/* fhandler_pipe.cc: pipes for Cygwin. This file is part of Cygwin. This software is a copyrighted work licensed under the terms of the Cygwin license. Please consult the file "CYGWIN_LICENSE" for details. */ #include "winsup.h" #include #include #include "cygerrno.h" #include "security.h" #include "path.h" #include "fhandler.h" #include "dtable.h" #include "cygheap.h" #include "pinfo.h" #include "shared_info.h" #include "tls_pbuf.h" #include /* This is only to be used for writing. When reading, STATUS_PIPE_EMPTY simply means there's no data to be read. */ #define STATUS_PIPE_IS_CLOSED(status) \ ({ NTSTATUS _s = (status); \ _s == STATUS_PIPE_CLOSING \ || _s == STATUS_PIPE_BROKEN \ || _s == STATUS_PIPE_EMPTY; }) fhandler_pipe_fifo::fhandler_pipe_fifo () : fhandler_base (), pipe_buf_size (DEFAULT_PIPEBUFSIZE) { } fhandler_pipe::fhandler_pipe () : fhandler_pipe_fifo (), popen_pid (0) { need_fork_fixup (true); } /* The following function is intended for fhandler_pipe objects created by the second version of fhandler_pipe::create below. See the comment preceding the latter. In addition to setting the blocking mode of the pipe handle, it also sets the pipe's read mode to byte_stream unconditionally. */ void fhandler_pipe::set_pipe_non_blocking (bool nonblocking) { NTSTATUS status; IO_STATUS_BLOCK io; FILE_PIPE_INFORMATION fpi; fpi.ReadMode = FILE_PIPE_BYTE_STREAM_MODE; fpi.CompletionMode = nonblocking ? FILE_PIPE_COMPLETE_OPERATION : FILE_PIPE_QUEUE_OPERATION; status = NtSetInformationFile (get_handle (), &io, &fpi, sizeof fpi, FilePipeInformation); if (!NT_SUCCESS (status)) debug_printf ("NtSetInformationFile(FilePipeInformation): %y", status); } int fhandler_pipe::init (HANDLE f, DWORD a, mode_t mode, int64_t uniq_id) { /* FIXME: Have to clean this up someday FIXME: Do we have to check for both !get_win32_name() and !*get_win32_name()? */ if ((!get_win32_name () || !*get_win32_name ()) && get_name ()) { char *d; const char *s; char *hold_normalized_name = (char *) alloca (strlen (get_name ()) + 1); for (s = get_name (), d = hold_normalized_name; *s; s++, d++) if (*s == '/') *d = '\\'; else *d = *s; *d = '\0'; set_name (hold_normalized_name); } bool opened_properly = a & FILE_CREATE_PIPE_INSTANCE; a &= ~FILE_CREATE_PIPE_INSTANCE; fhandler_base::init (f, a, mode); close_on_exec (mode & O_CLOEXEC); set_ino (uniq_id); set_unique_id (uniq_id | !!(mode & GENERIC_WRITE)); if (opened_properly) /* Set read pipe always nonblocking to allow signal handling even with FILE_SYNCHRONOUS_IO_NONALERT. */ set_pipe_non_blocking (get_device () == FH_PIPER ? true : is_nonblocking ()); return 1; } extern "C" int sscanf (const char *, const char *, ...); int fhandler_pipe::open (int flags, mode_t mode) { HANDLE proc, nio_hdl = NULL; int64_t uniq_id; fhandler_pipe *fh = NULL, *fhr = NULL, *fhw = NULL; size_t size; int pid, rwflags = (flags & O_ACCMODE); bool inh; bool got_one = false; if (sscanf (get_name (), "/proc/%d/fd/pipe:[%llu]", &pid, (long long *) &uniq_id) < 2) { set_errno (ENOENT); return 0; } if (pid == myself->pid) { cygheap_fdenum cfd (true); while (cfd.next () >= 0) { /* Windows doesn't allow to copy a pipe HANDLE with another access mode. So we check for read and write side of pipe and try to find the one matching the requested access mode. */ if (cfd->get_unique_id () == uniq_id) got_one = true; else if (cfd->get_unique_id () == uniq_id + 1) got_one = true; else continue; if ((rwflags == O_RDONLY && !(cfd->get_access () & GENERIC_READ)) || (rwflags == O_WRONLY && !(cfd->get_access () & GENERIC_WRITE))) continue; copy_from (cfd); set_handle (NULL); pc.close_conv_handle (); if (!cfd->dup (this, flags)) return 1; return 0; } /* Found the pipe but access mode didn't match? EACCES. Otherwise ENOENT */ set_errno (got_one ? EACCES : ENOENT); return 0; } pinfo p (pid); if (!p) { set_errno (ESRCH); return 0; } if (!(proc = OpenProcess (PROCESS_DUP_HANDLE, false, p->dwProcessId))) { __seterrno (); return 0; } fhr = p->pipe_fhandler (uniq_id, size); if (fhr && rwflags == O_RDONLY) fh = fhr; else { fhw = p->pipe_fhandler (uniq_id + 1, size); if (fhw && rwflags == O_WRONLY) fh = fhw; } if (!fh) { /* Too bad, but Windows only allows the same access mode when dup'ing the pipe. */ set_errno (fhr || fhw ? EACCES : ENOENT); goto out; } inh = !(flags & O_CLOEXEC); if (!DuplicateHandle (proc, fh->get_handle (), GetCurrentProcess (), &nio_hdl, 0, inh, DUPLICATE_SAME_ACCESS)) { __seterrno (); goto out; } init (nio_hdl, fh->get_access (), mode & O_TEXT ?: O_BINARY, fh->get_plain_ino ()); cfree (fh); CloseHandle (proc); return 1; out: if (nio_hdl) CloseHandle (nio_hdl); if (fh) free (fh); if (proc) CloseHandle (proc); return 0; } bool fhandler_pipe::open_setup (int flags) { bool read_mtx_created = false; if (!fhandler_base::open_setup (flags)) goto err; if (get_dev () == FH_PIPER && !read_mtx) { SECURITY_ATTRIBUTES *sa = sec_none_cloexec (flags); read_mtx = CreateMutex (sa, FALSE, NULL); if (read_mtx) read_mtx_created = true; else { debug_printf ("CreateMutex read_mtx failed: %E"); goto err; } } if (!hdl_cnt_mtx) { SECURITY_ATTRIBUTES *sa = sec_none_cloexec (flags); hdl_cnt_mtx = CreateMutex (sa, FALSE, NULL); if (!hdl_cnt_mtx) { debug_printf ("CreateMutex hdl_cnt_mtx failed: %E"); goto err_close_read_mtx; } } return true; err_close_read_mtx: if (read_mtx_created) CloseHandle (read_mtx); err: return false; } off_t fhandler_pipe::lseek (off_t offset, int whence) { debug_printf ("(%D, %d)", offset, whence); set_errno (ESPIPE); return -1; } int fhandler_pipe::fadvise (off_t offset, off_t length, int advice) { return ESPIPE; } int fhandler_pipe::ftruncate (off_t length, bool allow_truncate) { return allow_truncate ? EINVAL : ESPIPE; } char * fhandler_pipe::get_proc_fd_name (char *buf) { __small_sprintf (buf, "pipe:[%U]", get_plain_ino ()); return buf; } void fhandler_pipe::release_select_sem (const char *from) { LONG n_release; if (get_dev () == FH_PIPER) /* Number of select() and writer */ n_release = get_obj_handle_count (select_sem) - get_obj_handle_count (read_mtx); else /* Number of select() call and reader */ n_release = get_obj_handle_count (select_sem) - get_obj_handle_count (get_handle ()); debug_printf("%s(%s) release %d", from, get_dev () == FH_PIPER ? "PIPER" : "PIPEW", n_release); if (n_release) ReleaseSemaphore (select_sem, n_release, NULL); } void fhandler_pipe::raw_read (void *ptr, size_t& len) { size_t nbytes = 0; NTSTATUS status = STATUS_SUCCESS; IO_STATUS_BLOCK io; if (!len) return; DWORD timeout = is_nonblocking () ? 0 : INFINITE; DWORD waitret = cygwait (read_mtx, timeout); switch (waitret) { case WAIT_OBJECT_0: break; case WAIT_TIMEOUT: set_errno (EAGAIN); len = (size_t) -1; return; case WAIT_SIGNALED: set_errno (EINTR); len = (size_t) -1; return; case WAIT_CANCELED: pthread::static_cancel_self (); /* NOTREACHED */ default: /* Should not reach here. */ __seterrno (); len = (size_t) -1; return; } while (nbytes < len) { ULONG_PTR nbytes_now = 0; ULONG len1 = (ULONG) (len - nbytes); FILE_PIPE_LOCAL_INFORMATION fpli; status = NtQueryInformationFile (get_handle (), &io, &fpli, sizeof (fpli), FilePipeLocalInformation); if (NT_SUCCESS (status)) { if (fpli.ReadDataAvailable == 0 && nbytes != 0) break; } else if (nbytes != 0) break; status = NtReadFile (get_handle (), NULL, NULL, NULL, &io, ptr, len1, NULL, NULL); if (isclosed ()) /* A signal handler might have closed the fd. */ { set_errno (EBADF); nbytes = (size_t) -1; } else if (NT_SUCCESS (status) || status == STATUS_BUFFER_OVERFLOW) { nbytes_now = io.Information; ptr = ((char *) ptr) + nbytes_now; nbytes += nbytes_now; if (select_sem && nbytes_now > 0) release_select_sem ("raw_read"); } else { /* Some errors are not really errors. Detect such cases here. */ switch (status) { case STATUS_END_OF_FILE: case STATUS_PIPE_BROKEN: /* This is really EOF. */ break; case STATUS_PIPE_LISTENING: case STATUS_PIPE_EMPTY: if (nbytes != 0) break; if (is_nonblocking ()) { set_errno (EAGAIN); nbytes = (size_t) -1; break; } waitret = cygwait (select_sem, 1); if (waitret == WAIT_CANCELED) pthread::static_cancel_self (); else if (waitret == WAIT_SIGNALED) { set_errno (EINTR); nbytes = (size_t) -1; break; } continue; default: __seterrno_from_nt_status (status); nbytes = (size_t) -1; break; } } if ((nbytes_now == 0 && !NT_SUCCESS (status)) || status == STATUS_BUFFER_OVERFLOW) break; } ReleaseMutex (read_mtx); len = nbytes; } bool fhandler_pipe::reader_closed () { if (!query_hdl) return false; WaitForSingleObject (hdl_cnt_mtx, INFINITE); int n_reader = get_obj_handle_count (query_hdl); int n_writer = get_obj_handle_count (get_handle ()); ReleaseMutex (hdl_cnt_mtx); return n_reader == n_writer; } ssize_t fhandler_pipe_fifo::raw_write (const void *ptr, size_t len) { size_t nbytes = 0; ULONG chunk; NTSTATUS status = STATUS_SUCCESS; IO_STATUS_BLOCK io; HANDLE evt; if (!len) return 0; if (reader_closed ()) { set_errno (EPIPE); raise (SIGPIPE); return -1; } if (len <= pipe_buf_size || pipe_buf_size == 0) chunk = len; else if (is_nonblocking ()) chunk = len = pipe_buf_size; else chunk = pipe_buf_size; if (!(evt = CreateEvent (NULL, false, false, NULL))) { __seterrno (); return -1; } /* Write in chunks, accumulating a total. If there's an error, just return the accumulated total unless the first write fails, in which case return -1. */ while (nbytes < len) { ULONG_PTR nbytes_now = 0; size_t left = len - nbytes; ULONG len1; DWORD waitret = WAIT_OBJECT_0; if (left > chunk) len1 = chunk; else len1 = (ULONG) left; /* NtWriteFile returns success with # of bytes written == 0 if writing on a non-blocking pipe fails because the pipe buffer doesn't have sufficient space. POSIX requires - A write request for {PIPE_BUF} or fewer bytes shall have the following effect: if there is sufficient space available in the pipe, write() shall transfer all the data and return the number of bytes requested. Otherwise, write() shall transfer no data and return -1 with errno set to [EAGAIN]. - A write request for more than {PIPE_BUF} bytes shall cause one of the following: - When at least one byte can be written, transfer what it can and return the number of bytes written. When all data previously written to the pipe is read, it shall transfer at least {PIPE_BUF} bytes. - When no data can be written, transfer no data, and return -1 with errno set to [EAGAIN]. */ while (len1 > 0) { status = NtWriteFile (get_handle (), evt, NULL, NULL, &io, (PVOID) ptr, len1, NULL, NULL); if (status == STATUS_PENDING) { while (WAIT_TIMEOUT == (waitret = cygwait (evt, (DWORD) 0, cw_cancel | cw_sig))) { if (reader_closed ()) { CancelIo (get_handle ()); set_errno (EPIPE); raise (SIGPIPE); goto out; } else cygwait (select_sem, 10); } /* If io.Status is STATUS_CANCELLED after CancelIo, IO has actually been cancelled and io.Information contains the number of bytes processed so far. Otherwise IO has been finished regulary and io.Status contains valid success or error information. */ CancelIo (get_handle ()); if (waitret == WAIT_SIGNALED && io.Status != STATUS_CANCELLED) waitret = WAIT_OBJECT_0; if (waitret == WAIT_CANCELED) status = STATUS_THREAD_CANCELED; else if (waitret == WAIT_SIGNALED) status = STATUS_THREAD_SIGNALED; else status = io.Status; } if (!is_nonblocking () || !NT_SUCCESS (status) || io.Information > 0 || len <= PIPE_BUF) break; len1 >>= 1; } if (isclosed ()) /* A signal handler might have closed the fd. */ { if (waitret == WAIT_OBJECT_0) set_errno (EBADF); else __seterrno (); } else if (NT_SUCCESS (status) || status == STATUS_THREAD_CANCELED || status == STATUS_THREAD_SIGNALED) { nbytes_now = io.Information; ptr = ((char *) ptr) + nbytes_now; nbytes += nbytes_now; if (select_sem && nbytes_now > 0) release_select_sem ("raw_write"); /* 0 bytes returned? EAGAIN. See above. */ if (NT_SUCCESS (status) && nbytes == 0) set_errno (EAGAIN); } else if (STATUS_PIPE_IS_CLOSED (status)) { set_errno (EPIPE); raise (SIGPIPE); } else __seterrno_from_nt_status (status); if (nbytes_now == 0) break; } out: CloseHandle (evt); if (status == STATUS_THREAD_SIGNALED && nbytes == 0) set_errno (EINTR); else if (status == STATUS_THREAD_CANCELED) pthread::static_cancel_self (); return nbytes ?: -1; } void fhandler_pipe::set_close_on_exec (bool val) { fhandler_base::set_close_on_exec (val); if (read_mtx) set_no_inheritance (read_mtx, val); if (select_sem) set_no_inheritance (select_sem, val); if (query_hdl) set_no_inheritance (query_hdl, val); set_no_inheritance (hdl_cnt_mtx, val); } void fhandler_pipe::fixup_after_fork (HANDLE parent) { fork_fixup (parent, hdl_cnt_mtx, "hdl_cnt_mtx"); WaitForSingleObject (hdl_cnt_mtx, INFINITE); if (read_mtx) fork_fixup (parent, read_mtx, "read_mtx"); if (select_sem) fork_fixup (parent, select_sem, "select_sem"); if (query_hdl) fork_fixup (parent, query_hdl, "query_hdl"); if (query_hdl_close_req_evt) fork_fixup (parent, query_hdl_close_req_evt, "query_hdl_close_req_evt"); fhandler_base::fixup_after_fork (parent); ReleaseMutex (hdl_cnt_mtx); } int fhandler_pipe::dup (fhandler_base *child, int flags) { fhandler_pipe *ftp = (fhandler_pipe *) child; ftp->set_popen_pid (0); int res = 0; WaitForSingleObject (hdl_cnt_mtx, INFINITE); if (fhandler_base::dup (child, flags)) res = -1; else if (read_mtx && !DuplicateHandle (GetCurrentProcess (), read_mtx, GetCurrentProcess (), &ftp->read_mtx, 0, !(flags & O_CLOEXEC), DUPLICATE_SAME_ACCESS)) { __seterrno (); ftp->close (); res = -1; } else if (select_sem && !DuplicateHandle (GetCurrentProcess (), select_sem, GetCurrentProcess (), &ftp->select_sem, 0, !(flags & O_CLOEXEC), DUPLICATE_SAME_ACCESS)) { __seterrno (); ftp->close (); res = -1; } else if (query_hdl && !DuplicateHandle (GetCurrentProcess (), query_hdl, GetCurrentProcess (), &ftp->query_hdl, 0, !(flags & O_CLOEXEC), DUPLICATE_SAME_ACCESS)) { __seterrno (); ftp->close (); res = -1; } else if (!DuplicateHandle (GetCurrentProcess (), hdl_cnt_mtx, GetCurrentProcess (), &ftp->hdl_cnt_mtx, 0, !(flags & O_CLOEXEC), DUPLICATE_SAME_ACCESS)) { __seterrno (); ftp->close (); res = -1; } else if (query_hdl_close_req_evt && !DuplicateHandle (GetCurrentProcess (), query_hdl_close_req_evt, GetCurrentProcess (), &ftp->query_hdl_close_req_evt, 0, !(flags & O_CLOEXEC), DUPLICATE_SAME_ACCESS)) { __seterrno (); ftp->close (); res = -1; } ReleaseMutex (hdl_cnt_mtx); debug_printf ("res %d", res); return res; } int fhandler_pipe::close () { if (select_sem) { release_select_sem ("close"); CloseHandle (select_sem); } if (read_mtx) CloseHandle (read_mtx); WaitForSingleObject (hdl_cnt_mtx, INFINITE); if (query_hdl) CloseHandle (query_hdl); if (query_hdl_close_req_evt) CloseHandle (query_hdl_close_req_evt); int ret = fhandler_base::close (); ReleaseMutex (hdl_cnt_mtx); CloseHandle (hdl_cnt_mtx); if (query_hdl_proc) CloseHandle (query_hdl_proc); return ret; } #define PIPE_INTRO "\\\\.\\pipe\\cygwin-" /* Create a pipe, and return handles to the read and write ends, just like CreatePipe, but ensure that the write end permits FILE_READ_ATTRIBUTES access, on later versions of win32 where this is supported. This access is needed by NtQueryInformationFile, which is used to implement select and nonblocking writes. Note that the return value is either 0 or GetLastError, unlike CreatePipe, which returns a bool for success or failure. */ DWORD fhandler_pipe::create (LPSECURITY_ATTRIBUTES sa_ptr, PHANDLE r, PHANDLE w, DWORD psize, const char *name, DWORD open_mode, int64_t *unique_id) { /* Default to error. */ if (r) *r = NULL; if (w) *w = NULL; /* Ensure that there is enough pipe buffer space for atomic writes. */ if (!psize) psize = DEFAULT_PIPEBUFSIZE; char pipename[MAX_PATH]; size_t len = __small_sprintf (pipename, PIPE_INTRO "%S-", &cygheap->installation_key); DWORD pipe_mode = PIPE_READMODE_BYTE | PIPE_REJECT_REMOTE_CLIENTS; if (!name) pipe_mode |= pipe_byte ? PIPE_TYPE_BYTE : PIPE_TYPE_MESSAGE; else pipe_mode |= PIPE_TYPE_MESSAGE; if (!name || (open_mode & PIPE_ADD_PID)) { len += __small_sprintf (pipename + len, "%u-", GetCurrentProcessId ()); open_mode &= ~PIPE_ADD_PID; } if (name) len += __small_sprintf (pipename + len, "%s", name); open_mode |= PIPE_ACCESS_INBOUND | FILE_FLAG_FIRST_PIPE_INSTANCE; /* Retry CreateNamedPipe as long as the pipe name is in use. Retrying will probably never be necessary, but we want to be as robust as possible. */ DWORD err = 0; while (r && !*r) { static volatile ULONG pipe_unique_id; if (!name) { LONG id = InterlockedIncrement ((LONG *) &pipe_unique_id); __small_sprintf (pipename + len, "pipe-%p", id); if (unique_id) *unique_id = ((int64_t) id << 32 | GetCurrentProcessId ()); } debug_printf ("name %s, size %u, mode %s", pipename, psize, (pipe_mode & PIPE_TYPE_MESSAGE) ? "PIPE_TYPE_MESSAGE" : "PIPE_TYPE_BYTE"); /* Use CreateNamedPipe instead of CreatePipe, because the latter returns a write handle that does not permit FILE_READ_ATTRIBUTES access, on versions of win32 earlier than WinXP SP2. CreatePipe also stupidly creates a full duplex pipe, which is a waste, since only a single direction is actually used. It's important to only allow a single instance, to ensure that the pipe was not created earlier by some other process, even if the pid has been reused. Note that the write side of the pipe is opened as PIPE_TYPE_MESSAGE. This *seems* to more closely mimic Linux pipe behavior and is definitely required for pty handling since fhandler_pty_master writes to the pipe in chunks, terminated by newline when CANON mode is specified. */ *r = CreateNamedPipe (pipename, open_mode, pipe_mode, 1, psize, psize, NMPWAIT_USE_DEFAULT_WAIT, sa_ptr); if (*r != INVALID_HANDLE_VALUE) { debug_printf ("pipe read handle %p", *r); err = 0; break; } err = GetLastError (); switch (err) { case ERROR_PIPE_BUSY: /* The pipe is already open with compatible parameters. Pick a new name and retry. */ debug_printf ("pipe busy", !name ? ", retrying" : ""); if (!name) *r = NULL; break; case ERROR_ACCESS_DENIED: /* The pipe is already open with incompatible parameters. Pick a new name and retry. */ debug_printf ("pipe access denied%s", !name ? ", retrying" : ""); if (!name) *r = NULL; break; default: { err = GetLastError (); debug_printf ("failed, %E"); } } } if (err) { *r = NULL; return err; } if (!w) debug_printf ("pipe write handle NULL"); else { debug_printf ("CreateFile: name %s", pipename); /* Open the named pipe for writing. Be sure to permit FILE_READ_ATTRIBUTES access. */ DWORD access = GENERIC_WRITE | FILE_READ_ATTRIBUTES; if ((open_mode & PIPE_ACCESS_DUPLEX) == PIPE_ACCESS_DUPLEX) access |= GENERIC_READ | FILE_WRITE_ATTRIBUTES; *w = CreateFile (pipename, access, 0, sa_ptr, OPEN_EXISTING, open_mode & FILE_FLAG_OVERLAPPED, 0); if (!*w || *w == INVALID_HANDLE_VALUE) { /* Failure. */ DWORD err = GetLastError (); debug_printf ("CreateFile failed, r %p, %E", r); if (r) CloseHandle (*r); *w = NULL; return err; } debug_printf ("pipe write handle %p", *w); } /* Success. */ return 0; } inline static bool is_running_as_service (void) { return check_token_membership (well_known_service_sid) || cygheap->user.saved_sid () == well_known_system_sid; } /* The next version of fhandler_pipe::create used to call the previous version. But the read handle created by the latter doesn't have FILE_WRITE_ATTRIBUTES access unless the pipe is created with PIPE_ACCESS_DUPLEX, and it doesn't seem possible to add that access right. This causes set_pipe_non_blocking to fail. To fix this we will define a helper function 'nt_create' that is similar to the above fhandler_pipe::create but uses NtCreateNamedPipeFile instead of CreateNamedPipe; this gives more flexibility in setting the access rights. We will use this helper function in the version of fhandler_pipe::create below, which suffices for all of our uses of set_pipe_non_blocking. For simplicity, nt_create will omit the 'open_mode' and 'name' parameters, which aren't needed for our purposes. */ static int nt_create (LPSECURITY_ATTRIBUTES, HANDLE &, HANDLE &, DWORD, int64_t *); int fhandler_pipe::create (fhandler_pipe *fhs[2], unsigned psize, int mode) { HANDLE r, w; SECURITY_ATTRIBUTES *sa = sec_none_cloexec (mode); int res = -1; int64_t unique_id; int ret = nt_create (sa, r, w, psize, &unique_id); if (ret) { __seterrno_from_win_error (ret); goto out; } if ((fhs[0] = (fhandler_pipe *) build_fh_dev (*piper_dev)) == NULL) goto err_close_rw_handle; if ((fhs[1] = (fhandler_pipe *) build_fh_dev (*pipew_dev)) == NULL) goto err_delete_fhs0; mode |= mode & O_TEXT ?: O_BINARY; fhs[0]->init (r, FILE_CREATE_PIPE_INSTANCE | GENERIC_READ, mode, unique_id); fhs[1]->init (w, FILE_CREATE_PIPE_INSTANCE | GENERIC_WRITE, mode, unique_id); /* For the read side of the pipe, add a mutex. See raw_read for the usage. */ fhs[0]->read_mtx = CreateMutexW (sa, FALSE, NULL); if (!fhs[0]->read_mtx) goto err_delete_fhs1; fhs[0]->select_sem = CreateSemaphore (sa, 0, INT32_MAX, NULL); if (!fhs[0]->select_sem) goto err_close_read_mtx; if (!DuplicateHandle (GetCurrentProcess (), fhs[0]->select_sem, GetCurrentProcess (), &fhs[1]->select_sem, 0, sa->bInheritHandle, DUPLICATE_SAME_ACCESS)) goto err_close_select_sem0; if (is_running_as_service () && !DuplicateHandle (GetCurrentProcess (), r, GetCurrentProcess (), &fhs[1]->query_hdl, FILE_READ_DATA, sa->bInheritHandle, 0)) goto err_close_select_sem1; fhs[0]->hdl_cnt_mtx = CreateMutexW (sa, FALSE, NULL); if (!fhs[0]->hdl_cnt_mtx) goto err_close_query_hdl; if (!DuplicateHandle (GetCurrentProcess (), fhs[0]->hdl_cnt_mtx, GetCurrentProcess (), &fhs[1]->hdl_cnt_mtx, 0, sa->bInheritHandle, DUPLICATE_SAME_ACCESS)) goto err_close_hdl_cnt_mtx0; if (fhs[1]->query_hdl) { fhs[1]->query_hdl_close_req_evt = CreateEvent (sa, TRUE, FALSE, NULL); if (!fhs[1]->query_hdl_close_req_evt) goto err_close_hdl_cnt_mtx1; } res = 0; goto out; err_close_hdl_cnt_mtx1: CloseHandle (fhs[1]->hdl_cnt_mtx); err_close_hdl_cnt_mtx0: CloseHandle (fhs[0]->hdl_cnt_mtx); err_close_query_hdl: if (fhs[1]->query_hdl) CloseHandle (fhs[1]->query_hdl); err_close_select_sem1: CloseHandle (fhs[1]->select_sem); err_close_select_sem0: CloseHandle (fhs[0]->select_sem); err_close_read_mtx: CloseHandle (fhs[0]->read_mtx); err_delete_fhs1: delete fhs[1]; err_delete_fhs0: delete fhs[0]; err_close_rw_handle: NtClose (r); NtClose (w); out: debug_printf ("%R = pipe([%p, %p], %d, %y)", res, fhs[0], fhs[1], psize, mode); return res; } static int nt_create (LPSECURITY_ATTRIBUTES sa_ptr, HANDLE &r, HANDLE &w, DWORD psize, int64_t *unique_id) { NTSTATUS status; HANDLE npfsh; ACCESS_MASK access; OBJECT_ATTRIBUTES attr; IO_STATUS_BLOCK io; LARGE_INTEGER timeout; /* Default to error. */ r = NULL; w = NULL; status = fhandler_base::npfs_handle (npfsh); if (!NT_SUCCESS (status)) { __seterrno_from_nt_status (status); return GetLastError (); } /* Ensure that there is enough pipe buffer space for atomic writes. */ if (!psize) psize = DEFAULT_PIPEBUFSIZE; UNICODE_STRING pipename; WCHAR pipename_buf[MAX_PATH]; size_t len = __small_swprintf (pipename_buf, L"%S-%u-", &cygheap->installation_key, GetCurrentProcessId ()); access = GENERIC_READ | FILE_WRITE_ATTRIBUTES | SYNCHRONIZE; access |= FILE_WRITE_EA; /* Add this right as a marker of cygwin read pipe */ ULONG pipe_type = pipe_byte ? FILE_PIPE_BYTE_STREAM_TYPE : FILE_PIPE_MESSAGE_TYPE; /* Retry NtCreateNamedPipeFile as long as the pipe name is in use. Retrying will probably never be necessary, but we want to be as robust as possible. */ DWORD err = 0; while (!r) { static volatile ULONG pipe_unique_id; LONG id = InterlockedIncrement ((LONG *) &pipe_unique_id); __small_swprintf (pipename_buf + len, L"pipe-nt-%p", id); if (unique_id) *unique_id = ((int64_t) id << 32 | GetCurrentProcessId ()); debug_printf ("name %W, size %u, mode %s", pipename_buf, psize, (pipe_type & FILE_PIPE_MESSAGE_TYPE) ? "PIPE_TYPE_MESSAGE" : "PIPE_TYPE_BYTE"); RtlInitUnicodeString (&pipename, pipename_buf); InitializeObjectAttributes (&attr, &pipename, sa_ptr->bInheritHandle ? OBJ_INHERIT : 0, npfsh, sa_ptr->lpSecurityDescriptor); timeout.QuadPart = -500000; /* Set FILE_SYNCHRONOUS_IO_NONALERT flag so that native C# programs work with cygwin pipe. */ status = NtCreateNamedPipeFile (&r, access, &attr, &io, FILE_SHARE_READ | FILE_SHARE_WRITE, FILE_CREATE, FILE_SYNCHRONOUS_IO_NONALERT, pipe_type, FILE_PIPE_BYTE_STREAM_MODE, 0, 1, psize, psize, &timeout); if (NT_SUCCESS (status)) { debug_printf ("pipe read handle %p", r); err = 0; break; } switch (status) { case STATUS_PIPE_BUSY: case STATUS_INSTANCE_NOT_AVAILABLE: case STATUS_PIPE_NOT_AVAILABLE: /* The pipe is already open with compatible parameters. Pick a new name and retry. */ debug_printf ("pipe busy, retrying"); r = NULL; break; case STATUS_ACCESS_DENIED: /* The pipe is already open with incompatible parameters. Pick a new name and retry. */ debug_printf ("pipe access denied, retrying"); r = NULL; break; default: { __seterrno_from_nt_status (status); err = GetLastError (); debug_printf ("failed, %E"); r = NULL; } } } if (err) { r = NULL; return err; } debug_printf ("NtOpenFile: name %S", &pipename); access = GENERIC_WRITE | FILE_READ_ATTRIBUTES | SYNCHRONIZE; status = NtOpenFile (&w, access, &attr, &io, 0, 0); if (!NT_SUCCESS (status)) { DWORD err = GetLastError (); debug_printf ("NtOpenFile failed, r %p, %E", r); if (r) NtClose (r); w = NULL; return err; } /* Success. */ return 0; } /* Called by dtable::init_std_file_from_handle for stdio handles inherited from non-Cygwin processes. */ void fhandler_pipe::set_pipe_buf_size () { NTSTATUS status; IO_STATUS_BLOCK io; FILE_PIPE_LOCAL_INFORMATION fpli; status = NtQueryInformationFile (get_handle (), &io, &fpli, sizeof fpli, FilePipeLocalInformation); if (NT_SUCCESS (status)) pipe_buf_size = fpli.InboundQuota; } int fhandler_pipe::ioctl (unsigned int cmd, void *p) { int n; switch (cmd) { case FIONREAD: if (get_device () == FH_PIPEW) { set_errno (EINVAL); return -1; } if (!PeekNamedPipe (get_handle (), NULL, 0, NULL, (DWORD *) &n, NULL)) { __seterrno (); return -1; } break; default: return fhandler_base::ioctl (cmd, p); break; } *(int *) p = n; return 0; } int fhandler_pipe::fcntl (int cmd, intptr_t arg) { if (cmd != F_SETFL) return fhandler_base::fcntl (cmd, arg); const bool was_nonblocking = is_nonblocking (); int res = fhandler_base::fcntl (cmd, arg); const bool now_nonblocking = is_nonblocking (); /* Do not set blocking mode for read pipe to allow signal handling even with FILE_SYNCHRONOUS_IO_NONALERT. */ if (now_nonblocking != was_nonblocking && get_device () != FH_PIPER) set_pipe_non_blocking (now_nonblocking); return res; } int fhandler_pipe::fstat (struct stat *buf) { int ret = fhandler_base::fstat (buf); if (!ret) { buf->st_dev = FH_PIPE; if (!(buf->st_ino = get_plain_ino ())) sscanf (get_name (), "/proc/%*d/fd/pipe:[%llu]", (long long *) &buf->st_ino); } return ret; } int fhandler_pipe::fstatvfs (struct statvfs *sfs) { set_errno (EBADF); return -1; } HANDLE fhandler_pipe::temporary_query_hdl () { if (get_dev () != FH_PIPEW) return NULL; ULONG len; NTSTATUS status; tmp_pathbuf tp; OBJECT_NAME_INFORMATION *ntfn = (OBJECT_NAME_INFORMATION *) tp.w_get (); /* Try process handle opened and pipe handle value cached first in order to reduce overhead. */ if (query_hdl_proc && query_hdl_value) { HANDLE h; if (!DuplicateHandle (query_hdl_proc, query_hdl_value, GetCurrentProcess (), &h, FILE_READ_DATA, 0, 0)) goto cache_err; /* Check name */ status = NtQueryObject (h, ObjectNameInformation, ntfn, 65536, &len); if (!NT_SUCCESS (status) || !ntfn->Name.Buffer) goto hdl_err; ntfn->Name.Buffer[ntfn->Name.Length / sizeof (WCHAR)] = L'\0'; uint64_t key; DWORD pid; LONG id; if (swscanf (ntfn->Name.Buffer, L"\\Device\\NamedPipe\\%llx-%u-pipe-nt-0x%x", &key, &pid, &id) == 3 && key == pipename_key && pid == pipename_pid && id == pipename_id) return h; hdl_err: CloseHandle (h); cache_err: CloseHandle (query_hdl_proc); query_hdl_proc = NULL; query_hdl_value = NULL; } status = NtQueryObject (get_handle (), ObjectNameInformation, ntfn, 65536, &len); if (!NT_SUCCESS (status) || !ntfn->Name.Buffer) return NULL; /* Non cygwin pipe? */ WCHAR name[MAX_PATH]; int namelen = min (ntfn->Name.Length / sizeof (WCHAR), MAX_PATH-1); memcpy (name, ntfn->Name.Buffer, namelen * sizeof (WCHAR)); name[namelen] = L'\0'; if (swscanf (name, L"\\Device\\NamedPipe\\%llx-%u-pipe-nt-0x%x", &pipename_key, &pipename_pid, &pipename_id) != 3) return NULL; /* Non cygwin pipe? */ return get_query_hdl_per_process (name, ntfn); /* Since Win8 */ } HANDLE fhandler_pipe::get_query_hdl_per_process (WCHAR *name, OBJECT_NAME_INFORMATION *ntfn) { NTSTATUS status; ULONG len; DWORD n_process = 256; PSYSTEM_PROCESS_INFORMATION spi; do { /* Enumerate processes */ DWORD nbytes = n_process * sizeof (SYSTEM_PROCESS_INFORMATION); spi = (PSYSTEM_PROCESS_INFORMATION) HeapAlloc (GetProcessHeap (), 0, nbytes); if (!spi) return NULL; status = NtQuerySystemInformation (SystemProcessInformation, spi, nbytes, &len); if (NT_SUCCESS (status)) break; HeapFree (GetProcessHeap (), 0, spi); n_process *= 2; } while (n_process < (1L<<20) && status == STATUS_INFO_LENGTH_MISMATCH); if (!NT_SUCCESS (status)) return NULL; /* In most cases, it is faster to check the processes in reverse order. To do this, store PIDs into an array. */ DWORD *proc_pids = (DWORD *) HeapAlloc (GetProcessHeap (), 0, n_process * sizeof (DWORD)); if (!proc_pids) { HeapFree (GetProcessHeap (), 0, spi); return NULL; } PSYSTEM_PROCESS_INFORMATION p = spi; n_process = 0; while (true) { proc_pids[n_process++] = (DWORD)(intptr_t) p->UniqueProcessId; if (!p->NextEntryOffset) break; p = (PSYSTEM_PROCESS_INFORMATION) ((char *) p + p->NextEntryOffset); } HeapFree (GetProcessHeap (), 0, spi); for (LONG i = (LONG) n_process - 1; i >= 0; i--) { HANDLE proc = OpenProcess (PROCESS_DUP_HANDLE | PROCESS_QUERY_INFORMATION, 0, proc_pids[i]); if (!proc) continue; /* Retrieve process handles */ DWORD n_handle = 256; PPROCESS_HANDLE_SNAPSHOT_INFORMATION phi; do { DWORD nbytes = 2 * sizeof (ULONG_PTR) + n_handle * sizeof (PROCESS_HANDLE_TABLE_ENTRY_INFO); phi = (PPROCESS_HANDLE_SNAPSHOT_INFORMATION) HeapAlloc (GetProcessHeap (), 0, nbytes); if (!phi) goto close_proc; /* NtQueryInformationProcess can return STATUS_SUCCESS with invalid handle data for certain processes. See https://github.com/processhacker/processhacker/blob/05f5e9fa477dcaa1709d9518170d18e1b3b8330d/phlib/native.c#L5754. We need to ensure that NumberOfHandles is zero in this case to avoid a crash in the for loop below. */ phi->NumberOfHandles = 0; status = NtQueryInformationProcess (proc, ProcessHandleInformation, phi, nbytes, &len); if (NT_SUCCESS (status)) break; HeapFree (GetProcessHeap (), 0, phi); n_handle *= 2; } while (n_handle < (1L<<20) && status == STATUS_INFO_LENGTH_MISMATCH); if (!NT_SUCCESS (status)) goto close_proc; /* Sanity check in case Microsoft changes NtQueryInformationProcess and the initialization of NumberOfHandles above is no longer sufficient. */ assert (phi->NumberOfHandles <= n_handle); for (ULONG j = 0; j < phi->NumberOfHandles; j++) { /* Check for the peculiarity of cygwin read pipe */ const ULONG access = FILE_READ_DATA | FILE_READ_EA | FILE_WRITE_EA /* marker */ | FILE_READ_ATTRIBUTES | FILE_WRITE_ATTRIBUTES | READ_CONTROL | SYNCHRONIZE; if (phi->Handles[j].GrantedAccess != access) continue; /* Retrieve handle */ HANDLE h = (HANDLE)(intptr_t) phi->Handles[j].HandleValue; BOOL res = DuplicateHandle (proc, h, GetCurrentProcess (), &h, FILE_READ_DATA, 0, 0); if (!res) continue; /* Check object name */ status = NtQueryObject (h, ObjectNameInformation, ntfn, 65536, &len); if (!NT_SUCCESS (status) || !ntfn->Name.Buffer) goto close_handle; ntfn->Name.Buffer[ntfn->Name.Length / sizeof (WCHAR)] = L'\0'; if (wcscmp (name, ntfn->Name.Buffer) == 0) { query_hdl_proc = proc; query_hdl_value = (HANDLE)(intptr_t) phi->Handles[j].HandleValue; HeapFree (GetProcessHeap (), 0, phi); HeapFree (GetProcessHeap (), 0, proc_pids); return h; } close_handle: CloseHandle (h); } HeapFree (GetProcessHeap (), 0, phi); close_proc: CloseHandle (proc); } HeapFree (GetProcessHeap (), 0, proc_pids); return NULL; }