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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [powerpc/] [shared/] [bootloader/] [em86.c] - Rev 173
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/* * em86.c -- Include file for bootloader. * * Copyright (C) 1998, 1999 Gabriel Paubert, paubert@iram.es * * Modified to compile in RTEMS development environment * by Eric Valette * * Copyright (C) 1999 Eric Valette. valette@crf.canon.fr * * The license and distribution terms for this file may be * found in found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id: em86.c,v 1.2 2001-09-27 12:01:06 chris Exp $ */ /***************************************************************************** * * Code to interpret Video BIOS ROM routines. * * ******************************************************************************/ /* These include are for the development version only */ #include <sys/types.h> #include "pci.h" #include <libcpu/byteorder.h> #ifdef __BOOT__ #include "bootldr.h" #include <limits.h> #endif /* Code options, put them on the compiler command line */ /* #define EIP_STATS */ /* EIP based profiling */ /* #undef EIP_STATS */ typedef union _reg_type1 { unsigned e; unsigned short x; struct { unsigned char l, h; } lh; } reg_type1; typedef union _reg_type2 { unsigned e; unsigned short x; } reg_type2; typedef struct _x86 { reg_type1 _eax, _ecx, _edx, _ebx; reg_type2 _esp, _ebp, _esi, _edi; unsigned es, cs, ss, ds, fs, gs, eip, eflags; unsigned char *esbase, *csbase, *ssbase, *dsbase, *fsbase, *gsbase; volatile unsigned char *iobase; unsigned char *ioperm; unsigned reason, nexteip, parm1, parm2, opcode, base; unsigned *optable, opreg; /* no more used! */ unsigned char* vbase; unsigned instructions; #ifdef __BOOT__ u_char * ram; u_char * rom; struct pci_dev * dev; #else unsigned filler[14]; /* Skip to next 64 byte boundary */ unsigned eipstats[32768][2]; #endif } x86; x86 v86_private __attribute__((aligned(32))); /* Emulator is in another source file */ extern void em86_enter(x86 * p); #define EAX (p->_eax.e) #define ECX (p->_ecx.e) #define EDX (p->_edx.e) #define EBX (p->_ebx.e) #define ESP (p->_esp.e) #define EBP (p->_ebp.e) #define ESI (p->_esi.e) #define EDI (p->_edi.e) #define AX (p->_eax.x) #define CX (p->_ecx.x) #define DX (p->_edx.x) #define BX (p->_ebx.x) #define SP (p->_esp.x) #define BP (p->_ebp.x) #define SI (p->_esi.x) #define DI (p->_edi.x) #define AL (p->_eax.lh.l) #define CL (p->_ecx.lh.l) #define DL (p->_edx.lh.l) #define BL (p->_ebx.lh.l) #define AH (p->_eax.lh.h) #define CH (p->_ecx.lh.h) #define DH (p->_edx.lh.h) #define BH (p->_ebx.lh.h) /* Function used to debug */ #ifdef __BOOT__ #define printf printk #endif #ifdef DEBUG static void dump86(x86 * p){ unsigned char *s = p->csbase + p->eip; printf("cs:eip=%04x:%08x, eax=%08x, ecx=%08x, edx=%08x, ebx=%08x\n", p->cs, p->eip, ld_le32(&EAX), ld_le32(&ECX), ld_le32(&EDX), ld_le32(&EBX)); printf("ss:esp=%04x:%08x, ebp=%08x, esi=%08x, edi=%08x, efl=%08x\n", p->ss, ld_le32(&ESP), ld_le32(&EBP), ld_le32(&ESI), ld_le32(&EDI), p->eflags); printf("nip=%08x, ds=%04x, es=%04x, fs=%04x, gs=%04x, total=%d\n", p->nexteip, p->ds, p->es, p->fs, p->gs, p->instructions); printf("code: %02x %02x %02x %02x %02x %02x " "%02x %02x %02x %02x %02x %02x\n", s[0], s[1], s[2], s[3], s[4], s[5], s[6], s[7], s[8], s[9], s[10], s[11]); #ifndef __BOOT__ printf("op1=%08x, op2=%08x, result=%08x, flags=%08x\n", p->filler[11], p->filler[12], p->filler[13], p->filler[14]); #endif } #else #define dump86(x) #endif int bios86pci(x86 * p) { unsigned reg=ld_le16(&DI); reg_type2 tmp; if (AL>=8 && AL<=13 && reg>0xff) { AH = PCIBIOS_BAD_REGISTER_NUMBER; } else { switch(AL) { case 2: /* find_device */ /* Should be improved for BIOS able to handle * multiple devices. We simply suppose the BIOS * inits a single device, and return an error * if it tries to find more... */ if (SI) { AH=PCIBIOS_DEVICE_NOT_FOUND; } else { BH = p->dev->bus->number; BL = p->dev->devfn; AH = 0; } break; /* case 3: find_class not implemented for now. */ case 8: /* read_config_byte */ AH=pcibios_read_config_byte(BH, BL, reg, &CL); break; case 9: /* read_config_word */ AH=pcibios_read_config_word(BH, BL, reg, &tmp.x); CX=ld_le16(&tmp.x); break; case 10: /* read_config_dword */ AH=pcibios_read_config_dword(BH, BL, reg, &tmp.e); ECX=ld_le32(&tmp.e); break; case 11: /* write_config_byte */ AH=pcibios_write_config_byte(BH, BL, reg, CL); break; case 12: /* write_config_word */ AH=pcibios_write_config_word(BH, BL, reg, ld_le16(&CX)); break; case 13: /* write_config_dword */ AH=pcibios_write_config_dword(BH, BL, reg, ld_le32(&ECX)); break; default: printf("Unimplemented or illegal PCI service call #%d!\n", AL); return 1; } } p->eip = p->nexteip; /* Set/clear carry according to result */ if (AH) p->eflags |= 1; else p->eflags &=~1; return 0; } void push2(x86 *p, unsigned value) { unsigned char * sbase= p->ssbase; unsigned newsp = (ld_le16(&SP)-2)&0xffff; st_le16(&SP,newsp); st_le16((unsigned short *)(sbase+newsp), value); } unsigned pop2(x86 *p) { unsigned char * sbase=p->ssbase; unsigned oldsp = ld_le16(&SP); st_le16(&SP,oldsp+2); return ld_le16((unsigned short *)(sbase+oldsp)); } int int10h(x86 * p) { /* Process BIOS video interrupt */ unsigned vector; vector=ld_le32((unsigned *)p->vbase+0x10); if (((vector&0xffff0000)>>16)==0xc000) { push2(p, p->eflags); push2(p, p->cs); push2(p, p->nexteip); p->cs=vector>>16; p->csbase=p->vbase + (p->cs<<4); p->eip=vector&0xffff; #if 1 p->eflags&=0xfcff; /* Clear AC/TF/IF */ #else p->eflags = (p->eflags&0xfcff)|0x100; /* Set TF for debugging */ #endif /* p->eflags|=0x100; uncomment to force a trap */ return(0); } else { switch(AH) { case 0x12: switch(BL){ case 0x32: p->eip=p->nexteip; return(0); break; default: break; } default: break; } printf("unhandled soft interrupt 0x10: vector=%x\n", vector); return(1); } } int process_softint(x86 * p) { #if 0 if (p->parm1!=0x10 || AH!=0x0e) { printf("Soft interrupt\n"); dump86(p); } #endif switch(p->parm1) { case 0x10: /* BIOS video interrupt */ return int10h(p); case 0x1a: if(AH==0xb1) return bios86pci(p); break; default: break; } dump86(p); printf("Unhandled soft interrupt number 0x%04x, AX=0x%04x\n", p->parm1, ld_le16(&AX)); return(1); } /* The only function called back by the emulator is em86_trap, all instructions may that change the code segment are trapped here. p->reason is one of the following codes. */ #define code_zerdiv 0 #define code_trap 1 #define code_int3 3 #define code_into 4 #define code_bound 5 #define code_ud 6 #define code_dna 7 #define code_iretw 256 #define code_iretl 257 #define code_lcallw 258 #define code_lcalll 259 #define code_ljmpw 260 #define code_ljmpl 261 #define code_lretw 262 #define code_lretl 263 #define code_softint 264 #define code_lock 265 /* Lock prefix */ /* Codes 1024 to 2047 are used for I/O port access instructions: - The three LSB define the port size (1, 2 or 4) - bit of weight 512 means out if set, in if clear - bit of weight 256 means ins/outs if set, in/out if clear - bit of weight 128 means use esi/edi if set, si/di if clear (only used for ins/outs instructions, always clear for in/out) */ #define code_inb 1024+1 #define code_inw 1024+2 #define code_inl 1024+4 #define code_outb 1024+512+1 #define code_outw 1024+512+2 #define code_outl 1024+512+4 #define code_insb_a16 1024+256+1 #define code_insw_a16 1024+256+2 #define code_insl_a16 1024+256+4 #define code_outsb_a16 1024+512+256+1 #define code_outsw_a16 1024+512+256+2 #define code_outsl_a16 1024+512+256+4 #define code_insb_a32 1024+256+128+1 #define code_insw_a32 1024+256+128+2 #define code_insl_a32 1024+256+128+4 #define code_outsb_a32 1024+512+256+128+1 #define code_outsw_a32 1024+512+256+128+2 #define code_outsl_a32 1024+512+256+128+4 int em86_trap(x86 *p) { #ifndef __BOOT__ int i; unsigned char command[80]; unsigned char *verb, *t; unsigned short *fp; static unsigned char def=0; static unsigned char * bptaddr=NULL; /* Breakpoint address */ static unsigned char bptopc; /* Replaced breakpoint opcode */ unsigned char cmd; unsigned tmp; #endif switch(p->reason) { case code_int3: #ifndef __BOOT__ if(p->csbase+p->eip == bptaddr) { *bptaddr=bptopc; bptaddr=NULL; } else printf("Unexpected "); #endif printf("Breakpoint Interrupt !\n"); /* Note that this fallthrough (no break;) is on purpose */ #ifdef __BOOT__ return 0; #else case code_trap: dump86(p); for(;;) { printf("b(reakpoint, g(o, q(uit, s(tack, t(race ? [%c] ", def); fgets(command,sizeof(command),stdin); verb = strtok(command," \n"); if(verb) cmd=*verb; else cmd=def; def=0; switch(cmd) { case 'b': case 'B': if(bptaddr) *bptaddr=bptopc; t=strtok(0," \n"); i=sscanf(t,"%x",&tmp); if(i==1) { bptaddr=p->vbase + tmp; bptopc=*bptaddr; *bptaddr=0xcc; } else bptaddr=NULL; break; case 'q': case 'Q': return 1; break; case 'g': case 'G': p->eflags &= ~0x100; return 0; break; case 's': case 'S': /* Print the 8 stack top words */ fp = (unsigned short *)(p->ssbase+ld_le16(&SP)); printf("Stack [%04x:%04x]: %04x %04x %04x %04x %04x %04x %04x %04x\n", p->ss, ld_le16(&SP), ld_le16(fp+0), ld_le16(fp+1), ld_le16(fp+2), ld_le16(fp+3), ld_le16(fp+4), ld_le16(fp+5), ld_le16(fp+6), ld_le16(fp+7)); break; case 't': case 'T': p->eflags |= 0x10100; /* Set the resume and trap flags */ def='t'; return 0; break; /* Should add some code to edit registers */ } } #endif break; case code_ud: printf("Attempt to execute an unimplemented" "or undefined opcode!\n"); dump86(p); return(1); /* exit interpreter */ break; case code_dna: printf("Attempt to execute a floating point instruction!\n"); dump86(p); return(1); break; case code_softint: return process_softint(p); break; case code_iretw: p->eip=pop2(p); p->cs=pop2(p); p->csbase=p->vbase + (p->cs<<4); p->eflags= (p->eflags&0xfffe0000)|pop2(p); /* p->eflags|= 0x100; */ /* Uncomment to trap after iretws */ return(0); break; #ifndef __BOOT__ case code_inb: case code_inw: case code_inl: case code_insb_a16: case code_insw_a16: case code_insl_a16: case code_insb_a32: case code_insw_a32: case code_insl_a32: case code_outb: case code_outw: case code_outl: case code_outsb_a16: case code_outsw_a16: case code_outsl_a16: case code_outsb_a32: case code_outsw_a32: case code_outsl_a32: /* For now we simply enable I/O to the ports and continue */ for(i=p->parm1; i<p->parm1+(p->reason&7); i++) { p->ioperm[i/8] &= ~(1<<i%8); } printf("Access to ports %04x-%04x enabled.\n", p->parm1, p->parm1+(p->reason&7)-1); return(0); #endif case code_lretw: /* Check for the exit eyecatcher */ if ( *(u_int *)(p->ssbase+ld_le16(&SP)) == UINT_MAX) return 1; /* No break on purpose */ default: dump86(p); printf("em86_trap called with unhandled reason code !\n"); return(1); } } void cleanup_v86_mess(void) { x86 *p = (x86 *) bd->v86_private; /* This automatically removes the mappings ! */ vfree(p->vbase); p->vbase = 0; pfree(p->ram); p->ram = 0; sfree(p->ioperm); p->ioperm=0; } int init_v86(void) { x86 *p = (x86 *) bd->v86_private; /* p->vbase is non null when the v86 is properly set-up */ if (p->vbase) return 0; /* Set everything to 0 */ memset(p, 0, sizeof(*p)); p->ioperm = salloc(65536/8+1); p->ram = palloc(0xa0000); p->iobase = ptr_mem_map->io_base; if (!p->ram || !p->ioperm) return 1; /* The ioperm array must have an additional byte at the end ! */ p->ioperm[65536/8] = 0xff; p->vbase = valloc(0x110000); if (!p->vbase) return 1; /* These calls should never fail. */ vmap(p->vbase, (u_long)p->ram|PTE_RAM, 0xa0000); vmap(p->vbase+0x100000, (u_long)p->ram|PTE_RAM, 0x10000); vmap(p->vbase+0xa0000, ((u_long)ptr_mem_map->isa_mem_base+0xa0000)|PTE_IO, 0x20000); return 0; } void em86_main(struct pci_dev *dev){ x86 *p = (x86 *) bd->v86_private; u_short signature; u_char length; volatile u_int *src; u_int *dst, left, saved_rom; #if defined(MONITOR_IO) && !defined(__BOOT__) #define IOMASK 0xff #else #define IOMASK 0 #endif #ifndef __BOOT__ int i; /* Allow or disable access to all ports */ for(i=0; i<65536/8; i++) p->ioperm[i]=IOMASK; p->ioperm[i] = 0xff; /* Last unused byte must have this value */ #endif p->dev = dev; memset(p->vbase, 0, 0xa0000); /* Set up a few registers */ p->cs = 0xc000; p->csbase = p->vbase + 0xc0000; p->ss = 0x1000; p->ssbase = p->vbase + 0x10000; p->eflags=0x200; st_le16(&SP,0xfffc); p->eip=3; p->dsbase = p->esbase = p->fsbase = p->gsbase = p->vbase; /* Follow the PCI BIOS specification */ AH=dev->bus->number; AL=dev->devfn; /* All other registers are irrelevant except ES:DI which * should point to a PnP installation check block. This * is not yet implemented due to lack of references. */ /* Store a return address of 0xffff:0xffff as eyecatcher */ *(u_int *)(p->ssbase+ld_le16(&SP)) = UINT_MAX; /* Interrupt for BIOS EGA services is 0xf000:0xf065 (int 0x10) */ st_le32((u_int *)p->vbase + 0x10, 0xf000f065); /* Enable the ROM, read it and disable it immediately */ pci_read_config_dword(dev, PCI_ROM_ADDRESS, &saved_rom); pci_write_config_dword(dev, PCI_ROM_ADDRESS, 0x000c0001); /* Check that there is an Intel ROM. Should we also check that * the first instruction is a jump (0xe9 or 0xeb) ? */ signature = *(u_short *)(ptr_mem_map->isa_mem_base+0xc0000); if (signature!=0x55aa) { printf("bad signature: %04x.\n", signature); return; } /* Allocate memory and copy the video rom to vbase+0xc0000; */ length = ptr_mem_map->isa_mem_base[0xc0002]; p->rom = palloc(length*512); if (!p->rom) return; for(dst=(u_int *) p->rom, src=(volatile u_int *)(ptr_mem_map->isa_mem_base+0xc0000), left = length*512/sizeof(u_int); left--; *dst++=*src++); /* Disable the ROM and map the copy in virtual address space, note * that the ROM has to be mapped as RAM since some BIOSes (at least * Cirrus) perform write accesses to their own ROM. The reason seems * to be that they check that they must execute from shadow RAM * because accessing the ROM prevents accessing the video RAM * according to comments in linux/arch/alpha/kernel/bios32.c. */ pci_write_config_dword(dev, PCI_ROM_ADDRESS, saved_rom); vmap(p->vbase+0xc0000, (u_long)p->rom|PTE_RAM, length*512); /* Now actually emulate the ROM init routine */ em86_enter(p); /* Free the acquired resources */ vunmap(p->vbase+0xc0000); pfree(p->rom); }