Projet_SETI_RISC-V/riscv-gnu-toolchain/binutils/sim/erc32/erc32.c
2023-03-06 14:48:14 +01:00

1801 lines
37 KiB
C

/* This file is part of SIS (SPARC instruction simulator)
Copyright (C) 1995-2022 Free Software Foundation, Inc.
Contributed by Jiri Gaisler, European Space Agency
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/>. */
/* The control space devices */
/* This must come before any other includes. */
#include "defs.h"
#include <sys/types.h>
#include <stdio.h>
#include <string.h>
#ifdef HAVE_TERMIOS_H
#include <termios.h>
#endif
#include <sys/fcntl.h>
#include <sys/file.h>
#include <unistd.h>
#include "sis.h"
#include "sim-config.h"
extern int ctrl_c;
extern int32_t sis_verbose;
extern int32_t sparclite, sparclite_board;
extern int rom8,wrp,uben;
extern char uart_dev1[], uart_dev2[];
int dumbio = 0; /* normal, smart, terminal oriented IO by default */
/* MEC registers */
#define MEC_START 0x01f80000
#define MEC_END 0x01f80100
/* Memory exception waitstates */
#define MEM_EX_WS 1
/* ERC32 always adds one waitstate during RAM std */
#define STD_WS 1
#ifdef ERRINJ
extern int errmec;
#endif
#define MEC_WS 0 /* Waitstates per MEC access (0 ws) */
#define MOK 0
/* MEC register addresses */
#define MEC_MCR 0x000
#define MEC_SFR 0x004
#define MEC_PWDR 0x008
#define MEC_MEMCFG 0x010
#define MEC_IOCR 0x014
#define MEC_WCR 0x018
#define MEC_MAR0 0x020
#define MEC_MAR1 0x024
#define MEC_SSA1 0x020
#define MEC_SEA1 0x024
#define MEC_SSA2 0x028
#define MEC_SEA2 0x02C
#define MEC_ISR 0x044
#define MEC_IPR 0x048
#define MEC_IMR 0x04C
#define MEC_ICR 0x050
#define MEC_IFR 0x054
#define MEC_WDOG 0x060
#define MEC_TRAPD 0x064
#define MEC_RTC_COUNTER 0x080
#define MEC_RTC_RELOAD 0x080
#define MEC_RTC_SCALER 0x084
#define MEC_GPT_COUNTER 0x088
#define MEC_GPT_RELOAD 0x088
#define MEC_GPT_SCALER 0x08C
#define MEC_TIMER_CTRL 0x098
#define MEC_SFSR 0x0A0
#define MEC_FFAR 0x0A4
#define MEC_ERSR 0x0B0
#define MEC_DBG 0x0C0
#define MEC_TCR 0x0D0
#define MEC_BRK 0x0C4
#define MEC_WPR 0x0C8
#define MEC_UARTA 0x0E0
#define MEC_UARTB 0x0E4
#define MEC_UART_CTRL 0x0E8
#define SIM_LOAD 0x0F0
/* Memory exception causes */
#define PROT_EXC 0x3
#define UIMP_ACC 0x4
#define MEC_ACC 0x6
#define WATCH_EXC 0xa
#define BREAK_EXC 0xb
/* Size of UART buffers (bytes) */
#define UARTBUF 1024
/* Number of simulator ticks between flushing the UARTS. */
/* For good performance, keep above 1000 */
#define UART_FLUSH_TIME 3000
/* MEC timer control register bits */
#define TCR_GACR 1
#define TCR_GACL 2
#define TCR_GASE 4
#define TCR_GASL 8
#define TCR_TCRCR 0x100
#define TCR_TCRCL 0x200
#define TCR_TCRSE 0x400
#define TCR_TCRSL 0x800
/* New uart defines */
#define UART_TX_TIME 1000
#define UART_RX_TIME 1000
#define UARTA_DR 0x1
#define UARTA_SRE 0x2
#define UARTA_HRE 0x4
#define UARTA_OR 0x40
#define UARTA_CLR 0x80
#define UARTB_DR 0x10000
#define UARTB_SRE 0x20000
#define UARTB_HRE 0x40000
#define UARTB_OR 0x400000
#define UARTB_CLR 0x800000
#define UART_DR 0x100
#define UART_TSE 0x200
#define UART_THE 0x400
/* MEC registers */
static char fname[256];
static int32_t find = 0;
static uint32_t mec_ssa[2]; /* Write protection start address */
static uint32_t mec_sea[2]; /* Write protection end address */
static uint32_t mec_wpr[2]; /* Write protection control fields */
static uint32_t mec_sfsr;
static uint32_t mec_ffar;
static uint32_t mec_ipr;
static uint32_t mec_imr;
static uint32_t mec_isr;
static uint32_t mec_icr;
static uint32_t mec_ifr;
static uint32_t mec_mcr; /* MEC control register */
static uint32_t mec_memcfg; /* Memory control register */
static uint32_t mec_wcr; /* MEC waitstate register */
static uint32_t mec_iocr; /* MEC IO control register */
static uint32_t posted_irq;
static uint32_t mec_ersr; /* MEC error and status register */
static uint32_t mec_tcr; /* MEC test comtrol register */
static uint32_t rtc_counter;
static uint32_t rtc_reload;
static uint32_t rtc_scaler;
static uint32_t rtc_scaler_start;
static uint32_t rtc_enabled;
static uint32_t rtc_cr;
static uint32_t rtc_se;
static uint32_t gpt_counter;
static uint32_t gpt_reload;
static uint32_t gpt_scaler;
static uint32_t gpt_scaler_start;
static uint32_t gpt_enabled;
static uint32_t gpt_cr;
static uint32_t gpt_se;
static uint32_t wdog_scaler;
static uint32_t wdog_counter;
static uint32_t wdog_rst_delay;
static uint32_t wdog_rston;
enum wdog_type {
init, disabled, enabled, stopped
};
static enum wdog_type wdog_status;
/* ROM size 1024 Kbyte */
#define ROM_SZ 0x100000
#define ROM_MASK 0x0fffff
/* RAM size 4 Mbyte */
#define RAM_START 0x02000000
#define RAM_END 0x02400000
#define RAM_MASK 0x003fffff
/* SPARClite boards all seem to have RAM at the same place. */
#define RAM_START_SLITE 0x40000000
#define RAM_END_SLITE 0x40400000
#define RAM_MASK_SLITE 0x003fffff
/* Memory support variables */
static uint32_t mem_ramr_ws; /* RAM read waitstates */
static uint32_t mem_ramw_ws; /* RAM write waitstates */
static uint32_t mem_romr_ws; /* ROM read waitstates */
static uint32_t mem_romw_ws; /* ROM write waitstates */
static uint32_t mem_ramstart; /* RAM start */
static uint32_t mem_ramend; /* RAM end */
static uint32_t mem_rammask; /* RAM address mask */
static uint32_t mem_ramsz; /* RAM size */
static uint32_t mem_romsz; /* ROM size */
static uint32_t mem_accprot; /* RAM write protection enabled */
static uint32_t mem_blockprot; /* RAM block write protection enabled */
static unsigned char romb[ROM_SZ];
static unsigned char ramb[RAM_END - RAM_START];
/* UART support variables */
static int32_t fd1, fd2; /* file descriptor for input file */
static int32_t Ucontrol; /* UART status register */
static unsigned char aq[UARTBUF], bq[UARTBUF];
static int32_t anum, aind = 0;
static int32_t bnum, bind = 0;
static char wbufa[UARTBUF], wbufb[UARTBUF];
static unsigned wnuma;
static unsigned wnumb;
static FILE *f1in, *f1out, *f2in, *f2out;
#ifdef HAVE_TERMIOS_H
static struct termios ioc1, ioc2, iocold1, iocold2;
#endif
static int f1open = 0, f2open = 0;
static char uarta_sreg, uarta_hreg, uartb_sreg, uartb_hreg;
static uint32_t uart_stat_reg;
static uint32_t uarta_data, uartb_data;
#ifdef ERA
int era = 0;
int erareg;
#endif
/* Forward declarations */
static void decode_ersr (void);
#ifdef ERRINJ
static void iucomperr (void);
#endif
static void mecparerror (void);
static void decode_memcfg (void);
static void decode_wcr (void);
static void decode_mcr (void);
static void close_port (void);
static void mec_reset (void);
static void mec_intack (int32_t level);
static void chk_irq (void);
static void mec_irq (int32_t level);
static void set_sfsr (uint32_t fault, uint32_t addr,
uint32_t asi, uint32_t read);
static int32_t mec_read (uint32_t addr, uint32_t asi, uint32_t *data);
static int mec_write (uint32_t addr, uint32_t data);
static void port_init (void);
static uint32_t read_uart (uint32_t addr);
static void write_uart (uint32_t addr, uint32_t data);
static void flush_uart (void);
static void uarta_tx (void);
static void uartb_tx (void);
static void uart_rx (void *arg);
static void uart_intr (void *arg);
static void uart_irq_start (void);
static void wdog_intr (void *arg);
static void wdog_start (void);
static void rtc_intr (void *arg);
static void rtc_start (void);
static uint32_t rtc_counter_read (void);
static void rtc_scaler_set (uint32_t val);
static void rtc_reload_set (uint32_t val);
static void gpt_intr (void *arg);
static void gpt_start (void);
static uint32_t gpt_counter_read (void);
static void gpt_scaler_set (uint32_t val);
static void gpt_reload_set (uint32_t val);
static void timer_ctrl (uint32_t val);
static void * get_mem_ptr (uint32_t addr, uint32_t size);
static void store_bytes (unsigned char *mem, uint32_t waddr,
uint32_t *data, int sz, int32_t *ws);
extern int ext_irl;
/* One-time init */
void
init_sim(void)
{
port_init();
}
/* Power-on reset init */
void
reset(void)
{
mec_reset();
uart_irq_start();
wdog_start();
}
static void
decode_ersr(void)
{
if (mec_ersr & 0x01) {
if (!(mec_mcr & 0x20)) {
if (mec_mcr & 0x40) {
sys_reset();
mec_ersr = 0x8000;
if (sis_verbose)
printf("Error manager reset - IU in error mode\n");
} else {
sys_halt();
mec_ersr |= 0x2000;
if (sis_verbose)
printf("Error manager halt - IU in error mode\n");
}
} else
mec_irq(1);
}
if (mec_ersr & 0x04) {
if (!(mec_mcr & 0x200)) {
if (mec_mcr & 0x400) {
sys_reset();
mec_ersr = 0x8000;
if (sis_verbose)
printf("Error manager reset - IU comparison error\n");
} else {
sys_halt();
mec_ersr |= 0x2000;
if (sis_verbose)
printf("Error manager halt - IU comparison error\n");
}
} else
mec_irq(1);
}
if (mec_ersr & 0x20) {
if (!(mec_mcr & 0x2000)) {
if (mec_mcr & 0x4000) {
sys_reset();
mec_ersr = 0x8000;
if (sis_verbose)
printf("Error manager reset - MEC hardware error\n");
} else {
sys_halt();
mec_ersr |= 0x2000;
if (sis_verbose)
printf("Error manager halt - MEC hardware error\n");
}
} else
mec_irq(1);
}
}
#ifdef ERRINJ
static void
iucomperr()
{
mec_ersr |= 0x04;
decode_ersr();
}
#endif
static void
mecparerror(void)
{
mec_ersr |= 0x20;
decode_ersr();
}
/* IU error mode manager */
void
error_mode(uint32_t pc)
{
mec_ersr |= 0x1;
decode_ersr();
}
/* Check memory settings */
static void
decode_memcfg(void)
{
if (rom8) mec_memcfg &= ~0x20000;
else mec_memcfg |= 0x20000;
mem_ramsz = (256 * 1024) << ((mec_memcfg >> 10) & 7);
mem_romsz = (128 * 1024) << ((mec_memcfg >> 18) & 7);
if (sparclite_board) {
mem_ramstart = RAM_START_SLITE;
mem_ramend = RAM_END_SLITE;
mem_rammask = RAM_MASK_SLITE;
}
else {
mem_ramstart = RAM_START;
mem_ramend = RAM_END;
mem_rammask = RAM_MASK;
}
if (sis_verbose)
printf("RAM start: 0x%x, RAM size: %d K, ROM size: %d K\n",
mem_ramstart, mem_ramsz >> 10, mem_romsz >> 10);
}
static void
decode_wcr(void)
{
mem_ramr_ws = mec_wcr & 3;
mem_ramw_ws = (mec_wcr >> 2) & 3;
mem_romr_ws = (mec_wcr >> 4) & 0x0f;
if (rom8) {
if (mem_romr_ws > 0 ) mem_romr_ws--;
mem_romr_ws = 5 + (4*mem_romr_ws);
}
mem_romw_ws = (mec_wcr >> 8) & 0x0f;
if (sis_verbose)
printf("Waitstates = RAM read: %d, RAM write: %d, ROM read: %d, ROM write: %d\n",
mem_ramr_ws, mem_ramw_ws, mem_romr_ws, mem_romw_ws);
}
static void
decode_mcr(void)
{
mem_accprot = (mec_wpr[0] | mec_wpr[1]);
mem_blockprot = (mec_mcr >> 3) & 1;
if (sis_verbose && mem_accprot)
printf("Memory block write protection enabled\n");
if (mec_mcr & 0x08000) {
mec_ersr |= 0x20;
decode_ersr();
}
if (sis_verbose && (mec_mcr & 2))
printf("Software reset enabled\n");
if (sis_verbose && (mec_mcr & 1))
printf("Power-down mode enabled\n");
}
/* Flush ports when simulator stops */
void
sim_halt(void)
{
#ifdef FAST_UART
flush_uart();
#endif
}
int
sim_stop(SIM_DESC sd)
{
ctrl_c = 1;
return 1;
}
static void
close_port(void)
{
if (f1open && f1in != stdin)
fclose(f1in);
if (f2open && f2in != stdin)
fclose(f2in);
}
void
exit_sim(void)
{
close_port();
}
static void
mec_reset(void)
{
int i;
find = 0;
for (i = 0; i < 2; i++)
mec_ssa[i] = mec_sea[i] = mec_wpr[i] = 0;
mec_mcr = 0x01350014;
mec_iocr = 0;
mec_sfsr = 0x078;
mec_ffar = 0;
mec_ipr = 0;
mec_imr = 0x7ffe;
mec_isr = 0;
mec_icr = 0;
mec_ifr = 0;
mec_memcfg = 0x10000;
mec_wcr = -1;
mec_ersr = 0; /* MEC error and status register */
mec_tcr = 0; /* MEC test comtrol register */
decode_memcfg();
decode_wcr();
decode_mcr();
posted_irq = 0;
wnuma = wnumb = 0;
anum = aind = bnum = bind = 0;
uart_stat_reg = UARTA_SRE | UARTA_HRE | UARTB_SRE | UARTB_HRE;
uarta_data = uartb_data = UART_THE | UART_TSE;
rtc_counter = 0xffffffff;
rtc_reload = 0xffffffff;
rtc_scaler = 0xff;
rtc_enabled = 0;
rtc_cr = 0;
rtc_se = 0;
gpt_counter = 0xffffffff;
gpt_reload = 0xffffffff;
gpt_scaler = 0xffff;
gpt_enabled = 0;
gpt_cr = 0;
gpt_se = 0;
wdog_scaler = 255;
wdog_rst_delay = 255;
wdog_counter = 0xffff;
wdog_rston = 0;
wdog_status = init;
#ifdef ERA
erareg = 0;
#endif
}
static void
mec_intack(int32_t level)
{
int irq_test;
if (sis_verbose)
printf("interrupt %d acknowledged\n", level);
irq_test = mec_tcr & 0x80000;
if ((irq_test) && (mec_ifr & (1 << level)))
mec_ifr &= ~(1 << level);
else
mec_ipr &= ~(1 << level);
chk_irq();
}
static void
chk_irq(void)
{
int32_t i;
uint32_t itmp;
int old_irl;
old_irl = ext_irl;
if (mec_tcr & 0x80000) itmp = mec_ifr;
else itmp = 0;
itmp = ((mec_ipr | itmp) & ~mec_imr) & 0x0fffe;
ext_irl = 0;
if (itmp != 0) {
for (i = 15; i > 0; i--) {
if (((itmp >> i) & 1) != 0) {
if ((sis_verbose) && (i > old_irl))
printf("IU irl: %d\n", i);
ext_irl = i;
set_int(i, mec_intack, i);
break;
}
}
}
}
static void
mec_irq(int32_t level)
{
mec_ipr |= (1 << level);
chk_irq();
}
static void
set_sfsr(uint32_t fault, uint32_t addr, uint32_t asi, uint32_t read)
{
if ((asi == 0xa) || (asi == 0xb)) {
mec_ffar = addr;
mec_sfsr = (fault << 3) | (!read << 15);
mec_sfsr |= ((mec_sfsr & 1) ^ 1) | (mec_sfsr & 1);
switch (asi) {
case 0xa:
mec_sfsr |= 0x0004;
break;
case 0xb:
mec_sfsr |= 0x1004;
break;
}
}
}
static int32_t
mec_read(uint32_t addr, uint32_t asi, uint32_t *data)
{
switch (addr & 0x0ff) {
case MEC_MCR: /* 0x00 */
*data = mec_mcr;
break;
case MEC_MEMCFG: /* 0x10 */
*data = mec_memcfg;
break;
case MEC_IOCR:
*data = mec_iocr; /* 0x14 */
break;
case MEC_SSA1: /* 0x20 */
*data = mec_ssa[0] | (mec_wpr[0] << 23);
break;
case MEC_SEA1: /* 0x24 */
*data = mec_sea[0];
break;
case MEC_SSA2: /* 0x28 */
*data = mec_ssa[1] | (mec_wpr[1] << 23);
break;
case MEC_SEA2: /* 0x2c */
*data = mec_sea[1];
break;
case MEC_ISR: /* 0x44 */
*data = mec_isr;
break;
case MEC_IPR: /* 0x48 */
*data = mec_ipr;
break;
case MEC_IMR: /* 0x4c */
*data = mec_imr;
break;
case MEC_IFR: /* 0x54 */
*data = mec_ifr;
break;
case MEC_RTC_COUNTER: /* 0x80 */
*data = rtc_counter_read();
break;
case MEC_RTC_SCALER: /* 0x84 */
if (rtc_enabled)
*data = rtc_scaler - (now() - rtc_scaler_start);
else
*data = rtc_scaler;
break;
case MEC_GPT_COUNTER: /* 0x88 */
*data = gpt_counter_read();
break;
case MEC_GPT_SCALER: /* 0x8c */
if (rtc_enabled)
*data = gpt_scaler - (now() - gpt_scaler_start);
else
*data = gpt_scaler;
break;
case MEC_SFSR: /* 0xA0 */
*data = mec_sfsr;
break;
case MEC_FFAR: /* 0xA4 */
*data = mec_ffar;
break;
case SIM_LOAD:
fname[find] = 0;
if (find == 0)
strcpy(fname, "simload");
find = bfd_load(fname);
if (find == -1)
*data = 0;
else
*data = 1;
find = 0;
break;
case MEC_ERSR: /* 0xB0 */
*data = mec_ersr;
break;
case MEC_TCR: /* 0xD0 */
*data = mec_tcr;
break;
case MEC_UARTA: /* 0xE0 */
case MEC_UARTB: /* 0xE4 */
if (asi != 0xb) {
set_sfsr(MEC_ACC, addr, asi, 1);
return 1;
}
*data = read_uart(addr);
break;
case MEC_UART_CTRL: /* 0xE8 */
*data = read_uart(addr);
break;
case 0xF4: /* simulator RAM size in bytes */
*data = 4096*1024;
break;
case 0xF8: /* simulator ROM size in bytes */
*data = 1024*1024;
break;
default:
set_sfsr(MEC_ACC, addr, asi, 1);
return 1;
break;
}
return MOK;
}
static int
mec_write(uint32_t addr, uint32_t data)
{
if (sis_verbose > 1)
printf("MEC write a: %08x, d: %08x\n",addr,data);
switch (addr & 0x0ff) {
case MEC_MCR:
mec_mcr = data;
decode_mcr();
if (mec_mcr & 0x08000) mecparerror();
break;
case MEC_SFR:
if (mec_mcr & 0x2) {
sys_reset();
mec_ersr = 0x4000;
if (sis_verbose)
printf(" Software reset issued\n");
}
break;
case MEC_IOCR:
mec_iocr = data;
if (mec_iocr & 0xC0C0C0C0) mecparerror();
break;
case MEC_SSA1: /* 0x20 */
if (data & 0xFE000000) mecparerror();
mec_ssa[0] = data & 0x7fffff;
mec_wpr[0] = (data >> 23) & 0x03;
mem_accprot = mec_wpr[0] || mec_wpr[1];
if (sis_verbose && mec_wpr[0])
printf("Segment 1 memory protection enabled (0x02%06x - 0x02%06x)\n",
mec_ssa[0] << 2, mec_sea[0] << 2);
break;
case MEC_SEA1: /* 0x24 */
if (data & 0xFF800000) mecparerror();
mec_sea[0] = data & 0x7fffff;
break;
case MEC_SSA2: /* 0x28 */
if (data & 0xFE000000) mecparerror();
mec_ssa[1] = data & 0x7fffff;
mec_wpr[1] = (data >> 23) & 0x03;
mem_accprot = mec_wpr[0] || mec_wpr[1];
if (sis_verbose && mec_wpr[1])
printf("Segment 2 memory protection enabled (0x02%06x - 0x02%06x)\n",
mec_ssa[1] << 2, mec_sea[1] << 2);
break;
case MEC_SEA2: /* 0x2c */
if (data & 0xFF800000) mecparerror();
mec_sea[1] = data & 0x7fffff;
break;
case MEC_UARTA:
case MEC_UARTB:
if (data & 0xFFFFFF00) mecparerror();
case MEC_UART_CTRL:
if (data & 0xFF00FF00) mecparerror();
write_uart(addr, data);
break;
case MEC_GPT_RELOAD:
gpt_reload_set(data);
break;
case MEC_GPT_SCALER:
if (data & 0xFFFF0000) mecparerror();
gpt_scaler_set(data);
break;
case MEC_TIMER_CTRL:
if (data & 0xFFFFF0F0) mecparerror();
timer_ctrl(data);
break;
case MEC_RTC_RELOAD:
rtc_reload_set(data);
break;
case MEC_RTC_SCALER:
if (data & 0xFFFFFF00) mecparerror();
rtc_scaler_set(data);
break;
case MEC_SFSR: /* 0xA0 */
if (data & 0xFFFF0880) mecparerror();
mec_sfsr = 0x78;
break;
case MEC_ISR:
if (data & 0xFFFFE000) mecparerror();
mec_isr = data;
break;
case MEC_IMR: /* 0x4c */
if (data & 0xFFFF8001) mecparerror();
mec_imr = data & 0x7ffe;
chk_irq();
break;
case MEC_ICR: /* 0x50 */
if (data & 0xFFFF0001) mecparerror();
mec_ipr &= ~data & 0x0fffe;
chk_irq();
break;
case MEC_IFR: /* 0x54 */
if (mec_tcr & 0x080000) {
if (data & 0xFFFF0001) mecparerror();
mec_ifr = data & 0xfffe;
chk_irq();
}
break;
case SIM_LOAD:
fname[find++] = (char) data;
break;
case MEC_MEMCFG: /* 0x10 */
if (data & 0xC0E08000) mecparerror();
mec_memcfg = data;
decode_memcfg();
if (mec_memcfg & 0xc0e08000)
mecparerror();
break;
case MEC_WCR: /* 0x18 */
mec_wcr = data;
decode_wcr();
break;
case MEC_ERSR: /* 0xB0 */
if (mec_tcr & 0x100000)
if (data & 0xFFFFEFC0) mecparerror();
mec_ersr = data & 0x103f;
break;
case MEC_TCR: /* 0xD0 */
if (data & 0xFFE1FFC0) mecparerror();
mec_tcr = data & 0x1e003f;
break;
case MEC_WDOG: /* 0x60 */
wdog_scaler = (data >> 16) & 0x0ff;
wdog_counter = data & 0x0ffff;
wdog_rst_delay = data >> 24;
wdog_rston = 0;
if (wdog_status == stopped)
wdog_start();
wdog_status = enabled;
break;
case MEC_TRAPD: /* 0x64 */
if (wdog_status == init) {
wdog_status = disabled;
if (sis_verbose)
printf("Watchdog disabled\n");
}
break;
case MEC_PWDR:
if (mec_mcr & 1)
wait_for_irq();
break;
default:
set_sfsr(MEC_ACC, addr, 0xb, 0);
return 1;
break;
}
return MOK;
}
/* MEC UARTS */
static int ifd1 = -1, ifd2 = -1, ofd1 = -1, ofd2 = -1;
void
init_stdio(void)
{
if (dumbio)
return; /* do nothing */
#ifdef HAVE_TERMIOS_H
if (!ifd1)
tcsetattr(0, TCSANOW, &ioc1);
if (!ifd2)
tcsetattr(0, TCSANOW, &ioc2);
#endif
}
void
restore_stdio(void)
{
if (dumbio)
return; /* do nothing */
#ifdef HAVE_TERMIOS_H
if (!ifd1)
tcsetattr(0, TCSANOW, &iocold1);
if (!ifd2)
tcsetattr(0, TCSANOW, &iocold2);
#endif
}
#define DO_STDIO_READ( _fd_, _buf_, _len_ ) \
( dumbio \
? (0) /* no bytes read, no delay */ \
: read( _fd_, _buf_, _len_ ) )
static void
port_init(void)
{
if (uben) {
f2in = stdin;
f1in = NULL;
f2out = stdout;
f1out = NULL;
} else {
f1in = stdin;
f2in = NULL;
f1out = stdout;
f2out = NULL;
}
if (uart_dev1[0] != 0) {
if ((fd1 = open(uart_dev1, O_RDWR | O_NONBLOCK)) < 0) {
printf("Warning, couldn't open output device %s\n", uart_dev1);
} else {
if (sis_verbose)
printf("serial port A on %s\n", uart_dev1);
f1in = f1out = fdopen(fd1, "r+");
setbuf(f1out, NULL);
f1open = 1;
}
}
if (f1in) ifd1 = fileno(f1in);
if (ifd1 == 0) {
if (sis_verbose)
printf("serial port A on stdin/stdout\n");
if (!dumbio) {
#ifdef HAVE_TERMIOS_H
tcgetattr(ifd1, &ioc1);
iocold1 = ioc1;
ioc1.c_lflag &= ~(ICANON | ECHO);
ioc1.c_cc[VMIN] = 0;
ioc1.c_cc[VTIME] = 0;
#endif
}
f1open = 1;
}
if (f1out) {
ofd1 = fileno(f1out);
if (!dumbio && ofd1 == 1) setbuf(f1out, NULL);
}
if (uart_dev2[0] != 0) {
if ((fd2 = open(uart_dev2, O_RDWR | O_NONBLOCK)) < 0) {
printf("Warning, couldn't open output device %s\n", uart_dev2);
} else {
if (sis_verbose)
printf("serial port B on %s\n", uart_dev2);
f2in = f2out = fdopen(fd2, "r+");
setbuf(f2out, NULL);
f2open = 1;
}
}
if (f2in) ifd2 = fileno(f2in);
if (ifd2 == 0) {
if (sis_verbose)
printf("serial port B on stdin/stdout\n");
if (!dumbio) {
#ifdef HAVE_TERMIOS_H
tcgetattr(ifd2, &ioc2);
iocold2 = ioc2;
ioc2.c_lflag &= ~(ICANON | ECHO);
ioc2.c_cc[VMIN] = 0;
ioc2.c_cc[VTIME] = 0;
#endif
}
f2open = 1;
}
if (f2out) {
ofd2 = fileno(f2out);
if (!dumbio && ofd2 == 1) setbuf(f2out, NULL);
}
wnuma = wnumb = 0;
}
static uint32_t
read_uart(uint32_t addr)
{
unsigned tmp;
tmp = 0;
switch (addr & 0xff) {
case 0xE0: /* UART 1 */
#ifndef _WIN32
#ifdef FAST_UART
if (aind < anum) {
if ((aind + 1) < anum)
mec_irq(4);
return (0x700 | (uint32_t) aq[aind++]);
} else {
if (f1open) {
anum = DO_STDIO_READ(ifd1, aq, UARTBUF);
}
if (anum > 0) {
aind = 0;
if ((aind + 1) < anum)
mec_irq(4);
return (0x700 | (uint32_t) aq[aind++]);
} else {
return (0x600 | (uint32_t) aq[aind]);
}
}
#else
tmp = uarta_data;
uarta_data &= ~UART_DR;
uart_stat_reg &= ~UARTA_DR;
return tmp;
#endif
#else
return 0;
#endif
break;
case 0xE4: /* UART 2 */
#ifndef _WIN32
#ifdef FAST_UART
if (bind < bnum) {
if ((bind + 1) < bnum)
mec_irq(5);
return (0x700 | (uint32_t) bq[bind++]);
} else {
if (f2open) {
bnum = DO_STDIO_READ(ifd2, bq, UARTBUF);
}
if (bnum > 0) {
bind = 0;
if ((bind + 1) < bnum)
mec_irq(5);
return (0x700 | (uint32_t) bq[bind++]);
} else {
return (0x600 | (uint32_t) bq[bind]);
}
}
#else
tmp = uartb_data;
uartb_data &= ~UART_DR;
uart_stat_reg &= ~UARTB_DR;
return tmp;
#endif
#else
return 0;
#endif
break;
case 0xE8: /* UART status register */
#ifndef _WIN32
#ifdef FAST_UART
Ucontrol = 0;
if (aind < anum) {
Ucontrol |= 0x00000001;
} else {
if (f1open) {
anum = DO_STDIO_READ(ifd1, aq, UARTBUF);
}
if (anum > 0) {
Ucontrol |= 0x00000001;
aind = 0;
mec_irq(4);
}
}
if (bind < bnum) {
Ucontrol |= 0x00010000;
} else {
if (f2open) {
bnum = DO_STDIO_READ(ifd2, bq, UARTBUF);
}
if (bnum > 0) {
Ucontrol |= 0x00010000;
bind = 0;
mec_irq(5);
}
}
Ucontrol |= 0x00060006;
return Ucontrol;
#else
return uart_stat_reg;
#endif
#else
return 0x00060006;
#endif
break;
default:
if (sis_verbose)
printf("Read from unimplemented MEC register (%x)\n", addr);
}
return 0;
}
static void
write_uart(uint32_t addr, uint32_t data)
{
unsigned char c;
c = (unsigned char) data;
switch (addr & 0xff) {
case 0xE0: /* UART A */
#ifdef FAST_UART
if (f1open) {
if (wnuma < UARTBUF)
wbufa[wnuma++] = c;
else {
while (wnuma)
wnuma -= fwrite(wbufa, 1, wnuma, f1out);
wbufa[wnuma++] = c;
}
}
mec_irq(4);
#else
if (uart_stat_reg & UARTA_SRE) {
uarta_sreg = c;
uart_stat_reg &= ~UARTA_SRE;
event(uarta_tx, 0, UART_TX_TIME);
} else {
uarta_hreg = c;
uart_stat_reg &= ~UARTA_HRE;
}
#endif
break;
case 0xE4: /* UART B */
#ifdef FAST_UART
if (f2open) {
if (wnumb < UARTBUF)
wbufb[wnumb++] = c;
else {
while (wnumb)
wnumb -= fwrite(wbufb, 1, wnumb, f2out);
wbufb[wnumb++] = c;
}
}
mec_irq(5);
#else
if (uart_stat_reg & UARTB_SRE) {
uartb_sreg = c;
uart_stat_reg &= ~UARTB_SRE;
event(uartb_tx, 0, UART_TX_TIME);
} else {
uartb_hreg = c;
uart_stat_reg &= ~UARTB_HRE;
}
#endif
break;
case 0xE8: /* UART status register */
#ifndef FAST_UART
if (data & UARTA_CLR) {
uart_stat_reg &= 0xFFFF0000;
uart_stat_reg |= UARTA_SRE | UARTA_HRE;
}
if (data & UARTB_CLR) {
uart_stat_reg &= 0x0000FFFF;
uart_stat_reg |= UARTB_SRE | UARTB_HRE;
}
#endif
break;
default:
if (sis_verbose)
printf("Write to unimplemented MEC register (%x)\n", addr);
}
}
static void
flush_uart(void)
{
while (wnuma && f1open)
wnuma -= fwrite(wbufa, 1, wnuma, f1out);
while (wnumb && f2open)
wnumb -= fwrite(wbufb, 1, wnumb, f2out);
}
ATTRIBUTE_UNUSED
static void
uarta_tx(void)
{
while (f1open && fwrite(&uarta_sreg, 1, 1, f1out) != 1);
if (uart_stat_reg & UARTA_HRE) {
uart_stat_reg |= UARTA_SRE;
} else {
uarta_sreg = uarta_hreg;
uart_stat_reg |= UARTA_HRE;
event(uarta_tx, 0, UART_TX_TIME);
}
mec_irq(4);
}
ATTRIBUTE_UNUSED
static void
uartb_tx(void)
{
while (f2open && fwrite(&uartb_sreg, 1, 1, f2out) != 1);
if (uart_stat_reg & UARTB_HRE) {
uart_stat_reg |= UARTB_SRE;
} else {
uartb_sreg = uartb_hreg;
uart_stat_reg |= UARTB_HRE;
event(uartb_tx, 0, UART_TX_TIME);
}
mec_irq(5);
}
ATTRIBUTE_UNUSED
static void
uart_rx(void *arg)
{
int32_t rsize;
char rxd;
rsize = 0;
if (f1open)
rsize = DO_STDIO_READ(ifd1, &rxd, 1);
if (rsize > 0) {
uarta_data = UART_DR | rxd;
if (uart_stat_reg & UARTA_HRE)
uarta_data |= UART_THE;
if (uart_stat_reg & UARTA_SRE)
uarta_data |= UART_TSE;
if (uart_stat_reg & UARTA_DR) {
uart_stat_reg |= UARTA_OR;
mec_irq(7); /* UART error interrupt */
}
uart_stat_reg |= UARTA_DR;
mec_irq(4);
}
rsize = 0;
if (f2open)
rsize = DO_STDIO_READ(ifd2, &rxd, 1);
if (rsize) {
uartb_data = UART_DR | rxd;
if (uart_stat_reg & UARTB_HRE)
uartb_data |= UART_THE;
if (uart_stat_reg & UARTB_SRE)
uartb_data |= UART_TSE;
if (uart_stat_reg & UARTB_DR) {
uart_stat_reg |= UARTB_OR;
mec_irq(7); /* UART error interrupt */
}
uart_stat_reg |= UARTB_DR;
mec_irq(5);
}
event(uart_rx, 0, UART_RX_TIME);
}
static void
uart_intr(void *arg)
{
read_uart(0xE8); /* Check for UART interrupts every 1000 clk */
flush_uart(); /* Flush UART ports */
event(uart_intr, 0, UART_FLUSH_TIME);
}
static void
uart_irq_start(void)
{
#ifdef FAST_UART
event(uart_intr, 0, UART_FLUSH_TIME);
#else
#ifndef _WIN32
event(uart_rx, 0, UART_RX_TIME);
#endif
#endif
}
/* Watch-dog */
static void
wdog_intr(void *arg)
{
if (wdog_status == disabled) {
wdog_status = stopped;
} else {
if (wdog_counter) {
wdog_counter--;
event(wdog_intr, 0, wdog_scaler + 1);
} else {
if (wdog_rston) {
printf("Watchdog reset!\n");
sys_reset();
mec_ersr = 0xC000;
} else {
mec_irq(15);
wdog_rston = 1;
wdog_counter = wdog_rst_delay;
event(wdog_intr, 0, wdog_scaler + 1);
}
}
}
}
static void
wdog_start(void)
{
event(wdog_intr, 0, wdog_scaler + 1);
if (sis_verbose)
printf("Watchdog started, scaler = %d, counter = %d\n",
wdog_scaler, wdog_counter);
}
/* MEC timers */
static void
rtc_intr(void *arg)
{
if (rtc_counter == 0) {
mec_irq(13);
if (rtc_cr)
rtc_counter = rtc_reload;
else
rtc_se = 0;
} else
rtc_counter -= 1;
if (rtc_se) {
event(rtc_intr, 0, rtc_scaler + 1);
rtc_scaler_start = now();
rtc_enabled = 1;
} else {
if (sis_verbose)
printf("RTC stopped\n\r");
rtc_enabled = 0;
}
}
static void
rtc_start(void)
{
if (sis_verbose)
printf("RTC started (period %d)\n\r", rtc_scaler + 1);
event(rtc_intr, 0, rtc_scaler + 1);
rtc_scaler_start = now();
rtc_enabled = 1;
}
static uint32_t
rtc_counter_read(void)
{
return rtc_counter;
}
static void
rtc_scaler_set(uint32_t val)
{
rtc_scaler = val & 0x0ff; /* eight-bit scaler only */
}
static void
rtc_reload_set(uint32_t val)
{
rtc_reload = val;
}
static void
gpt_intr(void *arg)
{
if (gpt_counter == 0) {
mec_irq(12);
if (gpt_cr)
gpt_counter = gpt_reload;
else
gpt_se = 0;
} else
gpt_counter -= 1;
if (gpt_se) {
event(gpt_intr, 0, gpt_scaler + 1);
gpt_scaler_start = now();
gpt_enabled = 1;
} else {
if (sis_verbose)
printf("GPT stopped\n\r");
gpt_enabled = 0;
}
}
static void
gpt_start(void)
{
if (sis_verbose)
printf("GPT started (period %d)\n\r", gpt_scaler + 1);
event(gpt_intr, 0, gpt_scaler + 1);
gpt_scaler_start = now();
gpt_enabled = 1;
}
static uint32_t
gpt_counter_read(void)
{
return gpt_counter;
}
static void
gpt_scaler_set(uint32_t val)
{
gpt_scaler = val & 0x0ffff; /* 16-bit scaler */
}
static void
gpt_reload_set(uint32_t val)
{
gpt_reload = val;
}
static void
timer_ctrl(uint32_t val)
{
rtc_cr = ((val & TCR_TCRCR) != 0);
if (val & TCR_TCRCL) {
rtc_counter = rtc_reload;
}
if (val & TCR_TCRSL) {
}
rtc_se = ((val & TCR_TCRSE) != 0);
if (rtc_se && (rtc_enabled == 0))
rtc_start();
gpt_cr = (val & TCR_GACR);
if (val & TCR_GACL) {
gpt_counter = gpt_reload;
}
if (val & TCR_GACL) {
}
gpt_se = (val & TCR_GASE) >> 2;
if (gpt_se && (gpt_enabled == 0))
gpt_start();
}
/* Store data in host byte order. MEM points to the beginning of the
emulated memory; WADDR contains the index the emulated memory,
DATA points to words in host byte order to be stored. SZ contains log(2)
of the number of bytes to retrieve, and can be 0 (1 byte), 1 (one half-word),
2 (one word), or 3 (two words); WS should return the number of
wait-states. */
static void
store_bytes (unsigned char *mem, uint32_t waddr, uint32_t *data, int32_t sz,
int32_t *ws)
{
switch (sz) {
case 0:
waddr ^= EBT;
mem[waddr] = *data & 0x0ff;
*ws = mem_ramw_ws + 3;
break;
case 1:
#ifdef HOST_LITTLE_ENDIAN
waddr ^= 2;
#endif
memcpy (&mem[waddr], data, 2);
*ws = mem_ramw_ws + 3;
break;
case 2:
memcpy (&mem[waddr], data, 4);
*ws = mem_ramw_ws;
break;
case 3:
memcpy (&mem[waddr], data, 8);
*ws = 2 * mem_ramw_ws + STD_WS;
break;
}
}
/* Memory emulation */
int
memory_iread (uint32_t addr, uint32_t *data, uint32_t *ws)
{
uint32_t asi;
if ((addr >= mem_ramstart) && (addr < (mem_ramstart + mem_ramsz))) {
memcpy (data, &ramb[addr & mem_rammask & ~3], 4);
*ws = mem_ramr_ws;
return 0;
} else if (addr < mem_romsz) {
memcpy (data, &romb[addr & ~3], 4);
*ws = mem_romr_ws;
return 0;
}
if (sis_verbose)
printf ("Memory exception at %x (illegal address)\n", addr);
if (sregs.psr & 0x080)
asi = 9;
else
asi = 8;
set_sfsr (UIMP_ACC, addr, asi, 1);
*ws = MEM_EX_WS;
return 1;
}
int
memory_read(int32_t asi, uint32_t addr, void *data, int32_t sz, int32_t *ws)
{
int32_t mexc;
#ifdef ERRINJ
if (errmec) {
if (sis_verbose)
printf("Inserted MEC error %d\n",errmec);
set_sfsr(errmec, addr, asi, 1);
if (errmec == 5) mecparerror();
if (errmec == 6) iucomperr();
errmec = 0;
return 1;
}
#endif
if ((addr >= mem_ramstart) && (addr < (mem_ramstart + mem_ramsz))) {
memcpy (data, &ramb[addr & mem_rammask & ~3], 4);
*ws = mem_ramr_ws;
return 0;
} else if ((addr >= MEC_START) && (addr < MEC_END)) {
mexc = mec_read(addr, asi, data);
if (mexc) {
set_sfsr(MEC_ACC, addr, asi, 1);
*ws = MEM_EX_WS;
} else {
*ws = 0;
}
return mexc;
#ifdef ERA
} else if (era) {
if ((addr < 0x100000) ||
((addr>= 0x80000000) && (addr < 0x80100000))) {
memcpy (data, &romb[addr & ROM_MASK & ~3], 4);
*ws = 4;
return 0;
} else if ((addr >= 0x10000000) &&
(addr < (0x10000000 + (512 << (mec_iocr & 0x0f)))) &&
(mec_iocr & 0x10)) {
memcpy (data, &erareg, 4);
return 0;
}
} else if (addr < mem_romsz) {
memcpy (data, &romb[addr & ~3], 4);
*ws = mem_romr_ws;
return 0;
#else
} else if (addr < mem_romsz) {
memcpy (data, &romb[addr & ~3], 4);
*ws = mem_romr_ws;
return 0;
#endif
}
if (sis_verbose)
printf ("Memory exception at %x (illegal address)\n", addr);
set_sfsr(UIMP_ACC, addr, asi, 1);
*ws = MEM_EX_WS;
return 1;
}
int
memory_write(int32_t asi, uint32_t addr, uint32_t *data, int32_t sz, int32_t *ws)
{
uint32_t byte_addr;
uint32_t byte_mask;
uint32_t waddr;
uint32_t *ram;
int32_t mexc;
int i;
int wphit[2];
#ifdef ERRINJ
if (errmec) {
if (sis_verbose)
printf("Inserted MEC error %d\n",errmec);
set_sfsr(errmec, addr, asi, 0);
if (errmec == 5) mecparerror();
if (errmec == 6) iucomperr();
errmec = 0;
return 1;
}
#endif
if ((addr >= mem_ramstart) && (addr < (mem_ramstart + mem_ramsz))) {
if (mem_accprot) {
waddr = (addr & 0x7fffff) >> 2;
for (i = 0; i < 2; i++)
wphit[i] =
(((asi == 0xa) && (mec_wpr[i] & 1)) ||
((asi == 0xb) && (mec_wpr[i] & 2))) &&
((waddr >= mec_ssa[i]) && ((waddr | (sz == 3)) < mec_sea[i]));
if (((mem_blockprot) && (wphit[0] || wphit[1])) ||
((!mem_blockprot) &&
!((mec_wpr[0] && wphit[0]) || (mec_wpr[1] && wphit[1]))
)) {
if (sis_verbose)
printf("Memory access protection error at 0x%08x\n", addr);
set_sfsr(PROT_EXC, addr, asi, 0);
*ws = MEM_EX_WS;
return 1;
}
}
waddr = addr & mem_rammask;
store_bytes (ramb, waddr, data, sz, ws);
return 0;
} else if ((addr >= MEC_START) && (addr < MEC_END)) {
if ((sz != 2) || (asi != 0xb)) {
set_sfsr(MEC_ACC, addr, asi, 0);
*ws = MEM_EX_WS;
return 1;
}
mexc = mec_write(addr, *data);
if (mexc) {
set_sfsr(MEC_ACC, addr, asi, 0);
*ws = MEM_EX_WS;
} else {
*ws = 0;
}
return mexc;
#ifdef ERA
} else if (era) {
if ((erareg & 2) &&
((addr < 0x100000) || ((addr >= 0x80000000) && (addr < 0x80100000)))) {
addr &= ROM_MASK;
*ws = sz == 3 ? 8 : 4;
store_bytes (romb, addr, data, sz, ws);
return 0;
} else if ((addr >= 0x10000000) &&
(addr < (0x10000000 + (512 << (mec_iocr & 0x0f)))) &&
(mec_iocr & 0x10)) {
erareg = *data & 0x0e;
return 0;
}
} else if ((addr < mem_romsz) && (mec_memcfg & 0x10000) && (wrp) &&
(((mec_memcfg & 0x20000) && (sz > 1)) ||
(!(mec_memcfg & 0x20000) && (sz == 0)))) {
*ws = mem_romw_ws + 1;
if (sz == 3)
*ws += mem_romw_ws + STD_WS;
store_bytes (romb, addr, data, sz, ws);
return 0;
#else
} else if ((addr < mem_romsz) && (mec_memcfg & 0x10000) && (wrp) &&
(((mec_memcfg & 0x20000) && (sz > 1)) ||
(!(mec_memcfg & 0x20000) && (sz == 0)))) {
*ws = mem_romw_ws + 1;
if (sz == 3)
*ws += mem_romw_ws + STD_WS;
store_bytes (romb, addr, data, sz, ws);
return 0;
#endif
}
*ws = MEM_EX_WS;
set_sfsr(UIMP_ACC, addr, asi, 0);
return 1;
}
static void *
get_mem_ptr(uint32_t addr, uint32_t size)
{
if ((addr + size) < ROM_SZ) {
return &romb[addr];
} else if ((addr >= mem_ramstart) && ((addr + size) < mem_ramend)) {
return &ramb[addr & mem_rammask];
}
#ifdef ERA
else if ((era) && ((addr <0x100000) ||
((addr >= (unsigned) 0x80000000) && ((addr + size) < (unsigned) 0x80100000)))) {
return &romb[addr & ROM_MASK];
}
#endif
return (void *) -1;
}
int
sis_memory_write(uint32_t addr, const void *data, uint32_t length)
{
void *mem;
if ((mem = get_mem_ptr(addr, length)) == ((void *) -1))
return 0;
memcpy(mem, data, length);
return length;
}
int
sis_memory_read(uint32_t addr, void *data, uint32_t length)
{
char *mem;
if ((mem = get_mem_ptr(addr, length)) == ((void *) -1))
return 0;
memcpy(data, mem, length);
return length;
}
extern struct pstate sregs;
void
boot_init (void)
{
mec_write(MEC_WCR, 0); /* zero waitstates */
mec_write(MEC_TRAPD, 0); /* turn off watch-dog */
mec_write(MEC_RTC_SCALER, sregs.freq - 1); /* generate 1 MHz RTC tick */
mec_write(MEC_MEMCFG, (3 << 18) | (4 << 10)); /* 1 MB ROM, 4 MB RAM */
sregs.wim = 2;
sregs.psr = 0x110010e0;
sregs.r[30] = RAM_END;
sregs.r[14] = sregs.r[30] - 96 * 4;
mec_mcr |= 1; /* power-down enabled */
}