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[/] [or1k_old/] [trunk/] [rc203soc/] [sw/] [uClinux/] [arch/] [m68k/] [atari/] [config.c] - Rev 1782
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/* * linux/atari/config.c * * Copyright (C) 1994 Bj”rn Brauel * * 5/2/94 Roman Hodek: * Added setting of time_adj to get a better clock. * * 5/14/94 Roman Hodek: * gettod() for TT * * 5/15/94 Roman Hodek: * hard_reset_now() for Atari (and others?) * * 94/12/30 Andreas Schwab: * atari_sched_init fixed to get precise clock. * * This file is subject to the terms and conditions of the GNU General Public * License. See the file COPYING in the main directory of this archive * for more details. */ /* * Miscellaneous atari stuff */ #include <linux/config.h> #include <linux/types.h> #include <linux/mm.h> #include <asm/bootinfo.h> #include <linux/mc146818rtc.h> #include <linux/kd.h> #include <linux/tty.h> #include <linux/console.h> #include <asm/atarihw.h> #include <asm/atarihdreg.h> #include <asm/atariints.h> #include <asm/system.h> #include <asm/io.h> #include <asm/irq.h> #include <asm/pgtable.h> #include <asm/machdep.h> extern void atari_sched_init(isrfunc); extern int atari_keyb_init(void); extern int atari_kbdrate (struct kbd_repeat *); extern void atari_kbd_leds (unsigned int); extern void atari_init_INTS (void); extern int atari_add_isr (unsigned long, isrfunc, int, void *, char *); extern int atari_remove_isr (unsigned long, isrfunc, void *); extern void atari_enable_irq (unsigned); extern void atari_disable_irq (unsigned); extern int atari_get_irq_list (char *buf, int len); extern unsigned long atari_gettimeoffset (void); extern void atari_mste_gettod (int *, int *, int *, int *, int *, int *); extern void atari_gettod (int *, int *, int *, int *, int *, int *); extern int atari_mste_hwclk (int, struct hwclk_time *); extern int atari_hwclk (int, struct hwclk_time *); extern int atari_mste_set_clock_mmss (unsigned long); extern int atari_set_clock_mmss (unsigned long); extern void atari_mksound( unsigned int count, unsigned int ticks ); extern void atari_reset( void ); #ifdef CONFIG_BLK_DEV_FD extern int atari_floppy_init (void); extern void atari_floppy_setup(char *, int *); #endif extern void atari_waitbut (void); extern struct consw fb_con; extern struct fb_info *atari_fb_init(long *); extern void atari_debug_init (void); extern void atari_video_setup(char *, int *); extern void (*kd_mksound)(unsigned int, unsigned int); /* This function tests for the presence of an address, specially a * hardware register address. It is called very early in the kernel * initialization process, when the VBR register isn't set up yet. On * an Atari, it still points to address 0, which is unmapped. So a bus * error would cause another bus error while fetching the exception * vector, and the CPU would do nothing at all. So we needed to set up * a temporary VBR and a vector table for the duration of the test. */ static int hwreg_present( volatile void *regp ) { int ret = 0; long save_sp, save_vbr; long tmp_vectors[3]; __asm__ __volatile__ ( "movec %/vbr,%2\n\t" "movel #Lberr1,%4@(8)\n\t" "movec %4,%/vbr\n\t" "movel %/sp,%1\n\t" "moveq #0,%0\n\t" "tstb %3@\n\t" "nop\n\t" "moveq #1,%0\n" "Lberr1:\n\t" "movel %1,%/sp\n\t" "movec %2,%/vbr" : "=&d" (ret), "=&r" (save_sp), "=&r" (save_vbr) : "a" (regp), "a" (tmp_vectors) ); return( ret ); } #if 0 static int hwreg_present_bywrite( volatile void *regp, unsigned char val ) { int ret; long save_sp, save_vbr; static long tmp_vectors[3] = { 0, 0, (long)&&after_test }; __asm__ __volatile__ ( "movec %/vbr,%2\n\t" /* save vbr value */ "movec %4,%/vbr\n\t" /* set up temporary vectors */ "movel %/sp,%1\n\t" /* save sp */ "moveq #0,%0\n\t" /* assume not present */ "moveb %5,%3@\n\t" /* write the hardware reg */ "cmpb %3@,%5\n\t" /* compare it */ "seq %0" /* comes here only if reg */ /* is present */ : "=d&" (ret), "=r&" (save_sp), "=r&" (save_vbr) : "a" (regp), "r" (tmp_vectors), "d" (val) ); after_test: __asm__ __volatile__ ( "movel %0,%/sp\n\t" /* restore sp */ "movec %1,%/vbr" /* restore vbr */ : : "r" (save_sp), "r" (save_vbr) : "sp" ); return( ret ); } #endif /* Basically the same, but writes a value into a word register, protected * by a bus error handler */ static int hwreg_write( volatile void *regp, unsigned short val ) { int ret; long save_sp, save_vbr; long tmp_vectors[3]; __asm__ __volatile__ ( "movec %/vbr,%2\n\t" "movel #Lberr2,%4@(8)\n\t" "movec %4,%/vbr\n\t" "movel %/sp,%1\n\t" "moveq #0,%0\n\t" "movew %5,%3@\n\t" "nop \n\t" /* If this nop isn't present, 'ret' may already be * loaded with 1 at the time the bus error * happens! */ "moveq #1,%0\n" "Lberr2:\n\t" "movel %1,%/sp\n\t" "movec %2,%/vbr" : "=&d" (ret), "=&r" (save_sp), "=&r" (save_vbr) : "a" (regp), "a" (tmp_vectors), "g" (val) ); return( ret ); } /* ++roman: This is a more elaborate test for an SCC chip, since the plain * Medusa board generates DTACK at the SCC's standard addresses, but a SCC * board in the Medusa is possible. Also, the addresses where the ST_ESCC * resides generate DTACK without the chip, too. * The method is to write values into the interrupt vector register, that * should be readable without trouble (from channel A!). */ static int scc_test( volatile char *ctla ) { if (!hwreg_present( ctla )) return( 0 ); MFPDELAY(); *ctla = 2; MFPDELAY(); *ctla = 0x40; MFPDELAY(); *ctla = 2; MFPDELAY(); if (*ctla != 0x40) return( 0 ); MFPDELAY(); *ctla = 2; MFPDELAY(); *ctla = 0x60; MFPDELAY(); *ctla = 2; MFPDELAY(); if (*ctla != 0x60) return( 0 ); return( 1 ); } void config_atari(void) { mach_sched_init = atari_sched_init; mach_keyb_init = atari_keyb_init; mach_kbdrate = atari_kbdrate; mach_kbd_leds = atari_kbd_leds; mach_init_INTS = atari_init_INTS; mach_add_isr = atari_add_isr; mach_remove_isr = atari_remove_isr; mach_enable_irq = atari_enable_irq; mach_disable_irq = atari_disable_irq; mach_get_irq_list = atari_get_irq_list; mach_gettimeoffset = atari_gettimeoffset; mach_mksound = atari_mksound; mach_reset = atari_reset; #ifdef CONFIG_BLK_DEV_FD mach_floppy_init = atari_floppy_init; mach_floppy_setup = atari_floppy_setup; #endif conswitchp = &fb_con; waitbut = atari_waitbut; mach_fb_init = atari_fb_init; mach_max_dma_address = 0xffffff; mach_debug_init = atari_debug_init; mach_video_setup = atari_video_setup; kd_mksound = atari_mksound; /* ++bjoern: * Determine hardware present */ printk( "Atari hardware found: " ); if (is_medusa) { /* There's no Atari video hardware on the Medusa, but all the * addresses below generate a DTACK so no bus error occurs! */ } else if (hwreg_present( f030_xreg )) { ATARIHW_SET(VIDEL_SHIFTER); printk( "VIDEL " ); /* This is a temporary hack: If there is Falcon video * hardware, we assume that the ST-DMA serves SCSI instead of * ACSI. In the future, there should be a better method for * this... */ ATARIHW_SET(ST_SCSI); printk( "STDMA-SCSI " ); } else if (hwreg_present( tt_palette )) { ATARIHW_SET(TT_SHIFTER); printk( "TT_SHIFTER " ); } else if (hwreg_present( &shifter.bas_hi )) { if (hwreg_present( &shifter.bas_lo ) && (shifter.bas_lo = 0x0aau, shifter.bas_lo == 0x0aau)) { ATARIHW_SET(EXTD_SHIFTER); printk( "EXTD_SHIFTER " ); } else { ATARIHW_SET(STND_SHIFTER); printk( "STND_SHIFTER " ); } } if (hwreg_present( &mfp.par_dt_reg )) { ATARIHW_SET(ST_MFP); printk( "ST_MFP " ); } if (hwreg_present( &tt_mfp.par_dt_reg )) { ATARIHW_SET(TT_MFP); printk( "TT_MFP " ); } if (hwreg_present( &tt_scsi_dma.dma_addr_hi )) { ATARIHW_SET(SCSI_DMA); printk( "TT_SCSI_DMA " ); } if (hwreg_present( &st_dma.dma_hi )) { ATARIHW_SET(STND_DMA); printk( "STND_DMA " ); } if (is_medusa || /* The ST-DMA address registers aren't readable * on all Medusas, so the test below may fail */ (hwreg_present( &st_dma.dma_vhi ) && (st_dma.dma_vhi = 0x55) && (st_dma.dma_hi = 0xaa) && st_dma.dma_vhi == 0x55 && st_dma.dma_hi == 0xaa && (st_dma.dma_vhi = 0xaa) && (st_dma.dma_hi = 0x55) && st_dma.dma_vhi == 0xaa && st_dma.dma_hi == 0x55)) { ATARIHW_SET(EXTD_DMA); printk( "EXTD_DMA " ); } if (hwreg_present( &tt_scsi.scsi_data )) { ATARIHW_SET(TT_SCSI); printk( "TT_SCSI " ); } if (hwreg_present( &sound_ym.rd_data_reg_sel )) { ATARIHW_SET(YM_2149); printk( "YM2149 " ); } if (!is_medusa && hwreg_present( &tt_dmasnd.ctrl )) { ATARIHW_SET(PCM_8BIT); printk( "PCM " ); } if (hwreg_present( (void *)(0xffff8940) )) { ATARIHW_SET(CODEC); printk( "CODEC " ); } if (hwreg_present( &tt_scc_dma.dma_ctrl ) && #if 0 /* This test sucks! Who knows some better? */ (tt_scc_dma.dma_ctrl = 0x01, (tt_scc_dma.dma_ctrl & 1) == 1) && (tt_scc_dma.dma_ctrl = 0x00, (tt_scc_dma.dma_ctrl & 1) == 0) #else !is_medusa #endif ) { ATARIHW_SET(SCC_DMA); printk( "SCC_DMA " ); } if (scc_test( &scc.cha_a_ctrl )) { ATARIHW_SET(SCC); printk( "SCC " ); } if (scc_test( &st_escc.cha_b_ctrl )) { ATARIHW_SET( ST_ESCC ); printk( "ST_ESCC " ); } if (hwreg_present( &tt_scu.sys_mask )) { ATARIHW_SET(SCU); /* Assume a VME bus if there's a SCU */ ATARIHW_SET( VME ); printk( "VME SCU " ); } if (hwreg_present( (void *)(0xffff9210) )) { ATARIHW_SET(ANALOG_JOY); printk( "ANALOG_JOY " ); } if (hwreg_present( blitter.halftone )) { ATARIHW_SET(BLITTER); printk( "BLITTER " ); } if (hwreg_present( (void *)(ATA_HD_BASE+ATA_HD_CMD) )) { ATARIHW_SET(IDE); printk( "IDE " ); } #if 1 /* This maybe wrong */ if (!is_medusa && hwreg_present( &tt_microwire.data ) && hwreg_present( &tt_microwire.mask ) && (tt_microwire.mask = 0x7ff, tt_microwire.data = MW_LM1992_PSG_HIGH | MW_LM1992_ADDR, tt_microwire.data != 0)) { ATARIHW_SET(MICROWIRE); while (tt_microwire.mask != 0x7ff) ; printk( "MICROWIRE " ); } #endif if (hwreg_present( &tt_rtc.regsel )) { ATARIHW_SET(TT_CLK); printk( "TT_CLK " ); mach_gettod = atari_gettod; mach_hwclk = atari_hwclk; mach_set_clock_mmss = atari_set_clock_mmss; } if (hwreg_present( &mste_rtc.sec_ones)) { ATARIHW_SET(MSTE_CLK); printk( "MSTE_CLK "); mach_gettod = atari_mste_gettod; mach_hwclk = atari_mste_hwclk; mach_set_clock_mmss = atari_mste_set_clock_mmss; } if (!is_medusa && hwreg_present( &dma_wd.fdc_speed ) && hwreg_write( &dma_wd.fdc_speed, 0 )) { ATARIHW_SET(FDCSPEED); printk( "FDC_SPEED "); } if (!ATARIHW_PRESENT(ST_SCSI)) { ATARIHW_SET(ACSI); printk( "ACSI " ); } printk("\n"); if (m68k_is040or060) /* Now it seems to be safe to turn of the tt0 transparent * translation (the one that must not be turned off in * head.S...) */ __asm__ volatile ("moveq #0,%/d0;" ".long 0x4e7b0004;" /* movec d0,itt0 */ ".long 0x4e7b0006;" /* movec d0,dtt0 */ : /* no outputs */ : /* no inputs */ : "d0"); /* allocator for memory that must reside in st-ram */ atari_stram_init (); /* Set up a mapping for the VMEbus address region: * * VME is either at phys. 0xfexxxxxx (TT) or 0xa00000..0xdfffff * (MegaSTE) In both cases, the whole 16 MB chunk is mapped at * 0xfe000000 virt., because this can be done with a single * transparent translation. On the 68040, lots of often unused * page tables would be needed otherwise. On a MegaSTE or similar, * the highest byte is stripped off by hardware due to the 24 bit * design of the bus. */ if (!m68k_is040or060) { unsigned long tt1_val; tt1_val = 0xfe008543; /* Translate 0xfexxxxxx, enable, cache * inhibit, read and write, FDC mask = 3, * FDC val = 4 -> Supervisor only */ __asm__ __volatile__ ( "pmove %0@,%/tt1" : : "a" (&tt1_val) ); } else { __asm__ __volatile__ ( "movel %0,%/d0\n\t" ".long 0x4e7b0005\n\t" /* movec d0,itt1 */ ".long 0x4e7b0007" /* movec d0,dtt1 */ : : "g" (0xfe00a040) /* Translate 0xfexxxxxx, enable, * supervisor only, non-cacheable/ * serialized, writable */ : "d0" ); } } void atari_sched_init (isrfunc timer_routine) { /* set Timer C data Register */ mfp.tim_dt_c = INT_TICKS; /* start timer C, div = 1:100 */ mfp.tim_ct_cd = (mfp.tim_ct_cd & 15) | 0x60; /* install interrupt service routine for MFP Timer C */ add_isr (IRQ_MFP_TIMC, timer_routine, IRQ_TYPE_SLOW, NULL, "timer"); } /* ++andreas: gettimeoffset fixed to check for pending interrupt */ #define TICK_SIZE 10000 /* This is always executed with interrupts disabled. */ unsigned long atari_gettimeoffset (void) { unsigned long ticks, offset = 0; /* read MFP timer C current value */ ticks = mfp.tim_dt_c; /* The probability of underflow is less than 2% */ if (ticks > INT_TICKS - INT_TICKS / 50) /* Check for pending timer interrupt */ if (mfp.int_pn_b & (1 << 5)) offset = TICK_SIZE; ticks = INT_TICKS - ticks; ticks = ticks * 10000L / INT_TICKS; return ticks + offset; } static void mste_read(struct MSTE_RTC *val) { #define COPY(v) val->v=(mste_rtc.v & 0xf) do { COPY(sec_ones) ; COPY(sec_tens) ; COPY(min_ones) ; COPY(min_tens) ; COPY(hr_ones) ; COPY(hr_tens) ; COPY(weekday) ; COPY(day_ones) ; COPY(day_tens) ; COPY(mon_ones) ; COPY(mon_tens) ; COPY(year_ones) ; COPY(year_tens) ; /* prevent from reading the clock while it changed */ } while (val->sec_ones != (mste_rtc.sec_ones & 0xf)); #undef COPY } static void mste_write(struct MSTE_RTC *val) { #define COPY(v) mste_rtc.v=val->v do { COPY(sec_ones) ; COPY(sec_tens) ; COPY(min_ones) ; COPY(min_tens) ; COPY(hr_ones) ; COPY(hr_tens) ; COPY(weekday) ; COPY(day_ones) ; COPY(day_tens) ; COPY(mon_ones) ; COPY(mon_tens) ; COPY(year_ones) ; COPY(year_tens) ; /* prevent from writing the clock while it changed */ } while (val->sec_ones != (mste_rtc.sec_ones & 0xf)); #undef COPY } #define RTC_READ(reg) \ ({ unsigned char __val; \ outb(reg,&tt_rtc.regsel); \ __val = tt_rtc.data; \ __val; \ }) #define RTC_WRITE(reg,val) \ do { \ outb(reg,&tt_rtc.regsel); \ tt_rtc.data = (val); \ } while(0) void atari_mste_gettod (int *yearp, int *monp, int *dayp, int *hourp, int *minp, int *secp) { int hr24=0; struct MSTE_RTC val; mste_rtc.mode=(mste_rtc.mode | 1); hr24=mste_rtc.mon_tens & 1; mste_rtc.mode=(mste_rtc.mode & ~1); mste_read(&val); *secp = val.sec_ones + val.sec_tens * 10; *minp = val.min_ones + val.min_tens * 10; if (hr24) *hourp = val.hr_ones + val.hr_tens * 10; else { *hourp = val.hr_ones + (val.hr_tens & 1) * 10; if (val.hr_tens & 2) *hourp += 12; } *dayp = val.day_ones + val.day_tens * 10; *monp = val.mon_ones + val.mon_tens * 10; *yearp = val.year_ones + val.year_tens * 10 + 80; } void atari_gettod (int *yearp, int *monp, int *dayp, int *hourp, int *minp, int *secp) { unsigned char ctrl; unsigned short tos_version; while (!(RTC_READ(RTC_FREQ_SELECT) & RTC_UIP)) ; while (RTC_READ(RTC_FREQ_SELECT) & RTC_UIP) ; *secp = RTC_READ(RTC_SECONDS); *minp = RTC_READ(RTC_MINUTES); *hourp = RTC_READ(RTC_HOURS); *dayp = RTC_READ(RTC_DAY_OF_MONTH); *monp = RTC_READ(RTC_MONTH); *yearp = RTC_READ(RTC_YEAR); ctrl = RTC_READ(RTC_CONTROL); if (!(ctrl & RTC_DM_BINARY)) { BCD_TO_BIN(*secp); BCD_TO_BIN(*minp); BCD_TO_BIN(*hourp); BCD_TO_BIN(*dayp); BCD_TO_BIN(*monp); BCD_TO_BIN(*yearp); } if (!(ctrl & RTC_24H)) { if (*hourp & 0x80) { *hourp &= ~0x80; *hourp += 12; } } /* Adjust values (let the setup valid) */ /* Fetch tos version at Physical 2 */ /* We my not be able to access this address if the kernel is loaded to st ram, since the first page is unmapped. On the Medusa this is always the case and there is nothing we can do about this, so we just assume the smaller offset. For the TT we use the fact that in head.S we have set up a mapping 0xFFxxxxxx -> 0x00xxxxxx, so that the first 16MB is accessible in the last 16MB of the address space. */ tos_version = is_medusa ? 0xfff : *(unsigned short *)0xFF000002; *yearp += (tos_version < 0x306) ? 70 : 68; } #define HWCLK_POLL_INTERVAL 5 int atari_mste_hwclk( int op, struct hwclk_time *t ) { int hour, year; int hr24=0; struct MSTE_RTC val; mste_rtc.mode=(mste_rtc.mode | 1); hr24=mste_rtc.mon_tens & 1; mste_rtc.mode=(mste_rtc.mode & ~1); if (op) { /* write: prepare values */ val.sec_ones = t->sec % 10; val.sec_tens = t->sec / 10; val.min_ones = t->min % 10; val.min_tens = t->min / 10; hour = t->hour; val.hr_ones = hour % 10; val.hr_tens = hour / 10; if (!hr24 && hour > 11) { hour -= 12; val.hr_ones = hour % 10; val.hr_tens = (hour / 10) | 2; } val.day_ones = t->day % 10; val.day_tens = t->day / 10; val.mon_ones = (t->mon+1) % 10; val.mon_tens = (t->mon+1) / 10; year = t->year - 80; val.year_ones = year % 10; val.year_tens = year / 10; val.weekday = t->wday; mste_write(&val); mste_rtc.mode=(mste_rtc.mode | 1); val.year_ones = (year % 4); /* leap year register */ mste_rtc.mode=(mste_rtc.mode & ~1); } else { mste_read(&val); t->sec = val.sec_ones + val.sec_tens * 10; t->min = val.min_ones + val.min_tens * 10; if (hr24) t->hour = val.hr_ones + val.hr_tens * 10; else { t->hour = val.hr_ones + (val.hr_tens & 1) * 10; if (val.hr_tens & 2) t->hour += 12; } t->day = val.day_ones + val.day_tens * 10; t->mon = val.mon_ones + val.mon_tens * 10 - 1; t->year = val.year_ones + val.year_tens * 10 + 80; t->wday = val.weekday; } return 0; } int atari_hwclk( int op, struct hwclk_time *t ) { int sec=0, min=0, hour=0, day=0, mon=0, year=0, wday=0; unsigned long flags; unsigned short tos_version; unsigned char ctrl; /* Tos version at Physical 2. See above for explanation why we cannot use PTOV(2). */ tos_version = is_medusa ? 0xfff : *(unsigned short *)0xff000002; ctrl = RTC_READ(RTC_CONTROL); /* control registers are * independent from the UIP */ if (op) { /* write: prepare values */ sec = t->sec; min = t->min; hour = t->hour; day = t->day; mon = t->mon + 1; year = t->year - ((tos_version < 0x306) ? 70 : 68); wday = t->wday + (t->wday >= 0); if (!(ctrl & RTC_24H) && hour > 11) { hour -= 12; hour |= 0x80; } if (!(ctrl & RTC_DM_BINARY)) { BIN_TO_BCD(sec); BIN_TO_BCD(min); BIN_TO_BCD(hour); BIN_TO_BCD(day); BIN_TO_BCD(mon); BIN_TO_BCD(year); if (wday >= 0) BIN_TO_BCD(wday); } } /* Reading/writing the clock registers is a bit critical due to * the regular update cycle of the RTC. While an update is in * progress, registers 0..9 shouldn't be touched. * The problem is solved like that: If an update is currently in * progress (the UIP bit is set), the process sleeps for a while * (50ms). This really should be enough, since the update cycle * normally needs 2 ms. * If the UIP bit reads as 0, we have at least 244 usecs until the * update starts. This should be enough... But to be sure, * additionally the RTC_SET bit is set to prevent an update cycle. */ while( RTC_READ(RTC_FREQ_SELECT) & RTC_UIP ) { current->state = TASK_INTERRUPTIBLE; current->timeout = jiffies + HWCLK_POLL_INTERVAL; schedule(); } save_flags(flags); cli(); RTC_WRITE( RTC_CONTROL, ctrl | RTC_SET ); if (!op) { sec = RTC_READ( RTC_SECONDS ); min = RTC_READ( RTC_MINUTES ); hour = RTC_READ( RTC_HOURS ); day = RTC_READ( RTC_DAY_OF_MONTH ); mon = RTC_READ( RTC_MONTH ); year = RTC_READ( RTC_YEAR ); wday = RTC_READ( RTC_DAY_OF_WEEK ); } else { RTC_WRITE( RTC_SECONDS, sec ); RTC_WRITE( RTC_MINUTES, min ); RTC_WRITE( RTC_HOURS, hour ); RTC_WRITE( RTC_DAY_OF_MONTH, day ); RTC_WRITE( RTC_MONTH, mon ); RTC_WRITE( RTC_YEAR, year ); if (wday >= 0) RTC_WRITE( RTC_DAY_OF_WEEK, wday ); } RTC_WRITE( RTC_CONTROL, ctrl & ~RTC_SET ); restore_flags(flags); if (!op) { /* read: adjust values */ if (!(ctrl & RTC_DM_BINARY)) { BCD_TO_BIN(sec); BCD_TO_BIN(min); BCD_TO_BIN(hour); BCD_TO_BIN(day); BCD_TO_BIN(mon); BCD_TO_BIN(year); BCD_TO_BIN(wday); } if (!(ctrl & RTC_24H)) { if (hour & 0x80) { hour &= ~0x80; hour += 12; } } t->sec = sec; t->min = min; t->hour = hour; t->day = day; t->mon = mon - 1; t->year = year + ((tos_version < 0x306) ? 70 : 68); t->wday = wday - 1; } return( 0 ); } int atari_mste_set_clock_mmss (unsigned long nowtime) { short real_seconds = nowtime % 60, real_minutes = (nowtime / 60) % 60; struct MSTE_RTC val; unsigned char rtc_minutes; mste_read(&val); rtc_minutes= val.min_ones + val.min_tens * 10; if ((rtc_minutes < real_minutes ? real_minutes - rtc_minutes : rtc_minutes - real_minutes) < 30) { val.sec_ones = real_seconds % 10; val.sec_tens = real_seconds / 10; val.min_ones = real_minutes % 10; val.min_tens = real_minutes / 10; mste_write(&val); } else return -1; return 0; } int atari_set_clock_mmss (unsigned long nowtime) { int retval = 0; short real_seconds = nowtime % 60, real_minutes = (nowtime / 60) % 60; unsigned char save_control, save_freq_select, rtc_minutes; save_control = RTC_READ (RTC_CONTROL); /* tell the clock it's being set */ RTC_WRITE (RTC_CONTROL, save_control | RTC_SET); save_freq_select = RTC_READ (RTC_FREQ_SELECT); /* stop and reset prescaler */ RTC_WRITE (RTC_FREQ_SELECT, save_freq_select | RTC_DIV_RESET2); rtc_minutes = RTC_READ (RTC_MINUTES); if (!(save_control & RTC_DM_BINARY)) BCD_TO_BIN (rtc_minutes); /* Since we're only adjusting minutes and seconds, don't interfere with hour overflow. This avoids messing with unknown time zones but requires your RTC not to be off by more than 30 minutes. */ if ((rtc_minutes < real_minutes ? real_minutes - rtc_minutes : rtc_minutes - real_minutes) < 30) { if (!(save_control & RTC_DM_BINARY)) { BIN_TO_BCD (real_seconds); BIN_TO_BCD (real_minutes); } RTC_WRITE (RTC_SECONDS, real_seconds); RTC_WRITE (RTC_MINUTES, real_minutes); } else retval = -1; RTC_WRITE (RTC_FREQ_SELECT, save_freq_select); RTC_WRITE (RTC_CONTROL, save_control); return retval; } void atari_waitbut (void) { /* sorry, no-op */ } static inline void ata_mfp_out (char c) { while (!(mfp.trn_stat & 0x80)) /* wait for tx buf empty */ barrier (); mfp.usart_dta = c; } void ata_mfp_print (const char *str) { for( ; *str; ++str ) { if (*str == '\n') ata_mfp_out( '\r' ); ata_mfp_out( *str ); } } static inline void ata_scc_out (char c) { do { MFPDELAY(); } while (!(scc.cha_b_ctrl & 0x04)); /* wait for tx buf empty */ MFPDELAY(); scc.cha_b_data = c; } void ata_scc_print (const char *str) { for( ; *str; ++str ) { if (*str == '\n') ata_scc_out( '\r' ); ata_scc_out( *str ); } } static int ata_par_out (char c) { extern unsigned long loops_per_sec; unsigned char tmp; /* This a some-seconds timeout in case no printer is connected */ unsigned long i = loops_per_sec > 1 ? loops_per_sec : 10000000; while( (mfp.par_dt_reg & 1) && --i ) /* wait for BUSY == L */ ; if (!i) return( 0 ); sound_ym.rd_data_reg_sel = 15; /* select port B */ sound_ym.wd_data = c; /* put char onto port */ sound_ym.rd_data_reg_sel = 14; /* select port A */ tmp = sound_ym.rd_data_reg_sel; sound_ym.wd_data = tmp & ~0x20; /* set strobe L */ MFPDELAY(); /* wait a bit */ sound_ym.wd_data = tmp | 0x20; /* set strobe H */ return( 1 ); } void ata_par_print (const char *str) { static int printer_present = 1; if (!printer_present) return; for( ; *str; ++str ) { if (*str == '\n') if (!ata_par_out( '\r' )) { printer_present = 0; return; } if (!ata_par_out( *str )) { printer_present = 0; return; } } } void atari_debug_init( void ) { extern void (*debug_print_proc)(const char *); extern char m68k_debug_device[]; if (!strcmp( m68k_debug_device, "ser" )) { /* defaults to ser2 for a Falcon and ser1 otherwise */ strcpy( m68k_debug_device, ((boot_info.bi_atari.mch_cookie >> 16) == ATARI_MCH_FALCON) ? "ser2" : "ser1" ); } if (!strcmp( m68k_debug_device, "ser1" )) { /* ST-MFP Modem1 serial port */ mfp.trn_stat &= ~0x01; /* disable TX */ mfp.usart_ctr = 0x88; /* clk 1:16, 8N1 */ mfp.tim_ct_cd &= 0x70; /* stop timer D */ mfp.tim_dt_d = 2; /* 9600 bps */ mfp.tim_ct_cd |= 0x01; /* start timer D, 1:4 */ mfp.trn_stat |= 0x01; /* enable TX */ debug_print_proc = ata_mfp_print; } else if (!strcmp( m68k_debug_device, "ser2" )) { /* SCC Modem2 serial port */ static unsigned char *p, scc_table[] = { 9, 12, /* Reset */ 4, 0x44, /* x16, 1 stopbit, no parity */ 3, 0xc0, /* receiver: 8 bpc */ 5, 0xe2, /* transmitter: 8 bpc, assert dtr/rts */ 9, 0, /* no interrupts */ 10, 0, /* NRZ */ 11, 0x50, /* use baud rate generator */ 12, 24, 13, 0, /* 9600 baud */ 14, 2, 14, 3, /* use master clock for BRG, enable */ 3, 0xc1, /* enable receiver */ 5, 0xea, /* enable transmitter */ 0 }; (void)scc.cha_b_ctrl; /* reset reg pointer */ for( p = scc_table; *p != 0; ) { scc.cha_b_ctrl = *p++; MFPDELAY(); scc.cha_b_ctrl = *p++; MFPDELAY(); } debug_print_proc = ata_scc_print; } else if (!strcmp( m68k_debug_device, "par" )) { /* parallel printer */ atari_turnoff_irq( IRQ_MFP_BUSY ); /* avoid ints */ sound_ym.rd_data_reg_sel = 7; /* select mixer control */ sound_ym.wd_data = 0xff; /* sound off, ports are output */ sound_ym.rd_data_reg_sel = 15; /* select port B */ sound_ym.wd_data = 0; /* no char */ sound_ym.rd_data_reg_sel = 14; /* select port A */ sound_ym.wd_data = sound_ym.rd_data_reg_sel | 0x20; /* strobe H */ debug_print_proc = ata_par_print; } else debug_print_proc = NULL; } void ata_serial_print (const char *str) { int c; while (c = *str++, c != 0) { if (c == '\n') { while (!(mfp.trn_stat & (1 << 7))) barrier (); mfp.usart_dta = '\r'; } while (!(mfp.trn_stat & (1 << 7))) barrier (); mfp.usart_dta = c; } } /* ++roman: * * This function does a reset on machines that lack the ability to * assert the processor's _RESET signal somehow via hardware. It is * based on the fact that you can find the initial SP and PC values * after a reset at physical addresses 0 and 4. This works pretty well * for Atari machines, since the lowest 8 bytes of physical memory are * really ROM (mapped by hardware). For other 680x0 machines: don't * know if it works... * * To get the values at addresses 0 and 4, the MMU better is turned * off first. After that, we have to jump into physical address space * (the PC before the pmove statement points to the virtual address of * the code). Getting that physical address is not hard, but the code * becomes a bit complex since I've tried to ensure that the jump * statement after the pmove is in the cache already (otherwise the * processor can't fetch it!). For that, the code first jumps to the * jump statement with the (virtual) address of the pmove section in * an address register . The jump statement is surely in the cache * now. After that, that physical address of the reset code is loaded * into the same address register, pmove is done and the same jump * statements goes to the reset code. Since there are not many * statements between the two jumps, I hope it stays in the cache. * * The C code makes heavy use of the GCC features that you can get the * address of a C label. No hope to compile this with another compiler * than GCC! */ /* ++andreas: no need for complicated code, just depend on prefetch */ void atari_reset (void) { long tc_val = 0; long reset_addr; /* On the Medusa, phys. 0x4 may contain garbage because it's no ROM. See above for explanation why we cannot use PTOV(4). */ reset_addr = is_medusa ? 0xe00030 : *(unsigned long *) 0xff000004; acia.key_ctrl = ACIA_RESET; /* reset ACIA for switch off OverScan, if it's active */ /* processor independent: turn off interrupts and reset the VBR; * the caches must be left enabled, else prefetching the final jump * instruction doesn't work. */ cli(); __asm__ __volatile__ ("moveq #0,%/d0\n\t" "movec %/d0,%/vbr" : : : "d0" ); if (m68k_is040or060) { unsigned long jmp_addr040 = VTOP(&&jmp_addr_label040); if (m68k_is040or060 == 6) { /* 68060: clear PCR to turn off superscalar operation */ __asm__ __volatile__ ("moveq #0,%/d0\n\t" ".long 0x4e7b0808" /* movec d0,pcr */ : : : "d0" ); } __asm__ __volatile__ ("movel %0,%/d0\n\t" "andl #0xff000000,%/d0\n\t" "orw #0xe020,%/d0\n\t" /* map 16 MB, enable, cacheable */ ".long 0x4e7b0004\n\t" /* movec d0,itt0 */ ".long 0x4e7b0006\n\t" /* movec d0,dtt0 */ "jmp %0@\n\t" : /* no outputs */ : "a" (jmp_addr040) : "d0" ); jmp_addr_label040: __asm__ __volatile__ ("moveq #0,%/d0\n\t" "nop\n\t" ".word 0xf4d8\n\t" /* cinva i/d */ ".word 0xf518\n\t" /* pflusha */ ".long 0x4e7b0003\n\t" /* movec d0,tc */ "jmp %0@" : /* no outputs */ : "a" (reset_addr) : "d0"); } else __asm__ __volatile__ ("pmove %0@,%/tc\n\t" "jmp %1@" : /* no outputs */ : "a" (&tc_val), "a" (reset_addr)); } void atari_get_model(char *model) { strcpy(model, "Atari "); switch (boot_info.bi_atari.mch_cookie >> 16) { case ATARI_MCH_ST: if (ATARIHW_PRESENT(MSTE_CLK)) strcat (model, "Mega ST"); else strcat (model, "ST"); break; case ATARI_MCH_STE: if ((boot_info.bi_atari.mch_cookie & 0xffff) == 0x10) strcat (model, "Mega STE"); else strcat (model, "STE"); break; case ATARI_MCH_TT: if (is_medusa) /* Medusa has TT _MCH cookie */ strcat (model, "Medusa"); else strcat (model, "TT"); break; case ATARI_MCH_FALCON: strcat (model, "Falcon"); break; default: sprintf (model + strlen (model), "(unknown mach cookie 0x%lx)", boot_info.bi_atari.mch_cookie); break; } } int atari_get_hardware_list(char *buffer) { int len = 0, i; for (i = 0; i < boot_info.num_memory; i++) len += sprintf (buffer+len, "\t%3ld MB at 0x%08lx (%s)\n", boot_info.memory[i].size >> 20, boot_info.memory[i].addr, (boot_info.memory[i].addr & 0xff000000 ? "alternate RAM" : "ST-RAM")); #define ATARIHW_ANNOUNCE(name,str) \ if (ATARIHW_PRESENT(name)) \ len += sprintf (buffer + len, "\t%s\n", str) len += sprintf (buffer + len, "Detected hardware:\n"); ATARIHW_ANNOUNCE(STND_SHIFTER, "ST Shifter"); ATARIHW_ANNOUNCE(EXTD_SHIFTER, "STe Shifter"); ATARIHW_ANNOUNCE(TT_SHIFTER, "TT Shifter"); ATARIHW_ANNOUNCE(VIDEL_SHIFTER, "Falcon Shifter"); ATARIHW_ANNOUNCE(YM_2149, "Programmable Sound Generator"); ATARIHW_ANNOUNCE(PCM_8BIT, "PCM 8 Bit Sound"); ATARIHW_ANNOUNCE(CODEC, "CODEC Sound"); ATARIHW_ANNOUNCE(TT_SCSI, "SCSI Controller NCR5380 (TT style)"); ATARIHW_ANNOUNCE(ST_SCSI, "SCSI Controller NCR5380 (Falcon style)"); ATARIHW_ANNOUNCE(ACSI, "ACSI Interface"); ATARIHW_ANNOUNCE(IDE, "IDE Interface"); ATARIHW_ANNOUNCE(FDCSPEED, "8/16 Mhz Switch for FDC"); ATARIHW_ANNOUNCE(ST_MFP, "Multi Function Peripheral MFP 68901"); ATARIHW_ANNOUNCE(TT_MFP, "Second Multi Function Peripheral MFP 68901"); ATARIHW_ANNOUNCE(SCC, "Serial Communications Controller SCC 8530"); ATARIHW_ANNOUNCE(ST_ESCC, "Extended Serial Communications Controller SCC 85230"); ATARIHW_ANNOUNCE(ANALOG_JOY, "Paddle Interface"); ATARIHW_ANNOUNCE(MICROWIRE, "MICROWIRE(tm) Interface"); ATARIHW_ANNOUNCE(STND_DMA, "DMA Controller (24 bit)"); ATARIHW_ANNOUNCE(EXTD_DMA, "DMA Controller (32 bit)"); ATARIHW_ANNOUNCE(SCSI_DMA, "DMA Controller for NCR5380"); ATARIHW_ANNOUNCE(SCC_DMA, "DMA Controller for SCC"); ATARIHW_ANNOUNCE(TT_CLK, "Clock Chip MC146818A"); ATARIHW_ANNOUNCE(MSTE_CLK, "Clock Chip RP5C15"); ATARIHW_ANNOUNCE(SCU, "System Control Unit"); ATARIHW_ANNOUNCE(BLITTER, "Blitter"); ATARIHW_ANNOUNCE(VME, "VME Bus"); return(len); }