/* * Copyright (c) 2000 Apple Computer, Inc. All rights reserved. * * @APPLE_OSREFERENCE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. The rights granted to you under the License * may not be used to create, or enable the creation or redistribution of, * unlawful or unlicensed copies of an Apple operating system, or to * circumvent, violate, or enable the circumvention or violation of, any * terms of an Apple operating system software license agreement. * * Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_OSREFERENCE_LICENSE_HEADER_END@ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include unsigned kdp_vm_read( caddr_t, caddr_t, unsigned); unsigned kdp_vm_write( caddr_t, caddr_t, unsigned); boolean_t kdp_read_io; boolean_t kdp_trans_off; uint32_t kdp_src_high32; extern pmap_paddr_t avail_start, avail_end; extern void bcopy_phys(addr64_t from, addr64_t to, int size); static addr64_t kdp_vtophys(pmap_t pmap, addr64_t va); pmap_t kdp_pmap = 0; unsigned int not_in_kdp = 1; /* Cleared when we begin to access vm functions in kdp */ extern vm_offset_t sectTEXTB, sectDATAB, sectLINKB, sectPRELINKB; extern int sectSizeTEXT, sectSizeDATA, sectSizeLINK, sectSizePRELINK; int kern_dump(void); int kdp_dump_trap(int type, x86_saved_state32_t *regs); typedef struct { int flavor; /* the number for this flavor */ mach_msg_type_number_t count; /* count of ints in this flavor */ } mythread_state_flavor_t; static mythread_state_flavor_t thread_flavor_array [] = { {x86_THREAD_STATE32, x86_THREAD_STATE32_COUNT} }; static int kdp_mynum_flavors = 1; static int MAX_TSTATE_FLAVORS = 1; typedef struct { vm_offset_t header; int hoffset; mythread_state_flavor_t *flavors; int tstate_size; } tir_t; char command_buffer[512]; static addr64_t kdp_vtophys( pmap_t pmap, addr64_t va) { addr64_t pa; ppnum_t pp; pp = pmap_find_phys(pmap, va); if(!pp) return 0; pa = ((addr64_t)pp << 12) | (va & 0x0000000000000FFFULL); return(pa); } /* * */ unsigned kdp_vm_read( caddr_t src, caddr_t dst, unsigned len) { addr64_t cur_virt_src = (addr64_t)((unsigned int)src | (((uint64_t)kdp_src_high32) << 32)); addr64_t cur_virt_dst = (addr64_t)((unsigned int)dst); addr64_t cur_phys_dst, cur_phys_src; unsigned resid = len; unsigned cnt = 0; pmap_t src_pmap = kernel_pmap; /* If a different pmap has been specified with kdp_pmap, use it to translate the * source (cur_virt_src); otherwise, the source is translated using the * kernel_pmap. */ if (kdp_pmap) src_pmap = kdp_pmap; while (resid != 0) { /* Translate, unless kdp_trans_off is set */ if (!kdp_trans_off) { if (!(cur_phys_src = kdp_vtophys(src_pmap, cur_virt_src))) goto exit; } else cur_phys_src = cur_virt_src; /* Always translate the destination buffer using the kernel_pmap */ if(!(cur_phys_dst = kdp_vtophys(kernel_pmap, cur_virt_dst))) goto exit; /* Validate physical page numbers unless kdp_read_io is set */ if (kdp_read_io == FALSE) if (!pmap_valid_page(i386_btop(cur_phys_dst)) || !pmap_valid_page(i386_btop(cur_phys_src))) goto exit; /* Get length left on page */ cnt = PAGE_SIZE - (cur_phys_src & PAGE_MASK); if (cnt > (PAGE_SIZE - (cur_phys_dst & PAGE_MASK))) cnt = PAGE_SIZE - (cur_phys_dst & PAGE_MASK); if (cnt > resid) cnt = resid; /* Do a physical copy */ bcopy_phys(cur_phys_src, cur_phys_dst, cnt); cur_virt_src += cnt; cur_virt_dst += cnt; resid -= cnt; } exit: return (len - resid); } /* * */ unsigned kdp_vm_write( caddr_t src, caddr_t dst, unsigned len) { addr64_t cur_virt_src, cur_virt_dst; addr64_t cur_phys_src, cur_phys_dst; unsigned resid, cnt, cnt_src, cnt_dst; #ifdef KDP_VM_WRITE_DEBUG printf("kdp_vm_write: src %x dst %x len %x - %08X %08X\n", src, dst, len, ((unsigned long *)src)[0], ((unsigned long *)src)[1]); #endif cur_virt_src = (addr64_t)((unsigned int)src); cur_virt_dst = (addr64_t)((unsigned int)dst); resid = len; while (resid != 0) { if ((cur_phys_dst = kdp_vtophys(kernel_pmap, cur_virt_dst)) == 0) goto exit; if ((cur_phys_src = kdp_vtophys(kernel_pmap, cur_virt_src)) == 0) goto exit; cnt_src = ((cur_phys_src + PAGE_SIZE) & (PAGE_MASK)) - cur_phys_src; cnt_dst = ((cur_phys_dst + PAGE_SIZE) & (PAGE_MASK)) - cur_phys_dst; if (cnt_src > cnt_dst) cnt = cnt_dst; else cnt = cnt_src; if (cnt > resid) cnt = resid; bcopy_phys(cur_phys_src, cur_phys_dst, cnt); /* Copy stuff over */ cur_virt_src +=cnt; cur_virt_dst +=cnt; resid -= cnt; } exit: return (len - resid); } static void kern_collectth_state(thread_t thread, tir_t *t) { vm_offset_t header; int hoffset, i ; mythread_state_flavor_t *flavors; struct thread_command *tc; /* * Fill in thread command structure. */ header = t->header; hoffset = t->hoffset; flavors = t->flavors; tc = (struct thread_command *) (header + hoffset); tc->cmd = LC_THREAD; tc->cmdsize = sizeof(struct thread_command) + t->tstate_size; hoffset += sizeof(struct thread_command); /* * Follow with a struct thread_state_flavor and * the appropriate thread state struct for each * thread state flavor. */ for (i = 0; i < kdp_mynum_flavors; i++) { *(mythread_state_flavor_t *)(header+hoffset) = flavors[i]; hoffset += sizeof(mythread_state_flavor_t); /* Locate and obtain the non-volatile register context * for this kernel thread. This should ideally be * encapsulated in machine_thread_get_kern_state() * but that routine appears to have been co-opted * by CHUD to obtain pre-interrupt state. */ if (flavors[i].flavor == x86_THREAD_STATE32) { x86_thread_state32_t *tstate = (x86_thread_state32_t *) (header + hoffset); vm_offset_t kstack; bzero(tstate, x86_THREAD_STATE32_COUNT * sizeof(int)); if ((kstack = thread->kernel_stack) != 0){ struct x86_kernel_state32 *iks = STACK_IKS(kstack); tstate->ebx = iks->k_ebx; tstate->esp = iks->k_esp; tstate->ebp = iks->k_ebp; tstate->edi = iks->k_edi; tstate->esi = iks->k_esi; tstate->eip = iks->k_eip; } } else if (machine_thread_get_kern_state(thread, flavors[i].flavor, (thread_state_t) (header+hoffset), &flavors[i].count) != KERN_SUCCESS) printf ("Failure in machine_thread_get_kern_state()\n"); hoffset += flavors[i].count*sizeof(int); } t->hoffset = hoffset; } /* Intended to be called from the kernel trap handler if an unrecoverable fault * occurs during a crashdump (which shouldn't happen since we validate mappings * and so on). This should be reworked to attempt some form of recovery. */ int kdp_dump_trap( int type, __unused x86_saved_state32_t *saved_state) { printf ("An unexpected trap (type %d) occurred during the system dump, terminating.\n", type); kdp_send_crashdump_pkt (KDP_EOF, NULL, 0, ((void *) 0)); abort_panic_transfer(); kdp_flag &= ~KDP_PANIC_DUMP_ENABLED; kdp_flag &= ~PANIC_CORE_ON_NMI; kdp_flag &= ~PANIC_LOG_DUMP; kdp_reset(); kdp_raise_exception(EXC_BAD_ACCESS, 0, 0, kdp.saved_state); return( 0 ); } int kern_dump(void) { vm_map_t map; unsigned int thread_count, segment_count; unsigned int command_size = 0, header_size = 0, tstate_size = 0; unsigned int hoffset = 0, foffset = 0, nfoffset = 0, vmoffset = 0; unsigned int max_header_size = 0; vm_offset_t header; struct mach_header *mh; struct segment_command *sc; vm_size_t size; vm_prot_t prot = 0; vm_prot_t maxprot = 0; vm_inherit_t inherit = 0; mythread_state_flavor_t flavors[MAX_TSTATE_FLAVORS]; vm_size_t nflavors; vm_size_t i; uint32_t nesting_depth = 0; kern_return_t kret = 0; struct vm_region_submap_info_64 vbr; mach_msg_type_number_t vbrcount = 0; tir_t tir1; int error = 0; int panic_error = 0; unsigned int txstart = 0; unsigned int mach_section_count = 4; unsigned int num_sects_txed = 0; map = kernel_map; not_in_kdp = 0; /* Signal vm functions not to acquire locks */ thread_count = 1; segment_count = get_vmmap_entries(map); printf("Kernel map has %d entries\n", segment_count); nflavors = kdp_mynum_flavors; bcopy((char *)thread_flavor_array,(char *) flavors,sizeof(thread_flavor_array)); for (i = 0; i < nflavors; i++) tstate_size += sizeof(mythread_state_flavor_t) + (flavors[i].count * sizeof(int)); command_size = (segment_count + mach_section_count) * sizeof(struct segment_command) + thread_count * sizeof(struct thread_command) + tstate_size * thread_count; header_size = command_size + sizeof(struct mach_header); header = (vm_offset_t) command_buffer; /* * Set up Mach-O header for currently executing 32 bit kernel. */ printf ("Generated Mach-O header size was %d\n", header_size); mh = (struct mach_header *) header; mh->magic = MH_MAGIC; mh->cputype = cpu_type(); mh->cpusubtype = cpu_subtype(); mh->filetype = MH_CORE; mh->ncmds = segment_count + thread_count + mach_section_count; mh->sizeofcmds = command_size; mh->flags = 0; hoffset = sizeof(struct mach_header); /* offset into header */ foffset = round_page_32(header_size); /* offset into file */ /* Padding */ if ((foffset - header_size) < (4*sizeof(struct segment_command))) { foffset += ((4*sizeof(struct segment_command)) - (foffset-header_size)); } max_header_size = foffset; vmoffset = VM_MIN_ADDRESS; /* offset into VM */ /* Transmit the Mach-O MH_CORE header, and seek forward past the * area reserved for the segment and thread commands * to begin data transmission */ if ((panic_error = kdp_send_crashdump_pkt (KDP_SEEK, NULL, sizeof(nfoffset) , &nfoffset)) < 0) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } if ((panic_error = kdp_send_crashdump_data (KDP_DATA, NULL, sizeof(struct mach_header), (caddr_t) mh) < 0)) { printf ("kdp_send_crashdump_data failed with error %d\n", panic_error); error = panic_error; goto out; } if ((panic_error = kdp_send_crashdump_pkt (KDP_SEEK, NULL, sizeof(foffset) , &foffset) < 0)) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } printf ("Transmitting kernel state, please wait: "); while ((segment_count > 0) || (kret == KERN_SUCCESS)){ /* Check if we've transmitted all the kernel sections */ if (num_sects_txed == mach_section_count) { while (1) { /* * Get region information for next region. */ vbrcount = VM_REGION_SUBMAP_INFO_COUNT_64; if((kret = vm_region_recurse_64(map, &vmoffset, &size, &nesting_depth, (vm_region_recurse_info_t)&vbr, &vbrcount)) != KERN_SUCCESS) { break; } if(vbr.is_submap) { nesting_depth++; continue; } else { break; } } if(kret != KERN_SUCCESS) break; prot = vbr.protection; maxprot = vbr.max_protection; inherit = vbr.inheritance; } else { switch (num_sects_txed) { case 0: /* Transmit the kernel text section */ vmoffset = sectTEXTB; size = sectSizeTEXT; break; case 1: vmoffset = sectDATAB; size = sectSizeDATA; break; case 2: vmoffset = sectPRELINKB; size = sectSizePRELINK; break; case 3: vmoffset = sectLINKB; size = sectSizeLINK; break; } num_sects_txed++; } /* * Fill in segment command structure. */ if (hoffset > max_header_size) break; sc = (struct segment_command *) (header); sc->cmd = LC_SEGMENT; sc->cmdsize = sizeof(struct segment_command); sc->segname[0] = 0; sc->vmaddr = vmoffset; sc->vmsize = size; sc->fileoff = foffset; sc->filesize = size; sc->maxprot = maxprot; sc->initprot = prot; sc->nsects = 0; if ((panic_error = kdp_send_crashdump_pkt (KDP_SEEK, NULL, sizeof(hoffset) , &hoffset)) < 0) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } if ((panic_error = kdp_send_crashdump_data (KDP_DATA, NULL, sizeof(struct segment_command) , (caddr_t) sc)) < 0) { printf ("kdp_send_crashdump_data failed with error %d\n", panic_error); error = panic_error; goto out; } /* Do not transmit memory tagged VM_MEMORY_IOKIT - instead, * seek past that region on the server - this creates a * hole in the file. */ if ((vbr.user_tag != VM_MEMORY_IOKIT)) { if ((panic_error = kdp_send_crashdump_pkt (KDP_SEEK, NULL, sizeof(foffset) , &foffset)) < 0) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } txstart = vmoffset; if ((panic_error = kdp_send_crashdump_data (KDP_DATA, NULL, size, (caddr_t) txstart)) < 0) { printf ("kdp_send_crashdump_data failed with error %d\n", panic_error); error = panic_error; goto out; } } hoffset += sizeof(struct segment_command); foffset += size; vmoffset += size; segment_count--; } tir1.header = header; tir1.hoffset = 0; tir1.flavors = flavors; tir1.tstate_size = tstate_size; /* Now send out the LC_THREAD load command, with the thread information * for the current activation. * Note that the corefile can contain LC_SEGMENT commands with file * offsets that point past the edge of the corefile, in the event that * the last N VM regions were all I/O mapped or otherwise * non-transferable memory, not followed by a normal VM region; * i.e. there will be no hole that reaches to the end of the core file. */ kern_collectth_state (current_thread(), &tir1); if ((panic_error = kdp_send_crashdump_pkt (KDP_SEEK, NULL, sizeof(hoffset) , &hoffset)) < 0) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } if ((panic_error = kdp_send_crashdump_data (KDP_DATA, NULL, tir1.hoffset , (caddr_t) header)) < 0) { printf ("kdp_send_crashdump_data failed with error %d\n", panic_error); error = panic_error; goto out; } /* last packet */ if ((panic_error = kdp_send_crashdump_pkt (KDP_EOF, NULL, 0, ((void *) 0))) < 0) { printf ("kdp_send_crashdump_pkt failed with error %d\n", panic_error); error = panic_error; goto out; } out: return (error); }