freebsd-nq/usr.bin/gzip/unpack.c
Pedro F. Giffuni 1de7b4b805 various: general adoption of SPDX licensing ID tags.
Mainly focus on files that use BSD 2-Clause license, however the tool I
was using misidentified many licenses so this was mostly a manual - error
prone - task.

The Software Package Data Exchange (SPDX) group provides a specification
to make it easier for automated tools to detect and summarize well known
opensource licenses. We are gradually adopting the specification, noting
that the tags are considered only advisory and do not, in any way,
superceed or replace the license texts.

No functional change intended.
2017-11-27 15:37:16 +00:00

342 lines
10 KiB
C

/* $FreeBSD$ */
/* $NetBSD: unpack.c,v 1.3 2017/08/04 07:27:08 mrg Exp $ */
/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2009 Xin LI <delphij@FreeBSD.org>
* 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.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR 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 THE AUTHOR OR CONTRIBUTORS 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.
*
* $FreeBSD$
*/
/* This file is #included by gzip.c */
/*
* pack(1) file format:
*
* The first 7 bytes is the header:
* 00, 01 - Signature (US, RS), we already validated it earlier.
* 02..05 - Uncompressed size
* 06 - Level for the huffman tree (<=24)
*
* pack(1) will then store symbols (leaf) nodes count in each huffman
* tree levels, each level would consume 1 byte (See [1]).
*
* After the symbol count table, there is the symbol table, storing
* symbols represented by corresponding leaf node. EOB is not being
* explicitly transmitted (not necessary anyway) in the symbol table.
*
* Compressed data goes after the symbol table.
*
* NOTES
*
* [1] If we count EOB into the symbols, that would mean that we will
* have at most 256 symbols in the huffman tree. pack(1) rejects empty
* file and files that just repeats one character, which means that we
* will have at least 2 symbols. Therefore, pack(1) would reduce the
* last level symbol count by 2 which makes it a number in
* range [0..254], so all levels' symbol count would fit into 1 byte.
*/
#define PACK_HEADER_LENGTH 7
#define HTREE_MAXLEVEL 24
/*
* unpack descriptor
*
* Represent the huffman tree in a similar way that pack(1) would
* store in a packed file. We store all symbols in a linear table,
* and store pointers to each level's first symbol. In addition to
* that, maintain two counts for each level: inner nodes count and
* leaf nodes count.
*/
typedef struct {
int symbol_size; /* Size of the symbol table */
int treelevels; /* Levels for the huffman tree */
int *symbolsin; /* Table of leaf symbols count in each
* level */
int *inodesin; /* Table of internal nodes count in
* each level */
char *symbol; /* The symbol table */
char *symbol_eob; /* Pointer to the EOB symbol */
char **tree; /* Decoding huffman tree (pointers to
* first symbol of each tree level */
off_t uncompressed_size; /* Uncompressed size */
FILE *fpIn; /* Input stream */
FILE *fpOut; /* Output stream */
} unpack_descriptor_t;
/*
* Release resource allocated to an unpack descriptor.
*
* Caller is responsible to make sure that all of these pointers are
* initialized (in our case, they all point to valid memory block).
* We don't zero out pointers here because nobody else would ever
* reference the memory block without scrubbing them.
*/
static void
unpack_descriptor_fini(unpack_descriptor_t *unpackd)
{
free(unpackd->symbolsin);
free(unpackd->inodesin);
free(unpackd->symbol);
free(unpackd->tree);
fclose(unpackd->fpIn);
fclose(unpackd->fpOut);
}
/*
* Recursively fill the internal node count table
*/
static void
unpackd_fill_inodesin(const unpack_descriptor_t *unpackd, int level)
{
/*
* The internal nodes would be 1/2 of total internal nodes and
* leaf nodes in the next level. For the last level there
* would be no internal node by definition.
*/
if (level < unpackd->treelevels) {
unpackd_fill_inodesin(unpackd, level + 1);
unpackd->inodesin[level] = (unpackd->inodesin[level + 1] +
unpackd->symbolsin[level + 1]) / 2;
} else
unpackd->inodesin[level] = 0;
}
/*
* Update counter for accepted bytes
*/
static void
accepted_bytes(off_t *bytes_in, off_t newbytes)
{
if (bytes_in != NULL)
(*bytes_in) += newbytes;
}
/*
* Read file header and construct the tree. Also, prepare the buffered I/O
* for decode routine.
*
* Return value is uncompressed size.
*/
static void
unpack_parse_header(int in, int out, char *pre, size_t prelen, off_t *bytes_in,
unpack_descriptor_t *unpackd)
{
unsigned char hdr[PACK_HEADER_LENGTH]; /* buffer for header */
ssize_t bytesread; /* Bytes read from the file */
int i, j, thisbyte;
if (prelen > sizeof hdr)
maybe_err("prelen too long");
/* Prepend the header buffer if we already read some data */
if (prelen != 0)
memcpy(hdr, pre, prelen);
/* Read in and fill the rest bytes of header */
bytesread = read(in, hdr + prelen, PACK_HEADER_LENGTH - prelen);
if (bytesread < 0)
maybe_err("Error reading pack header");
infile_newdata(bytesread);
accepted_bytes(bytes_in, PACK_HEADER_LENGTH);
/* Obtain uncompressed length (bytes 2,3,4,5) */
unpackd->uncompressed_size = 0;
for (i = 2; i <= 5; i++) {
unpackd->uncompressed_size <<= 8;
unpackd->uncompressed_size |= hdr[i];
}
/* Get the levels of the tree */
unpackd->treelevels = hdr[6];
if (unpackd->treelevels > HTREE_MAXLEVEL || unpackd->treelevels < 1)
maybe_errx("Huffman tree has insane levels");
/* Let libc take care for buffering from now on */
if ((unpackd->fpIn = fdopen(in, "r")) == NULL)
maybe_err("Can not fdopen() input stream");
if ((unpackd->fpOut = fdopen(out, "w")) == NULL)
maybe_err("Can not fdopen() output stream");
/* Allocate for the tables of bounds and the tree itself */
unpackd->inodesin =
calloc(unpackd->treelevels, sizeof(*(unpackd->inodesin)));
unpackd->symbolsin =
calloc(unpackd->treelevels, sizeof(*(unpackd->symbolsin)));
unpackd->tree =
calloc(unpackd->treelevels, (sizeof(*(unpackd->tree))));
if (unpackd->inodesin == NULL || unpackd->symbolsin == NULL ||
unpackd->tree == NULL)
maybe_err("calloc");
/* We count from 0 so adjust to match array upper bound */
unpackd->treelevels--;
/* Read the levels symbol count table and calculate total */
unpackd->symbol_size = 1; /* EOB */
for (i = 0; i <= unpackd->treelevels; i++) {
if ((thisbyte = fgetc(unpackd->fpIn)) == EOF)
maybe_err("File appears to be truncated");
unpackd->symbolsin[i] = (unsigned char)thisbyte;
unpackd->symbol_size += unpackd->symbolsin[i];
}
accepted_bytes(bytes_in, unpackd->treelevels);
if (unpackd->symbol_size > 256)
maybe_errx("Bad symbol table");
infile_newdata(unpackd->treelevels);
/* Allocate for the symbol table, point symbol_eob at the beginning */
unpackd->symbol_eob = unpackd->symbol = calloc(1, unpackd->symbol_size);
if (unpackd->symbol == NULL)
maybe_err("calloc");
/*
* Read in the symbol table, which contain [2, 256] symbols.
* In order to fit the count in one byte, pack(1) would offset
* it by reducing 2 from the actual number from the last level.
*
* We adjust the last level's symbol count by 1 here, because
* the EOB symbol is not being transmitted explicitly. Another
* adjustment would be done later afterward.
*/
unpackd->symbolsin[unpackd->treelevels]++;
for (i = 0; i <= unpackd->treelevels; i++) {
unpackd->tree[i] = unpackd->symbol_eob;
for (j = 0; j < unpackd->symbolsin[i]; j++) {
if ((thisbyte = fgetc(unpackd->fpIn)) == EOF)
maybe_errx("Symbol table truncated");
*unpackd->symbol_eob++ = (char)thisbyte;
}
infile_newdata(unpackd->symbolsin[i]);
accepted_bytes(bytes_in, unpackd->symbolsin[i]);
}
/* Now, take account for the EOB symbol as well */
unpackd->symbolsin[unpackd->treelevels]++;
/*
* The symbolsin table has been constructed now.
* Calculate the internal nodes count table based on it.
*/
unpackd_fill_inodesin(unpackd, 0);
}
/*
* Decode huffman stream, based on the huffman tree.
*/
static void
unpack_decode(const unpack_descriptor_t *unpackd, off_t *bytes_in)
{
int thislevel, thiscode, thisbyte, inlevelindex;
int i;
off_t bytes_out = 0;
const char *thissymbol; /* The symbol pointer decoded from stream */
/*
* Decode huffman. Fetch every bytes from the file, get it
* into 'thiscode' bit-by-bit, then output the symbol we got
* when one has been found.
*
* Assumption: sizeof(int) > ((max tree levels + 1) / 8).
* bad things could happen if not.
*/
thislevel = 0;
thiscode = thisbyte = 0;
while ((thisbyte = fgetc(unpackd->fpIn)) != EOF) {
accepted_bytes(bytes_in, 1);
infile_newdata(1);
check_siginfo();
/*
* Split one bit from thisbyte, from highest to lowest,
* feed the bit into thiscode, until we got a symbol from
* the tree.
*/
for (i = 7; i >= 0; i--) {
thiscode = (thiscode << 1) | ((thisbyte >> i) & 1);
/* Did we got a symbol? (referencing leaf node) */
if (thiscode >= unpackd->inodesin[thislevel]) {
inlevelindex =
thiscode - unpackd->inodesin[thislevel];
if (inlevelindex > unpackd->symbolsin[thislevel])
maybe_errx("File corrupt");
thissymbol =
&(unpackd->tree[thislevel][inlevelindex]);
if ((thissymbol == unpackd->symbol_eob) &&
(bytes_out == unpackd->uncompressed_size))
goto finished;
fputc((*thissymbol), unpackd->fpOut);
bytes_out++;
/* Prepare for next input */
thislevel = 0; thiscode = 0;
} else {
thislevel++;
if (thislevel > unpackd->treelevels)
maybe_errx("File corrupt");
}
}
}
finished:
if (bytes_out != unpackd->uncompressed_size)
maybe_errx("Premature EOF");
}
/* Handler for pack(1)'ed file */
static off_t
unpack(int in, int out, char *pre, size_t prelen, off_t *bytes_in)
{
unpack_descriptor_t unpackd;
in = dup(in);
if (in == -1)
maybe_err("dup");
out = dup(out);
if (out == -1)
maybe_err("dup");
unpack_parse_header(in, out, pre, prelen, bytes_in, &unpackd);
unpack_decode(&unpackd, bytes_in);
unpack_descriptor_fini(&unpackd);
/* If we reached here, the unpack was successful */
return (unpackd.uncompressed_size);
}