/** \file io.c Utilities for io redirection. */ #include "config.h" #include #include #include #include #include #include #include #include #ifdef HAVE_SYS_TERMIOS_H #include #endif #ifdef HAVE_SYS_IOCTL_H #include #endif #include #include #if HAVE_NCURSES_H #include #else #include #endif #if HAVE_TERMIO_H #include #endif #if HAVE_TERM_H #include #elif HAVE_NCURSES_TERM_H #include #endif #include "fallback.h" #include "util.h" #include "wutil.h" #include "exec.h" #include "common.h" #include "io.h" void io_buffer_read(io_data_t *d) { exec_close(d->param1.pipe_fd[1]); if (d->io_mode == IO_BUFFER) { /* if( fcntl( d->param1.pipe_fd[0], F_SETFL, 0 ) ) { wperror( L"fcntl" ); return; } */ debug(4, L"io_buffer_read: blocking read on fd %d", d->param1.pipe_fd[0]); while (1) { char b[4096]; long l; l=read_blocked(d->param1.pipe_fd[0], b, 4096); if (l==0) { break; } else if (l<0) { /* exec_read_io_buffer is only called on jobs that have exited, and will therefore never block. But a broken pipe seems to cause some flags to reset, causing the EOF flag to not be set. Therefore, EAGAIN is ignored and we exit anyway. */ if (errno != EAGAIN) { debug(1, _(L"An error occured while reading output from code block on file descriptor %d"), d->param1.pipe_fd[0]); wperror(L"io_buffer_read"); } break; } else { d->out_buffer_append(b, l); } } } } io_data_t *io_buffer_create(bool is_input) { bool success = true; io_data_t *buffer_redirect = new io_data_t; buffer_redirect->out_buffer_create(); buffer_redirect->io_mode = IO_BUFFER; buffer_redirect->is_input = is_input ? true : false; buffer_redirect->fd=is_input?0:1; if (exec_pipe(buffer_redirect->param1.pipe_fd) == -1) { debug(1, PIPE_ERROR); wperror(L"pipe"); success = false; } else if (fcntl(buffer_redirect->param1.pipe_fd[0], F_SETFL, O_NONBLOCK)) { debug(1, PIPE_ERROR); wperror(L"fcntl"); success = false; } if (! success) { delete buffer_redirect; buffer_redirect = NULL; } return buffer_redirect; } void io_buffer_destroy(shared_ptr io_buffer) { /** If this is an input buffer, then io_read_buffer will not have been called, and we need to close the output fd as well. */ if (io_buffer->is_input) { exec_close(io_buffer->param1.pipe_fd[1]); } exec_close(io_buffer->param1.pipe_fd[0]); /* Dont free fd for writing. This should already be free'd before calling exec_read_io_buffer on the buffer */ } void io_chain_t::remove(shared_ptr element) { // See if you can guess why std::find doesn't work here for (io_chain_t::iterator iter = this->begin(); iter != this->end(); ++iter) { if (*iter == element) { this->erase(iter); break; } } } io_chain_t io_chain_t::duplicate() const { io_chain_t result; result.reserve(this->size()); for (io_chain_t::const_iterator iter = this->begin(); iter != this->end(); iter++) { result.push_back(shared_ptr(new io_data_t(**iter))); } return result; } void io_chain_t::duplicate_prepend(const io_chain_t &src) { /* Prepend a duplicate of src before this. Start by inserting a bunch of empty shared_ptr's (so we only have to reallocate once) and then replace them. */ this->insert(this->begin(), src.size(), shared_ptr()); for (size_t idx = 0; idx < src.size(); idx++) { this->at(idx).reset(new io_data_t(*src.at(idx))); } } void io_chain_t::destroy() { for (size_t idx = 0; idx < this->size(); idx++) { this->at(idx).reset(); } this->clear(); } void io_remove(io_chain_t &list, shared_ptr element) { list.remove(element); } io_chain_t io_duplicate(const io_chain_t &chain) { return chain.duplicate(); } void io_print(const io_chain_t &chain) { if (chain.empty()) { fprintf(stderr, "Empty chain %p\n", &chain); return; } fprintf(stderr, "Chain %p (%ld items):\n", &chain, (long)chain.size()); for (size_t i=0; i < chain.size(); i++) { shared_ptr io = chain.at(i); fprintf(stderr, "\t%lu: fd:%d, input:%s, ", (unsigned long)i, io->fd, io->is_input ? "yes" : "no"); switch (io->io_mode) { case IO_FILE: fprintf(stderr, "file (%s)\n", io->filename_cstr); break; case IO_PIPE: fprintf(stderr, "pipe {%d, %d}\n", io->param1.pipe_fd[0], io->param1.pipe_fd[1]); break; case IO_FD: fprintf(stderr, "FD map %d -> %d\n", io->param1.old_fd, io->fd); break; case IO_BUFFER: fprintf(stderr, "buffer %p (size %lu)\n", io->out_buffer_ptr(), io->out_buffer_size()); break; case IO_CLOSE: fprintf(stderr, "close %d\n", io->fd); break; } } } void io_duplicate_prepend(const io_chain_t &src, io_chain_t &dst) { return dst.duplicate_prepend(src); } void io_chain_destroy(io_chain_t &chain) { chain.destroy(); } /* Return the last IO for the given fd */ shared_ptr io_chain_t::get_io_for_fd(int fd) const { size_t idx = this->size(); while (idx--) { shared_ptr data = this->at(idx); if (data->fd == fd) { return data; } } return shared_ptr(); } shared_ptr io_chain_t::get_io_for_fd(int fd) { size_t idx = this->size(); while (idx--) { shared_ptr data = this->at(idx); if (data->fd == fd) { return data; } } return shared_ptr(); } /* The old function returned the last match, so we mimic that. */ shared_ptr io_chain_get(const io_chain_t &src, int fd) { return src.get_io_for_fd(fd); } shared_ptr io_chain_get(io_chain_t &src, int fd) { return src.get_io_for_fd(fd); } io_chain_t::io_chain_t(shared_ptr data) : std::vector >(1, data) { } io_chain_t::io_chain_t() : std::vector >() { }