/* * vmware_vmss.c * * Copyright (c) 2015 VMware, Inc. * Copyright (c) 2018 Red Hat Inc. * * 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. * * Authors: Dyno Hongjun Fu * Sergio Lopez */ #include "defs.h" #include "vmware_vmss.h" #define LOGPRX "vmw: " /* VMware only supports X86/X86_64 virtual machines. */ #define VMW_PAGE_SIZE (4096) #define VMW_PAGE_SHIFT (12) #define MAX_BLOCK_DUMP (128) static vmssdata vmss = { 0 }; int is_vmware_vmss(char *filename) { struct cptdumpheader hdr; FILE *fp; if ((fp = fopen(filename, "r")) == NULL) { error(INFO, LOGPRX"Failed to open '%s': [Error %d] %s\n", filename, errno, strerror(errno)); return FALSE; } if (fread(&hdr, sizeof(cptdumpheader), 1, fp) != 1) { error(INFO, LOGPRX"Failed to read '%s': [Error %d] %s\n", filename, errno, strerror(errno)); fclose(fp); return FALSE; } fclose(fp); if (hdr.id != CPTDUMP_OLD_MAGIC_NUMBER && hdr.id != CPTDUMP_MAGIC_NUMBER && hdr.id != CPTDUMP_PARTIAL_MAGIC_NUMBER && hdr.id != CPTDUMP_RESTORED_MAGIC_NUMBER && hdr.id != CPTDUMP_NORESTORE_MAGIC_NUMBER) { if (CRASHDEBUG(1)) error(INFO, LOGPRX"Unrecognized .vmss file (magic %x).\n", hdr.id); return FALSE; } return TRUE; } int vmware_vmss_init(char *filename, FILE *ofp) { cptdumpheader hdr; cptgroupdesc *grps = NULL; unsigned grpsize; unsigned i; FILE *fp = NULL; int result = TRUE; if (!machine_type("X86") && !machine_type("X86_64")) { error(INFO, LOGPRX"Invalid or unsupported host architecture for .vmss file: %s\n", MACHINE_TYPE); result = FALSE; goto exit; } if ((fp = fopen(filename, "r")) == NULL) { error(INFO, LOGPRX"Failed to open '%s': %s [Error %d] %s\n", filename, errno, strerror(errno)); result = FALSE; goto exit; } if (fread(&hdr, sizeof(cptdumpheader), 1, fp) != 1) { error(INFO, LOGPRX"Failed to read '%s': %s [Error %d] %s\n", filename, errno, strerror(errno)); result = FALSE; goto exit; } DEBUG_PARSE_PRINT((ofp, LOGPRX"Header: id=%x version=%d numgroups=%d\n", hdr.id, hdr.version, hdr.numgroups)); vmss.cpt64bit = (hdr.id != CPTDUMP_OLD_MAGIC_NUMBER); DEBUG_PARSE_PRINT((ofp, LOGPRX"Checkpoint is %d-bit\n", vmss.cpt64bit ? 64 : 32)); if (!vmss.cpt64bit) { error(INFO, LOGPRX"Not implemented for 32-bit VMSS file!\n"); result = FALSE; goto exit; } grpsize = hdr.numgroups * sizeof (cptgroupdesc); grps = (cptgroupdesc *) malloc(grpsize * sizeof(cptgroupdesc)); if (grps == NULL) { error(INFO, LOGPRX"Failed to allocate memory! [Error %d] %s\n", errno, strerror(errno)); result = FALSE; goto exit; } if (fread(grps, sizeof(cptgroupdesc), grpsize, fp) != grpsize) { error(INFO, LOGPRX"Failed to read '%s': [Error %d] %s\n", filename, errno, strerror(errno)); result = FALSE; goto exit; } for (i = 0; i < hdr.numgroups; i++) { if (fseek(fp, grps[i].position, SEEK_SET) == -1) { error(INFO, LOGPRX"Bad offset of VMSS Group['%s'] in '%s' at %#llx.\n", grps[i].name, filename, (ulonglong)grps[i].position); continue; } DEBUG_PARSE_PRINT((ofp, LOGPRX"Group: %-20s offset=%#llx size=0x%#llx.\n", grps[i].name, (ulonglong)grps[i].position, (ulonglong)grps[i].size)); if (strcmp(grps[i].name, "memory") != 0 && (strcmp(grps[i].name, "cpu") != 0 || !machine_type("X86_64"))) { continue; } for (;;) { uint16_t tag; char name[TAG_NAMELEN_MASK + 1]; unsigned nameLen; unsigned nindx; int idx[3]; unsigned j; int nextgroup = FALSE; if (fread(&tag, sizeof(tag), 1, fp) != 1) { error(INFO, LOGPRX"Cannot read tag.\n"); break; } if (tag == NULL_TAG) break; nameLen = TAG_NAMELEN(tag); if (fread(name, nameLen, 1, fp) != 1) { error(INFO, LOGPRX"Cannot read tag name.\n"); break; } name[nameLen] = 0; DEBUG_PARSE_PRINT((ofp, LOGPRX"\t Item %20s", name)); nindx = TAG_NINDX(tag); if (nindx > 3) { error(INFO, LOGPRX"Too many indexes %d (> 3).\n", nindx); break; } idx[0] = idx[1] = idx[2] = NO_INDEX; for (j= 0; j < nindx; j++) { if (fread(&idx[j], sizeof(idx[0]), 1, fp) != 1) { error(INFO, LOGPRX"Cannot read index.\n"); nextgroup = TRUE; break; } DEBUG_PARSE_PRINT((ofp, "[%d]", idx[j])); } if (nextgroup) break; if (IS_BLOCK_TAG(tag)) { uint64_t nbytes; uint64_t blockpos; uint64_t nbytesinmem; int compressed = IS_BLOCK_COMPRESSED_TAG(tag); uint16_t padsize; if (fread(&nbytes, sizeof(nbytes), 1, fp) != 1) { error(INFO, LOGPRX"Cannot read block size.\n"); break; } if (fread(&nbytesinmem, sizeof(nbytesinmem), 1, fp) != 1) { error(INFO, LOGPRX"Cannot read block memory size.\n"); break; } if (fread(&padsize, sizeof(padsize), 1, fp) != 1) { error(INFO, LOGPRX"Cannot read block padding size.\n"); break; } if ((blockpos = ftell(fp)) == -1) { error(INFO, LOGPRX"Cannot determine location within VMSS file.\n"); break; } blockpos += padsize; if (strcmp(name, "Memory") == 0) { /* The things that we really care about...*/ vmss.memoffset = blockpos; vmss.memsize = nbytesinmem; vmss.separate_vmem = FALSE; DEBUG_PARSE_PRINT((ofp, "\t=> %sBLOCK: position=%#llx size=%#llx memsize=%#llx\n", compressed ? "COMPRESSED " : "", (ulonglong)blockpos, (ulonglong)nbytes, (ulonglong)nbytesinmem)); if (compressed) { error(INFO, LOGPRX"Cannot handle compressed memory dump yet!\n"); result = FALSE; goto exit; } if (fseek(fp, blockpos + nbytes, SEEK_SET) == -1) { error(INFO, LOGPRX"Cannot seek past block at %#llx.\n", (ulonglong)(blockpos + nbytes)); break; } } else if (strcmp(name, "gpregs") == 0 && nbytes == VMW_GPREGS_SIZE && idx[0] < vmss.num_vcpus) { int cpu = idx[0]; if (fread(vmss.regs64[cpu], VMW_GPREGS_SIZE, 1, fp) != 1) { error(INFO, LOGPRX"Failed to read '%s': [Error %d] %s\n", filename, errno, strerror(errno)); break; } vmss.vcpu_regs[cpu] |= REGS_PRESENT_GPREGS; } else if (strcmp(name, "CR64") == 0 && nbytes == VMW_CR64_SIZE && idx[0] < vmss.num_vcpus) { int cpu = idx[0]; if (fread(&vmss.regs64[cpu]->cr[0], VMW_CR64_SIZE, 1, fp) != 1) { error(INFO, LOGPRX"Failed to read '%s': [Error %d] %s\n", filename, errno, strerror(errno)); break; } vmss.vcpu_regs[cpu] |= REGS_PRESENT_CRS; } else if (strcmp(name, "IDTR") == 0 && nbytes == VMW_IDTR_SIZE && idx[0] < vmss.num_vcpus) { int cpu = idx[0]; uint64_t idtr; if (fseek(fp, blockpos + 2, SEEK_SET) == -1) { error(INFO, LOGPRX"Cannot seek past block at %#llx.\n", (ulonglong)(blockpos + 2)); break; } if (fread(&idtr, sizeof(idtr), 1, fp) != 1) { error(INFO, LOGPRX"Failed to read '%s': [Error %d] %s\n", filename, errno, strerror(errno)); break; } vmss.regs64[cpu]->idtr = idtr; vmss.vcpu_regs[cpu] |= REGS_PRESENT_IDTR; } else { if (fseek(fp, blockpos + nbytes, SEEK_SET) == -1) { error(INFO, LOGPRX"Cannot seek past block at %#llx.\n", (ulonglong)(blockpos + nbytes)); break; } } } else { union { uint8_t val[TAG_VALSIZE_MASK]; uint32_t val32; uint64_t val64; } u; unsigned k; unsigned valsize = TAG_VALSIZE(tag); uint64_t blockpos = ftell(fp); DEBUG_PARSE_PRINT((ofp, "\t=> position=%#llx size=%#x: ", (ulonglong)blockpos, valsize)); if (fread(u.val, sizeof(u.val[0]), valsize, fp) != valsize) { error(INFO, LOGPRX"Cannot read item.\n"); break; } for (k = 0; k < valsize; k++) { /* Assume Little Endian */ DEBUG_PARSE_PRINT((ofp, "%02X", u.val[valsize - k - 1])); } if (strcmp(grps[i].name, "memory") == 0) { if (strcmp(name, "regionsCount") == 0) { vmss.regionscount = u.val32; } if (strcmp(name, "regionPageNum") == 0) { vmss.regions[idx[0]].startpagenum = u.val32; } if (strcmp(name, "regionPPN") == 0) { vmss.regions[idx[0]].startppn = u.val32; } if (strcmp(name, "regionSize") == 0) { vmss.regions[idx[0]].size = u.val32; } if (strcmp(name, "align_mask") == 0) { vmss.alignmask = u.val32; } } else if (strcmp(grps[i].name, "cpu") == 0) { if (strcmp(name, "cpu:numVCPUs") == 0) { if (vmss.regs64 != NULL) { error(INFO, LOGPRX"Duplicated cpu:numVCPUs entry.\n"); break; } vmss.num_vcpus = u.val32; vmss.regs64 = malloc(vmss.num_vcpus * sizeof(void *)); vmss.vcpu_regs = malloc(vmss.num_vcpus * sizeof(uint32_t)); for (k = 0; k < vmss.num_vcpus; k++) { vmss.regs64[k] = malloc(sizeof(vmssregs64)); memset(vmss.regs64[k], 0, sizeof(vmssregs64)); vmss.vcpu_regs[k] = 0; } } else if (strcmp(name, "rax") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rax = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RAX; } else if (strcmp(name, "rcx") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rcx = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RCX; } else if (strcmp(name, "rdx") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rdx = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RDX; } else if (strcmp(name, "rbx") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rbx = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RBX; } else if (strcmp(name, "rbp") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rbp = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RBP; } else if (strcmp(name, "rsp") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rsp = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RSP; } else if (strcmp(name, "rsi") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rsi = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RSI; } else if (strcmp(name, "rdi") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rdi = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RDI; } else if (strcmp(name, "r8") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r8 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R8; } else if (strcmp(name, "r9") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r9 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R9; } else if (strcmp(name, "r10") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r10 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R10; } else if (strcmp(name, "r11") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r11 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R11; } else if (strcmp(name, "r12") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r12 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R12; } else if (strcmp(name, "r13") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r13 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R13; } else if (strcmp(name, "r14") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r14 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R14; } else if (strcmp(name, "r15") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->r15 = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_R15; } else if (strcmp(name, "CR64") == 0) { int cpu = idx[0]; switch (idx[1]) { case 0: vmss.regs64[cpu]->cr[0] = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_CR0; break; case 1: vmss.regs64[cpu]->cr[1] = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_CR1; break; case 2: vmss.regs64[cpu]->cr[2] = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_CR2; break; case 3: vmss.regs64[cpu]->cr[3] = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_CR3; break; case 4: vmss.regs64[cpu]->cr[4] = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_CR4; break; } } else if (strcmp(name, "IDTR") == 0) { int cpu = idx[0]; if (idx[1] == 1) vmss.regs64[cpu]->idtr = u.val32; else if (idx[1] == 2) { vmss.regs64[cpu]->idtr |= (uint64_t) u.val32 << 32; vmss.vcpu_regs[cpu] |= REGS_PRESENT_IDTR; } } else if (strcmp(name, "rip") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rip = u.val64; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RIP; } else if (strcmp(name, "eflags") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rflags |= u.val32; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RFLAGS; } else if (strcmp(name, "EFLAGS") == 0) { int cpu = idx[0]; vmss.regs64[cpu]->rflags |= u.val32; vmss.vcpu_regs[cpu] |= REGS_PRESENT_RFLAGS; } } DEBUG_PARSE_PRINT((ofp, "\n")); } } } if (vmss.memsize == 0) { char *vmem_filename, *p; fprintf(ofp, LOGPRX"Memory dump is not part of this vmss file.\n"); fclose(fp); fp = NULL; fprintf(ofp, LOGPRX"Try to locate the companion vmem file ...\n"); /* check the companion vmem file */ vmem_filename = strdup(filename); p = vmem_filename + strlen(vmem_filename) - 4; if (strcmp(p, "vmss") != 0 && strcmp(p, "vmsn") != 0) { free(vmem_filename); result = FALSE; goto exit; } strcpy(p, "vmem"); if ((fp = fopen(vmem_filename, "r")) == NULL) { error(INFO, LOGPRX"%s: %s\n", vmem_filename, strerror(errno)); free(vmem_filename); result = FALSE; goto exit; } fseek(fp, 0L, SEEK_END); vmss.memsize = ftell(fp); fseek(fp, 0L, SEEK_SET); vmss.separate_vmem = TRUE; vmss.filename = filename; fprintf(ofp, LOGPRX"vmem file: %s\n\n", vmem_filename); free(vmem_filename); } vmss.dfp = fp; exit: if (grps) free(grps); if (!result && fp) fclose(fp); return result; } uint vmware_vmss_page_size(void) { return VMW_PAGE_SIZE; } int read_vmware_vmss(int fd, void *bufptr, int cnt, ulong addr, physaddr_t paddr) { uint64_t pos = paddr; if (vmss.regionscount > 0) { /* Memory is divided into regions and there are holes between them. */ uint32_t ppn = (uint32_t) (pos >> VMW_PAGE_SHIFT); int i; for (i = 0; i < vmss.regionscount; i++) { if (ppn < vmss.regions[i].startppn) break; /* skip holes. */ pos -= ((vmss.regions[i].startppn - vmss.regions[i].startpagenum) << VMW_PAGE_SHIFT); } } if (pos + cnt > vmss.memsize) { error(INFO, LOGPRX"Read beyond the end of file! paddr=%#lx cnt=%d\n", paddr, cnt); } pos += vmss.memoffset; if (fseek(vmss.dfp, pos, SEEK_SET) != 0) return SEEK_ERROR; if (fread(bufptr, 1, cnt, vmss.dfp) != cnt) return READ_ERROR; return cnt; } int write_vmware_vmss(int fd, void *bufptr, int cnt, ulong addr, physaddr_t paddr) { return SEEK_ERROR; } void vmware_vmss_display_regs(int cpu, FILE *ofp) { if (cpu >= vmss.num_vcpus) return; if (machine_type("X86_64")) { fprintf(ofp, " RIP: %016llx RSP: %016llx RFLAGS: %08llx\n" " RAX: %016llx RBX: %016llx RCX: %016llx\n" " RDX: %016llx RSI: %016llx RDI: %016llx\n" " RBP: %016llx R8: %016llx R9: %016llx\n" " R10: %016llx R11: %016llx R12: %016llx\n" " R13: %016llx R14: %016llx R15: %016llx\n", (ulonglong)vmss.regs64[cpu]->rip, (ulonglong)vmss.regs64[cpu]->rsp, (ulonglong)vmss.regs64[cpu]->rflags, (ulonglong)vmss.regs64[cpu]->rax, (ulonglong)vmss.regs64[cpu]->rbx, (ulonglong)vmss.regs64[cpu]->rcx, (ulonglong)vmss.regs64[cpu]->rdx, (ulonglong)vmss.regs64[cpu]->rsi, (ulonglong)vmss.regs64[cpu]->rdi, (ulonglong)vmss.regs64[cpu]->rbp, (ulonglong)vmss.regs64[cpu]->r8, (ulonglong)vmss.regs64[cpu]->r9, (ulonglong)vmss.regs64[cpu]->r10, (ulonglong)vmss.regs64[cpu]->r11, (ulonglong)vmss.regs64[cpu]->r12, (ulonglong)vmss.regs64[cpu]->r13, (ulonglong)vmss.regs64[cpu]->r14, (ulonglong)vmss.regs64[cpu]->r15 ); } } void get_vmware_vmss_regs(struct bt_info *bt, ulong *ipp, ulong *spp) { ulong ip, sp; ip = sp = 0; if (bt->tc->processor >= vmss.num_vcpus || vmss.regs64 == NULL || vmss.vcpu_regs[bt->tc->processor] != REGS_PRESENT_ALL) { machdep->get_stack_frame(bt, ipp, spp); return; } if (!is_task_active(bt->task)) { machdep->get_stack_frame(bt, ipp, spp); return; } bt->flags |= BT_DUMPFILE_SEARCH; if (machine_type("X86_64")) machdep->get_stack_frame(bt, ipp, spp); else if (machine_type("X86")) get_netdump_regs_x86(bt, ipp, spp); if (bt->flags & BT_DUMPFILE_SEARCH) return; ip = (ulong)vmss.regs64[bt->tc->processor]->rip; sp = (ulong)vmss.regs64[bt->tc->processor]->rsp; if (is_kernel_text(ip) && (((sp >= GET_STACKBASE(bt->task)) && (sp < GET_STACKTOP(bt->task))) || in_alternate_stack(bt->tc->processor, sp))) { *ipp = ip; *spp = sp; bt->flags |= BT_KERNEL_SPACE; return; } if (!is_kernel_text(ip) && in_user_stack(bt->tc->task, sp)) bt->flags |= BT_USER_SPACE; } int vmware_vmss_memory_dump(FILE *ofp) { cptdumpheader hdr; cptgroupdesc *grps = NULL; unsigned grpsize; unsigned i; int result = TRUE; FILE *fp = vmss.dfp; if (vmss.separate_vmem) { if ((fp = fopen(vmss.filename, "r")) == NULL) { error(INFO, LOGPRX"Failed to open '%s': %s [Error %d] %s\n", vmss.filename, errno, strerror(errno)); return FALSE; } } if (fseek(fp, 0, SEEK_SET) != 0) { fprintf(ofp, "Error seeking to position 0.\n"); fclose(fp); return FALSE; } if (fread(&hdr, sizeof(cptdumpheader), 1, fp) != 1) { fprintf(ofp, "Failed to read vmss file: [Error %d] %s\n", errno, strerror(errno)); fclose(fp); return FALSE; } fprintf(ofp, "vmware_vmss:\n"); fprintf(ofp, " Header: id=%x version=%d numgroups=%d\n", hdr.id, hdr.version, hdr.numgroups); vmss.cpt64bit = (hdr.id != CPTDUMP_OLD_MAGIC_NUMBER); fprintf(ofp, " Checkpoint is %d-bit\n", vmss.cpt64bit ? 64 : 32); grpsize = hdr.numgroups * sizeof (cptgroupdesc); grps = (cptgroupdesc *) malloc(grpsize * sizeof(cptgroupdesc)); if (grps == NULL) { fprintf(ofp, "Failed to allocate memory! [Error %d] %s\n", errno, strerror(errno)); fclose(fp); return FALSE; } if (fread(grps, sizeof(cptgroupdesc), grpsize, fp) != grpsize) { fprintf(ofp, "Failed to read vmss file: [Error %d] %s\n", errno, strerror(errno)); result = FALSE; goto exit; } for (i = 0; i < hdr.numgroups; i++) { if (fseek(fp, grps[i].position, SEEK_SET) == -1) { fprintf(ofp, "Bad offset of VMSS Group['%s'] in vmss file at %#llx.\n", grps[i].name, (ulonglong)grps[i].position); continue; } fprintf(ofp, "\nGroup: %s offset=%#llx size=0x%#llx\n", grps[i].name, (ulonglong)grps[i].position, (ulonglong)grps[i].size); for (;;) { uint16_t tag; char name[TAG_NAMELEN_MASK + 1]; unsigned nameLen; unsigned nindx; int idx[3]; unsigned j; int nextgroup = FALSE; if (fread(&tag, sizeof(tag), 1, fp) != 1) { fprintf(ofp, "Cannot read tag.\n"); break; } if (tag == NULL_TAG) break; nameLen = TAG_NAMELEN(tag); if (fread(name, nameLen, 1, fp) != 1) { fprintf(ofp, "Cannot read tag name.\n"); break; } name[nameLen] = 0; fprintf(ofp, " Item %20s", name); nindx = TAG_NINDX(tag); if (nindx > 3) { fprintf(ofp, "Too many indexes %d (> 3).\n", nindx); break; } idx[0] = idx[1] = idx[2] = NO_INDEX; for (j= 0; j < 3; j++) { if (j < nindx) { if (fread(&idx[j], sizeof(idx[0]), 1, fp) != 1) { fprintf(ofp, "Cannot read index.\n"); nextgroup = TRUE; break; } fprintf(ofp, "[%d]", idx[j]); } else fprintf(ofp, " "); } if (nextgroup) break; if (IS_BLOCK_TAG(tag)) { uint64_t nbytes; uint64_t blockpos; uint64_t nbytesinmem; int compressed = IS_BLOCK_COMPRESSED_TAG(tag); uint16_t padsize; unsigned k, l; char byte; if (fread(&nbytes, sizeof(nbytes), 1, fp) != 1) { fprintf(ofp, "Cannot read block size.\n"); break; } if (fread(&nbytesinmem, sizeof(nbytesinmem), 1, fp) != 1) { fprintf(ofp, "Cannot read block memory size.\n"); break; } if (fread(&padsize, sizeof(padsize), 1, fp) != 1) { fprintf(ofp, "Cannot read block padding size.\n"); break; } if ((blockpos = ftell(fp)) == -1) { fprintf(ofp, "Cannot determine location within VMSS file.\n"); break; } blockpos += padsize; fprintf(ofp, " => %sBLOCK: position=%#llx size=%#llx memsize=%#llx\n", compressed ? "COMPRESSED " : "", (ulonglong)blockpos, (ulonglong)nbytes, (ulonglong)nbytesinmem); if (nbytes && nbytes <= MAX_BLOCK_DUMP && !compressed) { fprintf(ofp, "Hex dump: \n"); l = 0; for (k = 0; k < nbytes; k++) { if (fread(&byte, 1, 1, fp) != 1) { fprintf(ofp, "Cannot read byte.\n"); result = FALSE; goto exit; } fprintf(ofp, " %02hhX", byte); if (l++ == 15) { fprintf(ofp, "\n"); l = 0; } } if (l) fprintf(ofp, "\n\n"); else fprintf(ofp, "\n"); } else { if (fseek(fp, blockpos + nbytes, SEEK_SET) == -1) { fprintf(ofp, "Cannot seek past block at %#llx.\n", (ulonglong)(blockpos + nbytes)); result = FALSE; goto exit; } } } else { union { uint8_t val[TAG_VALSIZE_MASK]; uint32_t val32; uint64_t val64; } u; unsigned k; unsigned valsize = TAG_VALSIZE(tag); uint64_t blockpos = ftell(fp); fprintf(ofp, " => position=%#llx size=%#x: ", (ulonglong)blockpos, valsize); if (fread(u.val, sizeof(u.val[0]), valsize, fp) != valsize) { fprintf(ofp, "Cannot read item.\n"); break; } for (k = 0; k < valsize; k++) { /* Assume Little Endian */ fprintf(ofp, "%02X", u.val[valsize - k - 1]); } fprintf(ofp, "\n"); } } } exit: if (vmss.separate_vmem) fclose(fp); if (grps) free(grps); return result; } void dump_registers_for_vmss_dump(void) { int i; vmssregs64 *regs; if (!machine_type("X86_64")) { fprintf(fp, "-r option not supported on this dumpfile type\n"); return; } for (i = 0; i < vmss.num_vcpus; i++) { regs = vmss.regs64[i]; if (i) fprintf(fp, "\n"); fprintf(fp, "CPU %d:\n", i); if (vmss.vcpu_regs[i] != REGS_PRESENT_ALL) { fprintf(fp, "Missing registers for this CPU: 0x%x\n", vmss.vcpu_regs[i]); continue; } fprintf(fp, " RAX: %016llx RBX: %016llx RCX: %016llx\n", (ulonglong)regs->rax, (ulonglong)regs->rbx, (ulonglong)regs->rcx); fprintf(fp, " RDX: %016llx RSI: %016llx RDI: %016llx\n", (ulonglong)regs->rdx, (ulonglong)regs->rsi, (ulonglong)regs->rdi); fprintf(fp, " RSP: %016llx RBP: %016llx R8: %016llx\n", (ulonglong)regs->rsp, (ulonglong)regs->rbp, (ulonglong)regs->r8); fprintf(fp, " R9: %016llx R10: %016llx R11: %016llx\n", (ulonglong)regs->r9, (ulonglong)regs->r10, (ulonglong)regs->r11); fprintf(fp, " R12: %016llx R13: %016llx R14: %016llx\n", (ulonglong)regs->r12, (ulonglong)regs->r13, (ulonglong)regs->r14); fprintf(fp, " R15: %016llx RIP: %016llx RFLAGS: %08llx\n", (ulonglong)regs->r15, (ulonglong)regs->rip, (ulonglong)regs->rflags); fprintf(fp, " IDT: base: %016llx\n", (ulonglong)regs->idtr); fprintf(fp, " CR0: %016llx CR1: %016llx CR2: %016llx\n", (ulonglong)regs->cr[0], (ulonglong)regs->cr[1], (ulonglong)regs->cr[2]); fprintf(fp, " CR3: %016llx CR4: %016llx\n", (ulonglong)regs->cr[3], (ulonglong)regs->cr[4]); } } int vmware_vmss_valid_regs(struct bt_info *bt) { if (vmss.vcpu_regs[bt->tc->processor] == REGS_PRESENT_ALL) return TRUE; return FALSE; } int vmware_vmss_get_cr3_idtr(ulong *cr3, ulong *idtr) { if (vmss.num_vcpus == 0 || vmss.vcpu_regs[0] != REGS_PRESENT_ALL) return FALSE; *cr3 = vmss.regs64[0]->cr[3]; *idtr = vmss.regs64[0]->idtr; return TRUE; } int vmware_vmss_phys_base(ulong *phys_base) { *phys_base = vmss.phys_base; return TRUE; } int vmware_vmss_set_phys_base(ulong phys_base) { vmss.phys_base = phys_base; return TRUE; }