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[/] [scarts/] [trunk/] [toolchain/] [scarts-gdb/] [gdb-6.8/] [sim/] [mn10300/] [dv-mn103ser.c] - Rev 26
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/* This file is part of the program GDB, the GNU debugger. Copyright (C) 1998, 2007, 2008 Free Software Foundation, Inc. Contributed by Cygnus Solutions. This program 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 3 of the License, or (at your option) any later version. This program 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 this program. If not, see <http://www.gnu.org/licenses/>. */ #include "sim-main.h" #include "hw-main.h" #include "dv-sockser.h" /* DEVICE mn103ser - mn103002 serial devices 0, 1 and 2. DESCRIPTION Implements the mn103002 serial interfaces as described in the mn103002 user guide. PROPERTIES reg = <serial-addr> <serial-size> BUGS */ /* The serial devices' registers' address block */ struct mn103ser_block { unsigned_word base; unsigned_word bound; }; enum serial_register_types { SC0CTR, SC1CTR, SC2CTR, SC0ICR, SC1ICR, SC2ICR, SC0TXB, SC1TXB, SC2TXB, SC0RXB, SC1RXB, SC2RXB, SC0STR, SC1STR, SC2STR, SC2TIM, }; /* Access dv-sockser state */ extern char* sockser_addr; #define USE_SOCKSER_P (sockser_addr != NULL) #define NR_SERIAL_DEVS 3 #define SIO_STAT_RRDY 0x0010 typedef struct _mn10300_serial { unsigned16 status, control; unsigned8 txb, rxb, intmode; struct hw_event *event; } mn10300_serial; struct mn103ser { struct mn103ser_block block; mn10300_serial device[NR_SERIAL_DEVS]; unsigned8 serial2_timer_reg; do_hw_poll_read_method *reader; }; /* output port ID's */ /* for mn103002 */ enum { SERIAL0_RECEIVE, SERIAL1_RECEIVE, SERIAL2_RECEIVE, SERIAL0_SEND, SERIAL1_SEND, SERIAL2_SEND, }; static const struct hw_port_descriptor mn103ser_ports[] = { { "serial-0-receive", SERIAL0_RECEIVE, 0, output_port, }, { "serial-1-receive", SERIAL1_RECEIVE, 0, output_port, }, { "serial-2-receive", SERIAL2_RECEIVE, 0, output_port, }, { "serial-0-transmit", SERIAL0_SEND, 0, output_port, }, { "serial-1-transmit", SERIAL1_SEND, 0, output_port, }, { "serial-2-transmit", SERIAL2_SEND, 0, output_port, }, { NULL, }, }; /* Finish off the partially created hw device. Attach our local callbacks. Wire up our port names etc */ static hw_io_read_buffer_method mn103ser_io_read_buffer; static hw_io_write_buffer_method mn103ser_io_write_buffer; static void attach_mn103ser_regs (struct hw *me, struct mn103ser *serial) { unsigned_word attach_address; int attach_space; unsigned attach_size; reg_property_spec reg; if (hw_find_property (me, "reg") == NULL) hw_abort (me, "Missing \"reg\" property"); if (!hw_find_reg_array_property (me, "reg", 0, ®)) hw_abort (me, "\"reg\" property must contain three addr/size entries"); hw_unit_address_to_attach_address (hw_parent (me), ®.address, &attach_space, &attach_address, me); serial->block.base = attach_address; hw_unit_size_to_attach_size (hw_parent (me), ®.size, &attach_size, me); serial->block.bound = attach_address + (attach_size - 1); hw_attach_address (hw_parent (me), 0, attach_space, attach_address, attach_size, me); } static void mn103ser_finish (struct hw *me) { struct mn103ser *serial; int i; serial = HW_ZALLOC (me, struct mn103ser); set_hw_data (me, serial); set_hw_io_read_buffer (me, mn103ser_io_read_buffer); set_hw_io_write_buffer (me, mn103ser_io_write_buffer); set_hw_ports (me, mn103ser_ports); /* Attach ourself to our parent bus */ attach_mn103ser_regs (me, serial); /* If so configured, enable polled input */ if (hw_find_property (me, "poll?") != NULL && hw_find_boolean_property (me, "poll?")) { serial->reader = sim_io_poll_read; } else { serial->reader = sim_io_read; } /* Initialize the serial device registers. */ for ( i=0; i<NR_SERIAL_DEVS; ++i ) { serial->device[i].txb = 0; serial->device[i].rxb = 0; serial->device[i].status = 0; serial->device[i].control = 0; serial->device[i].intmode = 0; serial->device[i].event = NULL; } } /* read and write */ static int decode_addr (struct hw *me, struct mn103ser *serial, unsigned_word address) { unsigned_word offset; offset = address - serial->block.base; switch (offset) { case 0x00: return SC0CTR; case 0x04: return SC0ICR; case 0x08: return SC0TXB; case 0x09: return SC0RXB; case 0x0C: return SC0STR; case 0x10: return SC1CTR; case 0x14: return SC1ICR; case 0x18: return SC1TXB; case 0x19: return SC1RXB; case 0x1C: return SC1STR; case 0x20: return SC2CTR; case 0x24: return SC2ICR; case 0x28: return SC2TXB; case 0x29: return SC2RXB; case 0x2C: return SC2STR; case 0x2D: return SC2TIM; default: { hw_abort (me, "bad address"); return -1; } } } static void do_polling_event (struct hw *me, void *data) { struct mn103ser *serial = hw_data(me); long serial_reg = (long) data; char c; int count; if(USE_SOCKSER_P) { int rd; rd = dv_sockser_read (hw_system (me)); if(rd != -1) { c = (char) rd; count = 1; } else { count = HW_IO_NOT_READY; } } else { count = do_hw_poll_read (me, serial->reader, 0/*STDIN*/, &c, sizeof(c)); } switch (count) { case HW_IO_NOT_READY: case HW_IO_EOF: serial->device[serial_reg].rxb = 0; serial->device[serial_reg].status &= ~SIO_STAT_RRDY; break; default: serial->device[serial_reg].rxb = c; serial->device[serial_reg].status |= SIO_STAT_RRDY; hw_port_event (me, serial_reg+SERIAL0_RECEIVE, 1); } /* Schedule next polling event */ serial->device[serial_reg].event = hw_event_queue_schedule (me, 1000, do_polling_event, (void *)serial_reg); } static void read_control_reg (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, void *dest, unsigned nr_bytes) { /* really allow 1 byte read, too */ if ( nr_bytes == 2 ) { *(unsigned16 *)dest = H2LE_2 (serial->device[serial_reg].control); } else { hw_abort (me, "bad read size of %d bytes from SC%dCTR.", nr_bytes, serial_reg); } } static void read_intmode_reg (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, void *dest, unsigned nr_bytes) { if ( nr_bytes == 1 ) { *(unsigned8 *)dest = serial->device[serial_reg].intmode; } else { hw_abort (me, "bad read size of %d bytes from SC%dICR.", nr_bytes, serial_reg); } } static void read_txb (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, void *dest, unsigned nr_bytes) { if ( nr_bytes == 1 ) { *(unsigned8 *)dest = serial->device[serial_reg].txb; } else { hw_abort (me, "bad read size of %d bytes from SC%dTXB.", nr_bytes, serial_reg); } } static void read_rxb (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, void *dest, unsigned nr_bytes) { if ( nr_bytes == 1 ) { *(unsigned8 *)dest = serial->device[serial_reg].rxb; /* Reception buffer is now empty. */ serial->device[serial_reg].status &= ~SIO_STAT_RRDY; } else { hw_abort (me, "bad read size of %d bytes from SC%dRXB.", nr_bytes, serial_reg); } } static void read_status_reg (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, void *dest, unsigned nr_bytes) { char c; int count; if ( (serial->device[serial_reg].status & SIO_STAT_RRDY) == 0 ) { /* FIFO is empty */ /* Kill current poll event */ if ( NULL != serial->device[serial_reg].event ) { hw_event_queue_deschedule (me, serial->device[serial_reg].event); serial->device[serial_reg].event = NULL; } if(USE_SOCKSER_P) { int rd; rd = dv_sockser_read (hw_system (me)); if(rd != -1) { c = (char) rd; count = 1; } else { count = HW_IO_NOT_READY; } } else { count = do_hw_poll_read (me, serial->reader, 0/*STDIN*/, &c, sizeof(c)); } switch (count) { case HW_IO_NOT_READY: case HW_IO_EOF: serial->device[serial_reg].rxb = 0; serial->device[serial_reg].status &= ~SIO_STAT_RRDY; break; default: serial->device[serial_reg].rxb = c; serial->device[serial_reg].status |= SIO_STAT_RRDY; hw_port_event (me, serial_reg+SERIAL0_RECEIVE, 1); } /* schedule polling event */ serial->device[serial_reg].event = hw_event_queue_schedule (me, 1000, do_polling_event, (void *) (long) serial_reg); } if ( nr_bytes == 1 ) { *(unsigned8 *)dest = (unsigned8)serial->device[serial_reg].status; } else if ( nr_bytes == 2 && serial_reg != SC2STR ) { *(unsigned16 *)dest = H2LE_2 (serial->device[serial_reg].status); } else { hw_abort (me, "bad read size of %d bytes from SC%dSTR.", nr_bytes, serial_reg); } } static void read_serial2_timer_reg (struct hw *me, struct mn103ser *serial, void *dest, unsigned nr_bytes) { if ( nr_bytes == 1 ) { * (unsigned8 *) dest = (unsigned8) serial->serial2_timer_reg; } else { hw_abort (me, "bad read size of %d bytes to SC2TIM.", nr_bytes); } } static unsigned mn103ser_io_read_buffer (struct hw *me, void *dest, int space, unsigned_word base, unsigned nr_bytes) { struct mn103ser *serial = hw_data (me); enum serial_register_types serial_reg; HW_TRACE ((me, "read 0x%08lx %d", (long) base, (int) nr_bytes)); serial_reg = decode_addr (me, serial, base); switch (serial_reg) { /* control registers */ case SC0CTR: case SC1CTR: case SC2CTR: read_control_reg(me, serial, serial_reg-SC0CTR, dest, nr_bytes); HW_TRACE ((me, "read - ctrl reg%d has 0x%x\n", serial_reg-SC0CTR, *(unsigned8 *)dest)); break; /* interrupt mode registers */ case SC0ICR: case SC1ICR: case SC2ICR: read_intmode_reg(me, serial, serial_reg-SC0ICR, dest, nr_bytes); HW_TRACE ((me, "read - intmode reg%d has 0x%x\n", serial_reg-SC0ICR, *(unsigned8 *)dest)); break; /* transmission buffers */ case SC0TXB: case SC1TXB: case SC2TXB: read_txb(me, serial, serial_reg-SC0TXB, dest, nr_bytes); HW_TRACE ((me, "read - txb%d has %c\n", serial_reg-SC0TXB, *(char *)dest)); break; /* reception buffers */ case SC0RXB: case SC1RXB: case SC2RXB: read_rxb(me, serial, serial_reg-SC0RXB, dest, nr_bytes); HW_TRACE ((me, "read - rxb%d has %c\n", serial_reg-SC0RXB, *(char *)dest)); break; /* status registers */ case SC0STR: case SC1STR: case SC2STR: read_status_reg(me, serial, serial_reg-SC0STR, dest, nr_bytes); HW_TRACE ((me, "read - status reg%d has 0x%x\n", serial_reg-SC0STR, *(unsigned8 *)dest)); break; case SC2TIM: read_serial2_timer_reg(me, serial, dest, nr_bytes); HW_TRACE ((me, "read - serial2 timer reg %d\n", *(unsigned8 *)dest)); break; default: hw_abort(me, "invalid address"); } return nr_bytes; } static void write_control_reg (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, const void *source, unsigned nr_bytes) { unsigned16 val = LE2H_2 (*(unsigned16 *)source); /* really allow 1 byte write, too */ if ( nr_bytes == 2 ) { if ( serial_reg == 2 && (val & 0x0C04) != 0 ) { hw_abort(me, "Cannot write to read-only bits of SC2CTR."); } else { serial->device[serial_reg].control = val; } } else { hw_abort (me, "bad read size of %d bytes from SC%dSTR.", nr_bytes, serial_reg); } } static void write_intmode_reg (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, const void *source, unsigned nr_bytes) { unsigned8 val = *(unsigned8 *)source; if ( nr_bytes == 1 ) { /* Check for attempt to write to read-only bits of register. */ if ( ( serial_reg == 2 && (val & 0xCA) != 0 ) || ( serial_reg != 2 && (val & 0x4A) != 0 ) ) { hw_abort(me, "Cannot write to read-only bits of SC%dICR.", serial_reg); } else { serial->device[serial_reg].intmode = val; } } else { hw_abort (me, "bad write size of %d bytes to SC%dICR.", nr_bytes, serial_reg); } } static void write_txb (struct hw *me, struct mn103ser *serial, unsigned_word serial_reg, const void *source, unsigned nr_bytes) { if ( nr_bytes == 1 ) { serial->device[serial_reg].txb = *(unsigned8 *)source; if(USE_SOCKSER_P) { dv_sockser_write(hw_system (me), * (char*) source); } else { sim_io_write_stdout(hw_system (me), (char *)source, 1); sim_io_flush_stdout(hw_system (me)); } hw_port_event (me, serial_reg+SERIAL0_SEND, 1); } else { hw_abort (me, "bad write size of %d bytes to SC%dTXB.", nr_bytes, serial_reg); } } static void write_serial2_timer_reg (struct hw *me, struct mn103ser *serial, const void *source, unsigned nr_bytes) { if ( nr_bytes == 1 ) { serial->serial2_timer_reg = *(unsigned8 *)source; } else { hw_abort (me, "bad write size of %d bytes to SC2TIM.", nr_bytes); } } static unsigned mn103ser_io_write_buffer (struct hw *me, const void *source, int space, unsigned_word base, unsigned nr_bytes) { struct mn103ser *serial = hw_data (me); enum serial_register_types serial_reg; HW_TRACE ((me, "write 0x%08lx %d", (long) base, (int) nr_bytes)); serial_reg = decode_addr (me, serial, base); switch (serial_reg) { /* control registers */ case SC0CTR: case SC1CTR: case SC2CTR: HW_TRACE ((me, "write - ctrl reg%d has 0x%x, nrbytes=%d.\n", serial_reg-SC0CTR, *(unsigned8 *)source, nr_bytes)); write_control_reg(me, serial, serial_reg-SC0CTR, source, nr_bytes); break; /* interrupt mode registers */ case SC0ICR: case SC1ICR: case SC2ICR: HW_TRACE ((me, "write - intmode reg%d has 0x%x, nrbytes=%d.\n", serial_reg-SC0ICR, *(unsigned8 *)source, nr_bytes)); write_intmode_reg(me, serial, serial_reg-SC0ICR, source, nr_bytes); break; /* transmission buffers */ case SC0TXB: case SC1TXB: case SC2TXB: HW_TRACE ((me, "write - txb%d has %c, nrbytes=%d.\n", serial_reg-SC0TXB, *(char *)source, nr_bytes)); write_txb(me, serial, serial_reg-SC0TXB, source, nr_bytes); break; /* reception buffers */ case SC0RXB: case SC1RXB: case SC2RXB: hw_abort(me, "Cannot write to reception buffer."); break; /* status registers */ case SC0STR: case SC1STR: case SC2STR: hw_abort(me, "Cannot write to status register."); break; case SC2TIM: HW_TRACE ((me, "read - serial2 timer reg %d (nrbytes=%d)\n", *(unsigned8 *)source, nr_bytes)); write_serial2_timer_reg(me, serial, source, nr_bytes); break; default: hw_abort(me, "invalid address"); } return nr_bytes; } const struct hw_descriptor dv_mn103ser_descriptor[] = { { "mn103ser", mn103ser_finish, }, { NULL }, };