and overwrite the d_name field (which has 2329 // space for UTF-16 wchar_t's) with UTF-8 char's. 2330 struct dirent* ent = reinterpret_cast<struct dirent*>(went); 2331 2332 if (name_utf8.length() + 1 > sizeof(went->d_name)) { 2333 // Name too big to fit in existing buffer. 2334 errno = ENOMEM; 2335 return nullptr; 2336 } 2337 2338 // Note that sizeof(_wdirent::d_name) is bigger than sizeof(dirent::d_name) 2339 // because _wdirent contains wchar_t instead of char. So even if name_utf8 2340 // can fit in _wdirent::d_name, the resulting dirent::d_name field may be 2341 // bigger than the caller expects because they expect a dirent structure 2342 // which has a smaller d_name field. Ignore this since the caller should be 2343 // resilient. 2344 2345 // Rewrite the UTF-16 d_name field to UTF-8. 2346 strcpy(ent->d_name, name_utf8.c_str()); 2347 2348 return ent; 2349 } 2350 2351 // Version of closedir() to go with our version of adb_opendir(). 2352 int adb_closedir(DIR* dir) { 2353 return _wclosedir(reinterpret_cast<_WDIR*>(dir)); 2354 } 2355 2356 // Version of unlink() that takes a UTF-8 path. 2357 int adb_unlink(const char* path) { 2358 std::wstring wpath; 2359 if (!android::base::UTF8ToWide(path, &wpath)) { 2360 return -1; 2361 } 2362 2363 int rc = _wunlink(wpath.c_str()); 2364 2365 if (rc == -1 && errno == EACCES) { 2366 /* unlink returns EACCES when the file is read-only, so we first */ 2367 /* try to make it writable, then unlink again... */ 2368 rc = _wchmod(wpath.c_str(), _S_IREAD | _S_IWRITE); 2369 if (rc == 0) 2370 rc = _wunlink(wpath.c_str()); 2371 } 2372 return rc; 2373 } 2374 2375 // Version of mkdir() that takes a UTF-8 path. 2376 int adb_mkdir(const std::string& path, int mode) { 2377 std::wstring path_wide; 2378 if (!android::base::UTF8ToWide(path, &path_wide)) { 2379 return -1; 2380 } 2381 2382 return _wmkdir(path_wide.c_str()); 2383 } 2384 2385 // Version of utime() that takes a UTF-8 path. 2386 int adb_utime(const char* path, struct utimbuf* u) { 2387 std::wstring path_wide; 2388 if (!android::base::UTF8ToWide(path, &path_wide)) { 2389 return -1; 2390 } 2391 2392 static_assert(sizeof(struct utimbuf) == sizeof(struct _utimbuf), 2393 "utimbuf and _utimbuf should be the same size because they both " 2394 "contain the same types, namely time_t"); 2395 return _wutime(path_wide.c_str(), reinterpret_cast<struct _utimbuf*>(u)); 2396 } 2397 2398 // Version of chmod() that takes a UTF-8 path. 2399 int adb_chmod(const char* path, int mode) { 2400 std::wstring path_wide; 2401 if (!android::base::UTF8ToWide(path, &path_wide)) { 2402 return -1; 2403 } 2404 2405 return _wchmod(path_wide.c_str(), mode); 2406 } 2407 2408 // From libutils/Unicode.cpp, get the length of a UTF-8 sequence given the lead byte. 2409 static inline size_t utf8_codepoint_len(uint8_t ch) { 2410 return ((0xe5000000 >> ((ch >> 3) & 0x1e)) & 3) + 1; 2411 } 2412 2413 namespace internal { 2414 2415 // Given a sequence of UTF-8 bytes (denoted by the range [first, last)), return the number of bytes 2416 // (from the beginning) that are complete UTF-8 sequences and append the remaining bytes to 2417 // remaining_bytes. 2418 size_t ParseCompleteUTF8(const char* const first, const char* const last, 2419 std::vector<char>* const remaining_bytes) { 2420 // Walk backwards from the end of the sequence looking for the beginning of a UTF-8 sequence. 2421 // Current_after points one byte past the current byte to be examined. 2422 for (const char* current_after = last; current_after != first; --current_after) { 2423 const char* const current = current_after - 1; 2424 const char ch = *current; 2425 const char kHighBit = 0x80u; 2426 const char kTwoHighestBits = 0xC0u; 2427 if ((ch & kHighBit) == 0) { // high bit not set 2428 // The buffer ends with a one-byte UTF-8 sequence, possibly followed by invalid trailing 2429 // bytes with no leading byte, so return the entire buffer. 2430 break; 2431 } else if ((ch & kTwoHighestBits) == kTwoHighestBits) { // top two highest bits set 2432 // Lead byte in UTF-8 sequence, so check if we have all the bytes in the sequence. 2433 const size_t bytes_available = last - current; 2434 if (bytes_available < utf8_codepoint_len(ch)) { 2435 // We don't have all the bytes in the UTF-8 sequence, so return all the bytes 2436 // preceding the current incomplete UTF-8 sequence and append the remaining bytes 2437 // to remaining_bytes. 2438 remaining_bytes->insert(remaining_bytes->end(), current, last); 2439 return current - first; 2440 } else { 2441 // The buffer ends with a complete UTF-8 sequence, possibly followed by invalid 2442 // trailing bytes with no lead byte, so return the entire buffer. 2443 break; 2444 } 2445 } else { 2446 // Trailing byte, so keep going backwards looking for the lead byte. 2447 } 2448 } 2449 2450 // Return the size of the entire buffer. It is possible that we walked backward past invalid 2451 // trailing bytes with no lead byte, in which case we want to return all those invalid bytes 2452 // so that they can be processed. 2453 return last - first; 2454 } 2455 2456 } 2457 2458 // Bytes that have not yet been output to the console because they are incomplete UTF-8 sequences. 2459 // Note that we use only one buffer even though stderr and stdout are logically separate streams. 2460 // This matches the behavior of Linux. 2461 // Protected by g_console_output_buffer_lock. 2462 static auto& g_console_output_buffer = *new std::vector<char>(); 2463 2464 // Internal helper function to write UTF-8 bytes to a console. Returns -1 on error. 2465 static int _console_write_utf8(const char* const buf, const size_t buf_size, FILE* stream, 2466 HANDLE console) { 2467 const int saved_errno = errno; 2468 std::vector<char> combined_buffer; 2469 2470 // Complete UTF-8 sequences that should be immediately written to the console. 2471 const char* utf8; 2472 size_t utf8_size; 2473 2474 adb_mutex_lock(&g_console_output_buffer_lock); 2475 if (g_console_output_buffer.empty()) { 2476 // If g_console_output_buffer doesn't have a buffered up incomplete UTF-8 sequence (the 2477 // common case with plain ASCII), parse buf directly. 2478 utf8 = buf; 2479 utf8_size = internal::ParseCompleteUTF8(buf, buf + buf_size, &g_console_output_buffer); 2480 } else { 2481 // If g_console_output_buffer has a buffered up incomplete UTF-8 sequence, move it to 2482 // combined_buffer (and effectively clear g_console_output_buffer) and append buf to 2483 // combined_buffer, then parse it all together. 2484 combined_buffer.swap(g_console_output_buffer); 2485 combined_buffer.insert(combined_buffer.end(), buf, buf + buf_size); 2486 2487 utf8 = combined_buffer.data(); 2488 utf8_size = internal::ParseCompleteUTF8(utf8, utf8 + combined_buffer.size(), 2489 &g_console_output_buffer); 2490 } 2491 adb_mutex_unlock(&g_console_output_buffer_lock); 2492 2493 std::wstring utf16; 2494 2495 // Try to convert from data that might be UTF-8 to UTF-16, ignoring errors (just like Linux 2496 // which does not return an error on bad UTF-8). Data might not be UTF-8 if the user cat's 2497 // random data, runs dmesg (which might have non-UTF-8), etc. 2498 // This could throw std::bad_alloc. 2499 (void)android::base::UTF8ToWide(utf8, utf8_size, &utf16); 2500 2501 // Note that this does not do \n => \r\n translation because that 2502 // doesn't seem necessary for the Windows console. For the Windows 2503 // console \r moves to the beginning of the line and \n moves to a new 2504 // line. 2505 2506 // Flush any stream buffering so that our output is afterwards which 2507 // makes sense because our call is afterwards. 2508 (void)fflush(stream); 2509 2510 // Write UTF-16 to the console. 2511 DWORD written = 0; 2512 if (!WriteConsoleW(console, utf16.c_str(), utf16.length(), &written, NULL)) { 2513 errno = EIO; 2514 return -1; 2515 } 2516 2517 // Return the size of the original buffer passed in, signifying that we consumed it all, even 2518 // if nothing was displayed, in the case of being passed an incomplete UTF-8 sequence. This 2519 // matches the Linux behavior. 2520 errno = saved_errno; 2521 return buf_size; 2522 } 2523 2524 // Function prototype because attributes cannot be placed on func definitions. 2525 static int _console_vfprintf(const HANDLE console, FILE* stream, 2526 const char *format, va_list ap) 2527 __attribute__((__format__(ADB_FORMAT_ARCHETYPE, 3, 0))); 2528 2529 // Internal function to format a UTF-8 string and write it to a Win32 console. 2530 // Returns -1 on error. 2531 static int _console_vfprintf(const HANDLE console, FILE* stream, 2532 const char *format, va_list ap) { 2533 const int saved_errno = errno; 2534 std::string output_utf8; 2535 2536 // Format the string. 2537 // This could throw std::bad_alloc. 2538 android::base::StringAppendV(&output_utf8, format, ap); 2539 2540 const int result = _console_write_utf8(output_utf8.c_str(), output_utf8.length(), stream, 2541 console); 2542 if (result != -1) { 2543 errno = saved_errno; 2544 } else { 2545 // If -1 was returned, errno has been set. 2546 } 2547 return result; 2548 } 2549 2550 // Version of vfprintf() that takes UTF-8 and can write Unicode to a 2551 // Windows console. 2552 int adb_vfprintf(FILE *stream, const char *format, va_list ap) { 2553 const HANDLE console = _get_console_handle(stream); 2554 2555 // If there is an associated Win32 console, write to it specially, 2556 // otherwise defer to the regular C Runtime, passing it UTF-8. 2557 if (console != NULL) { 2558 return _console_vfprintf(console, stream, format, ap); 2559 } else { 2560 // If vfprintf is a macro, undefine it, so we can call the real 2561 // C Runtime API. 2562 #pragma push_macro("vfprintf") 2563 #undef vfprintf 2564 return vfprintf(stream, format, ap); 2565 #pragma pop_macro("vfprintf") 2566 } 2567 } 2568 2569 // Version of vprintf() that takes UTF-8 and can write Unicode to a Windows console. 2570 int adb_vprintf(const char *format, va_list ap) { 2571 return adb_vfprintf(stdout, format, ap); 2572 } 2573 2574 // Version of fprintf() that takes UTF-8 and can write Unicode to a 2575 // Windows console. 2576 int adb_fprintf(FILE *stream, const char *format, ...) { 2577 va_list ap; 2578 va_start(ap, format); 2579 const int result = adb_vfprintf(stream, format, ap); 2580 va_end(ap); 2581 2582 return result; 2583 } 2584 2585 // Version of printf() that takes UTF-8 and can write Unicode to a 2586 // Windows console. 2587 int adb_printf(const char *format, ...) { 2588 va_list ap; 2589 va_start(ap, format); 2590 const int result = adb_vfprintf(stdout, format, ap); 2591 va_end(ap); 2592 2593 return result; 2594 } 2595 2596 // Version of fputs() that takes UTF-8 and can write Unicode to a 2597 // Windows console. 2598 int adb_fputs(const char* buf, FILE* stream) { 2599 // adb_fprintf returns -1 on error, which is conveniently the same as EOF 2600 // which fputs (and hence adb_fputs) should return on error. 2601 static_assert(EOF == -1, "EOF is not -1, so this code needs to be fixed"); 2602 return adb_fprintf(stream, "%s", buf); 2603 } 2604 2605 // Version of fputc() that takes UTF-8 and can write Unicode to a 2606 // Windows console. 2607 int adb_fputc(int ch, FILE* stream) { 2608 const int result = adb_fprintf(stream, "%c", ch); 2609 if (result == -1) { 2610 return EOF; 2611 } 2612 // For success, fputc returns the char, cast to unsigned char, then to int. 2613 return static_cast<unsigned char>(ch); 2614 } 2615 2616 // Version of putchar() that takes UTF-8 and can write Unicode to a Windows console. 2617 int adb_putchar(int ch) { 2618 return adb_fputc(ch, stdout); 2619 } 2620 2621 // Version of puts() that takes UTF-8 and can write Unicode to a Windows console. 2622 int adb_puts(const char* buf) { 2623 // adb_printf returns -1 on error, which is conveniently the same as EOF 2624 // which puts (and hence adb_puts) should return on error. 2625 static_assert(EOF == -1, "EOF is not -1, so this code needs to be fixed"); 2626 return adb_printf("%s\n", buf); 2627 } 2628 2629 // Internal function to write UTF-8 to a Win32 console. Returns the number of 2630 // items (of length size) written. On error, returns a short item count or 0. 2631 static size_t _console_fwrite(const void* ptr, size_t size, size_t nmemb, 2632 FILE* stream, HANDLE console) { 2633 const int result = _console_write_utf8(reinterpret_cast<const char*>(ptr), size * nmemb, stream, 2634 console); 2635 if (result == -1) { 2636 return 0; 2637 } 2638 return result / size; 2639 } 2640 2641 // Version of fwrite() that takes UTF-8 and can write Unicode to a 2642 // Windows console. 2643 size_t adb_fwrite(const void* ptr, size_t size, size_t nmemb, FILE* stream) { 2644 const HANDLE console = _get_console_handle(stream); 2645 2646 // If there is an associated Win32 console, write to it specially, 2647 // otherwise defer to the regular C Runtime, passing it UTF-8. 2648 if (console != NULL) { 2649 return _console_fwrite(ptr, size, nmemb, stream, console); 2650 } else { 2651 // If fwrite is a macro, undefine it, so we can call the real 2652 // C Runtime API. 2653 #pragma push_macro("fwrite") 2654 #undef fwrite 2655 return fwrite(ptr, size, nmemb, stream); 2656 #pragma pop_macro("fwrite") 2657 } 2658 } 2659 2660 // Version of fopen() that takes a UTF-8 filename and can access a file with 2661 // a Unicode filename. 2662 FILE* adb_fopen(const char* path, const char* mode) { 2663 std::wstring path_wide; 2664 if (!android::base::UTF8ToWide(path, &path_wide)) { 2665 return nullptr; 2666 } 2667 2668 std::wstring mode_wide; 2669 if (!android::base::UTF8ToWide(mode, &mode_wide)) { 2670 return nullptr; 2671 } 2672 2673 return _wfopen(path_wide.c_str(), mode_wide.c_str()); 2674 } 2675 2676 // Return a lowercase version of the argument. Uses C Runtime tolower() on 2677 // each byte which is not UTF-8 aware, and theoretically uses the current C 2678 // Runtime locale (which in practice is not changed, so this becomes a ASCII 2679 // conversion). 2680 static std::string ToLower(const std::string& anycase) { 2681 // copy string 2682 std::string str(anycase); 2683 // transform the copy 2684 std::transform(str.begin(), str.end(), str.begin(), tolower); 2685 return str; 2686 } 2687 2688 extern "C" int main(int argc, char** argv); 2689 2690 // Link with -municode to cause this wmain() to be used as the program 2691 // entrypoint. It will convert the args from UTF-16 to UTF-8 and call the 2692 // regular main() with UTF-8 args. 2693 extern "C" int wmain(int argc, wchar_t **argv) { 2694 // Convert args from UTF-16 to UTF-8 and pass that to main(). 2695 NarrowArgs narrow_args(argc, argv); 2696 return main(argc, narrow_args.data()); 2697 } 2698 2699 // Shadow UTF-8 environment variable name/value pairs that are created from 2700 // _wenviron the first time that adb_getenv() is called. Note that this is not 2701 // currently updated if putenv, setenv, unsetenv are called. Note that no 2702 // thread synchronization is done, but we're called early enough in 2703 // single-threaded startup that things work ok. 2704 static auto& g_environ_utf8 = *new std::unordered_map<std::string, char*>(); 2705 2706 // Make sure that shadow UTF-8 environment variables are setup. 2707 static void _ensure_env_setup() { 2708 // If some name/value pairs exist, then we've already done the setup below. 2709 if (g_environ_utf8.size() != 0) { 2710 return; 2711 } 2712 2713 if (_wenviron == nullptr) { 2714 // If _wenviron is null, then -municode probably wasn't used. That 2715 // linker flag will cause the entry point to setup _wenviron. It will 2716 // also require an implementation of wmain() (which we provide above). 2717 fatal("_wenviron is not set, did you link with -municode?"); 2718 } 2719 2720 // Read name/value pairs from UTF-16 _wenviron and write new name/value 2721 // pairs to UTF-8 g_environ_utf8. Note that it probably does not make sense 2722 // to use the D() macro here because that tracing only works if the 2723 // ADB_TRACE environment variable is setup, but that env var can't be read 2724 // until this code completes. 2725 for (wchar_t** env = _wenviron; *env != nullptr; ++env) { 2726 wchar_t* const equal = wcschr(*env, L'='); 2727 if (equal == nullptr) { 2728 // Malformed environment variable with no equal sign. Shouldn't 2729 // really happen, but we should be resilient to this. 2730 continue; 2731 } 2732 2733 // If we encounter an error converting UTF-16, don't error-out on account of a single env 2734 // var because the program might never even read this particular variable. 2735 std::string name_utf8; 2736 if (!android::base::WideToUTF8(*env, equal - *env, &name_utf8)) { 2737 continue; 2738 } 2739 2740 // Store lowercase name so that we can do case-insensitive searches. 2741 name_utf8 = ToLower(name_utf8); 2742 2743 std::string value_utf8; 2744 if (!android::base::WideToUTF8(equal + 1, &value_utf8)) { 2745 continue; 2746 } 2747 2748 char* const value_dup = strdup(value_utf8.c_str()); 2749 2750 // Don't overwrite a previus env var with the same name. In reality, 2751 // the system probably won't let two env vars with the same name exist 2752 // in _wenviron. 2753 g_environ_utf8.insert({name_utf8, value_dup}); 2754 } 2755 } 2756 2757 // Version of getenv() that takes a UTF-8 environment variable name and 2758 // retrieves a UTF-8 value. Case-insensitive to match getenv() on Windows. 2759 char* adb_getenv(const char* name) { 2760 _ensure_env_setup(); 2761 2762 // Case-insensitive search by searching for lowercase name in a map of 2763 // lowercase names. 2764 const auto it = g_environ_utf8.find(ToLower(std::string(name))); 2765 if (it == g_environ_utf8.end()) { 2766 return nullptr; 2767 } 2768 2769 return it->second; 2770 } 2771 2772 // Version of getcwd() that returns the current working directory in UTF-8. 2773 char* adb_getcwd(char* buf, int size) { 2774 wchar_t* wbuf = _wgetcwd(nullptr, 0); 2775 if (wbuf == nullptr) { 2776 return nullptr; 2777 } 2778 2779 std::string buf_utf8; 2780 const bool narrow_result = android::base::WideToUTF8(wbuf, &buf_utf8); 2781 free(wbuf); 2782 wbuf = nullptr; 2783 2784 if (!narrow_result) { 2785 return nullptr; 2786 } 2787 2788 // If size was specified, make sure all the chars will fit. 2789 if (size != 0) { 2790 if (size < static_cast<int>(buf_utf8.length() + 1)) { 2791 errno = ERANGE; 2792 return nullptr; 2793 } 2794 } 2795 2796 // If buf was not specified, allocate storage. 2797 if (buf == nullptr) { 2798 if (size == 0) { 2799 size = buf_utf8.length() + 1; 2800 } 2801 buf = reinterpret_cast<char*>(malloc(size)); 2802 if (buf == nullptr) { 2803 return nullptr; 2804 } 2805 } 2806 2807 // Destination buffer was allocated with enough space, or we've already 2808 // checked an existing buffer size for enough space. 2809 strcpy(buf, buf_utf8.c_str()); 2810 2811 return buf; 2812 } 2813
