/* * atari_dma_emul.c -- TT SCSI DMA emulator for the Hades. * * Copyright 1997 Wout Klaren <W.Klaren@inter.nl.net> * * 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. * * This code was written using the Hades TOS source code as a * reference. This source code can be found on the home page * of Medusa Computer Systems. * * Version 0.1, 1997-09-24. * * This code should be considered experimental. It has only been * tested on a Hades with a 68060. It might not work on a Hades * with a 68040. Make backups of your hard drives before using * this code. */ #include <linux/compiler.h> #include <asm/thread_info.h> #include <asm/uaccess.h> #define hades_dma_ctrl (*(unsigned char *) 0xffff8717) #define hades_psdm_reg (*(unsigned char *) 0xffff8741) #define TRANSFER_SIZE 16 struct m68040_frame { unsigned long effaddr; /* effective address */ unsigned short ssw; /* special status word */ unsigned short wb3s; /* write back 3 status */ unsigned short wb2s; /* write back 2 status */ unsigned short wb1s; /* write back 1 status */ unsigned long faddr; /* fault address */ unsigned long wb3a; /* write back 3 address */ unsigned long wb3d; /* write back 3 data */ unsigned long wb2a; /* write back 2 address */ unsigned long wb2d; /* write back 2 data */ unsigned long wb1a; /* write back 1 address */ unsigned long wb1dpd0; /* write back 1 data/push data 0*/ unsigned long pd1; /* push data 1*/ unsigned long pd2; /* push data 2*/ unsigned long pd3; /* push data 3*/ }; static void writeback (unsigned short wbs, unsigned long wba, unsigned long wbd, void *old_buserr) { mm_segment_t fs = get_fs(); static void *save_buserr; __asm__ __volatile__ ("movec.l %%vbr,%%a0\n\t" "move.l %0,8(%%a0)\n\t" : : "r" (&&bus_error) : "a0" ); save_buserr = old_buserr; set_fs (MAKE_MM_SEG(wbs & WBTM_040)); switch (wbs & WBSIZ_040) { case BA_SIZE_BYTE: put_user (wbd & 0xff, (char *)wba); break; case BA_SIZE_WORD: put_user (wbd & 0xffff, (short *)wba); break; case BA_SIZE_LONG: put_user (wbd, (int *)wba); break; } set_fs (fs); return; bus_error: __asm__ __volatile__ ("cmp.l %0,2(%%sp)\n\t" "bcs.s .jump_old\n\t" "cmp.l %1,2(%%sp)\n\t" "bls.s .restore_old\n" ".jump_old:\n\t" "move.l %2,-(%%sp)\n\t" "rts\n" ".restore_old:\n\t" "move.l %%a0,-(%%sp)\n\t" "movec.l %%vbr,%%a0\n\t" "move.l %2,8(%%a0)\n\t" "move.l (%%sp)+,%%a0\n\t" "rte\n\t" : : "i" (writeback), "i" (&&bus_error), "m" (save_buserr) ); } /* * static inline void set_restdata_reg(unsigned char *cur_addr) * * Set the rest data register if necessary. */ static inline void set_restdata_reg(unsigned char *cur_addr) { if (((long) cur_addr & ~3) != 0) tt_scsi_dma.dma_restdata = *((unsigned long *) ((long) cur_addr & ~3)); } /* * void hades_dma_emulator(int irq, void *dummy) * * This code emulates TT SCSI DMA on the Hades. * * Note the following: * * 1. When there is no byte available to read from the SCSI bus, or * when a byte cannot yet bet written to the SCSI bus, a bus * error occurs when reading or writing the pseudo DMA data * register (hades_psdm_reg). We have to catch this bus error * and try again to read or write the byte. If after several tries * we still get a bus error, the interrupt handler is left. When * the byte can be read or written, the interrupt handler is * called again. * * 2. The SCSI interrupt must be disabled in this interrupt handler. * * 3. If we set the EOP signal, the SCSI controller still expects one * byte to be read or written. Therefore the last byte is transferred * separately, after setting the EOP signal. * * 4. When this function is left, the address pointer (start_addr) is * converted to a physical address. Because it points one byte * further than the last transferred byte, it can point outside the * current page. If virt_to_phys() is called with this address we * might get an access error. Therefore virt_to_phys() is called with * start_addr - 1 if the count has reached zero. The result is * increased with one. */ static irqreturn_t hades_dma_emulator(int irq, void *dummy) { unsigned long dma_base; register unsigned long dma_cnt asm ("d3"); static long save_buserr; register unsigned long save_sp asm ("d4"); register int tries asm ("d5"); register unsigned char *start_addr asm ("a3"), *end_addr asm ("a4"); register unsigned char *eff_addr; register unsigned char *psdm_reg; unsigned long rem; atari_disable_irq(IRQ_TT_MFP_SCSI); /* * Read the dma address and count registers. */ dma_base = SCSI_DMA_READ_P(dma_addr); dma_cnt = SCSI_DMA_READ_P(dma_cnt); /* * Check if DMA is still enabled. */ if ((tt_scsi_dma.dma_ctrl & 2) == 0) { atari_enable_irq(IRQ_TT_MFP_SCSI); return IRQ_HANDLED; } if (dma_cnt == 0) { printk(KERN_NOTICE "DMA emulation: count is zero.\n"); tt_scsi_dma.dma_ctrl &= 0xfd; /* DMA ready. */ atari_enable_irq(IRQ_TT_MFP_SCSI); return IRQ_HANDLED; } /* * Install new bus error routine. */ __asm__ __volatile__ ("movec.l %%vbr,%%a0\n\t" "move.l 8(%%a0),%0\n\t" "move.l %1,8(%%a0)\n\t" : "=&r" (save_buserr) : "r" (&&scsi_bus_error) : "a0" ); hades_dma_ctrl &= 0xfc; /* Bus error and EOP off. */ /* * Save the stack pointer. */ __asm__ __volatile__ ("move.l %%sp,%0\n\t" : "=&r" (save_sp) ); tries = 100; /* Maximum number of bus errors. */ start_addr = phys_to_virt(dma_base); end_addr = start_addr + dma_cnt; scsi_loop: dma_cnt--; rem = dma_cnt & (TRANSFER_SIZE - 1); dma_cnt &= ~(TRANSFER_SIZE - 1); psdm_reg = &hades_psdm_reg; if (tt_scsi_dma.dma_ctrl & 1) /* Read or write? */ { /* * SCSI write. Abort when count is zero. */ switch (rem) { case 0: while (dma_cnt > 0) { dma_cnt -= TRANSFER_SIZE; *psdm_reg = *start_addr++; case 15: *psdm_reg = *start_addr++; case 14: *psdm_reg = *start_addr++; case 13: *psdm_reg = *start_addr++; case 12: *psdm_reg = *start_addr++; case 11: *psdm_reg = *start_addr++; case 10: *psdm_reg = *start_addr++; case 9: *psdm_reg = *start_addr++; case 8: *psdm_reg = *start_addr++; case 7: *psdm_reg = *start_addr++; case 6: *psdm_reg = *start_addr++; case 5: *psdm_reg = *start_addr++; case 4: *psdm_reg = *start_addr++; case 3: *psdm_reg = *start_addr++; case 2: *psdm_reg = *start_addr++; case 1: *psdm_reg = *start_addr++; } } hades_dma_ctrl |= 1; /* Set EOP. */ udelay(10); *psdm_reg = *start_addr++; /* Dummy byte. */ tt_scsi_dma.dma_ctrl &= 0xfd; /* DMA ready. */ } else { /* * SCSI read. Abort when count is zero. */ switch (rem) { case 0: while (dma_cnt > 0) { dma_cnt -= TRANSFER_SIZE; *start_addr++ = *psdm_reg; case 15: *start_addr++ = *psdm_reg; case 14: *start_addr++ = *psdm_reg; case 13: *start_addr++ = *psdm_reg; case 12: *start_addr++ = *psdm_reg; case 11: *start_addr++ = *psdm_reg; case 10: *start_addr++ = *psdm_reg; case 9: *start_addr++ = *psdm_reg; case 8: *start_addr++ = *psdm_reg; case 7: *start_addr++ = *psdm_reg; case 6: *start_addr++ = *psdm_reg; case 5: *start_addr++ = *psdm_reg; case 4: *start_addr++ = *psdm_reg; case 3: *start_addr++ = *psdm_reg; case 2: *start_addr++ = *psdm_reg; case 1: *start_addr++ = *psdm_reg; } } hades_dma_ctrl |= 1; /* Set EOP. */ udelay(10); *start_addr++ = *psdm_reg; tt_scsi_dma.dma_ctrl &= 0xfd; /* DMA ready. */ set_restdata_reg(start_addr); } if (start_addr != end_addr) printk(KERN_CRIT "DMA emulation: FATAL: Count is not zero at end of transfer.\n"); dma_cnt = end_addr - start_addr; scsi_end: dma_base = (dma_cnt == 0) ? virt_to_phys(start_addr - 1) + 1 : virt_to_phys(start_addr); SCSI_DMA_WRITE_P(dma_addr, dma_base); SCSI_DMA_WRITE_P(dma_cnt, dma_cnt); /* * Restore old bus error routine. */ __asm__ __volatile__ ("movec.l %%vbr,%%a0\n\t" "move.l %0,8(%%a0)\n\t" : : "r" (save_buserr) : "a0" ); atari_enable_irq(IRQ_TT_MFP_SCSI); return IRQ_HANDLED; scsi_bus_error: /* * First check if the bus error is caused by our code. * If not, call the original handler. */ __asm__ __volatile__ ("cmp.l %0,2(%%sp)\n\t" "bcs.s .old_vector\n\t" "cmp.l %1,2(%%sp)\n\t" "bls.s .scsi_buserr\n" ".old_vector:\n\t" "move.l %2,-(%%sp)\n\t" "rts\n" ".scsi_buserr:\n\t" : : "i" (&&scsi_loop), "i" (&&scsi_end), "m" (save_buserr) ); if (CPU_IS_060) { /* * Get effective address and restore the stack. */ __asm__ __volatile__ ("move.l 8(%%sp),%0\n\t" "move.l %1,%%sp\n\t" : "=a&" (eff_addr) : "r" (save_sp) ); } else { register struct m68040_frame *frame; __asm__ __volatile__ ("lea 8(%%sp),%0\n\t" : "=a&" (frame) ); if (tt_scsi_dma.dma_ctrl & 1) { /* * Bus error while writing. */ if (frame->wb3s & WBV_040) { if (frame->wb3a == (long) &hades_psdm_reg) start_addr--; else writeback(frame->wb3s, frame->wb3a, frame->wb3d, &&scsi_bus_error); } if (frame->wb2s & WBV_040) { if (frame->wb2a == (long) &hades_psdm_reg) start_addr--; else writeback(frame->wb2s, frame->wb2a, frame->wb2d, &&scsi_bus_error); } if (frame->wb1s & WBV_040) { if (frame->wb1a == (long) &hades_psdm_reg) start_addr--; } } else { /* * Bus error while reading. */ if (frame->wb3s & WBV_040) writeback(frame->wb3s, frame->wb3a, frame->wb3d, &&scsi_bus_error); } eff_addr = (unsigned char *) frame->faddr; __asm__ __volatile__ ("move.l %0,%%sp\n\t" : : "r" (save_sp) ); } dma_cnt = end_addr - start_addr; if (eff_addr == &hades_psdm_reg) { /* * Bus error occurred while reading the pseudo * DMA register. Time out. */ tries--; if (tries <= 0) { if ((tt_scsi_dma.dma_ctrl & 1) == 0) /* Read or write? */ set_restdata_reg(start_addr); if (dma_cnt <= 1) printk(KERN_CRIT "DMA emulation: Fatal " "error while %s the last byte.\n", (tt_scsi_dma.dma_ctrl & 1) ? "writing" : "reading"); goto scsi_end; } else goto scsi_loop; } else { /* * Bus error during pseudo DMA transfer. * Terminate the DMA transfer. */ hades_dma_ctrl |= 3; /* Set EOP and bus error. */ if ((tt_scsi_dma.dma_ctrl & 1) == 0) /* Read or write? */ set_restdata_reg(start_addr); goto scsi_end; } }