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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [sim/] [erc32/] [erc32.c] - Rev 613
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/* * This file is part of SIS. * * SIS, SPARC instruction simulator V2.5 Copyright (C) 1995 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 2 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, write to the Free Software Foundation, Inc., 675 * Mass Ave, Cambridge, MA 02139, USA. * */ /* The control space devices */ #include <sys/types.h> #include <stdio.h> #include <string.h> #include <termios.h> #include <sys/fcntl.h> #include <sys/file.h> #include <unistd.h> #include "sis.h" #include "end.h" #include "sim-config.h" extern int ctrl_c; extern int32 sis_verbose; extern int32 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 /* The target's byte order is big-endian by default until we load a little-endian program. */ int current_target_byte_order = BIG_ENDIAN; #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 find = 0; static uint32 mec_ssa[2]; /* Write protection start address */ static uint32 mec_sea[2]; /* Write protection end address */ static uint32 mec_wpr[2]; /* Write protection control fields */ static uint32 mec_sfsr; static uint32 mec_ffar; static uint32 mec_ipr; static uint32 mec_imr; static uint32 mec_isr; static uint32 mec_icr; static uint32 mec_ifr; static uint32 mec_mcr; /* MEC control register */ static uint32 mec_memcfg; /* Memory control register */ static uint32 mec_wcr; /* MEC waitstate register */ static uint32 mec_iocr; /* MEC IO control register */ static uint32 posted_irq; static uint32 mec_ersr; /* MEC error and status register */ static uint32 mec_tcr; /* MEC test comtrol register */ static uint32 rtc_counter; static uint32 rtc_reload; static uint32 rtc_scaler; static uint32 rtc_scaler_start; static uint32 rtc_enabled; static uint32 rtc_cr; static uint32 rtc_se; static uint32 gpt_counter; static uint32 gpt_reload; static uint32 gpt_scaler; static uint32 gpt_scaler_start; static uint32 gpt_enabled; static uint32 gpt_cr; static uint32 gpt_se; static uint32 wdog_scaler; static uint32 wdog_counter; static uint32 wdog_rst_delay; static uint32 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 mem_ramr_ws; /* RAM read waitstates */ static uint32 mem_ramw_ws; /* RAM write waitstates */ static uint32 mem_romr_ws; /* ROM read waitstates */ static uint32 mem_romw_ws; /* ROM write waitstates */ static uint32 mem_ramstart; /* RAM start */ static uint32 mem_ramend; /* RAM end */ static uint32 mem_rammask; /* RAM address mask */ static uint32 mem_ramsz; /* RAM size */ static uint32 mem_romsz; /* ROM size */ static uint32 mem_accprot; /* RAM write protection enabled */ static uint32 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 fd1, fd2; /* file descriptor for input file */ static int32 Ucontrol; /* UART status register */ static unsigned char aq[UARTBUF], bq[UARTBUF]; static int32 anum, aind = 0; static int32 bnum, bind = 0; static char wbufa[UARTBUF], wbufb[UARTBUF]; static unsigned wnuma; static unsigned wnumb; static FILE *f1in, *f1out, *f2in, *f2out; static struct termios ioc1, ioc2, iocold1, iocold2; static int f1open = 0, f2open = 0; static char uarta_sreg, uarta_hreg, uartb_sreg, uartb_hreg; static uint32 uart_stat_reg; static uint32 uarta_data, uartb_data; #ifdef ERA int era = 0; int erareg; #endif /* Forward declarations */ static void decode_ersr PARAMS ((void)); #ifdef ERRINJ static void iucomperr PARAMS ((void)); #endif static void mecparerror PARAMS ((void)); static void decode_memcfg PARAMS ((void)); static void decode_wcr PARAMS ((void)); static void decode_mcr PARAMS ((void)); static void close_port PARAMS ((void)); static void mec_reset PARAMS ((void)); static void mec_intack PARAMS ((int32 level)); static void chk_irq PARAMS ((void)); static void mec_irq PARAMS ((int32 level)); static void set_sfsr PARAMS ((uint32 fault, uint32 addr, uint32 asi, uint32 read)); static int32 mec_read PARAMS ((uint32 addr, uint32 asi, uint32 *data)); static int mec_write PARAMS ((uint32 addr, uint32 data)); static void port_init PARAMS ((void)); static uint32 read_uart PARAMS ((uint32 addr)); static void write_uart PARAMS ((uint32 addr, uint32 data)); static void flush_uart PARAMS ((void)); static void uarta_tx PARAMS ((void)); static void uartb_tx PARAMS ((void)); static void uart_rx PARAMS ((caddr_t arg)); static void uart_intr PARAMS ((caddr_t arg)); static void uart_irq_start PARAMS ((void)); static void wdog_intr PARAMS ((caddr_t arg)); static void wdog_start PARAMS ((void)); static void rtc_intr PARAMS ((caddr_t arg)); static void rtc_start PARAMS ((void)); static uint32 rtc_counter_read PARAMS ((void)); static void rtc_scaler_set PARAMS ((uint32 val)); static void rtc_reload_set PARAMS ((uint32 val)); static void gpt_intr PARAMS ((caddr_t arg)); static void gpt_start PARAMS ((void)); static uint32 gpt_counter_read PARAMS ((void)); static void gpt_scaler_set PARAMS ((uint32 val)); static void gpt_reload_set PARAMS ((uint32 val)); static void timer_ctrl PARAMS ((uint32 val)); static unsigned char * get_mem_ptr PARAMS ((uint32 addr, uint32 size)); static void fetch_bytes PARAMS ((int asi, unsigned char *mem, uint32 *data, int sz)); static void store_bytes PARAMS ((unsigned char *mem, uint32 *data, int sz)); extern int ext_irl; /* One-time init */ void init_sim() { port_init(); } /* Power-on reset init */ void reset() { mec_reset(); uart_irq_start(); wdog_start(); } static void decode_ersr() { 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() { mec_ersr |= 0x20; decode_ersr(); } /* IU error mode manager */ void error_mode(pc) uint32 pc; { mec_ersr |= 0x1; decode_ersr(); } /* Check memory settings */ static void decode_memcfg() { 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() { 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() { 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() { #ifdef FAST_UART flush_uart(); #endif } int sim_stop(SIM_DESC sd) { ctrl_c = 1; return 1; } static void close_port() { if (f1open && f1in != stdin) fclose(f1in); if (f2open && f2in != stdin) fclose(f2in); } void exit_sim() { close_port(); } static void mec_reset() { 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(level) int32 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() { int32 i; uint32 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(level) int32 level; { mec_ipr |= (1 << level); chk_irq(); } static void set_sfsr(fault, addr, asi, read) uint32 fault; uint32 addr; uint32 asi; uint32 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 mec_read(addr, asi, data) uint32 addr; uint32 asi; uint32 *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; default: set_sfsr(MEC_ACC, addr, asi, 1); return (1); break; } return (MOK); } static int mec_write(addr, data) uint32 addr; uint32 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() { if (dumbio) return; /* do nothing */ if (!ifd1) tcsetattr(0, TCSANOW, &ioc1); if (!ifd2) tcsetattr(0, TCSANOW, &ioc2); } void restore_stdio() { if (dumbio) return; /* do nothing */ if (!ifd1) tcsetattr(0, TCSANOW, &iocold1); if (!ifd2) tcsetattr(0, TCSANOW, &iocold2); } #define DO_STDIO_READ( _fd_, _buf_, _len_ ) \ ( dumbio \ ? (0) /* no bytes read, no delay */ \ : read( _fd_, _buf_, _len_ ) ) static void port_init() { 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) { tcgetattr(ifd1, &ioc1); iocold1 = ioc1; ioc1.c_lflag &= ~(ICANON | ECHO); ioc1.c_cc[VMIN] = 0; ioc1.c_cc[VTIME] = 0; } 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) { tcgetattr(ifd2, &ioc2); iocold2 = ioc2; ioc2.c_lflag &= ~(ICANON | ECHO); ioc2.c_cc[VMIN] = 0; ioc2.c_cc[VTIME] = 0; } f2open = 1; } if (f2out) { ofd2 = fileno(f2out); if (!dumbio && ofd2 == 1) setbuf(f2out, NULL); } wnuma = wnumb = 0; } static uint32 read_uart(addr) uint32 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) 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) aq[aind++]); } else { return (0x600 | (uint32) 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) 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) bq[bind++]); } else { return (0x600 | (uint32) 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(addr, data) uint32 addr; uint32 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() { while (wnuma && f1open) wnuma -= fwrite(wbufa, 1, wnuma, f1out); while (wnumb && f2open) wnumb -= fwrite(wbufb, 1, wnumb, f2out); } static void uarta_tx() { 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); } static void uartb_tx() { 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); } static void uart_rx(arg) caddr_t arg; { int32 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(arg) caddr_t 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() { #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(arg) caddr_t 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() { 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(arg) caddr_t 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() { 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 rtc_counter_read() { return (rtc_counter); } static void rtc_scaler_set(val) uint32 val; { rtc_scaler = val & 0x0ff; /* eight-bit scaler only */ } static void rtc_reload_set(val) uint32 val; { rtc_reload = val; } static void gpt_intr(arg) caddr_t 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() { 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 gpt_counter_read() { return (gpt_counter); } static void gpt_scaler_set(val) uint32 val; { gpt_scaler = val & 0x0ffff; /* 16-bit scaler */ } static void gpt_reload_set(val) uint32 val; { gpt_reload = val; } static void timer_ctrl(val) uint32 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(); } /* Retrieve data from target memory. MEM points to location from which to read the data; DATA points to words where retrieved data will be stored in host byte order. 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). */ static void fetch_bytes (asi, mem, data, sz) int asi; unsigned char *mem; uint32 *data; int sz; { if (CURRENT_TARGET_BYTE_ORDER == BIG_ENDIAN || asi == 8 || asi == 9) { switch (sz) { case 3: data[1] = (((uint32) mem[7]) & 0xff) | ((((uint32) mem[6]) & 0xff) << 8) | ((((uint32) mem[5]) & 0xff) << 16) | ((((uint32) mem[4]) & 0xff) << 24); /* Fall through to 2 */ case 2: data[0] = (((uint32) mem[3]) & 0xff) | ((((uint32) mem[2]) & 0xff) << 8) | ((((uint32) mem[1]) & 0xff) << 16) | ((((uint32) mem[0]) & 0xff) << 24); break; case 1: data[0] = (((uint32) mem[1]) & 0xff) | ((((uint32) mem[0]) & 0xff) << 8); break; case 0: data[0] = mem[0] & 0xff; break; } } else { switch (sz) { case 3: data[1] = ((((uint32) mem[7]) & 0xff) << 24) | ((((uint32) mem[6]) & 0xff) << 16) | ((((uint32) mem[5]) & 0xff) << 8) | (((uint32) mem[4]) & 0xff); /* Fall through to 4 */ case 2: data[0] = ((((uint32) mem[3]) & 0xff) << 24) | ((((uint32) mem[2]) & 0xff) << 16) | ((((uint32) mem[1]) & 0xff) << 8) | (((uint32) mem[0]) & 0xff); break; case 1: data[0] = ((((uint32) mem[1]) & 0xff) << 8) | (((uint32) mem[0]) & 0xff); break; case 0: data[0] = mem[0] & 0xff; break; } } } /* Store data in target byte order. MEM points to location to store data; 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). */ static void store_bytes (mem, data, sz) unsigned char *mem; uint32 *data; int sz; { if (CURRENT_TARGET_BYTE_ORDER == LITTLE_ENDIAN) { switch (sz) { case 3: mem[7] = (data[1] >> 24) & 0xff; mem[6] = (data[1] >> 16) & 0xff; mem[5] = (data[1] >> 8) & 0xff; mem[4] = data[1] & 0xff; /* Fall through to 2 */ case 2: mem[3] = (data[0] >> 24) & 0xff; mem[2] = (data[0] >> 16) & 0xff; /* Fall through to 1 */ case 1: mem[1] = (data[0] >> 8) & 0xff; /* Fall through to 0 */ case 0: mem[0] = data[0] & 0xff; break; } } else { switch (sz) { case 3: mem[7] = data[1] & 0xff; mem[6] = (data[1] >> 8) & 0xff; mem[5] = (data[1] >> 16) & 0xff; mem[4] = (data[1] >> 24) & 0xff; /* Fall through to 2 */ case 2: mem[3] = data[0] & 0xff; mem[2] = (data[0] >> 8) & 0xff; mem[1] = (data[0] >> 16) & 0xff; mem[0] = (data[0] >> 24) & 0xff; break; case 1: mem[1] = data[0] & 0xff; mem[0] = (data[0] >> 8) & 0xff; break; case 0: mem[0] = data[0] & 0xff; break; } } } /* Memory emulation */ int memory_read(asi, addr, data, sz, ws) int32 asi; uint32 addr; uint32 *data; int32 sz; int32 *ws; { int32 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))) { fetch_bytes (asi, &ramb[addr & mem_rammask], data, sz); *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))) { fetch_bytes (asi, &romb[addr & ROM_MASK], data, sz); *ws = 4; return (0); } else if ((addr >= 0x10000000) && (addr < (0x10000000 + (512 << (mec_iocr & 0x0f)))) && (mec_iocr & 0x10)) { *data = erareg; return (0); } } else if (addr < mem_romsz) { fetch_bytes (asi, &romb[addr], data, sz); *ws = mem_romr_ws; return (0); #else } else if (addr < mem_romsz) { fetch_bytes (asi, &romb[addr], data, sz); *ws = mem_romr_ws; return (0); #endif } 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(asi, addr, data, sz, ws) int32 asi; uint32 addr; uint32 *data; int32 sz; int32 *ws; { uint32 byte_addr; uint32 byte_mask; uint32 waddr; uint32 *ram; int32 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); } } store_bytes (&ramb[addr & mem_rammask], data, sz); switch (sz) { case 0: case 1: *ws = mem_ramw_ws + 3; break; case 2: *ws = mem_ramw_ws; break; case 3: *ws = 2 * mem_ramw_ws + STD_WS; break; } 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); 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); 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); return (0); #endif } *ws = MEM_EX_WS; set_sfsr(UIMP_ACC, addr, asi, 0); return (1); } static unsigned char * get_mem_ptr(addr, size) uint32 addr; uint32 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 ((char *) -1); } int sis_memory_write(addr, data, length) uint32 addr; char *data; uint32 length; { char *mem; if ((mem = get_mem_ptr(addr, length)) == ((char *) -1)) return (0); memcpy(mem, data, length); return (length); } int sis_memory_read(addr, data, length) uint32 addr; char *data; uint32 length; { char *mem; if ((mem = get_mem_ptr(addr, length)) == ((char *) -1)) return (0); memcpy(data, mem, length); return (length); }
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