Current Path : /usr/src/sys/compat/ndis/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/sys/compat/ndis/subr_pe.c |
/*- * Copyright (c) 2003 * Bill Paul <wpaul@windriver.com>. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Bill Paul. * 4. Neither the name of the author nor the names of any co-contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL Bill Paul OR THE VOICES IN HIS HEAD * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/compat/ndis/subr_pe.c 198786 2009-11-02 11:07:42Z rpaulo $"); /* * This file contains routines for relocating and dynamically linking * executable object code files in the Windows(r) PE (Portable Executable) * format. In Windows, anything with a .EXE, .DLL or .SYS extention is * considered an executable, and all such files have some structures in * common. The PE format was apparently based largely on COFF but has * mutated significantly over time. We are mainly concerned with .SYS files, * so this module implements only enough routines to be able to parse the * headers and sections of a .SYS object file and perform the necessary * relocations and jump table patching to allow us to call into it * (and to have it call back to us). Note that while this module * can handle fixups for imported symbols, it knows nothing about * exporting them. */ #include <sys/param.h> #include <sys/types.h> #include <sys/errno.h> #ifdef _KERNEL #include <sys/systm.h> #else #include <stdio.h> #include <stddef.h> #include <stdlib.h> #include <unistd.h> #include <string.h> #endif #include <compat/ndis/pe_var.h> static vm_offset_t pe_functbl_match(image_patch_table *, char *); /* * Check for an MS-DOS executable header. All Windows binaries * have a small MS-DOS executable prepended to them to print out * the "This program requires Windows" message. Even .SYS files * have this header, in spite of the fact that you're can't actually * run them directly. */ int pe_get_dos_header(imgbase, hdr) vm_offset_t imgbase; image_dos_header *hdr; { uint16_t signature; if (imgbase == 0 || hdr == NULL) return (EINVAL); signature = *(uint16_t *)imgbase; if (signature != IMAGE_DOS_SIGNATURE) return (ENOEXEC); bcopy ((char *)imgbase, (char *)hdr, sizeof(image_dos_header)); return (0); } /* * Verify that this image has a Windows NT PE signature. */ int pe_is_nt_image(imgbase) vm_offset_t imgbase; { uint32_t signature; image_dos_header *dos_hdr; if (imgbase == 0) return (EINVAL); signature = *(uint16_t *)imgbase; if (signature == IMAGE_DOS_SIGNATURE) { dos_hdr = (image_dos_header *)imgbase; signature = *(uint32_t *)(imgbase + dos_hdr->idh_lfanew); if (signature == IMAGE_NT_SIGNATURE) return (0); } return (ENOEXEC); } /* * Return a copy of the optional header. This contains the * executable entry point and the directory listing which we * need to find the relocations and imports later. */ int pe_get_optional_header(imgbase, hdr) vm_offset_t imgbase; image_optional_header *hdr; { image_dos_header *dos_hdr; image_nt_header *nt_hdr; if (imgbase == 0 || hdr == NULL) return (EINVAL); if (pe_is_nt_image(imgbase)) return (EINVAL); dos_hdr = (image_dos_header *)(imgbase); nt_hdr = (image_nt_header *)(imgbase + dos_hdr->idh_lfanew); bcopy ((char *)&nt_hdr->inh_optionalhdr, (char *)hdr, nt_hdr->inh_filehdr.ifh_optionalhdrlen); return (0); } /* * Return a copy of the file header. Contains the number of * sections in this image. */ int pe_get_file_header(imgbase, hdr) vm_offset_t imgbase; image_file_header *hdr; { image_dos_header *dos_hdr; image_nt_header *nt_hdr; if (imgbase == 0 || hdr == NULL) return (EINVAL); if (pe_is_nt_image(imgbase)) return (EINVAL); dos_hdr = (image_dos_header *)imgbase; nt_hdr = (image_nt_header *)(imgbase + dos_hdr->idh_lfanew); /* * Note: the size of the nt_header is variable since it * can contain optional fields, as indicated by ifh_optionalhdrlen. * However it happens we're only interested in fields in the * non-variant portion of the nt_header structure, so we don't * bother copying the optional parts here. */ bcopy ((char *)&nt_hdr->inh_filehdr, (char *)hdr, sizeof(image_file_header)); return (0); } /* * Return the header of the first section in this image (usually * .text). */ int pe_get_section_header(imgbase, hdr) vm_offset_t imgbase; image_section_header *hdr; { image_dos_header *dos_hdr; image_nt_header *nt_hdr; image_section_header *sect_hdr; if (imgbase == 0 || hdr == NULL) return (EINVAL); if (pe_is_nt_image(imgbase)) return (EINVAL); dos_hdr = (image_dos_header *)imgbase; nt_hdr = (image_nt_header *)(imgbase + dos_hdr->idh_lfanew); sect_hdr = IMAGE_FIRST_SECTION(nt_hdr); bcopy ((char *)sect_hdr, (char *)hdr, sizeof(image_section_header)); return (0); } /* * Return the number of sections in this executable, or 0 on error. */ int pe_numsections(imgbase) vm_offset_t imgbase; { image_file_header file_hdr; if (pe_get_file_header(imgbase, &file_hdr)) return (0); return (file_hdr.ifh_numsections); } /* * Return the base address that this image was linked for. * This helps us calculate relocation addresses later. */ vm_offset_t pe_imagebase(imgbase) vm_offset_t imgbase; { image_optional_header optional_hdr; if (pe_get_optional_header(imgbase, &optional_hdr)) return (0); return (optional_hdr.ioh_imagebase); } /* * Return the offset of a given directory structure within the * image. Directories reside within sections. */ vm_offset_t pe_directory_offset(imgbase, diridx) vm_offset_t imgbase; uint32_t diridx; { image_optional_header opt_hdr; vm_offset_t dir; if (pe_get_optional_header(imgbase, &opt_hdr)) return (0); if (diridx >= opt_hdr.ioh_rva_size_cnt) return (0); dir = opt_hdr.ioh_datadir[diridx].idd_vaddr; return (pe_translate_addr(imgbase, dir)); } vm_offset_t pe_translate_addr(imgbase, rva) vm_offset_t imgbase; vm_offset_t rva; { image_optional_header opt_hdr; image_section_header *sect_hdr; image_dos_header *dos_hdr; image_nt_header *nt_hdr; int i = 0, sections, fixedlen; if (pe_get_optional_header(imgbase, &opt_hdr)) return (0); sections = pe_numsections(imgbase); dos_hdr = (image_dos_header *)imgbase; nt_hdr = (image_nt_header *)(imgbase + dos_hdr->idh_lfanew); sect_hdr = IMAGE_FIRST_SECTION(nt_hdr); /* * The test here is to see if the RVA falls somewhere * inside the section, based on the section's start RVA * and its length. However it seems sometimes the * virtual length isn't enough to cover the entire * area of the section. We fudge by taking into account * the section alignment and rounding the section length * up to a page boundary. */ while (i++ < sections) { fixedlen = sect_hdr->ish_misc.ish_vsize; fixedlen += ((opt_hdr.ioh_sectalign - 1) - sect_hdr->ish_misc.ish_vsize) & (opt_hdr.ioh_sectalign - 1); if (sect_hdr->ish_vaddr <= (uint32_t)rva && (sect_hdr->ish_vaddr + fixedlen) > (uint32_t)rva) break; sect_hdr++; } if (i > sections) return (0); return ((vm_offset_t)(imgbase + rva - sect_hdr->ish_vaddr + sect_hdr->ish_rawdataaddr)); } /* * Get the section header for a particular section. Note that * section names can be anything, but there are some standard * ones (.text, .data, .rdata, .reloc). */ int pe_get_section(imgbase, hdr, name) vm_offset_t imgbase; image_section_header *hdr; const char *name; { image_dos_header *dos_hdr; image_nt_header *nt_hdr; image_section_header *sect_hdr; int i, sections; if (imgbase == 0 || hdr == NULL) return (EINVAL); if (pe_is_nt_image(imgbase)) return (EINVAL); sections = pe_numsections(imgbase); dos_hdr = (image_dos_header *)imgbase; nt_hdr = (image_nt_header *)(imgbase + dos_hdr->idh_lfanew); sect_hdr = IMAGE_FIRST_SECTION(nt_hdr); for (i = 0; i < sections; i++) { if (!strcmp ((char *)§_hdr->ish_name, name)) { bcopy((char *)sect_hdr, (char *)hdr, sizeof(image_section_header)); return (0); } else sect_hdr++; } return (ENOEXEC); } /* * Apply the base relocations to this image. The relocation table * resides within the .reloc section. Relocations are specified in * blocks which refer to a particular page. We apply the relocations * one page block at a time. */ int pe_relocate(imgbase) vm_offset_t imgbase; { image_section_header sect; image_base_reloc *relhdr; uint16_t rel, *sloc; vm_offset_t base; vm_size_t delta; uint32_t *lloc; uint64_t *qloc; int i, count; vm_offset_t txt; base = pe_imagebase(imgbase); pe_get_section(imgbase, §, ".text"); txt = pe_translate_addr(imgbase, sect.ish_vaddr); delta = (uint32_t)(txt) - base - sect.ish_vaddr; pe_get_section(imgbase, §, ".reloc"); relhdr = (image_base_reloc *)(imgbase + sect.ish_rawdataaddr); do { count = (relhdr->ibr_blocksize - (sizeof(uint32_t) * 2)) / sizeof(uint16_t); for (i = 0; i < count; i++) { rel = relhdr->ibr_rel[i]; switch (IMR_RELTYPE(rel)) { case IMAGE_REL_BASED_ABSOLUTE: break; case IMAGE_REL_BASED_HIGHLOW: lloc = (uint32_t *)pe_translate_addr(imgbase, relhdr->ibr_vaddr + IMR_RELOFFSET(rel)); *lloc = pe_translate_addr(imgbase, (*lloc - base)); break; case IMAGE_REL_BASED_HIGH: sloc = (uint16_t *)pe_translate_addr(imgbase, relhdr->ibr_vaddr + IMR_RELOFFSET(rel)); *sloc += (delta & 0xFFFF0000) >> 16; break; case IMAGE_REL_BASED_LOW: sloc = (uint16_t *)pe_translate_addr(imgbase, relhdr->ibr_vaddr + IMR_RELOFFSET(rel)); *sloc += (delta & 0xFFFF); break; case IMAGE_REL_BASED_DIR64: qloc = (uint64_t *)pe_translate_addr(imgbase, relhdr->ibr_vaddr + IMR_RELOFFSET(rel)); *qloc = pe_translate_addr(imgbase, (*qloc - base)); break; default: printf("[%d]reloc type: %d\n",i, IMR_RELTYPE(rel)); break; } } relhdr = (image_base_reloc *)((vm_offset_t)relhdr + relhdr->ibr_blocksize); } while (relhdr->ibr_blocksize); return (0); } /* * Return the import descriptor for a particular module. An image * may be linked against several modules, typically HAL.dll, ntoskrnl.exe * and NDIS.SYS. For each module, there is a list of imported function * names and their addresses. * * Note: module names are case insensitive! */ int pe_get_import_descriptor(imgbase, desc, module) vm_offset_t imgbase; image_import_descriptor *desc; char *module; { vm_offset_t offset; image_import_descriptor *imp_desc; char *modname; if (imgbase == 0 || module == NULL || desc == NULL) return (EINVAL); offset = pe_directory_offset(imgbase, IMAGE_DIRECTORY_ENTRY_IMPORT); if (offset == 0) return (ENOENT); imp_desc = (void *)offset; while (imp_desc->iid_nameaddr) { modname = (char *)pe_translate_addr(imgbase, imp_desc->iid_nameaddr); if (!strncasecmp(module, modname, strlen(module))) { bcopy((char *)imp_desc, (char *)desc, sizeof(image_import_descriptor)); return (0); } imp_desc++; } return (ENOENT); } int pe_get_messagetable(imgbase, md) vm_offset_t imgbase; message_resource_data **md; { image_resource_directory *rdir, *rtype; image_resource_directory_entry *dent, *dent2; image_resource_data_entry *rent; vm_offset_t offset; int i; if (imgbase == 0) return (EINVAL); offset = pe_directory_offset(imgbase, IMAGE_DIRECTORY_ENTRY_RESOURCE); if (offset == 0) return (ENOENT); rdir = (image_resource_directory *)offset; dent = (image_resource_directory_entry *)(offset + sizeof(image_resource_directory)); for (i = 0; i < rdir->ird_id_entries; i++){ if (dent->irde_name != RT_MESSAGETABLE) { dent++; continue; } dent2 = dent; while (dent2->irde_dataoff & RESOURCE_DIR_FLAG) { rtype = (image_resource_directory *)(offset + (dent2->irde_dataoff & ~RESOURCE_DIR_FLAG)); dent2 = (image_resource_directory_entry *) ((uintptr_t)rtype + sizeof(image_resource_directory)); } rent = (image_resource_data_entry *)(offset + dent2->irde_dataoff); *md = (message_resource_data *)pe_translate_addr(imgbase, rent->irde_offset); return (0); } return (ENOENT); } int pe_get_message(imgbase, id, str, len, flags) vm_offset_t imgbase; uint32_t id; char **str; int *len; uint16_t *flags; { message_resource_data *md = NULL; message_resource_block *mb; message_resource_entry *me; uint32_t i; pe_get_messagetable(imgbase, &md); if (md == NULL) return (ENOENT); mb = (message_resource_block *)((uintptr_t)md + sizeof(message_resource_data)); for (i = 0; i < md->mrd_numblocks; i++) { if (id >= mb->mrb_lowid && id <= mb->mrb_highid) { me = (message_resource_entry *)((uintptr_t)md + mb->mrb_entryoff); for (i = id - mb->mrb_lowid; i > 0; i--) me = (message_resource_entry *)((uintptr_t)me + me->mre_len); *str = me->mre_text; *len = me->mre_len; *flags = me->mre_flags; return (0); } mb++; } return (ENOENT); } /* * Find the function that matches a particular name. This doesn't * need to be particularly speedy since it's only run when loading * a module for the first time. */ static vm_offset_t pe_functbl_match(functbl, name) image_patch_table *functbl; char *name; { image_patch_table *p; if (functbl == NULL || name == NULL) return (0); p = functbl; while (p->ipt_name != NULL) { if (!strcmp(p->ipt_name, name)) return ((vm_offset_t)p->ipt_wrap); p++; } printf("no match for %s\n", name); /* * Return the wrapper pointer for this routine. * For x86, this is the same as the funcptr. * For amd64, this points to a wrapper routine * that does calling convention translation and * then invokes the underlying routine. */ return ((vm_offset_t)p->ipt_wrap); } /* * Patch the imported function addresses for a given module. * The caller must specify the module name and provide a table * of function pointers that will be patched into the jump table. * Note that there are actually two copies of the jump table: one * copy is left alone. In a .SYS file, the jump tables are usually * merged into the INIT segment. */ int pe_patch_imports(imgbase, module, functbl) vm_offset_t imgbase; char *module; image_patch_table *functbl; { image_import_descriptor imp_desc; char *fname; vm_offset_t *nptr, *fptr; vm_offset_t func; if (imgbase == 0 || module == NULL || functbl == NULL) return (EINVAL); if (pe_get_import_descriptor(imgbase, &imp_desc, module)) return (ENOEXEC); nptr = (vm_offset_t *)pe_translate_addr(imgbase, imp_desc.iid_import_name_table_addr); fptr = (vm_offset_t *)pe_translate_addr(imgbase, imp_desc.iid_import_address_table_addr); while (nptr != NULL && pe_translate_addr(imgbase, *nptr)) { fname = (char *)pe_translate_addr(imgbase, (*nptr) + 2); func = pe_functbl_match(functbl, fname); if (func) *fptr = func; #ifdef notdef if (*fptr == 0) return (ENOENT); #endif nptr++; fptr++; } return (0); }