/* * Copyright (c) 2000-2004 Apple Computer, Inc. All rights reserved. * * @APPLE_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. 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_LICENSE_HEADER_END@ */ /* Copyright (c) 1998 Apple Computer, Inc. All rights reserved. * * File: bsd/kern/kern_symfile.c * * This file contains creates a dummy symbol file for mach_kernel * based on the symbol table information passed by the * SecondaryLoader/PlatformExpert. This allows us to correctly * link other executables (drivers, etc) against the the kernel in * cases where the kernel image on the root device does not match * the live kernel. This can occur during net-booting where the * actual kernel image is obtained from the network via tftp rather * than the root device. * * If a symbol table is available, then the file /mach.sym will be * created containing a Mach Header and a LC_SYMTAB load command * followed by the the symbol table data for mach_kernel. * * NOTE: This file supports only 32 bit kernels at the present time; * adding support for 64 bit kernels is possible, but is not * necessary at the present time. * * HISTORY * * . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern unsigned char rootdevice[]; extern struct mach_header _mh_execute_header; static int kernel_symfile_opened = 0; static int error_code = 0; extern int IODTGetLoaderInfo(char *key, void **infoAddr, int *infoSize); extern void IODTFreeLoaderInfo(char *key, void *infoAddr, int infoSize); /* * Can only operate against currently running 32 bit mach_kernel */ static int output_kernel_symbols(struct proc *p) { struct vnode *vp; kauth_cred_t cred = p->p_ucred; /* XXX */ struct vnode_attr va; struct vfs_context context; struct load_command *cmd; struct mach_header *orig_mh, *mh; struct segment_command *orig_ds, *orig_ts, *orig_le, *sg; struct section *se, *const_text; struct symtab_command *st, *orig_st; struct nlist *sym; vm_size_t orig_mhsize, orig_st_size; vm_offset_t header; vm_size_t header_size = 0; /* out: protected by header */ int error, error1; unsigned int i, j; caddr_t addr; vm_offset_t offset; int rc_mh, rc_sc; error = EFAULT; vp = NULL; header = NULL; orig_mh = NULL; orig_st = NULL; // Dispose of unnecessary gumf, the booter doesn't need to load these rc_mh = IODTGetLoaderInfo("Kernel-__HEADER", (void **)&orig_mh, &orig_mhsize); if (rc_mh == 0 && orig_mh) IODTFreeLoaderInfo("Kernel-__HEADER", (void *)orig_mh, round_page_32(orig_mhsize)); rc_sc = IODTGetLoaderInfo("Kernel-__SYMTAB", (void **) &orig_st, &orig_st_size); if (rc_sc == 0 && orig_st) IODTFreeLoaderInfo("Kernel-__SYMTAB", (void *)orig_st, round_page_32(orig_st_size)); if (cred->cr_svuid != cred->cr_ruid || cred->cr_svgid != cred->cr_rgid) goto out; // Check to see if the root is 'e' or 'n', is this a test for network? if (rootdevice[0] == 'e' && rootdevice[1] == 'n') goto out; context.vc_proc = p; context.vc_ucred = cred; if ((error = vnode_open("mach.sym", (O_CREAT | FWRITE), (S_IRUSR | S_IRGRP | S_IROTH), 0, &vp, &context))) goto out; /* Don't dump to non-regular files or files with links. */ error = EFAULT; VATTR_INIT(&va); VATTR_WANTED(&va, va_nlink); if ((vp->v_type != VREG) || vnode_getattr(vp, &va, &context) || (va.va_nlink != 1)) goto out; VATTR_INIT(&va); /* better to do it here than waste more stack in vnode_getsize */ VATTR_SET(&va, va_data_size, 0); vnode_setattr(vp, &va, &context); p->p_acflag |= ACORE; // If the file type is MH_EXECUTE then this must be a kernel // as all Kernel extensions must be of type MH_OBJECT orig_ds = orig_ts = orig_le = NULL; orig_st = NULL; orig_mh = &_mh_execute_header; cmd = (struct load_command *) &orig_mh[1]; for (i = 0; i < orig_mh->ncmds; i++) { if (cmd->cmd == LC_SEGMENT) { struct segment_command *orig_sg = (struct segment_command *) cmd; if (!strcmp(SEG_TEXT, orig_sg->segname)) orig_ts = orig_sg; else if (!strcmp(SEG_DATA, orig_sg->segname)) orig_ds = orig_sg; else if (!strcmp(SEG_LINKEDIT, orig_sg->segname)) orig_le = orig_sg; } else if (cmd->cmd == LC_SYMTAB) orig_st = (struct symtab_command *) cmd; cmd = (struct load_command *) ((caddr_t) cmd + cmd->cmdsize); } if (!orig_ts || !orig_ds || !orig_le || !orig_st) goto out; const_text = NULL; se = (struct section *) &orig_ts[1]; for (i = 0; i < orig_ts->nsects; i++, se++) { if (!strcmp("__const", se->sectname)) { const_text = se; break; } } if (!const_text) goto out; header_size = sizeof(struct mach_header) + orig_ts->cmdsize + orig_ds->cmdsize + sizeof(struct symtab_command); (void) kmem_alloc(kernel_map, (vm_offset_t *) &header, (vm_size_t) header_size); if (header) bzero((void *) header, header_size); else goto out; /* * Set up Mach-O header. */ mh = (struct mach_header *) header; mh->magic = orig_mh->magic; mh->cputype = orig_mh->cputype; mh->cpusubtype = orig_mh->cpusubtype; mh->filetype = orig_mh->filetype; mh->ncmds = 3; mh->sizeofcmds = header_size - sizeof(struct mach_header); mh->flags = orig_mh->flags; // Initialise the current file offset and addr offset = round_page(header_size); addr = (caddr_t) const_text->addr; // Load address of __TEXT,__const /* * Construct a TEXT segment load command * the only part of the TEXT segment we keep is the __TEXT,__const * which contains the kernel vtables. */ sg = (struct segment_command *) &mh[1]; bcopy(orig_ts, sg, orig_ts->cmdsize); sg->vmaddr = (unsigned long) addr; sg->vmsize = const_text->size; sg->fileoff = 0; sg->filesize = const_text->size + round_page(header_size); sg->maxprot = 0; sg->initprot = 0; sg->flags = 0; se = (struct section *)(sg+1); for ( j = 0; j < sg->nsects; j++, se++ ) { se->addr = (unsigned long) addr; se->size = 0; se->offset = offset; se->nreloc = 0; if (!strcmp("__const", se->sectname)) { se->size = const_text->size; addr += const_text->size; offset += const_text->size; const_text = se; } } offset = round_page(offset); // Now copy of the __DATA segment load command, the image need // not be stored to disk nobody needs it, yet! sg = (struct segment_command *)((int)sg + sg->cmdsize); bcopy(orig_ds, sg, orig_ds->cmdsize); sg->vmaddr = (unsigned long) addr; sg->vmsize = 0x1000; // One page for some reason? sg->fileoff = offset; sg->filesize = 0; sg->maxprot = 0; sg->initprot = 0; sg->flags = 0; se = (struct section *)(sg+1); for ( j = 0; j < sg->nsects; j++, se++ ) { se->addr = (unsigned long) addr; se->size = 0; se->offset = offset; se->nreloc = 0; } offset = round_page(offset); /* * Set up LC_SYMTAB command */ st = (struct symtab_command *)((int)sg + sg->cmdsize); st->cmd = LC_SYMTAB; st->cmdsize = sizeof(struct symtab_command); st->symoff = offset; st->nsyms = orig_st->nsyms; st->strsize = orig_st->strsize; st->stroff = offset + st->nsyms * sizeof(struct nlist); /* * Convert the symbol table in place from section references * to absolute references. */ sym = (struct nlist *) orig_le->vmaddr; for (i = 0; i < st->nsyms; i++, sym++ ) { if ( (sym->n_type & N_TYPE) == N_SECT) { sym->n_sect = NO_SECT; sym->n_type = (sym->n_type & ~N_TYPE) | N_ABS; } } /* * Write out the load commands at the beginning of the file. */ error = vn_rdwr(UIO_WRITE, vp, (caddr_t) mh, header_size, (off_t) 0, UIO_SYSSPACE32, IO_NODELOCKED|IO_UNIT, cred, (int *) 0, p); if (error) goto out; /* * Write out the __TEXT,__const data segment. */ error = vn_rdwr(UIO_WRITE, vp, (caddr_t) const_text->addr, const_text->size, const_text->offset, UIO_SYSSPACE32, IO_NODELOCKED|IO_UNIT, cred, (int *) 0, p); if (error) goto out; /* * Write out kernel symbols */ offset = st->nsyms * sizeof(struct nlist) + st->strsize; // symtab size error = vn_rdwr(UIO_WRITE, vp, (caddr_t) orig_le->vmaddr, offset, st->symoff, UIO_SYSSPACE32, IO_NODELOCKED|IO_UNIT, cred, (int *) 0, p); out: if (header) kmem_free(kernel_map, header, header_size); if (vp) { error1 = vnode_close(vp, FWRITE, &context); if (!error) error = error1; } return(error); } /* * */ int get_kernel_symfile(struct proc *p, char **symfile) { if (!kernel_symfile_opened) { kernel_symfile_opened = 1; error_code = output_kernel_symbols(p); } if (!error_code) *symfile = "\\mach.sym"; return error_code; } struct kern_direct_file_io_ref_t { struct vfs_context context; struct vnode *vp; }; static int file_ioctl(void * p1, void * p2, int theIoctl, caddr_t result) { dev_t device = (dev_t) p1; return ((*bdevsw[major(device)].d_ioctl) (device, theIoctl, result, S_IFBLK, p2)); } static int device_ioctl(void * p1, __unused void * p2, int theIoctl, caddr_t result) { return (VNOP_IOCTL(p1, theIoctl, result, 0, p2)); } struct kern_direct_file_io_ref_t * kern_open_file_for_direct_io(const char * name, kern_get_file_extents_callback_t callback, void * callback_ref, dev_t * device_result, uint64_t * partitionbase_result, uint64_t * maxiocount_result) { struct kern_direct_file_io_ref_t * ref; struct proc *p; struct ucred *cred; struct vnode_attr va; int error; off_t f_offset; uint32_t blksize; uint64_t size; dev_t device; off_t maxiocount, count; int (*do_ioctl)(void * p1, void * p2, int theIoctl, caddr_t result); void * p1; void * p2; error = EFAULT; ref = (struct kern_direct_file_io_ref_t *) kalloc(sizeof(struct kern_direct_file_io_ref_t)); if (!ref) { error = EFAULT; goto out; } ref->vp = NULL; p = current_proc(); // kernproc; cred = p->p_ucred; ref->context.vc_proc = p; ref->context.vc_ucred = cred; if ((error = vnode_open(name, (O_CREAT | FWRITE), (0), 0, &ref->vp, &ref->context))) goto out; VATTR_INIT(&va); VATTR_WANTED(&va, va_rdev); VATTR_WANTED(&va, va_fsid); VATTR_WANTED(&va, va_data_size); VATTR_WANTED(&va, va_nlink); error = EFAULT; if (vnode_getattr(ref->vp, &va, &ref->context)) goto out; kprintf("vp va_rdev major %d minor %d\n", major(va.va_rdev), minor(va.va_rdev)); kprintf("vp va_fsid major %d minor %d\n", major(va.va_fsid), minor(va.va_fsid)); kprintf("vp size %qd\n", va.va_data_size); if (ref->vp->v_type == VREG) { /* Don't dump files with links. */ if (va.va_nlink != 1) goto out; device = va.va_fsid; p1 = (void *) device; p2 = p; do_ioctl = &file_ioctl; } else if ((ref->vp->v_type == VBLK) || (ref->vp->v_type == VCHR)) { /* Partition. */ device = va.va_rdev; p1 = ref->vp; p2 = &ref->context; do_ioctl = &device_ioctl; } else { /* Don't dump to non-regular files. */ error = EFAULT; goto out; } // get partition base error = do_ioctl(p1, p2, DKIOCGETBASE, (caddr_t) partitionbase_result); if (error) goto out; // get block size & constraints error = do_ioctl(p1, p2, DKIOCGETBLOCKSIZE, (caddr_t) &blksize); if (error) goto out; maxiocount = 1*1024*1024*1024; error = do_ioctl(p1, p2, DKIOCGETMAXBLOCKCOUNTREAD, (caddr_t) &count); if (error) count = 0; count *= blksize; if (count && (count < maxiocount)) maxiocount = count; error = do_ioctl(p1, p2, DKIOCGETMAXBLOCKCOUNTWRITE, (caddr_t) &count); if (error) count = 0; count *= blksize; if (count && (count < maxiocount)) maxiocount = count; error = do_ioctl(p1, p2, DKIOCGETMAXBYTECOUNTREAD, (caddr_t) &count); if (error) count = 0; if (count && (count < maxiocount)) maxiocount = count; error = do_ioctl(p1, p2, DKIOCGETMAXBYTECOUNTWRITE, (caddr_t) &count); if (error) count = 0; if (count && (count < maxiocount)) maxiocount = count; error = do_ioctl(p1, p2, DKIOCGETMAXSEGMENTBYTECOUNTREAD, (caddr_t) &count); if (error) count = 0; if (count && (count < maxiocount)) maxiocount = count; error = do_ioctl(p1, p2, DKIOCGETMAXSEGMENTBYTECOUNTWRITE, (caddr_t) &count); if (error) count = 0; if (count && (count < maxiocount)) maxiocount = count; kprintf("max io 0x%qx bytes\n", maxiocount); if (maxiocount_result) *maxiocount_result = maxiocount; // generate the block list error = 0; if (ref->vp->v_type == VREG) { f_offset = 0; while(f_offset < (off_t) va.va_data_size) { size_t io_size = 1*1024*1024*1024; daddr64_t blkno; error = VNOP_BLOCKMAP(ref->vp, f_offset, io_size, &blkno, (size_t *)&io_size, NULL, 0, NULL); if (error) goto out; callback(callback_ref, ((uint64_t) blkno) * blksize, (uint64_t) io_size); f_offset += io_size; } callback(callback_ref, 0ULL, 0ULL); } else if ((ref->vp->v_type == VBLK) || (ref->vp->v_type == VCHR)) { error = do_ioctl(p1, p2, DKIOCGETBLOCKCOUNT, (caddr_t) &size); if (error) goto out; size *= blksize; callback(callback_ref, 0ULL, size); callback(callback_ref, size, 0ULL); } if (device_result) *device_result = device; out: kprintf("kern_open_file_for_direct_io(%d)\n", error); if (error && ref) { if (ref->vp) vnode_close(ref->vp, FWRITE, &ref->context); kfree(ref, sizeof(struct kern_direct_file_io_ref_t)); } return(ref); } int kern_write_file(struct kern_direct_file_io_ref_t * ref, off_t offset, caddr_t addr, vm_size_t len) { return (vn_rdwr(UIO_WRITE, ref->vp, addr, len, offset, UIO_SYSSPACE32, IO_SYNC|IO_NODELOCKED|IO_UNIT, ref->context.vc_ucred, (int *) 0, ref->context.vc_proc)); } void kern_close_file_for_direct_io(struct kern_direct_file_io_ref_t * ref) { kprintf("kern_close_file_for_direct_io\n"); if (ref) { int error; if (ref->vp) { error = vnode_close(ref->vp, FWRITE, &ref->context); kprintf("vnode_close(%d)\n", error); } kfree(ref, sizeof(struct kern_direct_file_io_ref_t)); } }