Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Alan Cox | 1942 | 46.36% | 2 | 2.82% |
Greg Ungerer | 821 | 19.60% | 7 | 9.86% |
Nico Pitre | 763 | 18.21% | 11 | 15.49% |
Al Viro | 129 | 3.08% | 6 | 8.45% |
Christoph Hellwig | 114 | 2.72% | 7 | 9.86% |
Niklas Svensson (Niklas Cassel) | 88 | 2.10% | 1 | 1.41% |
Luke Yang | 74 | 1.77% | 1 | 1.41% |
Oskar Schirmer | 54 | 1.29% | 2 | 2.82% |
Max Filippov | 32 | 0.76% | 1 | 1.41% |
Mike Frysinger | 32 | 0.76% | 5 | 7.04% |
David Howells | 28 | 0.67% | 2 | 2.82% |
Damien Le Moal | 20 | 0.48% | 1 | 1.41% |
Andrew Morton | 17 | 0.41% | 4 | 5.63% |
Eric W. Biedermann | 15 | 0.36% | 3 | 4.23% |
Kees Cook | 14 | 0.33% | 2 | 2.82% |
Volodymyr G. Lukiianyk | 8 | 0.19% | 1 | 1.41% |
Linus Torvalds | 8 | 0.19% | 2 | 2.82% |
Takashi YOSHII | 8 | 0.19% | 1 | 1.41% |
Jiri Slaby | 3 | 0.07% | 1 | 1.41% |
Jun Sun | 3 | 0.07% | 1 | 1.41% |
Ingo Molnar | 3 | 0.07% | 1 | 1.41% |
Yoshinori Sato | 2 | 0.05% | 1 | 1.41% |
Bernd Schmidt | 2 | 0.05% | 1 | 1.41% |
SF Markus Elfring | 2 | 0.05% | 1 | 1.41% |
Arnd Bergmann | 2 | 0.05% | 1 | 1.41% |
Lucas De Marchi | 1 | 0.02% | 1 | 1.41% |
Greg Kroah-Hartman | 1 | 0.02% | 1 | 1.41% |
Geert Uytterhoeven | 1 | 0.02% | 1 | 1.41% |
Malcolm Parsons | 1 | 0.02% | 1 | 1.41% |
Axel Lin | 1 | 0.02% | 1 | 1.41% |
Total | 4189 | 71 |
// SPDX-License-Identifier: GPL-2.0 /****************************************************************************/ /* * linux/fs/binfmt_flat.c * * Copyright (C) 2000-2003 David McCullough <davidm@snapgear.com> * Copyright (C) 2002 Greg Ungerer <gerg@snapgear.com> * Copyright (C) 2002 SnapGear, by Paul Dale <pauli@snapgear.com> * Copyright (C) 2000, 2001 Lineo, by David McCullough <davidm@lineo.com> * based heavily on: * * linux/fs/binfmt_aout.c: * Copyright (C) 1991, 1992, 1996 Linus Torvalds * linux/fs/binfmt_flat.c for 2.0 kernel * Copyright (C) 1998 Kenneth Albanowski <kjahds@kjahds.com> * JAN/99 -- coded full program relocation (gerg@snapgear.com) */ #define pr_fmt(fmt) KBUILD_MODNAME ": " fmt #include <linux/kernel.h> #include <linux/sched.h> #include <linux/sched/task_stack.h> #include <linux/mm.h> #include <linux/mman.h> #include <linux/errno.h> #include <linux/signal.h> #include <linux/string.h> #include <linux/fs.h> #include <linux/file.h> #include <linux/ptrace.h> #include <linux/user.h> #include <linux/slab.h> #include <linux/binfmts.h> #include <linux/personality.h> #include <linux/init.h> #include <linux/flat.h> #include <linux/uaccess.h> #include <linux/vmalloc.h> #include <asm/byteorder.h> #include <asm/unaligned.h> #include <asm/cacheflush.h> #include <asm/page.h> #include <asm/flat.h> #ifndef flat_get_relocate_addr #define flat_get_relocate_addr(rel) (rel) #endif /****************************************************************************/ /* * User data (data section and bss) needs to be aligned. * We pick 0x20 here because it is the max value elf2flt has always * used in producing FLAT files, and because it seems to be large * enough to make all the gcc alignment related tests happy. */ #define FLAT_DATA_ALIGN (0x20) /* * User data (stack) also needs to be aligned. * Here we can be a bit looser than the data sections since this * needs to only meet arch ABI requirements. */ #define FLAT_STACK_ALIGN max_t(unsigned long, sizeof(void *), ARCH_SLAB_MINALIGN) #define RELOC_FAILED 0xff00ff01 /* Relocation incorrect somewhere */ #define UNLOADED_LIB 0x7ff000ff /* Placeholder for unused library */ #define MAX_SHARED_LIBS (1) #ifdef CONFIG_BINFMT_FLAT_NO_DATA_START_OFFSET #define DATA_START_OFFSET_WORDS (0) #define MAX_SHARED_LIBS_UPDATE (0) #else #define DATA_START_OFFSET_WORDS (MAX_SHARED_LIBS) #define MAX_SHARED_LIBS_UPDATE (MAX_SHARED_LIBS) #endif struct lib_info { struct { unsigned long start_code; /* Start of text segment */ unsigned long start_data; /* Start of data segment */ unsigned long start_brk; /* End of data segment */ unsigned long text_len; /* Length of text segment */ unsigned long entry; /* Start address for this module */ unsigned long build_date; /* When this one was compiled */ bool loaded; /* Has this library been loaded? */ } lib_list[MAX_SHARED_LIBS]; }; static int load_flat_binary(struct linux_binprm *); static struct linux_binfmt flat_format = { .module = THIS_MODULE, .load_binary = load_flat_binary, }; /****************************************************************************/ /* * create_flat_tables() parses the env- and arg-strings in new user * memory and creates the pointer tables from them, and puts their * addresses on the "stack", recording the new stack pointer value. */ static int create_flat_tables(struct linux_binprm *bprm, unsigned long arg_start) { char __user *p; unsigned long __user *sp; long i, len; p = (char __user *)arg_start; sp = (unsigned long __user *)current->mm->start_stack; sp -= bprm->envc + 1; sp -= bprm->argc + 1; if (IS_ENABLED(CONFIG_BINFMT_FLAT_ARGVP_ENVP_ON_STACK)) sp -= 2; /* argvp + envp */ sp -= 1; /* &argc */ current->mm->start_stack = (unsigned long)sp & -FLAT_STACK_ALIGN; sp = (unsigned long __user *)current->mm->start_stack; if (put_user(bprm->argc, sp++)) return -EFAULT; if (IS_ENABLED(CONFIG_BINFMT_FLAT_ARGVP_ENVP_ON_STACK)) { unsigned long argv, envp; argv = (unsigned long)(sp + 2); envp = (unsigned long)(sp + 2 + bprm->argc + 1); if (put_user(argv, sp++) || put_user(envp, sp++)) return -EFAULT; } current->mm->arg_start = (unsigned long)p; for (i = bprm->argc; i > 0; i--) { if (put_user((unsigned long)p, sp++)) return -EFAULT; len = strnlen_user(p, MAX_ARG_STRLEN); if (!len || len > MAX_ARG_STRLEN) return -EINVAL; p += len; } if (put_user(0, sp++)) return -EFAULT; current->mm->arg_end = (unsigned long)p; current->mm->env_start = (unsigned long) p; for (i = bprm->envc; i > 0; i--) { if (put_user((unsigned long)p, sp++)) return -EFAULT; len = strnlen_user(p, MAX_ARG_STRLEN); if (!len || len > MAX_ARG_STRLEN) return -EINVAL; p += len; } if (put_user(0, sp++)) return -EFAULT; current->mm->env_end = (unsigned long)p; return 0; } /****************************************************************************/ #ifdef CONFIG_BINFMT_ZFLAT #include <linux/zlib.h> #define LBUFSIZE 4000 /* gzip flag byte */ #define ASCII_FLAG 0x01 /* bit 0 set: file probably ASCII text */ #define CONTINUATION 0x02 /* bit 1 set: continuation of multi-part gzip file */ #define EXTRA_FIELD 0x04 /* bit 2 set: extra field present */ #define ORIG_NAME 0x08 /* bit 3 set: original file name present */ #define COMMENT 0x10 /* bit 4 set: file comment present */ #define ENCRYPTED 0x20 /* bit 5 set: file is encrypted */ #define RESERVED 0xC0 /* bit 6,7: reserved */ static int decompress_exec(struct linux_binprm *bprm, loff_t fpos, char *dst, long len, int fd) { unsigned char *buf; z_stream strm; int ret, retval; pr_debug("decompress_exec(offset=%llx,buf=%p,len=%lx)\n", fpos, dst, len); memset(&strm, 0, sizeof(strm)); strm.workspace = kmalloc(zlib_inflate_workspacesize(), GFP_KERNEL); if (!strm.workspace) return -ENOMEM; buf = kmalloc(LBUFSIZE, GFP_KERNEL); if (!buf) { retval = -ENOMEM; goto out_free; } /* Read in first chunk of data and parse gzip header. */ ret = kernel_read(bprm->file, buf, LBUFSIZE, &fpos); strm.next_in = buf; strm.avail_in = ret; strm.total_in = 0; retval = -ENOEXEC; /* Check minimum size -- gzip header */ if (ret < 10) { pr_debug("file too small?\n"); goto out_free_buf; } /* Check gzip magic number */ if ((buf[0] != 037) || ((buf[1] != 0213) && (buf[1] != 0236))) { pr_debug("unknown compression magic?\n"); goto out_free_buf; } /* Check gzip method */ if (buf[2] != 8) { pr_debug("unknown compression method?\n"); goto out_free_buf; } /* Check gzip flags */ if ((buf[3] & ENCRYPTED) || (buf[3] & CONTINUATION) || (buf[3] & RESERVED)) { pr_debug("unknown flags?\n"); goto out_free_buf; } ret = 10; if (buf[3] & EXTRA_FIELD) { ret += 2 + buf[10] + (buf[11] << 8); if (unlikely(ret >= LBUFSIZE)) { pr_debug("buffer overflow (EXTRA)?\n"); goto out_free_buf; } } if (buf[3] & ORIG_NAME) { while (ret < LBUFSIZE && buf[ret++] != 0) ; if (unlikely(ret == LBUFSIZE)) { pr_debug("buffer overflow (ORIG_NAME)?\n"); goto out_free_buf; } } if (buf[3] & COMMENT) { while (ret < LBUFSIZE && buf[ret++] != 0) ; if (unlikely(ret == LBUFSIZE)) { pr_debug("buffer overflow (COMMENT)?\n"); goto out_free_buf; } } strm.next_in += ret; strm.avail_in -= ret; strm.next_out = dst; strm.avail_out = len; strm.total_out = 0; if (zlib_inflateInit2(&strm, -MAX_WBITS) != Z_OK) { pr_debug("zlib init failed?\n"); goto out_free_buf; } while ((ret = zlib_inflate(&strm, Z_NO_FLUSH)) == Z_OK) { ret = kernel_read(bprm->file, buf, LBUFSIZE, &fpos); if (ret <= 0) break; len -= ret; strm.next_in = buf; strm.avail_in = ret; strm.total_in = 0; } if (ret < 0) { pr_debug("decompression failed (%d), %s\n", ret, strm.msg); goto out_zlib; } retval = 0; out_zlib: zlib_inflateEnd(&strm); out_free_buf: kfree(buf); out_free: kfree(strm.workspace); return retval; } #endif /* CONFIG_BINFMT_ZFLAT */ /****************************************************************************/ static unsigned long calc_reloc(unsigned long r, struct lib_info *p) { unsigned long addr; unsigned long start_brk; unsigned long start_data; unsigned long text_len; unsigned long start_code; start_brk = p->lib_list[0].start_brk; start_data = p->lib_list[0].start_data; start_code = p->lib_list[0].start_code; text_len = p->lib_list[0].text_len; if (r > start_brk - start_data + text_len) { pr_err("reloc outside program 0x%lx (0 - 0x%lx/0x%lx)", r, start_brk-start_data+text_len, text_len); goto failed; } if (r < text_len) /* In text segment */ addr = r + start_code; else /* In data segment */ addr = r - text_len + start_data; /* Range checked already above so doing the range tests is redundant...*/ return addr; failed: pr_cont(", killing %s!\n", current->comm); send_sig(SIGSEGV, current, 0); return RELOC_FAILED; } /****************************************************************************/ #ifdef CONFIG_BINFMT_FLAT_OLD static void old_reloc(unsigned long rl) { static const char *segment[] = { "TEXT", "DATA", "BSS", "*UNKNOWN*" }; flat_v2_reloc_t r; unsigned long __user *ptr; unsigned long val; r.value = rl; #if defined(CONFIG_COLDFIRE) ptr = (unsigned long __user *)(current->mm->start_code + r.reloc.offset); #else ptr = (unsigned long __user *)(current->mm->start_data + r.reloc.offset); #endif get_user(val, ptr); pr_debug("Relocation of variable at DATASEG+%x " "(address %p, currently %lx) into segment %s\n", r.reloc.offset, ptr, val, segment[r.reloc.type]); switch (r.reloc.type) { case OLD_FLAT_RELOC_TYPE_TEXT: val += current->mm->start_code; break; case OLD_FLAT_RELOC_TYPE_DATA: val += current->mm->start_data; break; case OLD_FLAT_RELOC_TYPE_BSS: val += current->mm->end_data; break; default: pr_err("Unknown relocation type=%x\n", r.reloc.type); break; } put_user(val, ptr); pr_debug("Relocation became %lx\n", val); } #endif /* CONFIG_BINFMT_FLAT_OLD */ /****************************************************************************/ static inline u32 __user *skip_got_header(u32 __user *rp) { if (IS_ENABLED(CONFIG_RISCV)) { /* * RISC-V has a 16 byte GOT PLT header for elf64-riscv * and 8 byte GOT PLT header for elf32-riscv. * Skip the whole GOT PLT header, since it is reserved * for the dynamic linker (ld.so). */ u32 rp_val0, rp_val1; if (get_user(rp_val0, rp)) return rp; if (get_user(rp_val1, rp + 1)) return rp; if (rp_val0 == 0xffffffff && rp_val1 == 0xffffffff) rp += 4; else if (rp_val0 == 0xffffffff) rp += 2; } return rp; } static int load_flat_file(struct linux_binprm *bprm, struct lib_info *libinfo, unsigned long *extra_stack) { struct flat_hdr *hdr; unsigned long textpos, datapos, realdatastart; u32 text_len, data_len, bss_len, stack_len, full_data, flags; unsigned long len, memp, memp_size, extra, rlim; __be32 __user *reloc; u32 __user *rp; int i, rev, relocs; loff_t fpos; unsigned long start_code, end_code; ssize_t result; int ret; hdr = ((struct flat_hdr *) bprm->buf); /* exec-header */ text_len = ntohl(hdr->data_start); data_len = ntohl(hdr->data_end) - ntohl(hdr->data_start); bss_len = ntohl(hdr->bss_end) - ntohl(hdr->data_end); stack_len = ntohl(hdr->stack_size); if (extra_stack) { stack_len += *extra_stack; *extra_stack = stack_len; } relocs = ntohl(hdr->reloc_count); flags = ntohl(hdr->flags); rev = ntohl(hdr->rev); full_data = data_len + relocs * sizeof(unsigned long); if (strncmp(hdr->magic, "bFLT", 4)) { /* * Previously, here was a printk to tell people * "BINFMT_FLAT: bad header magic". * But for the kernel which also use ELF FD-PIC format, this * error message is confusing. * because a lot of people do not manage to produce good */ ret = -ENOEXEC; goto err; } if (flags & FLAT_FLAG_KTRACE) pr_info("Loading file: %s\n", bprm->filename); #ifdef CONFIG_BINFMT_FLAT_OLD if (rev != FLAT_VERSION && rev != OLD_FLAT_VERSION) { pr_err("bad flat file version 0x%x (supported 0x%lx and 0x%lx)\n", rev, FLAT_VERSION, OLD_FLAT_VERSION); ret = -ENOEXEC; goto err; } /* * fix up the flags for the older format, there were all kinds * of endian hacks, this only works for the simple cases */ if (rev == OLD_FLAT_VERSION && (flags || IS_ENABLED(CONFIG_BINFMT_FLAT_OLD_ALWAYS_RAM))) flags = FLAT_FLAG_RAM; #else /* CONFIG_BINFMT_FLAT_OLD */ if (rev != FLAT_VERSION) { pr_err("bad flat file version 0x%x (supported 0x%lx)\n", rev, FLAT_VERSION); ret = -ENOEXEC; goto err; } #endif /* !CONFIG_BINFMT_FLAT_OLD */ /* * Make sure the header params are sane. * 28 bits (256 MB) is way more than reasonable in this case. * If some top bits are set we have probable binary corruption. */ if ((text_len | data_len | bss_len | stack_len | full_data) >> 28) { pr_err("bad header\n"); ret = -ENOEXEC; goto err; } #ifndef CONFIG_BINFMT_ZFLAT if (flags & (FLAT_FLAG_GZIP|FLAT_FLAG_GZDATA)) { pr_err("Support for ZFLAT executables is not enabled.\n"); ret = -ENOEXEC; goto err; } #endif /* * Check initial limits. This avoids letting people circumvent * size limits imposed on them by creating programs with large * arrays in the data or bss. */ rlim = rlimit(RLIMIT_DATA); if (rlim >= RLIM_INFINITY) rlim = ~0; if (data_len + bss_len > rlim) { ret = -ENOMEM; goto err; } /* Flush all traces of the currently running executable */ ret = begin_new_exec(bprm); if (ret) goto err; /* OK, This is the point of no return */ set_personality(PER_LINUX_32BIT); setup_new_exec(bprm); /* * calculate the extra space we need to map in */ extra = max_t(unsigned long, bss_len + stack_len, relocs * sizeof(unsigned long)); /* * there are a couple of cases here, the separate code/data * case, and then the fully copied to RAM case which lumps * it all together. */ if (!IS_ENABLED(CONFIG_MMU) && !(flags & (FLAT_FLAG_RAM|FLAT_FLAG_GZIP))) { /* * this should give us a ROM ptr, but if it doesn't we don't * really care */ pr_debug("ROM mapping of file (we hope)\n"); textpos = vm_mmap(bprm->file, 0, text_len, PROT_READ|PROT_EXEC, MAP_PRIVATE, 0); if (!textpos || IS_ERR_VALUE(textpos)) { ret = textpos; if (!textpos) ret = -ENOMEM; pr_err("Unable to mmap process text, errno %d\n", ret); goto err; } len = data_len + extra + DATA_START_OFFSET_WORDS * sizeof(unsigned long); len = PAGE_ALIGN(len); realdatastart = vm_mmap(NULL, 0, len, PROT_READ|PROT_WRITE|PROT_EXEC, MAP_PRIVATE, 0); if (realdatastart == 0 || IS_ERR_VALUE(realdatastart)) { ret = realdatastart; if (!realdatastart) ret = -ENOMEM; pr_err("Unable to allocate RAM for process data, " "errno %d\n", ret); vm_munmap(textpos, text_len); goto err; } datapos = ALIGN(realdatastart + DATA_START_OFFSET_WORDS * sizeof(unsigned long), FLAT_DATA_ALIGN); pr_debug("Allocated data+bss+stack (%u bytes): %lx\n", data_len + bss_len + stack_len, datapos); fpos = ntohl(hdr->data_start); #ifdef CONFIG_BINFMT_ZFLAT if (flags & FLAT_FLAG_GZDATA) { result = decompress_exec(bprm, fpos, (char *)datapos, full_data, 0); } else #endif { result = read_code(bprm->file, datapos, fpos, full_data); } if (IS_ERR_VALUE(result)) { ret = result; pr_err("Unable to read data+bss, errno %d\n", ret); vm_munmap(textpos, text_len); vm_munmap(realdatastart, len); goto err; } reloc = (__be32 __user *) (datapos + (ntohl(hdr->reloc_start) - text_len)); memp = realdatastart; memp_size = len; } else { len = text_len + data_len + extra + DATA_START_OFFSET_WORDS * sizeof(u32); len = PAGE_ALIGN(len); textpos = vm_mmap(NULL, 0, len, PROT_READ | PROT_EXEC | PROT_WRITE, MAP_PRIVATE, 0); if (!textpos || IS_ERR_VALUE(textpos)) { ret = textpos; if (!textpos) ret = -ENOMEM; pr_err("Unable to allocate RAM for process text/data, " "errno %d\n", ret); goto err; } realdatastart = textpos + ntohl(hdr->data_start); datapos = ALIGN(realdatastart + DATA_START_OFFSET_WORDS * sizeof(u32), FLAT_DATA_ALIGN); reloc = (__be32 __user *) (datapos + (ntohl(hdr->reloc_start) - text_len)); memp = textpos; memp_size = len; #ifdef CONFIG_BINFMT_ZFLAT /* * load it all in and treat it like a RAM load from now on */ if (flags & FLAT_FLAG_GZIP) { #ifndef CONFIG_MMU result = decompress_exec(bprm, sizeof(struct flat_hdr), (((char *)textpos) + sizeof(struct flat_hdr)), (text_len + full_data - sizeof(struct flat_hdr)), 0); memmove((void *) datapos, (void *) realdatastart, full_data); #else /* * This is used on MMU systems mainly for testing. * Let's use a kernel buffer to simplify things. */ long unz_text_len = text_len - sizeof(struct flat_hdr); long unz_len = unz_text_len + full_data; char *unz_data = vmalloc(unz_len); if (!unz_data) { result = -ENOMEM; } else { result = decompress_exec(bprm, sizeof(struct flat_hdr), unz_data, unz_len, 0); if (result == 0 && (copy_to_user((void __user *)textpos + sizeof(struct flat_hdr), unz_data, unz_text_len) || copy_to_user((void __user *)datapos, unz_data + unz_text_len, full_data))) result = -EFAULT; vfree(unz_data); } #endif } else if (flags & FLAT_FLAG_GZDATA) { result = read_code(bprm->file, textpos, 0, text_len); if (!IS_ERR_VALUE(result)) { #ifndef CONFIG_MMU result = decompress_exec(bprm, text_len, (char *) datapos, full_data, 0); #else char *unz_data = vmalloc(full_data); if (!unz_data) { result = -ENOMEM; } else { result = decompress_exec(bprm, text_len, unz_data, full_data, 0); if (result == 0 && copy_to_user((void __user *)datapos, unz_data, full_data)) result = -EFAULT; vfree(unz_data); } #endif } } else #endif /* CONFIG_BINFMT_ZFLAT */ { result = read_code(bprm->file, textpos, 0, text_len); if (!IS_ERR_VALUE(result)) result = read_code(bprm->file, datapos, ntohl(hdr->data_start), full_data); } if (IS_ERR_VALUE(result)) { ret = result; pr_err("Unable to read code+data+bss, errno %d\n", ret); vm_munmap(textpos, text_len + data_len + extra + DATA_START_OFFSET_WORDS * sizeof(u32)); goto err; } } start_code = textpos + sizeof(struct flat_hdr); end_code = textpos + text_len; text_len -= sizeof(struct flat_hdr); /* the real code len */ /* The main program needs a little extra setup in the task structure */ current->mm->start_code = start_code; current->mm->end_code = end_code; current->mm->start_data = datapos; current->mm->end_data = datapos + data_len; /* * set up the brk stuff, uses any slack left in data/bss/stack * allocation. We put the brk after the bss (between the bss * and stack) like other platforms. * Userspace code relies on the stack pointer starting out at * an address right at the end of a page. */ current->mm->start_brk = datapos + data_len + bss_len; current->mm->brk = (current->mm->start_brk + 3) & ~3; #ifndef CONFIG_MMU current->mm->context.end_brk = memp + memp_size - stack_len; #endif if (flags & FLAT_FLAG_KTRACE) { pr_info("Mapping is %lx, Entry point is %x, data_start is %x\n", textpos, 0x00ffffff&ntohl(hdr->entry), ntohl(hdr->data_start)); pr_info("%s %s: TEXT=%lx-%lx DATA=%lx-%lx BSS=%lx-%lx\n", "Load", bprm->filename, start_code, end_code, datapos, datapos + data_len, datapos + data_len, (datapos + data_len + bss_len + 3) & ~3); } /* Store the current module values into the global library structure */ libinfo->lib_list[0].start_code = start_code; libinfo->lib_list[0].start_data = datapos; libinfo->lib_list[0].start_brk = datapos + data_len + bss_len; libinfo->lib_list[0].text_len = text_len; libinfo->lib_list[0].loaded = 1; libinfo->lib_list[0].entry = (0x00ffffff & ntohl(hdr->entry)) + textpos; libinfo->lib_list[0].build_date = ntohl(hdr->build_date); /* * We just load the allocations into some temporary memory to * help simplify all this mumbo jumbo * * We've got two different sections of relocation entries. * The first is the GOT which resides at the beginning of the data segment * and is terminated with a -1. This one can be relocated in place. * The second is the extra relocation entries tacked after the image's * data segment. These require a little more processing as the entry is * really an offset into the image which contains an offset into the * image. */ if (flags & FLAT_FLAG_GOTPIC) { rp = skip_got_header((u32 __user *) datapos); for (; ; rp++) { u32 addr, rp_val; if (get_user(rp_val, rp)) return -EFAULT; if (rp_val == 0xffffffff) break; if (rp_val) { addr = calc_reloc(rp_val, libinfo); if (addr == RELOC_FAILED) { ret = -ENOEXEC; goto err; } if (put_user(addr, rp)) return -EFAULT; } } } /* * Now run through the relocation entries. * We've got to be careful here as C++ produces relocatable zero * entries in the constructor and destructor tables which are then * tested for being not zero (which will always occur unless we're * based from address zero). This causes an endless loop as __start * is at zero. The solution used is to not relocate zero addresses. * This has the negative side effect of not allowing a global data * reference to be statically initialised to _stext (I've moved * __start to address 4 so that is okay). */ if (rev > OLD_FLAT_VERSION) { for (i = 0; i < relocs; i++) { u32 addr, relval; __be32 tmp; /* * Get the address of the pointer to be * relocated (of course, the address has to be * relocated first). */ if (get_user(tmp, reloc + i)) return -EFAULT; relval = ntohl(tmp); addr = flat_get_relocate_addr(relval); rp = (u32 __user *)calc_reloc(addr, libinfo); if (rp == (u32 __user *)RELOC_FAILED) { ret = -ENOEXEC; goto err; } /* Get the pointer's value. */ ret = flat_get_addr_from_rp(rp, relval, flags, &addr); if (unlikely(ret)) goto err; if (addr != 0) { /* * Do the relocation. PIC relocs in the data section are * already in target order */ if ((flags & FLAT_FLAG_GOTPIC) == 0) { /* * Meh, the same value can have a different * byte order based on a flag.. */ addr = ntohl((__force __be32)addr); } addr = calc_reloc(addr, libinfo); if (addr == RELOC_FAILED) { ret = -ENOEXEC; goto err; } /* Write back the relocated pointer. */ ret = flat_put_addr_at_rp(rp, addr, relval); if (unlikely(ret)) goto err; } } #ifdef CONFIG_BINFMT_FLAT_OLD } else { for (i = 0; i < relocs; i++) { __be32 relval; if (get_user(relval, reloc + i)) return -EFAULT; old_reloc(ntohl(relval)); } #endif /* CONFIG_BINFMT_FLAT_OLD */ } flush_icache_user_range(start_code, end_code); /* zero the BSS, BRK and stack areas */ if (clear_user((void __user *)(datapos + data_len), bss_len + (memp + memp_size - stack_len - /* end brk */ libinfo->lib_list[0].start_brk) + /* start brk */ stack_len)) return -EFAULT; return 0; err: return ret; } /****************************************************************************/ /* * These are the functions used to load flat style executables and shared * libraries. There is no binary dependent code anywhere else. */ static int load_flat_binary(struct linux_binprm *bprm) { struct lib_info libinfo; struct pt_regs *regs = current_pt_regs(); unsigned long stack_len = 0; unsigned long start_addr; int res; int i, j; memset(&libinfo, 0, sizeof(libinfo)); /* * We have to add the size of our arguments to our stack size * otherwise it's too easy for users to create stack overflows * by passing in a huge argument list. And yes, we have to be * pedantic and include space for the argv/envp array as it may have * a lot of entries. */ #ifndef CONFIG_MMU stack_len += PAGE_SIZE * MAX_ARG_PAGES - bprm->p; /* the strings */ #endif stack_len += (bprm->argc + 1) * sizeof(char *); /* the argv array */ stack_len += (bprm->envc + 1) * sizeof(char *); /* the envp array */ stack_len = ALIGN(stack_len, FLAT_STACK_ALIGN); res = load_flat_file(bprm, &libinfo, &stack_len); if (res < 0) return res; /* Update data segment pointers for all libraries */ for (i = 0; i < MAX_SHARED_LIBS_UPDATE; i++) { if (!libinfo.lib_list[i].loaded) continue; for (j = 0; j < MAX_SHARED_LIBS; j++) { unsigned long val = libinfo.lib_list[j].loaded ? libinfo.lib_list[j].start_data : UNLOADED_LIB; unsigned long __user *p = (unsigned long __user *) libinfo.lib_list[i].start_data; p -= j + 1; if (put_user(val, p)) return -EFAULT; } } set_binfmt(&flat_format); #ifdef CONFIG_MMU res = setup_arg_pages(bprm, STACK_TOP, EXSTACK_DEFAULT); if (!res) res = create_flat_tables(bprm, bprm->p); #else /* Stash our initial stack pointer into the mm structure */ current->mm->start_stack = ((current->mm->context.end_brk + stack_len + 3) & ~3) - 4; pr_debug("sp=%lx\n", current->mm->start_stack); /* copy the arg pages onto the stack */ res = transfer_args_to_stack(bprm, ¤t->mm->start_stack); if (!res) res = create_flat_tables(bprm, current->mm->start_stack); #endif if (res) return res; /* Fake some return addresses to ensure the call chain will * initialise library in order for us. We are required to call * lib 1 first, then 2, ... and finally the main program (id 0). */ start_addr = libinfo.lib_list[0].entry; #ifdef FLAT_PLAT_INIT FLAT_PLAT_INIT(regs); #endif finalize_exec(bprm); pr_debug("start_thread(regs=0x%p, entry=0x%lx, start_stack=0x%lx)\n", regs, start_addr, current->mm->start_stack); start_thread(regs, start_addr, current->mm->start_stack); return 0; } /****************************************************************************/ static int __init init_flat_binfmt(void) { register_binfmt(&flat_format); return 0; } core_initcall(init_flat_binfmt); /****************************************************************************/
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