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//========================================================================== // // io/serial/common/serial.c // // High level serial driver // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos is free software; you can redistribute it and/or modify it under // the terms of the GNU General Public License as published by the Free // Software Foundation; either version 2 or (at your option) any later version. // // eCos is distributed in the hope that it will be useful, but WITHOUT ANY // WARRANTY; without even the implied warranty of MERCHANTABILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): gthomas // Contributors: gthomas, grante, jlarmour, jskov // Date: 1999-02-04 // Purpose: Top level serial driver // Description: // //####DESCRIPTIONEND#### // //========================================================================== #include <pkgconf/io.h> #include <pkgconf/io_serial.h> #include <cyg/io/io.h> #include <cyg/io/devtab.h> #include <cyg/io/serial.h> #include <cyg/infra/cyg_ass.h> // assertion support #include <cyg/infra/diag.h> // diagnostic output static Cyg_ErrNo serial_write(cyg_io_handle_t handle, const void *buf, cyg_uint32 *len); static Cyg_ErrNo serial_read(cyg_io_handle_t handle, void *buf, cyg_uint32 *len); static Cyg_ErrNo serial_select(cyg_io_handle_t handle, cyg_uint32 which, CYG_ADDRWORD info); static Cyg_ErrNo serial_get_config(cyg_io_handle_t handle, cyg_uint32 key, void *buf, cyg_uint32 *len); static Cyg_ErrNo serial_set_config(cyg_io_handle_t handle, cyg_uint32 key, const void *buf, cyg_uint32 *len); DEVIO_TABLE(cyg_io_serial_devio, serial_write, serial_read, serial_select, serial_get_config, serial_set_config ); static void serial_init(serial_channel *chan); static void serial_xmt_char(serial_channel *chan); static void serial_rcv_char(serial_channel *chan, unsigned char c); #ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS static void serial_indicate_status(serial_channel *chan, cyg_serial_line_status_t *s); #endif #if CYGINT_IO_SERIAL_BLOCK_TRANSFER static rcv_req_reply_t serial_data_rcv_req(serial_channel *chan, int avail, int* space_avail, unsigned char** space); static void serial_data_rcv_done(serial_channel *chan, int chars_rcvd); static xmt_req_reply_t serial_data_xmt_req(serial_channel *chan, int space, int* chars_avail, unsigned char** chars); static void serial_data_xmt_done(serial_channel *chan, int chars_sent); # ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS SERIAL_CALLBACKS(cyg_io_serial_callbacks, serial_init, serial_xmt_char, serial_rcv_char, serial_data_rcv_req, serial_data_rcv_done, serial_data_xmt_req, serial_data_xmt_done, serial_indicate_status); # else SERIAL_CALLBACKS(cyg_io_serial_callbacks, serial_init, serial_xmt_char, serial_rcv_char, serial_data_rcv_req, serial_data_rcv_done, serial_data_xmt_req, serial_data_xmt_done); # endif #else # ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS SERIAL_CALLBACKS(cyg_io_serial_callbacks, serial_init, serial_xmt_char, serial_rcv_char, serial_indicate_status); # else SERIAL_CALLBACKS(cyg_io_serial_callbacks, serial_init, serial_xmt_char, serial_rcv_char); # endif #endif // --------------------------------------------------------------------------- #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL static __inline__ void throttle_tx( serial_channel *chan ) { chan->flow_desc.flags |= CYG_SERIAL_FLOW_OUT_THROTTLED; // the throttling itself occurs in the serial_xmt_char() callback } static __inline__ void restart_tx( serial_channel *chan ) { serial_funs *funs = chan->funs; chan->flow_desc.flags &= ~CYG_SERIAL_FLOW_OUT_THROTTLED; #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT // See if there is now enough room to say it is available // for writing { cbuf_t *cbuf = &chan->out_cbuf; int space; space = cbuf->len - cbuf->nb; if (space >= cbuf->low_water) cyg_selwakeup( &cbuf->selinfo ); } #endif if ( chan->out_cbuf.nb > 0 ) (funs->start_xmit)(chan); } static __inline__ void throttle_rx( serial_channel *chan, cyg_bool force ) { serial_funs *funs = chan->funs; chan->flow_desc.flags |= CYG_SERIAL_FLOW_IN_THROTTLED; #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // send an xoff if ( force || chan->config.flags & CYGNUM_SERIAL_FLOW_XONXOFF_RX ) { chan->flow_desc.xchar = CYGDAT_IO_SERIAL_FLOW_CONTROL_XOFF_CHAR; // Make sure xmit is running so we can send it (funs->start_xmit)(chan); } #endif #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_HW { cyg_uint32 i=1; cyg_uint32 len = sizeof(i); // set hardware flow control - don't care if it fails if ( force || (chan->config.flags & CYGNUM_SERIAL_FLOW_RTSCTS_RX) || (chan->config.flags & CYGNUM_SERIAL_FLOW_DSRDTR_RX) ) (funs->set_config)(chan, CYG_IO_SET_CONFIG_SERIAL_HW_RX_FLOW_THROTTLE, &i, &len); } #endif } static __inline__ void restart_rx( serial_channel *chan, cyg_bool force ) { serial_funs *funs = chan->funs; chan->flow_desc.flags &= ~CYG_SERIAL_FLOW_IN_THROTTLED; #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // send an xon if ( force || chan->config.flags & CYGNUM_SERIAL_FLOW_XONXOFF_RX ) { chan->flow_desc.xchar = CYGDAT_IO_SERIAL_FLOW_CONTROL_XON_CHAR; (funs->start_xmit)(chan); // Make sure xmit is running so we can send it } #endif #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_HW { cyg_uint32 i=0; cyg_uint32 len = sizeof(i); // set hardware flow control - don't care if it fails if ( force || (chan->config.flags & CYGNUM_SERIAL_FLOW_RTSCTS_RX) || (chan->config.flags & CYGNUM_SERIAL_FLOW_DSRDTR_RX) ) (funs->set_config)(chan, CYG_IO_SET_CONFIG_SERIAL_HW_RX_FLOW_THROTTLE, &i, &len); } #endif } #endif // --------------------------------------------------------------------------- static void serial_init(serial_channel *chan) { if (chan->init) return; if (chan->out_cbuf.len != 0) { #ifdef CYGDBG_IO_INIT diag_printf("Set output buffer - buf: %x len: %d\n", chan->out_cbuf.data, chan->out_cbuf.len); #endif chan->out_cbuf.waiting = false; chan->out_cbuf.abort = false; #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING chan->out_cbuf.blocking = true; #endif chan->out_cbuf.pending = 0; cyg_drv_mutex_init(&chan->out_cbuf.lock); cyg_drv_cond_init(&chan->out_cbuf.wait, &chan->out_cbuf.lock); chan->out_cbuf.low_water = chan->out_cbuf.len / 4; #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_selinit( &chan->out_cbuf.selinfo ); #endif } if (chan->in_cbuf.len != 0) { cbuf_t *cbuf = &chan->in_cbuf; #ifdef CYGDBG_IO_INIT diag_printf("Set input buffer - buf: %x len: %d\n", cbuf->data, cbuf->len); #endif cbuf->waiting = false; cbuf->abort = false; #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING cbuf->blocking = true; #endif #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_selinit( &cbuf->selinfo ); #endif #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL cbuf->low_water = (CYGNUM_IO_SERIAL_FLOW_CONTROL_LOW_WATER_PERCENT * cbuf->len) / 100; cbuf->high_water = (CYGNUM_IO_SERIAL_FLOW_CONTROL_HIGH_WATER_PERCENT * cbuf->len) / 100; # ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // But make sure it is at least 35 below buffer size, to allow // for 16 byte fifos, twice, plus some latency before s/w flow // control can kick in. This doesn't apply to h/w flow control // as it is near-instaneous if ( (cbuf->len - cbuf->high_water) < 35 ) cbuf->high_water = cbuf->len - 35; // and just in case... if ( cbuf->high_water <= 0 ) cbuf->high_water = 1; if ( cbuf->low_water > cbuf->high_water ) cbuf->low_water = cbuf->high_water; # endif #endif cyg_drv_mutex_init(&cbuf->lock); cyg_drv_cond_init(&cbuf->wait, &cbuf->lock); } #ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS chan->status_callback = NULL; #endif #ifdef CYGDBG_USE_ASSERTS #if CYGINT_IO_SERIAL_BLOCK_TRANSFER chan->in_cbuf.block_mode_xfer_running = false; chan->out_cbuf.block_mode_xfer_running = false; #endif // CYGINT_IO_SERIAL_BLOCK_TRANSFER #endif // CYGDBG_USE_ASSERTS chan->init = true; } // --------------------------------------------------------------------------- // FIXME:@@@ Throughout this file there are uses of cyg_drv_cond_signal and // cyg_drv_cond_broadcast. Does it matter which? -Jifl static Cyg_ErrNo serial_write(cyg_io_handle_t handle, const void *_buf, cyg_uint32 *len) { cyg_devtab_entry_t *t = (cyg_devtab_entry_t *)handle; serial_channel *chan = (serial_channel *)t->priv; serial_funs *funs = chan->funs; cyg_int32 size = *len; cyg_uint8 *buf = (cyg_uint8 *)_buf; int next; cbuf_t *cbuf = &chan->out_cbuf; Cyg_ErrNo res = ENOERR; cyg_drv_mutex_lock(&cbuf->lock); cbuf->abort = false; if (cbuf->len == 0) { // Non interrupt driven (i.e. polled) operation while (size-- > 0) { #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL while ( ( 0 == (chan->flow_desc.flags & CYG_SERIAL_FLOW_OUT_THROTTLED) ) && ((funs->putc)(chan, *buf) == false) ) ; // Ignore full, keep trying #else while ((funs->putc)(chan, *buf) == false) ; // Ignore full, keep trying #endif buf++; } } else { cyg_drv_dsr_lock(); // Avoid race condition testing pointers while (size > 0) { next = cbuf->put + 1; if (next == cbuf->len) next = 0; if (cbuf->nb == cbuf->len) { cbuf->waiting = true; // Buffer full - wait for space #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL if ( 0 == (chan->flow_desc.flags & CYG_SERIAL_FLOW_OUT_THROTTLED) ) #endif (funs->start_xmit)(chan); // Make sure xmit is running // Check flag: 'start_xmit' may have obviated the need // to wait :-) if (cbuf->waiting) { #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING // Optionally return if configured for non-blocking mode. if (!cbuf->blocking) { *len -= size; // number of characters actually sent cbuf->waiting = false; res = -EAGAIN; break; } #endif // CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING cbuf->pending += size; // Have this much more to send [eventually] if( !cyg_drv_cond_wait(&cbuf->wait) ) cbuf->abort = true; cbuf->pending -= size; } if (cbuf->abort) { // Give up! *len -= size; // number of characters actually sent cbuf->abort = false; cbuf->waiting = false; res = -EINTR; break; } } else { cbuf->data[cbuf->put++] = *buf++; cbuf->put = next; cbuf->nb++; size--; // Only count if actually sent! } } #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL if ( 0 == (chan->flow_desc.flags & CYG_SERIAL_FLOW_OUT_THROTTLED) ) #endif (funs->start_xmit)(chan); // Start output as necessary cyg_drv_dsr_unlock(); } cyg_drv_mutex_unlock(&cbuf->lock); return res; } // --------------------------------------------------------------------------- static Cyg_ErrNo serial_read(cyg_io_handle_t handle, void *_buf, cyg_uint32 *len) { cyg_devtab_entry_t *t = (cyg_devtab_entry_t *)handle; serial_channel *chan = (serial_channel *)t->priv; serial_funs *funs = chan->funs; cyg_uint8 *buf = (cyg_uint8 *)_buf; cyg_int32 size = 0; cbuf_t *cbuf = &chan->in_cbuf; Cyg_ErrNo res = ENOERR; #ifdef XX_CYGDBG_DIAG_BUF extern int enable_diag_uart; int _enable = enable_diag_uart; int _time, _stime; externC cyg_tick_count_t cyg_current_time(void); #endif // CYGDBG_DIAG_BUF cyg_drv_mutex_lock(&cbuf->lock); cbuf->abort = false; if (cbuf->len == 0) { // Non interrupt driven (i.e. polled) operation while (size++ < *len) { cyg_uint8 c = (funs->getc)(chan); #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // for software flow control, if the driver returns one of the // characters we act on it and then drop it (the app must not // see it) if ( chan->config.flags & CYGNUM_SERIAL_FLOW_XONXOFF_TX ) { if ( c == CYGDAT_IO_SERIAL_FLOW_CONTROL_XOFF_CHAR ) { throttle_tx( chan ); } else if ( c == CYGDAT_IO_SERIAL_FLOW_CONTROL_XON_CHAR ) { restart_tx( chan ); } else *buf++ = c; } else *buf++ = c; #else *buf++ = c; #endif } } else { cyg_drv_dsr_lock(); // Avoid races while (size < *len) { if (cbuf->nb > 0) { #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL if ( (cbuf->nb <= cbuf->low_water) && (chan->flow_desc.flags & CYG_SERIAL_FLOW_IN_THROTTLED) ) restart_rx( chan, false ); #endif *buf++ = cbuf->data[cbuf->get]; if (++cbuf->get == cbuf->len) cbuf->get = 0; cbuf->nb--; size++; } else { #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING if (!cbuf->blocking) { *len = size; // characters actually read res = -EAGAIN; break; } #endif // CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING cbuf->waiting = true; #ifdef XX_CYGDBG_DIAG_BUF enable_diag_uart = 0; HAL_CLOCK_READ(&_time); _stime = (int)cyg_current_time(); diag_printf("READ wait - get: %d, put: %d, time: %x.%x\n", cbuf->get, cbuf->put, _stime, _time); enable_diag_uart = _enable; #endif // CYGDBG_DIAG_BUF if( !cyg_drv_cond_wait(&cbuf->wait) ) cbuf->abort = true; #ifdef XX_CYGDBG_DIAG_BUF enable_diag_uart = 0; HAL_CLOCK_READ(&_time); _stime = (int)cyg_current_time(); diag_printf("READ continue - get: %d, put: %d, time: %x.%x\n", cbuf->get, cbuf->put, _stime, _time); enable_diag_uart = _enable; #endif // CYGDBG_DIAG_BUF if (cbuf->abort) { // Give up! *len = size; // characters actually read cbuf->abort = false; cbuf->waiting = false; res = -EINTR; break; } } } cyg_drv_dsr_unlock(); } #ifdef XX_CYGDBG_DIAG_BUF cyg_drv_isr_lock(); enable_diag_uart = 0; HAL_CLOCK_READ(&_time); _stime = (int)cyg_current_time(); diag_printf("READ done - size: %d, len: %d, time: %x.%x\n", size, *len, _stime, _time); enable_diag_uart = _enable; cyg_drv_isr_unlock(); #endif // CYGDBG_DIAG_BUF cyg_drv_mutex_unlock(&cbuf->lock); return res; } // --------------------------------------------------------------------------- static cyg_bool serial_select(cyg_io_handle_t handle, cyg_uint32 which, CYG_ADDRWORD info) { #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_devtab_entry_t *t = (cyg_devtab_entry_t *)handle; serial_channel *chan = (serial_channel *)t->priv; switch( which ) { case CYG_FREAD: { cbuf_t *cbuf = &chan->in_cbuf; // Check for data in the input buffer. If there is none, // register the select operation, otherwise return true. if( cbuf->nb == 0 ) cyg_selrecord( info, &cbuf->selinfo ); else return true; } break; case CYG_FWRITE: { // Check for space in the output buffer. If there is none, // register the select operation, otherwise return true. cbuf_t *cbuf = &chan->out_cbuf; int space = cbuf->len - cbuf->nb; #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL if ( (space < cbuf->low_water) || (chan->flow_desc.flags & CYG_SERIAL_FLOW_OUT_THROTTLED) ) cyg_selrecord( info, &cbuf->selinfo ); #else if (space < cbuf->low_water) cyg_selrecord( info, &cbuf->selinfo ); #endif else return true; } break; case 0: // exceptions - none supported break; } return false; #else // With no select support, we simply return true. return true; #endif } // --------------------------------------------------------------------------- static Cyg_ErrNo serial_get_config(cyg_io_handle_t handle, cyg_uint32 key, void *xbuf, cyg_uint32 *len) { cyg_devtab_entry_t *t = (cyg_devtab_entry_t *)handle; serial_channel *chan = (serial_channel *)t->priv; cyg_serial_info_t *buf = (cyg_serial_info_t *)xbuf; Cyg_ErrNo res = ENOERR; cbuf_t *out_cbuf = &chan->out_cbuf; cbuf_t *in_cbuf = &chan->in_cbuf; serial_funs *funs = chan->funs; switch (key) { case CYG_IO_GET_CONFIG_SERIAL_INFO: if (*len < sizeof(cyg_serial_info_t)) { return -EINVAL; } *buf = chan->config; *len = sizeof(chan->config); break; case CYG_IO_GET_CONFIG_SERIAL_BUFFER_INFO: // return rx/tx buffer sizes and counts { cyg_serial_buf_info_t *p; if (*len < sizeof(cyg_serial_buf_info_t)) return -EINVAL; *len = sizeof(cyg_serial_buf_info_t); p = (cyg_serial_buf_info_t *)xbuf; p->rx_bufsize = in_cbuf->len; if (p->rx_bufsize) p->rx_count = in_cbuf->nb; else p->rx_count = 0; p->tx_bufsize = out_cbuf->len; if (p->tx_bufsize) p->tx_count = out_cbuf->nb; else p->tx_count = 0; } break; case CYG_IO_GET_CONFIG_SERIAL_OUTPUT_DRAIN: // Wait for any pending output to complete if (out_cbuf->len == 0) break; // Nothing to do if not buffered cyg_drv_mutex_lock(&out_cbuf->lock); // Stop any further output processing cyg_drv_dsr_lock(); while (out_cbuf->pending || (out_cbuf->nb > 0)) { out_cbuf->waiting = true; if(!cyg_drv_cond_wait(&out_cbuf->wait) ) res = -EINTR; } cyg_drv_dsr_unlock(); cyg_drv_mutex_unlock(&out_cbuf->lock); break; case CYG_IO_GET_CONFIG_SERIAL_INPUT_FLUSH: // Flush any buffered input if (in_cbuf->len == 0) break; // Nothing to do if not buffered cyg_drv_mutex_lock(&in_cbuf->lock); // Stop any further input processing cyg_drv_dsr_lock(); if (in_cbuf->waiting) { in_cbuf->abort = true; cyg_drv_cond_signal(&in_cbuf->wait); in_cbuf->waiting = false; } in_cbuf->get = in_cbuf->put = in_cbuf->nb = 0; // Flush buffered input cyg_drv_dsr_unlock(); cyg_drv_mutex_unlock(&in_cbuf->lock); break; case CYG_IO_GET_CONFIG_SERIAL_ABORT: // Abort any outstanding I/O, including blocked reads // Caution - assumed to be called from 'timeout' (i.e. DSR) code if (in_cbuf->len != 0) { in_cbuf->abort = true; cyg_drv_cond_signal(&in_cbuf->wait); } if (out_cbuf->len != 0) { out_cbuf->abort = true; cyg_drv_cond_signal(&out_cbuf->wait); } break; case CYG_IO_GET_CONFIG_SERIAL_OUTPUT_FLUSH: // Throw away any pending output if (out_cbuf->len == 0) break; // Nothing to do if not buffered cyg_drv_mutex_lock(&out_cbuf->lock); // Stop any further output processing cyg_drv_dsr_lock(); if (out_cbuf->nb > 0) { out_cbuf->get = out_cbuf->put = out_cbuf->nb = 0; // Empties queue! (funs->stop_xmit)(chan); // Done with transmit } if (out_cbuf->waiting) { out_cbuf->abort = true; cyg_drv_cond_signal(&out_cbuf->wait); out_cbuf->waiting = false; } cyg_drv_dsr_unlock(); cyg_drv_mutex_unlock(&out_cbuf->lock); break; #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING case CYG_IO_GET_CONFIG_READ_BLOCKING: if (*len < sizeof(cyg_uint32)) { return -EINVAL; } *(cyg_uint32*)xbuf = (in_cbuf->blocking) ? 1 : 0; break; case CYG_IO_GET_CONFIG_WRITE_BLOCKING: if (*len < sizeof(cyg_uint32)) { return -EINVAL; } *(cyg_uint32*)xbuf = (out_cbuf->blocking) ? 1 : 0; break; #endif // CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING default: res = -EINVAL; } return res; } // --------------------------------------------------------------------------- static Cyg_ErrNo serial_set_config(cyg_io_handle_t handle, cyg_uint32 key, const void *xbuf, cyg_uint32 *len) { Cyg_ErrNo res = ENOERR; cyg_devtab_entry_t *t = (cyg_devtab_entry_t *)handle; serial_channel *chan = (serial_channel *)t->priv; #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING cbuf_t *out_cbuf = &chan->out_cbuf; cbuf_t *in_cbuf = &chan->in_cbuf; #endif serial_funs *funs = chan->funs; switch (key) { #ifdef CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING case CYG_IO_SET_CONFIG_READ_BLOCKING: if (*len < sizeof(cyg_uint32) || 0 == in_cbuf->len) { return -EINVAL; } in_cbuf->blocking = (1 == *(cyg_uint32*)xbuf) ? true : false; break; case CYG_IO_SET_CONFIG_WRITE_BLOCKING: if (*len < sizeof(cyg_uint32) || 0 == out_cbuf->len) { return -EINVAL; } out_cbuf->blocking = (1 == *(cyg_uint32*)xbuf) ? true : false; break; #endif // CYGOPT_IO_SERIAL_SUPPORT_NONBLOCKING #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL case CYG_IO_SET_CONFIG_SERIAL_FLOW_CONTROL_METHOD: { cyg_uint32 *f = (cyg_uint32 *)xbuf; if (*len < sizeof(*f)) return -EINVAL; cyg_drv_dsr_lock(); chan->config.flags &= ~(CYGNUM_SERIAL_FLOW_XONXOFF_RX| CYGNUM_SERIAL_FLOW_XONXOFF_TX| CYGNUM_SERIAL_FLOW_RTSCTS_RX| CYGNUM_SERIAL_FLOW_RTSCTS_TX| CYGNUM_SERIAL_FLOW_DSRDTR_RX| CYGNUM_SERIAL_FLOW_DSRDTR_TX); chan->config.flags |= (*f & ( #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE CYGNUM_SERIAL_FLOW_XONXOFF_RX| CYGNUM_SERIAL_FLOW_XONXOFF_TX| #endif #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_HW CYGNUM_SERIAL_FLOW_RTSCTS_RX| CYGNUM_SERIAL_FLOW_RTSCTS_TX| CYGNUM_SERIAL_FLOW_DSRDTR_RX| CYGNUM_SERIAL_FLOW_DSRDTR_TX| #endif 0)); #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_HW // up to hardware driver to clear flags if rejected res = (funs->set_config)(chan, CYG_IO_SET_CONFIG_SERIAL_HW_FLOW_CONFIG, NULL, NULL); #endif cyg_drv_dsr_unlock(); } break; case CYG_IO_SET_CONFIG_SERIAL_FLOW_CONTROL_FORCE: { cyg_uint32 *f = (cyg_uint32 *)xbuf; if (*len < sizeof(*f)) return -EINVAL; cyg_drv_dsr_lock(); switch (*f) { case CYGNUM_SERIAL_FLOW_THROTTLE_RX: throttle_rx( chan, true ); break; case CYGNUM_SERIAL_FLOW_RESTART_RX: restart_rx( chan, true ); break; case CYGNUM_SERIAL_FLOW_THROTTLE_TX: throttle_tx( chan ); break; case CYGNUM_SERIAL_FLOW_RESTART_TX: restart_tx( chan ); break; default: res = -EINVAL; break; } cyg_drv_dsr_unlock(); } break; #endif // CYGPKG_IO_SERIAL_FLOW_CONTROL #ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS case CYG_IO_SET_CONFIG_SERIAL_STATUS_CALLBACK: { cyg_serial_line_status_callback_fn_t newfn; CYG_ADDRWORD newpriv; cyg_serial_line_status_callback_t *tmp = (cyg_serial_line_status_callback_t *)xbuf; if ( *len < sizeof(*tmp) ) return -EINVAL; newfn = tmp->fn; newpriv = tmp->priv; // prevent callbacks while we do this cyg_drv_dsr_lock(); // store old callbacks in same structure tmp->fn = chan->status_callback; tmp->priv = chan->status_callback_priv; chan->status_callback = newfn; chan->status_callback_priv = newpriv; cyg_drv_dsr_unlock(); *len = sizeof(*tmp); } break; #endif default: // pass down to lower layers return (funs->set_config)(chan, key, xbuf, len); } return res; } // --------------------------------------------------------------------------- static void serial_xmt_char(serial_channel *chan) { cbuf_t *cbuf = &chan->out_cbuf; serial_funs *funs = chan->funs; unsigned char c; int space; #if CYGINT_IO_SERIAL_BLOCK_TRANSFER CYG_ASSERT(false == cbuf->block_mode_xfer_running, "Attempting char xmt while block transfer is running"); #endif #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // if we are required to send an XON/XOFF char, send it before // anything else // FIXME: what if XON gets corrupted in transit to the other end? // Should we resend XON even though the other end may not be wanting // to send us stuff at this point? if ( chan->config.flags & CYGNUM_SERIAL_FLOW_XONXOFF_RX ) { if ( chan->flow_desc.xchar ) { if ( (funs->putc)(chan, chan->flow_desc.xchar) ) { chan->flow_desc.xchar = '\0'; } else { // otherwise there's no space and we have to wait return; } } } #endif #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL // if we're meant to be throttled, just stop and leave if ( chan->flow_desc.flags & CYG_SERIAL_FLOW_OUT_THROTTLED ) { (funs->stop_xmit)(chan); // Stop transmitting for now return; } #endif while (cbuf->nb > 0) { c = cbuf->data[cbuf->get]; if ((funs->putc)(chan, c)) { cbuf->get++; if (cbuf->get == cbuf->len) cbuf->get = 0; cbuf->nb--; } else { // See if there is now enough room to restart writer space = cbuf->len - cbuf->nb; if (space >= cbuf->low_water) { if (cbuf->waiting) { cbuf->waiting = false; cyg_drv_cond_broadcast(&cbuf->wait); } #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_selwakeup( &cbuf->selinfo ); #endif } return; // Need to wait for more space } } (funs->stop_xmit)(chan); // Done with transmit // must signal waiters, and wake up selecters for the case when // this was the last char to be sent and they hadn't been signalled // before (e.g. because of flow control) if (cbuf->waiting) { cbuf->waiting = false; cyg_drv_cond_signal(&cbuf->wait); } #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_selwakeup( &cbuf->selinfo ); #endif } // --------------------------------------------------------------------------- static void serial_rcv_char(serial_channel *chan, unsigned char c) { cbuf_t *cbuf = &chan->in_cbuf; #if CYGINT_IO_SERIAL_BLOCK_TRANSFER CYG_ASSERT(false == cbuf->block_mode_xfer_running, "Attempting char rcv while block transfer is running"); #endif #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // for software flow control, if the driver returns one of the characters // we act on it and then drop it (the app must not see it) if ( chan->config.flags & CYGNUM_SERIAL_FLOW_XONXOFF_TX ) { if ( c == CYGDAT_IO_SERIAL_FLOW_CONTROL_XOFF_CHAR ) { throttle_tx( chan ); return; // it wasn't a "real" character } else if ( c == CYGDAT_IO_SERIAL_FLOW_CONTROL_XON_CHAR ) { restart_tx( chan ); return; // it wasn't a "real" character } } #endif #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL // If we've hit the high water mark, tell the other side to stop if ( cbuf->nb >= cbuf->high_water ) { throttle_rx( chan, false ); } #endif #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT // Wake up any pending selectors if we are about to // put some data into a previously empty buffer. if( cbuf->nb == 0 ) cyg_selwakeup( &cbuf->selinfo ); #endif // If the flow control is not enabled/sufficient and the buffer is // already full, just throw new characters away. if ( cbuf->nb < cbuf->len ) { cbuf->data[cbuf->put++] = c; if (cbuf->put == cbuf->len) cbuf->put = 0; cbuf->nb++; } // note trailing else #ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS else { // Overrun. Report the error. cyg_serial_line_status_t stat; stat.which = CYGNUM_SERIAL_STATUS_OVERRUNERR; serial_indicate_status(chan, &stat); } #endif if (cbuf->waiting) { #ifdef XX_CYGDBG_DIAG_BUF extern int enable_diag_uart; int _enable = enable_diag_uart; int _time, _stime; externC cyg_tick_count_t cyg_current_time(void); enable_diag_uart = 0; HAL_CLOCK_READ(&_time); _stime = (int)cyg_current_time(); diag_printf("Signal reader - time: %x.%x\n", _stime, _time); enable_diag_uart = _enable; #endif // CYGDBG_DIAG_BUF cbuf->waiting = false; cyg_drv_cond_signal(&cbuf->wait); } } //---------------------------------------------------------------------------- // Flow control indication callback #ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS static void serial_indicate_status(serial_channel *chan, cyg_serial_line_status_t *s ) { #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL if ( CYGNUM_SERIAL_STATUS_FLOW == s->which ) { if ( s->value ) restart_tx( chan ); else throttle_tx( chan ); } #endif if ( chan->status_callback ) (*chan->status_callback)(s, chan->status_callback_priv); } #endif // ifdef CYGOPT_IO_SERIAL_SUPPORT_LINE_STATUS //---------------------------------------------------------------------------- // Block transfer functions. Not all drivers require these. Those that // do must follow the required semantics: // // Attempt to transfer as much via the block transfer function as // possible, _but_ if that fails, do the remaining bytes via the // single-char function. That ensures that all policy decisions can be // made in this driver, and not in the device driver. // // Note: if the driver uses DMA for transmission, an initial failing // call to the xmt_req function must cause the start_xmit function to // fall-back to regular CPU-interrupt based single-character // transmission. #if CYGINT_IO_SERIAL_BLOCK_TRANSFER static rcv_req_reply_t serial_data_rcv_req(serial_channel *chan, int avail, int* space_avail, unsigned char** space) { cbuf_t *cbuf = &chan->in_cbuf; int gap; #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // When there is software flow-control, force the serial device // driver to use the single-char xmt/rcv functions, since these // have to make policy decision based on the data. Rcv function // may also have to transmit data to throttle the xmitter. if (chan->config.flags & (CYGNUM_SERIAL_FLOW_XONXOFF_TX|CYGNUM_SERIAL_FLOW_XONXOFF_RX)) return CYG_RCV_DISABLED; #endif CYG_ASSERT(false == cbuf->block_mode_xfer_running, "Attempting new block transfer while another is running"); // Check for space gap = cbuf->nb; if (gap == cbuf->len) return CYG_RCV_FULL; #ifdef CYGDBG_USE_ASSERTS cbuf->block_mode_xfer_running = true; #endif if (0 == gap) { // Buffer is empty. Reset put/get indexes to get max transfer in // one chunk. cbuf->get = 0; cbuf->put = 0; gap = cbuf->len; } else { // Free space (G = get, P = put, x = data, . = empty) // positive: xxxxP.....Gxxx // negative: ..GxxxxxP..... [offer last chunk only] // First try for a gap between put and get locations gap = cbuf->get - cbuf->put; if (gap < 0) { // If failed, the gap is between put and the end of buffer gap = cbuf->len - cbuf->put; } } if (avail < gap) gap = avail; // bound by what's available from hw *space_avail = gap; *space = &cbuf->data[cbuf->put]; CYG_ASSERT((gap+cbuf->nb) <= cbuf->len, "Buffer will overflow"); CYG_ASSERT(cbuf->put < cbuf->len, "Invalid put ptr"); CYG_ASSERT(cbuf->get < cbuf->len, "Invalid get ptr"); return CYG_RCV_OK; } static void serial_data_rcv_done(serial_channel *chan, int chars_rcvd) { cbuf_t *cbuf = &chan->in_cbuf; cbuf->put += chars_rcvd; cbuf->nb += chars_rcvd; if (cbuf->put == cbuf->len) cbuf->put = 0; CYG_ASSERT(cbuf->nb <= cbuf->len, "Buffer overflow"); CYG_ASSERT(cbuf->put < cbuf->len, "Invalid put ptr"); CYG_ASSERT(cbuf->get < cbuf->len, "Invalid get ptr"); if (cbuf->waiting) { cbuf->waiting = false; cyg_drv_cond_signal(&cbuf->wait); } #ifdef CYGPKG_IO_SERIAL_FLOW_CONTROL // If we've hit the high water mark, tell the other side to stop if ( cbuf->nb >= cbuf->high_water ) { throttle_rx( chan, false ); } #endif #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT // Wake up any pending selectors if we have // put some data into a previously empty buffer. if (chars_rcvd == cbuf->nb) cyg_selwakeup( &cbuf->selinfo ); #endif #ifdef CYGDBG_USE_ASSERTS cbuf->block_mode_xfer_running = false; #endif } static xmt_req_reply_t serial_data_xmt_req(serial_channel *chan, int space, int* chars_avail, unsigned char** chars) { cbuf_t *cbuf = &chan->out_cbuf; int avail; #ifdef CYGOPT_IO_SERIAL_FLOW_CONTROL_SOFTWARE // When there is software flow-control, force the serial device // driver to use the single-char xmt/rcv functions, since these // have to make policy decision based on the data. Rcv function // may also have to transmit data to throttle the xmitter. if (chan->config.flags & (CYGNUM_SERIAL_FLOW_XONXOFF_TX|CYGNUM_SERIAL_FLOW_XONXOFF_RX)) return CYG_XMT_DISABLED; #endif CYG_ASSERT(false == cbuf->block_mode_xfer_running, "Attempting new block transfer while another is running"); // Available data (G = get, P = put, x = data, . = empty) // 0: no data // negative: xxxxP.....Gxxx [offer last chunk only] // positive: ..GxxxxxP..... if (0 == cbuf->nb) return CYG_XMT_EMPTY; #ifdef CYGDBG_USE_ASSERTS cbuf->block_mode_xfer_running = true; #endif if (cbuf->get >= cbuf->put) { avail = cbuf->len - cbuf->get; } else { avail = cbuf->put - cbuf->get; } if (avail > space) avail = space; // bound by space in hardware *chars_avail = avail; *chars = &cbuf->data[cbuf->get]; CYG_ASSERT(avail <= cbuf->len, "Avail overflow"); CYG_ASSERT(cbuf->nb <= cbuf->len, "Buffer overflow"); CYG_ASSERT(cbuf->put < cbuf->len, "Invalid put ptr"); CYG_ASSERT(cbuf->get < cbuf->len, "Invalid get ptr"); return CYG_XMT_OK; } static void serial_data_xmt_done(serial_channel *chan, int chars_sent) { cbuf_t *cbuf = &chan->out_cbuf; serial_funs *funs = chan->funs; int space; cbuf->get += chars_sent; cbuf->nb -= chars_sent; if (cbuf->get == cbuf->len) cbuf->get = 0; CYG_ASSERT(cbuf->nb <= cbuf->len, "Buffer overflow"); CYG_ASSERT(cbuf->nb >= 0, "Buffer underflow"); CYG_ASSERT(cbuf->put < cbuf->len, "Invalid put ptr"); CYG_ASSERT(cbuf->get < cbuf->len, "Invalid get ptr"); if (0 == cbuf->nb) { (funs->stop_xmit)(chan); // Done with transmit cbuf->get = cbuf->put = 0; // reset ptrs if empty } // See if there is now enough room to restart writer space = cbuf->len - cbuf->nb; if (space >= cbuf->low_water) { if (cbuf->waiting) { cbuf->waiting = false; cyg_drv_cond_broadcast(&cbuf->wait); } #ifdef CYGPKG_IO_SERIAL_SELECT_SUPPORT cyg_selwakeup( &cbuf->selinfo ); #endif } #ifdef CYGDBG_USE_ASSERTS cbuf->block_mode_xfer_running = false; #endif } #endif // CYGINT_IO_SERIAL_BLOCK_TRANSFER // --------------------------------------------------------------------------- // EOF serial.c
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