///////////////////////////////////////////////////////////////////////// // $Id: serial.cc,v 1.81 2008-02-15 22:05:43 sshwarts Exp $ ///////////////////////////////////////////////////////////////////////// // // Copyright (C) 2004 MandrakeSoft S.A. // // MandrakeSoft S.A. // 43, rue d'Aboukir // 75002 Paris - France // http://www.linux-mandrake.com/ // http://www.mandrakesoft.com/ // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2 of the License, or (at your option) any later version. // // This library 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 // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA ///////////////////////////////////////////////////////////////////////// // Peter Grehan (grehan@iprg.nokia.com) coded the original version of this // serial emulation. He implemented a single 8250, and allow terminal // input/output to stdout on FreeBSD. // The current version emulates up to 4 UART 16550A with FIFO. Terminal // input/output now works on some more platforms. // Define BX_PLUGGABLE in files that can be compiled into plugins. For // platforms that require a special tag on exported symbols, BX_PLUGGABLE // is used to know when we are exporting symbols and when we are importing. #define BX_PLUGGABLE #include "iodev.h" #ifndef WIN32 #include #include #include #endif #if USE_RAW_SERIAL #include "serial_raw.h" #endif // USE_RAW_SERIAL #define LOG_THIS theSerialDevice-> bx_serial_c *theSerialDevice = NULL; int libserial_LTX_plugin_init(plugin_t *plugin, plugintype_t type, int argc, char *argv[]) { theSerialDevice = new bx_serial_c(); bx_devices.pluginSerialDevice = theSerialDevice; BX_REGISTER_DEVICE_DEVMODEL(plugin, type, theSerialDevice, BX_PLUGIN_SERIAL); return(0); // Success } void libserial_LTX_plugin_fini(void) { delete theSerialDevice; } bx_serial_c::bx_serial_c(void) { put("SER"); settype(SERLOG); for (int i=0; iget_param(pname); if (SIM->get_param_bool("enabled", base)->get()) { switch (BX_SER_THIS s[i].io_mode) { case BX_SER_MODE_FILE: if (BX_SER_THIS s[i].output != NULL) fclose(BX_SER_THIS s[i].output); break; case BX_SER_MODE_TERM: #if defined(SERIAL_ENABLE) && !defined(WIN32) if (s[i].tty_id >= 0) { tcsetattr(s[i].tty_id, TCSAFLUSH, &s[i].term_orig); } #endif break; case BX_SER_MODE_RAW: #if USE_RAW_SERIAL delete [] BX_SER_THIS s[i].raw; #endif break; case BX_SER_MODE_SOCKET: if (BX_SER_THIS s[i].socket_id >= 0) ::close(BX_SER_THIS s[i].socket_id); break; } } } BX_DEBUG(("Exit")); } void bx_serial_c::init(void) { Bit16u ports[BX_SERIAL_MAXDEV] = {0x03f8, 0x02f8, 0x03e8, 0x02e8}; char name[16], pname[20]; bx_list_c *base; unsigned i; BX_SER_THIS detect_mouse = 0; BX_SER_THIS mouse_port = -1; BX_SER_THIS mouse_type = BX_MOUSE_TYPE_NONE; BX_SER_THIS mouse_internal_buffer.num_elements = 0; for (i=0; iget_param(pname); if (SIM->get_param_bool("enabled", base)->get()) { sprintf(name, "Serial Port %d", i + 1); /* serial interrupt */ BX_SER_THIS s[i].IRQ = 4 - (i & 1); if (i < 2) { DEV_register_irq(BX_SER_THIS s[i].IRQ, name); } /* internal state */ BX_SER_THIS s[i].ls_ipending = 0; BX_SER_THIS s[i].ms_ipending = 0; BX_SER_THIS s[i].rx_ipending = 0; BX_SER_THIS s[i].fifo_ipending = 0; BX_SER_THIS s[i].ls_interrupt = 0; BX_SER_THIS s[i].ms_interrupt = 0; BX_SER_THIS s[i].rx_interrupt = 0; BX_SER_THIS s[i].tx_interrupt = 0; BX_SER_THIS s[i].fifo_interrupt = 0; if (BX_SER_THIS s[i].tx_timer_index == BX_NULL_TIMER_HANDLE) { BX_SER_THIS s[i].tx_timer_index = bx_pc_system.register_timer(this, tx_timer_handler, 0, 0,0, "serial.tx"); // one-shot, inactive } if (BX_SER_THIS s[i].rx_timer_index == BX_NULL_TIMER_HANDLE) { BX_SER_THIS s[i].rx_timer_index = bx_pc_system.register_timer(this, rx_timer_handler, 0, 0,0, "serial.rx"); // one-shot, inactive } if (BX_SER_THIS s[i].fifo_timer_index == BX_NULL_TIMER_HANDLE) { BX_SER_THIS s[i].fifo_timer_index = bx_pc_system.register_timer(this, fifo_timer_handler, 0, 0,0, "serial.fifo"); // one-shot, inactive } BX_SER_THIS s[i].rx_pollstate = BX_SER_RXIDLE; /* int enable: b0000 0000 */ BX_SER_THIS s[i].int_enable.rxdata_enable = 0; BX_SER_THIS s[i].int_enable.txhold_enable = 0; BX_SER_THIS s[i].int_enable.rxlstat_enable = 0; BX_SER_THIS s[i].int_enable.modstat_enable = 0; /* int ID: b0000 0001 */ BX_SER_THIS s[i].int_ident.ipending = 1; BX_SER_THIS s[i].int_ident.int_ID = 0; /* FIFO control: b0000 0000 */ BX_SER_THIS s[i].fifo_cntl.enable = 0; BX_SER_THIS s[i].fifo_cntl.rxtrigger = 0; BX_SER_THIS s[i].rx_fifo_end = 0; BX_SER_THIS s[i].tx_fifo_end = 0; /* Line Control reg: b0000 0000 */ BX_SER_THIS s[i].line_cntl.wordlen_sel = 0; BX_SER_THIS s[i].line_cntl.stopbits = 0; BX_SER_THIS s[i].line_cntl.parity_enable = 0; BX_SER_THIS s[i].line_cntl.evenparity_sel = 0; BX_SER_THIS s[i].line_cntl.stick_parity = 0; BX_SER_THIS s[i].line_cntl.break_cntl = 0; BX_SER_THIS s[i].line_cntl.dlab = 0; /* Modem Control reg: b0000 0000 */ BX_SER_THIS s[i].modem_cntl.dtr = 0; BX_SER_THIS s[i].modem_cntl.rts = 0; BX_SER_THIS s[i].modem_cntl.out1 = 0; BX_SER_THIS s[i].modem_cntl.out2 = 0; BX_SER_THIS s[i].modem_cntl.local_loopback = 0; /* Line Status register: b0110 0000 */ BX_SER_THIS s[i].line_status.rxdata_ready = 0; BX_SER_THIS s[i].line_status.overrun_error = 0; BX_SER_THIS s[i].line_status.parity_error = 0; BX_SER_THIS s[i].line_status.framing_error = 0; BX_SER_THIS s[i].line_status.break_int = 0; BX_SER_THIS s[i].line_status.thr_empty = 1; BX_SER_THIS s[i].line_status.tsr_empty = 1; BX_SER_THIS s[i].line_status.fifo_error = 0; /* Modem Status register: bXXXX 0000 */ BX_SER_THIS s[i].modem_status.delta_cts = 0; BX_SER_THIS s[i].modem_status.delta_dsr = 0; BX_SER_THIS s[i].modem_status.ri_trailedge = 0; BX_SER_THIS s[i].modem_status.delta_dcd = 0; BX_SER_THIS s[i].modem_status.cts = 0; BX_SER_THIS s[i].modem_status.dsr = 0; BX_SER_THIS s[i].modem_status.ri = 0; BX_SER_THIS s[i].modem_status.dcd = 0; BX_SER_THIS s[i].scratch = 0; /* scratch register */ BX_SER_THIS s[i].divisor_lsb = 1; /* divisor-lsb register */ BX_SER_THIS s[i].divisor_msb = 0; /* divisor-msb register */ BX_SER_THIS s[i].baudrate = 115200; for (unsigned addr=ports[i]; addr<(unsigned)(ports[i]+8); addr++) { BX_DEBUG(("com%d initialize register for read/write: 0x%04x",i+1, addr)); DEV_register_ioread_handler(this, read_handler, addr, name, 1); DEV_register_iowrite_handler(this, write_handler, addr, name, 1); } BX_SER_THIS s[i].io_mode = BX_SER_MODE_NULL; const char *mode = SIM->get_param_enum("mode", base)->get_selected(); const char *dev = SIM->get_param_string("dev", base)->getptr(); if (!strcmp(mode, "file")) { if (strlen(dev) > 0) { BX_SER_THIS s[i].output = fopen(dev, "wb"); if (BX_SER_THIS s[i].output) BX_SER_THIS s[i].io_mode = BX_SER_MODE_FILE; } } else if (!strcmp(mode, "term")) { #if defined(SERIAL_ENABLE) && !defined(WIN32) if (strlen(dev) > 0) { BX_SER_THIS s[i].tty_id = open(dev, O_RDWR|O_NONBLOCK,600); if (BX_SER_THIS s[i].tty_id < 0) { BX_PANIC(("open of com%d (%s) failed", i+1, dev)); } else { BX_SER_THIS s[i].io_mode = BX_SER_MODE_TERM; BX_DEBUG(("com%d tty_id: %d", i+1, BX_SER_THIS s[i].tty_id)); tcgetattr(BX_SER_THIS s[i].tty_id, &BX_SER_THIS s[i].term_orig); memcpy(&BX_SER_THIS s[i].term_orig, &BX_SER_THIS s[i].term_new, sizeof(struct termios)); BX_SER_THIS s[i].term_new.c_iflag &= ~(IGNBRK|BRKINT|PARMRK|ISTRIP|INLCR|IGNCR|ICRNL|IXON); BX_SER_THIS s[i].term_new.c_lflag &= ~(ECHO|ECHONL|ICANON|ISIG|IEXTEN); BX_SER_THIS s[i].term_new.c_cflag &= ~(CSIZE|PARENB); BX_SER_THIS s[i].term_new.c_cflag |= CS8; BX_SER_THIS s[i].term_new.c_oflag |= OPOST | ONLCR; // Enable NL to CR-NL translation #ifndef TRUE_CTLC // ctl-C will exit Bochs, or trap to the debugger BX_SER_THIS s[i].term_new.c_iflag &= ~IGNBRK; BX_SER_THIS s[i].term_new.c_iflag |= BRKINT; BX_SER_THIS s[i].term_new.c_lflag |= ISIG; #else // ctl-C will be delivered to the serial port BX_SER_THIS s[i].term_new.c_iflag |= IGNBRK; BX_SER_THIS s[i].term_new.c_iflag &= ~BRKINT; #endif /* !def TRUE_CTLC */ BX_SER_THIS s[i].term_new.c_iflag = 0; BX_SER_THIS s[i].term_new.c_oflag = 0; BX_SER_THIS s[i].term_new.c_cflag = CS8|CREAD|CLOCAL; BX_SER_THIS s[i].term_new.c_lflag = 0; BX_SER_THIS s[i].term_new.c_cc[VMIN] = 1; BX_SER_THIS s[i].term_new.c_cc[VTIME] = 0; //BX_SER_THIS s[i].term_new.c_iflag |= IXOFF; tcsetattr(BX_SER_THIS s[i].tty_id, TCSAFLUSH, &BX_SER_THIS s[i].term_new); } } #else BX_PANIC(("serial terminal support not available")); #endif /* def SERIAL_ENABLE */ } else if (!strcmp(mode, "raw")) { #if USE_RAW_SERIAL BX_SER_THIS s[i].raw = new serial_raw(dev); BX_SER_THIS s[i].io_mode = BX_SER_MODE_RAW; #else BX_PANIC(("raw serial support not present")); #endif } else if (!strcmp(mode, "mouse")) { BX_SER_THIS s[i].io_mode = BX_SER_MODE_MOUSE; BX_SER_THIS mouse_port = i; BX_SER_THIS mouse_type = SIM->get_param_enum(BXPN_MOUSE_TYPE)->get(); } else if (!strcmp(mode, "socket")) { BX_SER_THIS s[i].io_mode = BX_SER_MODE_SOCKET; struct sockaddr_in sin; struct hostent *hp; char host[BX_PATHNAME_LEN]; int port; int socket; #if defined(WIN32) static bool winsock_init = false; if (!winsock_init) { WORD wVersionRequested; WSADATA wsaData; int err; wVersionRequested = MAKEWORD(2, 0); err = WSAStartup(wVersionRequested, &wsaData); if (err != 0) BX_PANIC(("WSAStartup failed")); winsock_init = true; } #endif strcpy(host, dev); char *substr = strtok(host, ":"); substr = strtok(NULL, ":"); if (!substr) { BX_PANIC(("com%d: inet address is wrong (%s)", i+1, dev)); } port = atoi(substr); hp = gethostbyname(host); if (!hp) { BX_PANIC(("com%d: gethostbyname failed (%s)", i+1, host)); } memset ((char*) &sin, 0, sizeof (sin)); #if BX_HAVE_SOCKADDR_IN_SIN_LEN sin.sin_len = sizeof sin; #endif memcpy ((char*) &(sin.sin_addr), hp->h_addr, hp->h_length); sin.sin_family = hp->h_addrtype; sin.sin_port = htons (port); socket = ::socket (AF_INET, SOCK_STREAM, 0); if (socket < 0) { BX_PANIC(("com%d: socket() failed",i+1)); } if (::connect (socket, (sockaddr *) &sin, sizeof (sin)) < 0) { socket = -1; BX_INFO(("com%d: connect() failed (host:%s, port:%d)",i+1, host, port)); } else { BX_INFO(("com%d - inet - socket_id: %d, ip:%s, port:%d", i+1, socket, host, port)); } BX_SER_THIS s[i].socket_id = socket; } else if (strcmp(mode, "null")) { BX_PANIC(("unknown serial i/o mode")); } // simulate device connected if (BX_SER_THIS s[i].io_mode != BX_SER_MODE_RAW) { BX_SER_THIS s[i].modem_status.cts = 1; BX_SER_THIS s[i].modem_status.dsr = 1; } BX_INFO(("com%d at 0x%04x irq %d", i+1, ports[i], BX_SER_THIS s[i].IRQ)); } } } void bx_serial_c::reset(unsigned type) { } void bx_serial_c::register_state(void) { unsigned i, j; char name[6]; bx_list_c *port; bx_list_c *list = new bx_list_c(SIM->get_bochs_root(), "serial", "Serial Port State", 9); for (i=0; iread(address, io_len); } Bit32u bx_serial_c::read(Bit32u address, unsigned io_len) { #else UNUSED(this_ptr); #endif // !BX_USE_SER_SMF bx_bool prev_cts, prev_dsr, prev_ri, prev_dcd; Bit8u offset, val; Bit8u port = 0; offset = address & 0x07; switch (address & 0x03f8) { case 0x03f8: port = 0; break; case 0x02f8: port = 1; break; case 0x03e8: port = 2; break; case 0x02e8: port = 3; break; } switch (offset) { case BX_SER_RBR: /* receive buffer, or divisor latch LSB if DLAB set */ if (BX_SER_THIS s[port].line_cntl.dlab) { val = BX_SER_THIS s[port].divisor_lsb; } else { if (BX_SER_THIS s[port].fifo_cntl.enable) { val = BX_SER_THIS s[port].rx_fifo[0]; if (BX_SER_THIS s[port].rx_fifo_end > 0) { memcpy(&BX_SER_THIS s[port].rx_fifo[0], &BX_SER_THIS s[port].rx_fifo[1], 15); BX_SER_THIS s[port].rx_fifo_end--; } if (BX_SER_THIS s[port].rx_fifo_end == 0) { BX_SER_THIS s[port].line_status.rxdata_ready = 0; BX_SER_THIS s[port].rx_interrupt = 0; BX_SER_THIS s[port].rx_ipending = 0; BX_SER_THIS s[port].fifo_interrupt = 0; BX_SER_THIS s[port].fifo_ipending = 0; lower_interrupt(port); } } else { val = BX_SER_THIS s[port].rxbuffer; BX_SER_THIS s[port].line_status.rxdata_ready = 0; BX_SER_THIS s[port].rx_interrupt = 0; BX_SER_THIS s[port].rx_ipending = 0; lower_interrupt(port); } } break; case BX_SER_IER: /* interrupt enable register, or div. latch MSB */ if (BX_SER_THIS s[port].line_cntl.dlab) { val = BX_SER_THIS s[port].divisor_msb; } else { val = BX_SER_THIS s[port].int_enable.rxdata_enable | (BX_SER_THIS s[port].int_enable.txhold_enable << 1) | (BX_SER_THIS s[port].int_enable.rxlstat_enable << 2) | (BX_SER_THIS s[port].int_enable.modstat_enable << 3); } break; case BX_SER_IIR: /* interrupt ID register */ /* * Set the interrupt ID based on interrupt source */ if (BX_SER_THIS s[port].ls_interrupt) { BX_SER_THIS s[port].int_ident.int_ID = 0x3; BX_SER_THIS s[port].int_ident.ipending = 0; } else if (BX_SER_THIS s[port].fifo_interrupt) { BX_SER_THIS s[port].int_ident.int_ID = 0x6; BX_SER_THIS s[port].int_ident.ipending = 0; } else if (BX_SER_THIS s[port].rx_interrupt) { BX_SER_THIS s[port].int_ident.int_ID = 0x2; BX_SER_THIS s[port].int_ident.ipending = 0; } else if (BX_SER_THIS s[port].tx_interrupt) { BX_SER_THIS s[port].int_ident.int_ID = 0x1; BX_SER_THIS s[port].int_ident.ipending = 0; } else if (BX_SER_THIS s[port].ms_interrupt) { BX_SER_THIS s[port].int_ident.int_ID = 0x0; BX_SER_THIS s[port].int_ident.ipending = 0; } else { BX_SER_THIS s[port].int_ident.int_ID = 0x0; BX_SER_THIS s[port].int_ident.ipending = 1; } BX_SER_THIS s[port].tx_interrupt = 0; lower_interrupt(port); val = BX_SER_THIS s[port].int_ident.ipending | (BX_SER_THIS s[port].int_ident.int_ID << 1) | (BX_SER_THIS s[port].fifo_cntl.enable ? 0xc0 : 0x00); break; case BX_SER_LCR: /* Line control register */ val = BX_SER_THIS s[port].line_cntl.wordlen_sel | (BX_SER_THIS s[port].line_cntl.stopbits << 2) | (BX_SER_THIS s[port].line_cntl.parity_enable << 3) | (BX_SER_THIS s[port].line_cntl.evenparity_sel << 4) | (BX_SER_THIS s[port].line_cntl.stick_parity << 5) | (BX_SER_THIS s[port].line_cntl.break_cntl << 6) | (BX_SER_THIS s[port].line_cntl.dlab << 7); break; case BX_SER_MCR: /* MODEM control register */ val = BX_SER_THIS s[port].modem_cntl.dtr | (BX_SER_THIS s[port].modem_cntl.rts << 1) | (BX_SER_THIS s[port].modem_cntl.out1 << 2) | (BX_SER_THIS s[port].modem_cntl.out2 << 3) | (BX_SER_THIS s[port].modem_cntl.local_loopback << 4); break; case BX_SER_LSR: /* Line status register */ val = BX_SER_THIS s[port].line_status.rxdata_ready | (BX_SER_THIS s[port].line_status.overrun_error << 1) | (BX_SER_THIS s[port].line_status.parity_error << 2) | (BX_SER_THIS s[port].line_status.framing_error << 3) | (BX_SER_THIS s[port].line_status.break_int << 4) | (BX_SER_THIS s[port].line_status.thr_empty << 5) | (BX_SER_THIS s[port].line_status.tsr_empty << 6) | (BX_SER_THIS s[port].line_status.fifo_error << 7); BX_SER_THIS s[port].line_status.overrun_error = 0; BX_SER_THIS s[port].line_status.framing_error = 0; BX_SER_THIS s[port].line_status.break_int = 0; BX_SER_THIS s[port].ls_interrupt = 0; BX_SER_THIS s[port].ls_ipending = 0; lower_interrupt(port); break; case BX_SER_MSR: /* MODEM status register */ prev_cts = BX_SER_THIS s[port].modem_status.cts; prev_dsr = BX_SER_THIS s[port].modem_status.dsr; prev_ri = BX_SER_THIS s[port].modem_status.ri; prev_dcd = BX_SER_THIS s[port].modem_status.dcd; if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL val = BX_SER_THIS s[port].raw->get_modem_status(); BX_SER_THIS s[port].modem_status.cts = (val & 0x10) >> 4; BX_SER_THIS s[port].modem_status.dsr = (val & 0x20) >> 5; BX_SER_THIS s[port].modem_status.ri = (val & 0x40) >> 6; BX_SER_THIS s[port].modem_status.dcd = (val & 0x80) >> 7; if (BX_SER_THIS s[port].modem_status.cts != prev_cts) { BX_SER_THIS s[port].modem_status.delta_cts = 1; } if (BX_SER_THIS s[port].modem_status.dsr != prev_dsr) { BX_SER_THIS s[port].modem_status.delta_dsr = 1; } if ((BX_SER_THIS s[port].modem_status.ri == 0) && (prev_ri == 1)) BX_SER_THIS s[port].modem_status.ri_trailedge = 1; if (BX_SER_THIS s[port].modem_status.dcd != prev_dcd) { BX_SER_THIS s[port].modem_status.delta_dcd = 1; } #endif } val = BX_SER_THIS s[port].modem_status.delta_cts | (BX_SER_THIS s[port].modem_status.delta_dsr << 1) | (BX_SER_THIS s[port].modem_status.ri_trailedge << 2) | (BX_SER_THIS s[port].modem_status.delta_dcd << 3) | (BX_SER_THIS s[port].modem_status.cts << 4) | (BX_SER_THIS s[port].modem_status.dsr << 5) | (BX_SER_THIS s[port].modem_status.ri << 6) | (BX_SER_THIS s[port].modem_status.dcd << 7); BX_SER_THIS s[port].modem_status.delta_cts = 0; BX_SER_THIS s[port].modem_status.delta_dsr = 0; BX_SER_THIS s[port].modem_status.ri_trailedge = 0; BX_SER_THIS s[port].modem_status.delta_dcd = 0; BX_SER_THIS s[port].ms_interrupt = 0; BX_SER_THIS s[port].ms_ipending = 0; lower_interrupt(port); break; case BX_SER_SCR: /* scratch register */ val = BX_SER_THIS s[port].scratch; break; default: val = 0; // keep compiler happy BX_PANIC(("unsupported io read from address=0x%04x!", address)); break; } BX_DEBUG(("com%d register read from address: 0x%04x = 0x%02x", port+1, address, val)); return(val); } // static IO port write callback handler // redirects to non-static class handler to avoid virtual functions void bx_serial_c::write_handler(void *this_ptr, Bit32u address, Bit32u value, unsigned io_len) { #if !BX_USE_SER_SMF bx_serial_c *class_ptr = (bx_serial_c *) this_ptr; class_ptr->write(address, value, io_len); } void bx_serial_c::write(Bit32u address, Bit32u value, unsigned io_len) { #else UNUSED(this_ptr); #endif // !BX_USE_SER_SMF bx_bool prev_cts, prev_dsr, prev_ri, prev_dcd; bx_bool new_b0, new_b1, new_b2, new_b3; bx_bool new_b4, new_b5, new_b6, new_b7; bx_bool gen_int = 0; Bit8u offset, new_wordlen; #if USE_RAW_SERIAL bx_bool mcr_changed = 0; Bit8u p_mode; #endif Bit8u port = 0; offset = address & 0x07; switch (address & 0x03f8) { case 0x03f8: port = 0; break; case 0x02f8: port = 1; break; case 0x03e8: port = 2; break; case 0x02e8: port = 3; break; } BX_DEBUG(("com%d register write to address: 0x%04x = 0x%02x", port+1, address, value)); new_b0 = value & 0x01; new_b1 = (value & 0x02) >> 1; new_b2 = (value & 0x04) >> 2; new_b3 = (value & 0x08) >> 3; new_b4 = (value & 0x10) >> 4; new_b5 = (value & 0x20) >> 5; new_b6 = (value & 0x40) >> 6; new_b7 = (value & 0x80) >> 7; switch (offset) { case BX_SER_THR: /* transmit buffer, or divisor latch LSB if DLAB set */ if (BX_SER_THIS s[port].line_cntl.dlab) { BX_SER_THIS s[port].divisor_lsb = value; if ((value != 0) || (BX_SER_THIS s[port].divisor_msb != 0)) { BX_SER_THIS s[port].baudrate = (int) (BX_PC_CLOCK_XTL / (16 * ((BX_SER_THIS s[port].divisor_msb << 8) | BX_SER_THIS s[port].divisor_lsb))); } } else { Bit8u bitmask = 0xff >> (3 - BX_SER_THIS s[port].line_cntl.wordlen_sel); if (BX_SER_THIS s[port].line_status.thr_empty) { if (BX_SER_THIS s[port].fifo_cntl.enable) { BX_SER_THIS s[port].tx_fifo[BX_SER_THIS s[port].tx_fifo_end++] = value & bitmask; } else { BX_SER_THIS s[port].thrbuffer = value & bitmask; } BX_SER_THIS s[port].line_status.thr_empty = 0; if (BX_SER_THIS s[port].line_status.tsr_empty) { if (BX_SER_THIS s[port].fifo_cntl.enable) { BX_SER_THIS s[port].tsrbuffer = BX_SER_THIS s[port].tx_fifo[0]; memcpy(&BX_SER_THIS s[port].tx_fifo[0], &BX_SER_THIS s[port].tx_fifo[1], 15); BX_SER_THIS s[port].line_status.thr_empty = (--BX_SER_THIS s[port].tx_fifo_end == 0); } else { BX_SER_THIS s[port].tsrbuffer = BX_SER_THIS s[port].thrbuffer; BX_SER_THIS s[port].line_status.thr_empty = 1; } BX_SER_THIS s[port].line_status.tsr_empty = 0; raise_interrupt(port, BX_SER_INT_TXHOLD); bx_pc_system.activate_timer(BX_SER_THIS s[port].tx_timer_index, (int) (1000000.0 / BX_SER_THIS s[port].baudrate * (BX_SER_THIS s[port].line_cntl.wordlen_sel + 5)), 0); /* not continuous */ } else { BX_SER_THIS s[port].tx_interrupt = 0; lower_interrupt(port); } } else { if (BX_SER_THIS s[port].fifo_cntl.enable) { if (BX_SER_THIS s[port].tx_fifo_end < 16) { BX_SER_THIS s[port].tx_fifo[BX_SER_THIS s[port].tx_fifo_end++] = value & bitmask; } else { BX_ERROR(("com%d: transmit FIFO overflow", port+1)); } } else { BX_ERROR(("com%d: write to tx hold register when not empty", port+1)); } } } break; case BX_SER_IER: /* interrupt enable register, or div. latch MSB */ if (BX_SER_THIS s[port].line_cntl.dlab) { BX_SER_THIS s[port].divisor_msb = value; if ((value != 0) || (BX_SER_THIS s[port].divisor_lsb != 0)) { BX_SER_THIS s[port].baudrate = (int) (BX_PC_CLOCK_XTL / (16 * ((BX_SER_THIS s[port].divisor_msb << 8) | BX_SER_THIS s[port].divisor_lsb))); } } else { if (new_b3 != BX_SER_THIS s[port].int_enable.modstat_enable) { BX_SER_THIS s[port].int_enable.modstat_enable = new_b3; if (BX_SER_THIS s[port].int_enable.modstat_enable == 1) { if (BX_SER_THIS s[port].ms_ipending == 1) { BX_SER_THIS s[port].ms_interrupt = 1; BX_SER_THIS s[port].ms_ipending = 0; gen_int = 1; } } else { if (BX_SER_THIS s[port].ms_interrupt == 1) { BX_SER_THIS s[port].ms_interrupt = 0; BX_SER_THIS s[port].ms_ipending = 1; lower_interrupt(port); } } } if (new_b1 != BX_SER_THIS s[port].int_enable.txhold_enable) { BX_SER_THIS s[port].int_enable.txhold_enable = new_b1; if (BX_SER_THIS s[port].int_enable.txhold_enable == 1) { BX_SER_THIS s[port].tx_interrupt = BX_SER_THIS s[port].line_status.thr_empty; if (BX_SER_THIS s[port].tx_interrupt) gen_int = 1; } else { BX_SER_THIS s[port].tx_interrupt = 0; lower_interrupt(port); } } if (new_b0 != BX_SER_THIS s[port].int_enable.rxdata_enable) { BX_SER_THIS s[port].int_enable.rxdata_enable = new_b0; if (BX_SER_THIS s[port].int_enable.rxdata_enable == 1) { if (BX_SER_THIS s[port].fifo_ipending == 1) { BX_SER_THIS s[port].fifo_interrupt = 1; BX_SER_THIS s[port].fifo_ipending = 0; gen_int = 1; } if (BX_SER_THIS s[port].rx_ipending == 1) { BX_SER_THIS s[port].rx_interrupt = 1; BX_SER_THIS s[port].rx_ipending = 0; gen_int = 1; } } else { if (BX_SER_THIS s[port].rx_interrupt == 1) { BX_SER_THIS s[port].rx_interrupt = 0; BX_SER_THIS s[port].rx_ipending = 1; lower_interrupt(port); } if (BX_SER_THIS s[port].fifo_interrupt == 1) { BX_SER_THIS s[port].fifo_interrupt = 0; BX_SER_THIS s[port].fifo_ipending = 1; lower_interrupt(port); } } } if (new_b2 != BX_SER_THIS s[port].int_enable.rxlstat_enable) { BX_SER_THIS s[port].int_enable.rxlstat_enable = new_b2; if (BX_SER_THIS s[port].int_enable.rxlstat_enable == 1) { if (BX_SER_THIS s[port].ls_ipending == 1) { BX_SER_THIS s[port].ls_interrupt = 1; BX_SER_THIS s[port].ls_ipending = 0; gen_int = 1; } } else { if (BX_SER_THIS s[port].ls_interrupt == 1) { BX_SER_THIS s[port].ls_interrupt = 0; BX_SER_THIS s[port].ls_ipending = 1; lower_interrupt(port); } } } if (gen_int) raise_interrupt(port, BX_SER_INT_IER); } break; case BX_SER_FCR: /* FIFO control register */ if (new_b0 && !BX_SER_THIS s[port].fifo_cntl.enable) { BX_INFO(("com%d: FIFO enabled", port+1)); BX_SER_THIS s[port].rx_fifo_end = 0; BX_SER_THIS s[port].tx_fifo_end = 0; } BX_SER_THIS s[port].fifo_cntl.enable = new_b0; if (new_b1) { BX_SER_THIS s[port].rx_fifo_end = 0; } if (new_b2) { BX_SER_THIS s[port].tx_fifo_end = 0; } BX_SER_THIS s[port].fifo_cntl.rxtrigger = (value & 0xc0) >> 6; break; case BX_SER_LCR: /* Line control register */ new_wordlen = value & 0x03; if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL if (BX_SER_THIS s[port].line_cntl.wordlen_sel != new_wordlen) { BX_SER_THIS s[port].raw->set_data_bits(new_wordlen + 5); } if (new_b2 != BX_SER_THIS s[port].line_cntl.stopbits) { BX_SER_THIS s[port].raw->set_stop_bits(new_b2 ? 2 : 1); } if ((new_b3 != BX_SER_THIS s[port].line_cntl.parity_enable) || (new_b4 != BX_SER_THIS s[port].line_cntl.evenparity_sel) || (new_b5 != BX_SER_THIS s[port].line_cntl.stick_parity)) { if (new_b3 == 0) { p_mode = P_NONE; } else { p_mode = ((value & 0x30) >> 4) + 1; } BX_SER_THIS s[port].raw->set_parity_mode(p_mode); } if ((new_b6 != BX_SER_THIS s[port].line_cntl.break_cntl) && (!BX_SER_THIS s[port].modem_cntl.local_loopback)) { BX_SER_THIS s[port].raw->set_break(new_b6); } #endif // USE_RAW_SERIAL } BX_SER_THIS s[port].line_cntl.wordlen_sel = new_wordlen; /* These are ignored, but set them up so they can be read back */ BX_SER_THIS s[port].line_cntl.stopbits = new_b2; BX_SER_THIS s[port].line_cntl.parity_enable = new_b3; BX_SER_THIS s[port].line_cntl.evenparity_sel = new_b4; BX_SER_THIS s[port].line_cntl.stick_parity = new_b5; BX_SER_THIS s[port].line_cntl.break_cntl = new_b6; if (BX_SER_THIS s[port].modem_cntl.local_loopback && BX_SER_THIS s[port].line_cntl.break_cntl) { BX_SER_THIS s[port].line_status.break_int = 1; BX_SER_THIS s[port].line_status.framing_error = 1; rx_fifo_enq(port, 0x00); } /* used when doing future writes */ if (!new_b7 && BX_SER_THIS s[port].line_cntl.dlab) { // Start the receive polling process if not already started // and there is a valid baudrate. if (BX_SER_THIS s[port].rx_pollstate == BX_SER_RXIDLE && BX_SER_THIS s[port].baudrate != 0) { BX_SER_THIS s[port].rx_pollstate = BX_SER_RXPOLL; bx_pc_system.activate_timer(BX_SER_THIS s[port].rx_timer_index, (int) (1000000.0 / BX_SER_THIS s[port].baudrate * (BX_SER_THIS s[port].line_cntl.wordlen_sel + 5)), 0); /* not continuous */ } if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL BX_SER_THIS s[port].raw->set_baudrate(BX_SER_THIS s[port].baudrate); #endif // USE_RAW_SERIAL } BX_DEBUG(("com%d: baud rate set - %d", port+1, BX_SER_THIS s[port].baudrate)); } BX_SER_THIS s[port].line_cntl.dlab = new_b7; break; case BX_SER_MCR: /* MODEM control register */ if ((BX_SER_THIS s[port].io_mode == BX_SER_MODE_MOUSE) && ((BX_SER_THIS s[port].line_cntl.wordlen_sel == 2) || (BX_SER_THIS s[port].line_cntl.wordlen_sel == 3))) { if (new_b0 && !new_b1) BX_SER_THIS detect_mouse = 1; if (new_b0 && new_b1 && (BX_SER_THIS detect_mouse == 1)) BX_SER_THIS detect_mouse = 2; } if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL mcr_changed = (BX_SER_THIS s[port].modem_cntl.dtr != new_b0) | (BX_SER_THIS s[port].modem_cntl.rts != new_b1); #endif } BX_SER_THIS s[port].modem_cntl.dtr = new_b0; BX_SER_THIS s[port].modem_cntl.rts = new_b1; BX_SER_THIS s[port].modem_cntl.out1 = new_b2; BX_SER_THIS s[port].modem_cntl.out2 = new_b3; if (new_b4 != BX_SER_THIS s[port].modem_cntl.local_loopback) { BX_SER_THIS s[port].modem_cntl.local_loopback = new_b4; if (BX_SER_THIS s[port].modem_cntl.local_loopback) { /* transition to loopback mode */ if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL if (BX_SER_THIS s[port].modem_cntl.dtr || BX_SER_THIS s[port].modem_cntl.rts) { BX_SER_THIS s[port].raw->set_modem_control(0); } #endif } if (BX_SER_THIS s[port].line_cntl.break_cntl) { if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL BX_SER_THIS s[port].raw->set_break(0); #endif } BX_SER_THIS s[port].line_status.break_int = 1; BX_SER_THIS s[port].line_status.framing_error = 1; rx_fifo_enq(port, 0x00); } } else { /* transition to normal mode */ if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL mcr_changed = 1; if (BX_SER_THIS s[port].line_cntl.break_cntl) { BX_SER_THIS s[port].raw->set_break(0); } #endif } } } if (BX_SER_THIS s[port].modem_cntl.local_loopback) { prev_cts = BX_SER_THIS s[port].modem_status.cts; prev_dsr = BX_SER_THIS s[port].modem_status.dsr; prev_ri = BX_SER_THIS s[port].modem_status.ri; prev_dcd = BX_SER_THIS s[port].modem_status.dcd; BX_SER_THIS s[port].modem_status.cts = BX_SER_THIS s[port].modem_cntl.rts; BX_SER_THIS s[port].modem_status.dsr = BX_SER_THIS s[port].modem_cntl.dtr; BX_SER_THIS s[port].modem_status.ri = BX_SER_THIS s[port].modem_cntl.out1; BX_SER_THIS s[port].modem_status.dcd = BX_SER_THIS s[port].modem_cntl.out2; if (BX_SER_THIS s[port].modem_status.cts != prev_cts) { BX_SER_THIS s[port].modem_status.delta_cts = 1; BX_SER_THIS s[port].ms_ipending = 1; } if (BX_SER_THIS s[port].modem_status.dsr != prev_dsr) { BX_SER_THIS s[port].modem_status.delta_dsr = 1; BX_SER_THIS s[port].ms_ipending = 1; } if (BX_SER_THIS s[port].modem_status.ri != prev_ri) BX_SER_THIS s[port].ms_ipending = 1; if ((BX_SER_THIS s[port].modem_status.ri == 0) && (prev_ri == 1)) BX_SER_THIS s[port].modem_status.ri_trailedge = 1; if (BX_SER_THIS s[port].modem_status.dcd != prev_dcd) { BX_SER_THIS s[port].modem_status.delta_dcd = 1; BX_SER_THIS s[port].ms_ipending = 1; } raise_interrupt(port, BX_SER_INT_MODSTAT); } else { if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_MOUSE) { if (BX_SER_THIS detect_mouse == 2) { if ((BX_SER_THIS mouse_type == BX_MOUSE_TYPE_SERIAL) || (BX_SER_THIS mouse_type == BX_MOUSE_TYPE_SERIAL_MSYS)) { BX_SER_THIS mouse_internal_buffer.head = 0; BX_SER_THIS mouse_internal_buffer.num_elements = 1; BX_SER_THIS mouse_internal_buffer.buffer[0] = 'M'; } else if (BX_SER_THIS mouse_type == BX_MOUSE_TYPE_SERIAL_WHEEL) { BX_SER_THIS mouse_internal_buffer.head = 0; BX_SER_THIS mouse_internal_buffer.num_elements = 6; BX_SER_THIS mouse_internal_buffer.buffer[0] = 'M'; BX_SER_THIS mouse_internal_buffer.buffer[1] = 'Z'; BX_SER_THIS mouse_internal_buffer.buffer[2] = '@'; BX_SER_THIS mouse_internal_buffer.buffer[3] = '\0'; BX_SER_THIS mouse_internal_buffer.buffer[4] = '\0'; BX_SER_THIS mouse_internal_buffer.buffer[5] = '\0'; } BX_SER_THIS detect_mouse = 0; } } if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_RAW) { #if USE_RAW_SERIAL if (mcr_changed) { BX_SER_THIS s[port].raw->set_modem_control(value & 0x03); } #endif } else { /* simulate device connected */ BX_SER_THIS s[port].modem_status.cts = 1; BX_SER_THIS s[port].modem_status.dsr = 1; BX_SER_THIS s[port].modem_status.ri = 0; BX_SER_THIS s[port].modem_status.dcd = 0; } } break; case BX_SER_LSR: /* Line status register */ BX_ERROR(("com%d: write to line status register ignored", port+1)); break; case BX_SER_MSR: /* MODEM status register */ BX_ERROR(("com%d: write to MODEM status register ignored", port+1)); break; case BX_SER_SCR: /* scratch register */ BX_SER_THIS s[port].scratch = value; break; default: BX_PANIC(("unsupported io write to address=0x%04x, value = 0x%02x!", (unsigned) address, (unsigned) value)); break; } } void bx_serial_c::rx_fifo_enq(Bit8u port, Bit8u data) { bx_bool gen_int = 0; if (BX_SER_THIS s[port].fifo_cntl.enable) { if (BX_SER_THIS s[port].rx_fifo_end == 16) { BX_ERROR(("com%d: receive FIFO overflow", port+1)); BX_SER_THIS s[port].line_status.overrun_error = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); } else { BX_SER_THIS s[port].rx_fifo[BX_SER_THIS s[port].rx_fifo_end++] = data; switch (BX_SER_THIS s[port].fifo_cntl.rxtrigger) { case 1: if (BX_SER_THIS s[port].rx_fifo_end == 4) gen_int = 1; break; case 2: if (BX_SER_THIS s[port].rx_fifo_end == 8) gen_int = 1; break; case 3: if (BX_SER_THIS s[port].rx_fifo_end == 14) gen_int = 1; break; default: gen_int = 1; } if (gen_int) { bx_pc_system.deactivate_timer(BX_SER_THIS s[port].fifo_timer_index); BX_SER_THIS s[port].line_status.rxdata_ready = 1; raise_interrupt(port, BX_SER_INT_RXDATA); } else { bx_pc_system.activate_timer(BX_SER_THIS s[port].fifo_timer_index, (int) (1000000.0 / BX_SER_THIS s[port].baudrate * (BX_SER_THIS s[port].line_cntl.wordlen_sel + 5) * 16), 0); /* not continuous */ } } } else { if (BX_SER_THIS s[port].line_status.rxdata_ready == 1) { BX_ERROR(("com%d: overrun error", port+1)); BX_SER_THIS s[port].line_status.overrun_error = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); } BX_SER_THIS s[port].rxbuffer = data; BX_SER_THIS s[port].line_status.rxdata_ready = 1; raise_interrupt(port, BX_SER_INT_RXDATA); } } void bx_serial_c::tx_timer_handler(void *this_ptr) { bx_serial_c *class_ptr = (bx_serial_c *) this_ptr; class_ptr->tx_timer(); } void bx_serial_c::tx_timer(void) { bx_bool gen_int = 0; Bit8u port = 0; int timer_id; timer_id = bx_pc_system.triggeredTimerID(); if (timer_id == BX_SER_THIS s[0].tx_timer_index) { port = 0; } else if (timer_id == BX_SER_THIS s[1].tx_timer_index) { port = 1; } else if (timer_id == BX_SER_THIS s[2].tx_timer_index) { port = 2; } else if (timer_id == BX_SER_THIS s[3].tx_timer_index) { port = 3; } if (BX_SER_THIS s[port].modem_cntl.local_loopback) { rx_fifo_enq(port, BX_SER_THIS s[port].tsrbuffer); } else { switch (BX_SER_THIS s[port].io_mode) { case BX_SER_MODE_FILE: fputc(BX_SER_THIS s[port].tsrbuffer, BX_SER_THIS s[port].output); fflush(BX_SER_THIS s[port].output); break; case BX_SER_MODE_TERM: #if defined(SERIAL_ENABLE) BX_DEBUG(("com%d: write: '%c'", port+1, BX_SER_THIS s[port].tsrbuffer)); if (BX_SER_THIS s[port].tty_id >= 0) { write(BX_SER_THIS s[port].tty_id, (bx_ptr_t) & BX_SER_THIS s[port].tsrbuffer, 1); } #endif break; case BX_SER_MODE_RAW: #if USE_RAW_SERIAL if (!BX_SER_THIS s[port].raw->ready_transmit()) BX_PANIC(("com%d: not ready to transmit", port+1)); BX_SER_THIS s[port].raw->transmit(BX_SER_THIS s[port].tsrbuffer); #endif break; case BX_SER_MODE_MOUSE: BX_INFO(("com%d: write to mouse ignored: 0x%02x", port+1, BX_SER_THIS s[port].tsrbuffer)); break; case BX_SER_MODE_SOCKET: if (BX_SER_THIS s[port].socket_id >= 0) { #ifdef WIN32 BX_INFO(("attempting to write win32 : %c", BX_SER_THIS s[port].tsrbuffer)); ::send(BX_SER_THIS s[port].socket_id, (const char*) & BX_SER_THIS s[port].tsrbuffer, 1, 0); #else ::write(BX_SER_THIS s[port].socket_id, (bx_ptr_t) & BX_SER_THIS s[port].tsrbuffer, 1); #endif } } } BX_SER_THIS s[port].line_status.tsr_empty = 1; if (BX_SER_THIS s[port].fifo_cntl.enable && (BX_SER_THIS s[port].tx_fifo_end > 0)) { BX_SER_THIS s[port].tsrbuffer = BX_SER_THIS s[port].tx_fifo[0]; BX_SER_THIS s[port].line_status.tsr_empty = 0; memcpy(&BX_SER_THIS s[port].tx_fifo[0], &BX_SER_THIS s[port].tx_fifo[1], 15); gen_int = (--BX_SER_THIS s[port].tx_fifo_end == 0); } else if (!BX_SER_THIS s[port].line_status.thr_empty) { BX_SER_THIS s[port].tsrbuffer = BX_SER_THIS s[port].thrbuffer; BX_SER_THIS s[port].line_status.tsr_empty = 0; gen_int = 1; } if (!BX_SER_THIS s[port].line_status.tsr_empty) { if (gen_int) { BX_SER_THIS s[port].line_status.thr_empty = 1; raise_interrupt(port, BX_SER_INT_TXHOLD); } bx_pc_system.activate_timer(BX_SER_THIS s[port].tx_timer_index, (int) (1000000.0 / BX_SER_THIS s[port].baudrate * (BX_SER_THIS s[port].line_cntl.wordlen_sel + 5)), 0); /* not continuous */ } } void bx_serial_c::rx_timer_handler(void *this_ptr) { bx_serial_c *class_ptr = (bx_serial_c *) this_ptr; class_ptr->rx_timer(); } void bx_serial_c::rx_timer(void) { #if BX_HAVE_SELECT && defined(SERIAL_ENABLE) struct timeval tval; fd_set fds; #endif Bit8u port = 0; int timer_id; bx_bool data_ready = 0; timer_id = bx_pc_system.triggeredTimerID(); if (timer_id == BX_SER_THIS s[0].rx_timer_index) { port = 0; } else if (timer_id == BX_SER_THIS s[1].rx_timer_index) { port = 1; } else if (timer_id == BX_SER_THIS s[2].rx_timer_index) { port = 2; } else if (timer_id == BX_SER_THIS s[3].rx_timer_index) { port = 3; } int bdrate = BX_SER_THIS s[port].baudrate / (BX_SER_THIS s[port].line_cntl.wordlen_sel + 5); unsigned char chbuf = 0; if (BX_SER_THIS s[port].io_mode == BX_SER_MODE_TERM) { #if BX_HAVE_SELECT && defined(SERIAL_ENABLE) tval.tv_sec = 0; tval.tv_usec = 0; // MacOS: I'm not sure what to do with this, since I don't know // what an fd_set is or what FD_SET() or select() do. They aren't // declared in the CodeWarrior standard library headers. I'm just // leaving it commented out for the moment. FD_ZERO(&fds); if (BX_SER_THIS s[port].tty_id >= 0) FD_SET(BX_SER_THIS s[port].tty_id, &fds); #endif } if ((BX_SER_THIS s[port].line_status.rxdata_ready == 0) || (BX_SER_THIS s[port].fifo_cntl.enable)) { switch (BX_SER_THIS s[port].io_mode) { case BX_SER_MODE_SOCKET: #if defined(SERIAL_ENABLE) if (BX_SER_THIS s[port].line_status.rxdata_ready == 0) { tval.tv_sec = 0; tval.tv_usec = 0; FD_ZERO(&fds); int socketid = BX_SER_THIS s[port].socket_id; if (socketid >= 0) FD_SET(socketid, &fds); if ((socketid >= 0) && (select(socketid+1, &fds, NULL, NULL, &tval) == 1)) { #ifdef WIN32 (void) ::recv(socketid, (char*) &chbuf, 1, 0); #else (void) read(socketid, &chbuf, 1); #endif BX_INFO((" -- COM %d : read byte [%d]", port+1, chbuf)); data_ready = 1; } } #endif break; case BX_SER_MODE_RAW: #if USE_RAW_SERIAL int data; if ((data_ready = BX_SER_THIS s[port].raw->ready_receive())) { data = BX_SER_THIS s[port].raw->receive(); if (data < 0) { data_ready = 0; switch (data) { case RAW_EVENT_BREAK: BX_SER_THIS s[port].line_status.break_int = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); break; case RAW_EVENT_FRAME: BX_SER_THIS s[port].line_status.framing_error = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); break; case RAW_EVENT_OVERRUN: BX_SER_THIS s[port].line_status.overrun_error = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); break; case RAW_EVENT_PARITY: BX_SER_THIS s[port].line_status.parity_error = 1; raise_interrupt(port, BX_SER_INT_RXLSTAT); break; case RAW_EVENT_CTS_ON: case RAW_EVENT_CTS_OFF: case RAW_EVENT_DSR_ON: case RAW_EVENT_DSR_OFF: case RAW_EVENT_RING_ON: case RAW_EVENT_RING_OFF: case RAW_EVENT_RLSD_ON: case RAW_EVENT_RLSD_OFF: raise_interrupt(port, BX_SER_INT_MODSTAT); break; } } } if (data_ready) { chbuf = data; } #endif break; case BX_SER_MODE_TERM: #if BX_HAVE_SELECT && defined(SERIAL_ENABLE) if ((BX_SER_THIS s[port].tty_id >= 0) && (select(BX_SER_THIS s[port].tty_id + 1, &fds, NULL, NULL, &tval) == 1)) { (void) read(BX_SER_THIS s[port].tty_id, &chbuf, 1); BX_DEBUG(("com%d: read: '%c'", port+1, chbuf)); data_ready = 1; } #endif break; case BX_SER_MODE_MOUSE: if (BX_SER_THIS mouse_internal_buffer.num_elements > 0) { chbuf = BX_SER_THIS mouse_internal_buffer.buffer[BX_SER_THIS mouse_internal_buffer.head]; BX_SER_THIS mouse_internal_buffer.head = (BX_SER_THIS mouse_internal_buffer.head + 1) % BX_MOUSE_BUFF_SIZE; BX_SER_THIS mouse_internal_buffer.num_elements--; data_ready = 1; } break; } if (data_ready) { if (!BX_SER_THIS s[port].modem_cntl.local_loopback) { rx_fifo_enq(port, chbuf); } } else { if (!BX_SER_THIS s[port].fifo_cntl.enable) { bdrate = (int) (1000000.0 / 100000); // Poll frequency is 100ms } } } else { // Poll at 4x baud rate to see if the next-char can // be read bdrate *= 4; } bx_pc_system.activate_timer(BX_SER_THIS s[port].rx_timer_index, (int) (1000000.0 / bdrate), 0); /* not continuous */ } void bx_serial_c::fifo_timer_handler(void *this_ptr) { bx_serial_c *class_ptr = (bx_serial_c *) this_ptr; class_ptr->fifo_timer(); } void bx_serial_c::fifo_timer(void) { Bit8u port = 0; int timer_id; timer_id = bx_pc_system.triggeredTimerID(); if (timer_id == BX_SER_THIS s[0].fifo_timer_index) { port = 0; } else if (timer_id == BX_SER_THIS s[1].fifo_timer_index) { port = 1; } else if (timer_id == BX_SER_THIS s[2].fifo_timer_index) { port = 2; } else if (timer_id == BX_SER_THIS s[3].fifo_timer_index) { port = 3; } BX_SER_THIS s[port].line_status.rxdata_ready = 1; raise_interrupt(port, BX_SER_INT_FIFO); } void bx_serial_c::serial_mouse_enq(int delta_x, int delta_y, int delta_z, unsigned button_state) { Bit8u b1, b2, b3, mouse_data[4]; int bytes, tail; if (BX_SER_THIS mouse_port == -1) { BX_ERROR(("mouse not connected to a serial port")); return; } // if the DTR and RTS lines aren't up, the mouse doesn't have any power to send packets. if (!BX_SER_THIS s[BX_SER_THIS mouse_port].modem_cntl.dtr || !BX_SER_THIS s[BX_SER_THIS mouse_port].modem_cntl.rts) return; // scale down the motion if ((delta_x < -1) || (delta_x > 1)) delta_x /= 2; if ((delta_y < -1) || (delta_y > 1)) delta_y /= 2; if(delta_x>127) delta_x=127; if(delta_y>127) delta_y=127; if(delta_x<-128) delta_x=-128; if(delta_y<-128) delta_y=-128; BX_SER_THIS mouse_delayed_dx+=delta_x; BX_SER_THIS mouse_delayed_dy-=delta_y; BX_SER_THIS mouse_delayed_dz =delta_z; if ((BX_SER_THIS mouse_internal_buffer.num_elements + 4) >= BX_MOUSE_BUFF_SIZE) { return; /* buffer doesn't have the space */ } if (BX_SER_THIS mouse_delayed_dx > 127) { delta_x = 127; BX_SER_THIS mouse_delayed_dx -= 127; } else if (BX_SER_THIS mouse_delayed_dx < -128) { delta_x = -128; BX_SER_THIS mouse_delayed_dx += 128; } else { delta_x = BX_SER_THIS mouse_delayed_dx; BX_SER_THIS mouse_delayed_dx = 0; } if (BX_SER_THIS mouse_delayed_dy > 127) { delta_y = 127; BX_SER_THIS mouse_delayed_dy -= 127; } else if (BX_SER_THIS mouse_delayed_dy < -128) { delta_y = -128; BX_SER_THIS mouse_delayed_dy += 128; } else { delta_y = BX_SER_THIS mouse_delayed_dy; BX_SER_THIS mouse_delayed_dy = 0; } if (BX_SER_THIS mouse_type != BX_MOUSE_TYPE_SERIAL_MSYS) { b1 = (Bit8u) delta_x; b2 = (Bit8u) delta_y; b3 = (Bit8u) -((Bit8s) delta_z); mouse_data[0] = 0x40 | ((b1 & 0xc0) >> 6) | ((b2 & 0xc0) >> 4); mouse_data[0] |= ((button_state & 0x01) << 5) | ((button_state & 0x02) << 3); mouse_data[1] = b1 & 0x3f; mouse_data[2] = b2 & 0x3f; mouse_data[3] = b3 & 0x0f; mouse_data[3] |= ((button_state & 0x04) << 2); bytes = 3; if (BX_SER_THIS mouse_type == BX_MOUSE_TYPE_SERIAL_WHEEL) bytes = 4; } else { b1 = (Bit8u) (delta_x / 2); b2 = (Bit8u) -((Bit8s) (delta_y / 2)); mouse_data[0] = 0x80 | ((~button_state & 0x01) << 2); mouse_data[0] |= ((~button_state & 0x06) >> 1); mouse_data[1] = b1; mouse_data[2] = b2; mouse_data[3] = 0; mouse_data[4] = 0; bytes = 5; } /* enqueue mouse data in multibyte internal mouse buffer */ for (int i = 0; i < bytes; i++) { tail = (BX_SER_THIS mouse_internal_buffer.head + BX_SER_THIS mouse_internal_buffer.num_elements) % BX_MOUSE_BUFF_SIZE; BX_SER_THIS mouse_internal_buffer.buffer[tail] = mouse_data[i]; BX_SER_THIS mouse_internal_buffer.num_elements++; } }