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We are in bvmlinux now! With the help of misc.c:decompress_kernel(), we are going to decompress piggy.o to get the resident kernel image linux/vmlinux.
This file is of pure 32-bit startup code. Unlike previous two files, it has no ".code16" statement in the source file. Refer to Using as: Writing 16-bit Code for details.
The segment base addresses in segment descriptors (which correspond to segment selector __KERNEL_CS and __KERNEL_DS) are equal to 0; therefore, the logical address offset (in segment:offset format) will be equal to its linear address if either of these segment selectors is used. For zImage, CS:EIP is at logical address 10:1000 (linear address 0x1000) now; for bzImage, 10:100000 (linear address 0x100000).
As paging is not enabled, linear address is identical to physical address. Check IA-32 Manual (Vol.1. Ch.3.3. Memory Organization, and Vol.3. Ch.3. Protected-Mode Memory Management) and Linux Device Drivers: Memory Management in Linux for address issue.
It comes from setup.S that BX=0 and ESI=INITSEG<<4.
.text /////////////////////////////////////////////////////////////////////////////// startup_32() { cld; cli; DS = ES = FS = GS = __KERNEL_DS; SS:ESP = *stack_start; // end of user_stack[], defined in misc.c // all segment registers are reloaded after protected mode is enabled // check that A20 really IS enabled EAX = 0; do { 1: DS:[0] = ++EAX; } while (DS:[0x100000]==EAX); EFLAGS = 0; clear BSS; // from _edata to _end struct moveparams mp; // subl $16,%esp if (!decompress_kernel(&mp, ESI)) { // return value in AX restore ESI from stack; EBX = 0; goto __KERNEL_CS:100000; // see linux/arch/i386/kernel/head.S:startup_32 } /* * We come here, if we were loaded high. * We need to move the move-in-place routine down to 0x1000 * and then start it with the buffer addresses in registers, * which we got from the stack. */ 3: move move_rountine_start..move_routine_end to 0x1000; // move_routine_start & move_routine_end are defined below // prepare move_routine_start() parameters EBX = real mode pointer; // ESI value passed from setup.S ESI = mp.low_buffer_start; ECX = mp.lcount; EDX = mp.high_buffer_star; EAX = mp.hcount; EDI = 0x100000; cli; // make sure we don't get interrupted goto __KERNEL_CS:1000; // move_routine_start(); } /* Routine (template) for moving the decompressed kernel in place, * if we were high loaded. This _must_ PIC-code ! */ /////////////////////////////////////////////////////////////////////////////// move_routine_start() { move mp.low_buffer_start to 0x100000, mp.lcount bytes, in two steps: (lcount >> 2) words + (lcount & 3) bytes; move/append mp.high_buffer_start, ((mp.hcount + 3) >> 2) words // 1 word == 4 bytes, as I mean 32-bit code/data. ESI = EBX; // real mode pointer, as that from setup.S EBX = 0; goto __KERNEL_CS:100000; // see linux/arch/i386/kernel/head.S:startup_32() move_routine_end: } |
Didn't find _edata and _end definitions? No problem, they are defined in the "internal linker script". Without -T (--script=) option specified, ld uses this builtin script to link compressed/bvmlinux. Use "ld --verbose" to display this script, or check Appendix B. Internal Linker Script.
Refer to Using LD, the GNU linker: Command Line Options for -T (--script=), -L (--library-path=) and --verbose option description. "man ld" and "info ld" may help too.
piggy.o has been unzipped and control is passed to __KERNEL_CS:100000, i.e. linux/arch/i386/kernel/head.S:startup_32(). See Section 6.
#define LOW_BUFFER_START 0x2000 #define LOW_BUFFER_MAX 0x90000 #define HEAP_SIZE 0x3000 /////////////////////////////////////////////////////////////////////////////// asmlinkage int decompress_kernel(struct moveparams *mv, void *rmode) |-- setup real_mode(=rmode), vidmem, vidport, lines and cols; |-- if (is_zImage) setup_normal_output_buffer() { | output_data = 0x100000; | free_mem_end_ptr = real_mode; | } else (is_bzImage) setup_output_buffer_if_we_run_high(mv) { | output_data = LOW_BUFFER_START; | low_buffer_end = MIN(real_mode, LOW_BUFFER_MAX) & ~0xfff; | low_buffer_size = low_buffer_end - LOW_BUFFER_START; | free_mem_end_ptr = &end + HEAP_SIZE; | // get mv->low_buffer_start and mv->high_buffer_start | mv->low_buffer_start = LOW_BUFFER_START; | /* To make this program work, we must have | * high_buffer_start > &end+HEAP_SIZE; | * As we will move low_buffer from LOW_BUFFER_START to 0x100000 | * (max low_buffer_size bytes) finally, we should have | * high_buffer_start > 0x100000+low_buffer_size; */ | mv->high_buffer_start = high_buffer_start | = MAX(&end+HEAP_SIZE, 0x100000+low_buffer_size); | mv->hcount = 0 if (0x100000+low_buffer_size > &end+HEAP_SIZE); | = -1 if (0x100000+low_buffer_size <= &end+HEAP_SIZE); | /* mv->hcount==0 : we need not move high_buffer later, | * as it is already at 0x100000+low_buffer_size. | * Used by close_output_buffer_if_we_run_high() below. */ | } |-- makecrc(); // create crc_32_tab[] | puts("Uncompressing Linux... "); |-- gunzip(); | puts("Ok, booting the kernel.\n"); |-- if (is_bzImage) close_output_buffer_if_we_run_high(mv) { | // get mv->lcount and mv->hcount | if (bytes_out > low_buffer_size) { | mv->lcount = low_buffer_size; | if (mv->hcount) | mv->hcount = bytes_out - low_buffer_size; | } else { | mv->lcount = bytes_out; | mv->hcount = 0; | } | } `-- return is_bzImage; // return value in AX |
decompress_kernel() has an "asmlinkage" modifer. In linux/include/linux/linkage.h:
#ifdef __cplusplus #define CPP_ASMLINKAGE extern "C" #else #define CPP_ASMLINKAGE #endif #if defined __i386__ #define asmlinkage CPP_ASMLINKAGE __attribute__((regparm(0))) #elif defined __ia64__ #define asmlinkage CPP_ASMLINKAGE __attribute__((syscall_linkage)) #else #define asmlinkage CPP_ASMLINKAGE #endif |
decompress_kernel() calls gunzip() -> inflate(), which are defined in linux/lib/inflate.c, to decompress resident kernel image to low buffer (pointed by output_data) and high buffer (pointed by high_buffer_start, for bzImage only).
The gzip file format is specified in RFC 1952.
Table 6. gzip file format
Component | Meaning | Byte | Comment |
---|---|---|---|
ID1 | IDentification 1 | 1 | 31 (0x1f, \037) |
ID2 | IDentification 2 | 1 | 139 (0x8b, \213) [a] |
CM | Compression Method | 1 | 8 - denotes the "deflate" compression method |
FLG | FLaGs | 1 | 0 for most cases |
MTIME | Modification TIME | 4 | modification time of the original file |
XFL | eXtra FLags | 1 | 2 - compressor used maximum compression, slowest algorithm [b] |
OS | Operating System | 1 | 3 - Unix |
extra fields | - | - | variable length, field indicated by FLG [c] |
compressed blocks | - | - | variable length |
CRC32 | - | 4 | CRC value of the uncompressed data |
ISIZE | Input SIZE | 4 | the size of the uncompressed input data modulo 2^32 |
Notes: a. ID2 value can be 158 (0x9e, \236) for gzip 0.5; b. XFL value 4 - compressor used fastest algorithm; c. FLG bit 0, FTEXT, does not indicate any "extra field". |
We can use this file format knowledge to find out the beginning of gzipped linux/vmlinux.
[root@localhost boot]# hexdump -C /boot/vmlinuz-2.4.20-28.9 | grep '1f 8b 08 00' 00004c50 1f 8b 08 00 01 f6 e1 3f 02 03 ec 5d 7d 74 14 55 |.......?...]}t.U| [root@localhost boot]# hexdump -C /boot/vmlinuz-2.4.20-28.9 -s 0x4c40 -n 64 00004c40 00 80 0b 00 00 fc 21 00 68 00 00 00 1e 01 11 00 |......!.h.......| 00004c50 1f 8b 08 00 01 f6 e1 3f 02 03 ec 5d 7d 74 14 55 |.......?...]}t.U| 00004c60 96 7f d5 a9 d0 1d 4d ac 56 93 35 ac 01 3a 9c 6a |......M.V.5..:.j| 00004c70 4d 46 5c d3 7b f8 48 36 c9 6c 84 f0 25 88 20 9f |MF\.{.H6.l..%. .| 00004c80 [root@localhost boot]# hexdump -C /boot/vmlinuz-2.4.20-28.9 | tail -n 4 00114d40 bd 77 66 da ce 6f 3d d6 33 5c 14 a2 9f 7e fa e9 |.wf..o=.3\...~..| 00114d50 a7 9f 7e fa ff 57 3f 00 00 00 00 00 d8 bc ab ea |..~..W?.........| 00114d60 44 5d 76 d1 fd 03 33 58 c2 f0 00 51 27 00 |D]v...3X...Q'.| 00114d6e |
static uch *inbuf; /* input buffer */ static unsigned insize = 0; /* valid bytes in inbuf */ static unsigned inptr = 0; /* index of next byte to be processed in inbuf */ /////////////////////////////////////////////////////////////////////////////// static int gunzip(void) { Check input buffer for {ID1, ID2, CM}, must be {0x1f, 0x8b, 0x08} (normal case), or {0x1f, 0x9e, 0x08} (for gzip 0.5); Check FLG (flag byte), must not set bit 1, 5, 6 and 7; Ignore {MTIME, XFL, OS}; Handle optional structures, which correspond to FLG bit 2, 3 and 4; inflate(); // handle compressed blocks Validate {CRC32, ISIZE}; } |
// some important definitions in misc.c #define WSIZE 0x8000 /* Window size must be at least 32k, * and a power of two */ static uch window[WSIZE]; /* Sliding window buffer */ static unsigned outcnt = 0; /* bytes in output buffer */ // linux/lib/inflate.c #define wp outcnt #define flush_output(w) (wp=(w),flush_window()) STATIC unsigned long bb; /* bit buffer */ STATIC unsigned bk; /* bits in bit buffer */ STATIC unsigned hufts; /* track memory usage */ static long free_mem_ptr = (long)&end; /////////////////////////////////////////////////////////////////////////////// STATIC int inflate() { int e; /* last block flag */ int r; /* result code */ unsigned h; /* maximum struct huft's malloc'ed */ void *ptr; wp = bb = bk = 0; // inflate compressed blocks one by one do { hufts = 0; gzip_mark() { ptr = free_mem_ptr; }; if ((r = inflate_block(&e)) != 0) { gzip_release() { free_mem_ptr = ptr; }; return r; } gzip_release() { free_mem_ptr = ptr; }; if (hufts > h) h = hufts; } while (!e); /* Undo too much lookahead. The next read will be byte aligned so we * can discard unused bits in the last meaningful byte. */ while (bk >= 8) { bk -= 8; inptr--; } /* write the output window window[0..outcnt-1] to output_data, * update output_ptr/output_data, crc and bytes_out accordingly, and * reset outcnt to 0. */ flush_output(wp); /* return success */ return 0; } |
Gzip uses Lempel-Ziv coding (LZ77) to compress files. The compressed data format is specified in RFC 1951. inflate_block() will inflate compressed blocks, which can be treated as a bit sequence.
The data structure of each compressed block is outlined below:
BFINAL (1 bit) 0 - not the last block 1 - the last block BTYPE (2 bits) 00 - no compression remaining bits until the byte boundary; LEN (2 bytes); NLEN (2 bytes, the one's complement of LEN); data (LEN bytes); 01 - compressed with fixed Huffman codes { literal (7-9 bits, represent code 0..287, excluding 256); // See RFC 1951, table in Paragraph 3.2.6. length (0-5 bits if literal > 256, represent length 3..258); // See RFC 1951, 1st alphabet table in Paragraph 3.2.5. data (of literal bytes if literal < 256); distance (5 plus 0-13 extra bits if literal == 257..285, represent distance 1..32768); /* See RFC 1951, 2nd alphabet table in Paragraph 3.2.5, * but statement in Paragraph 3.2.6. */ /* Move backward "distance" bytes in the output stream, * and copy "length" bytes */ }* // can be of multiple instances literal (7 bits, all 0, literal == 256, means end of block); 10 - compressed with dynamic Huffman codes HLIT (5 bits, # of Literal/Length codes - 257, 257-286); HDIST (5 bits, # of Distance codes - 1, 1-32); HCLEN (4 bits, # of Code Length codes - 4, 4 - 19); Code Length sequence ((HCLEN+4)*3 bits) /* The following two alphabet tables will be decoded using * the Huffman decoding table which is generated from * the preceeding Code Length sequence. */ Literal/Length alphabet (HLIT+257 codes) Distance alphabet (HDIST+1 codes) // Decoding tables will be built from these alphpabet tables. /* The following is similar to that of fixed Huffman codes portion, * except that they use different decoding tables. */ { literal/length (variable length, depending on Literal/Length alphabet); data (of literal bytes if literal < 256); distance (variable length if literal == 257..285, depending on Distance alphabet); }* // can be of multiple instances literal (literal value 256, which means end of block); 11 - reserved (error) |
With the above data structure in mind and RFC 1951 by hand, it is not too hard to understand inflate_block(). Refer to related paragraphs in RFC 1951 for Huffman coding and alphabet table generation.
For more details, refer to linux/lib/inflate.c, gzip source code (many in-line comments) and related reference materials.
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Generated: 2007-01-26 17:58:03