File: | jdk/src/java.base/share/native/libjli/parse_manifest.c |
Warning: | line 603, column 10 Although the value stored to 'rc' is used in the enclosing expression, the value is never actually read from 'rc' |
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1 | /* |
2 | * Copyright (c) 2003, 2019, Oracle and/or its affiliates. All rights reserved. |
3 | * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. |
4 | * |
5 | * This code is free software; you can redistribute it and/or modify it |
6 | * under the terms of the GNU General Public License version 2 only, as |
7 | * published by the Free Software Foundation. Oracle designates this |
8 | * particular file as subject to the "Classpath" exception as provided |
9 | * by Oracle in the LICENSE file that accompanied this code. |
10 | * |
11 | * This code is distributed in the hope that it will be useful, but WITHOUT |
12 | * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or |
13 | * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License |
14 | * version 2 for more details (a copy is included in the LICENSE file that |
15 | * accompanied this code). |
16 | * |
17 | * You should have received a copy of the GNU General Public License version |
18 | * 2 along with this work; if not, write to the Free Software Foundation, |
19 | * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. |
20 | * |
21 | * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA |
22 | * or visit www.oracle.com if you need additional information or have any |
23 | * questions. |
24 | */ |
25 | |
26 | #include <sys/types.h> |
27 | #include <sys/stat.h> |
28 | #include <fcntl.h> |
29 | #include <stdio.h> |
30 | #include <stdlib.h> |
31 | #include <string.h> |
32 | #include "jni.h" |
33 | #include "jli_util.h" |
34 | |
35 | #include <zlib.h> |
36 | #include "manifest_info.h" |
37 | |
38 | static char *manifest; |
39 | |
40 | static const char *manifest_name = "META-INF/MANIFEST.MF"; |
41 | |
42 | /* |
43 | * Inflate the manifest file (or any file for that matter). |
44 | * |
45 | * fd: File descriptor of the jar file. |
46 | * entry: Contains the information necessary to perform the inflation |
47 | * (the compressed and uncompressed sizes and the offset in |
48 | * the file where the compressed data is located). |
49 | * size_out: Returns the size of the inflated file. |
50 | * |
51 | * Upon success, it returns a pointer to a NUL-terminated malloc'd buffer |
52 | * containing the inflated manifest file. When the caller is done with it, |
53 | * this buffer should be released by a call to free(). Upon failure, |
54 | * returns NULL. |
55 | */ |
56 | static char * |
57 | inflate_file(int fd, zentry *entry, int *size_out) |
58 | { |
59 | char *in; |
60 | char *out; |
61 | z_stream zs; |
62 | |
63 | if (entry->csize == (size_t) -1 || entry->isize == (size_t) -1 ) |
64 | return (NULL((void*)0)); |
65 | if (JLI_Lseeklseek64(fd, entry->offset, SEEK_SET0) < (jlong)0) |
66 | return (NULL((void*)0)); |
67 | if ((in = malloc(entry->csize + 1)) == NULL((void*)0)) |
68 | return (NULL((void*)0)); |
69 | if ((size_t)(read(fd, in, (unsigned int)entry->csize)) != entry->csize) { |
70 | free(in); |
71 | return (NULL((void*)0)); |
72 | } |
73 | if (entry->how == STORED0) { |
74 | *(char *)((size_t)in + entry->csize) = '\0'; |
75 | if (size_out) { |
76 | *size_out = (int)entry->csize; |
77 | } |
78 | return (in); |
79 | } else if (entry->how == DEFLATED8) { |
80 | zs.zalloc = (alloc_func)Z_NULL0; |
81 | zs.zfree = (free_func)Z_NULL0; |
82 | zs.opaque = (voidpf)Z_NULL0; |
83 | zs.next_in = (Byte*)in; |
84 | zs.avail_in = (uInt)entry->csize; |
85 | if (inflateInit2(&zs, -MAX_WBITS)inflateInit2_((&zs), (-15), "1.2.11", (int)sizeof(z_stream )) < 0) { |
86 | free(in); |
87 | return (NULL((void*)0)); |
88 | } |
89 | if ((out = malloc(entry->isize + 1)) == NULL((void*)0)) { |
90 | free(in); |
91 | return (NULL((void*)0)); |
92 | } |
93 | zs.next_out = (Byte*)out; |
94 | zs.avail_out = (uInt)entry->isize; |
95 | if (inflate(&zs, Z_PARTIAL_FLUSH1) < 0) { |
96 | free(in); |
97 | free(out); |
98 | return (NULL((void*)0)); |
99 | } |
100 | *(char *)((size_t)out + entry->isize) = '\0'; |
101 | free(in); |
102 | if (inflateEnd(&zs) < 0) { |
103 | free(out); |
104 | return (NULL((void*)0)); |
105 | } |
106 | if (size_out) { |
107 | *size_out = (int)entry->isize; |
108 | } |
109 | return (out); |
110 | } |
111 | free(in); |
112 | return (NULL((void*)0)); |
113 | } |
114 | |
115 | /* |
116 | * Implementation notes: |
117 | * |
118 | * This is a zip format reader for seekable files, that tolerates |
119 | * leading and trailing garbage, and tolerates having had internal |
120 | * offsets adjusted for leading garbage (as with Info-Zip's zip -A). |
121 | * |
122 | * We find the end header by scanning backwards from the end of the |
123 | * file for the end signature. This may fail in the presence of |
124 | * trailing garbage or a ZIP file comment that contains binary data. |
125 | * Similarly, the ZIP64 end header may need to be located by scanning |
126 | * backwards from the end header. It may be misidentified, but this |
127 | * is very unlikely to happen in practice without adversarial input. |
128 | * |
129 | * The zip file format is documented at: |
130 | * https://www.pkware.com/documents/casestudies/APPNOTE.TXT |
131 | * |
132 | * TODO: more informative error messages |
133 | */ |
134 | |
135 | /** Reads count bytes from fd at position pos into given buffer. */ |
136 | static jboolean |
137 | readAt(int fd, jlong pos, unsigned int count, void *buf) { |
138 | return (pos >= 0 |
139 | && JLI_Lseeklseek64(fd, pos, SEEK_SET0) == pos |
140 | && read(fd, buf, count) == (jlong) count); |
141 | } |
142 | |
143 | |
144 | /* |
145 | * Tells whether given header values (obtained from either ZIP64 or |
146 | * non-ZIP64 header) appear to be correct, by checking the first LOC |
147 | * and CEN headers. |
148 | */ |
149 | static jboolean |
150 | is_valid_end_header(int fd, jlong endpos, |
151 | jlong censiz, jlong cenoff, jlong entries) { |
152 | Byte cenhdr[CENHDR46]; |
153 | Byte lochdr[LOCHDR30]; |
154 | // Expected offset of the first central directory header |
155 | jlong censtart = endpos - censiz; |
156 | // Expected position within the file that offsets are relative to |
157 | jlong base_offset = endpos - (censiz + cenoff); |
158 | return censtart >= 0 && cenoff >= 0 && |
159 | (censiz == 0 || |
160 | // Validate first CEN and LOC header signatures. |
161 | // Central directory must come directly before the end header. |
162 | (readAt(fd, censtart, CENHDR46, cenhdr) |
163 | && CENSIG_AT(cenhdr)(((cenhdr)[0] == 'P') & ((cenhdr)[1] == 'K') & ((cenhdr )[2] == 1) & ((cenhdr)[3] == 2)) |
164 | && readAt(fd, base_offset + CENOFF(cenhdr)((((((unsigned char *)(cenhdr))[42]) | ((((unsigned char *)(cenhdr ))[42 +1]) << 8)) | (((((unsigned char *)(cenhdr))[42 + 2]) | ((((unsigned char *)(cenhdr))[42 +2 +1]) << 8)) << 16)) &0xffffffffUL), LOCHDR30, lochdr) |
165 | && LOCSIG_AT(lochdr)(((lochdr)[0] == 'P') & ((lochdr)[1] == 'K') & ((lochdr )[2] == 3) & ((lochdr)[3] == 4)) |
166 | && CENNAM(cenhdr)((((unsigned char *)(cenhdr))[28]) | ((((unsigned char *)(cenhdr ))[28 +1]) << 8)) == LOCNAM(lochdr)((((unsigned char *)(lochdr))[26]) | ((((unsigned char *)(lochdr ))[26 +1]) << 8)))); |
167 | } |
168 | |
169 | /* |
170 | * Tells whether p appears to be pointing at a valid ZIP64 end header. |
171 | * Values censiz, cenoff, and entries are the corresponding values |
172 | * from the non-ZIP64 end header. We perform extra checks to avoid |
173 | * misidentifying data from the last entry as a ZIP64 end header. |
174 | */ |
175 | static jboolean |
176 | is_zip64_endhdr(int fd, const Byte *p, jlong end64pos, |
177 | jlong censiz, jlong cenoff, jlong entries) { |
178 | if (ZIP64_ENDSIG_AT(p)(((p)[0] == 'P') & ((p)[1] == 'K') & ((p)[2] == 6) & ((p)[3] == 6))) { |
179 | jlong censiz64 = ZIP64_ENDSIZ(p)(((jlong)((((((unsigned char *)(p))[40]) | ((((unsigned char * )(p))[40 +1]) << 8)) | (((((unsigned char *)(p))[40 +2] ) | ((((unsigned char *)(p))[40 +2 +1]) << 8)) << 16)) &0xffffffffUL)) | (((jlong)((((((unsigned char *)(p ))[40 +4]) | ((((unsigned char *)(p))[40 +4 +1]) << 8)) | (((((unsigned char *)(p))[40 +4 +2]) | ((((unsigned char * )(p))[40 +4 +2 +1]) << 8)) << 16)) &0xffffffffUL )) << 32)); |
180 | jlong cenoff64 = ZIP64_ENDOFF(p)(((jlong)((((((unsigned char *)(p))[48]) | ((((unsigned char * )(p))[48 +1]) << 8)) | (((((unsigned char *)(p))[48 +2] ) | ((((unsigned char *)(p))[48 +2 +1]) << 8)) << 16)) &0xffffffffUL)) | (((jlong)((((((unsigned char *)(p ))[48 +4]) | ((((unsigned char *)(p))[48 +4 +1]) << 8)) | (((((unsigned char *)(p))[48 +4 +2]) | ((((unsigned char * )(p))[48 +4 +2 +1]) << 8)) << 16)) &0xffffffffUL )) << 32)); |
181 | jlong entries64 = ZIP64_ENDTOT(p)(((jlong)((((((unsigned char *)(p))[32]) | ((((unsigned char * )(p))[32 +1]) << 8)) | (((((unsigned char *)(p))[32 +2] ) | ((((unsigned char *)(p))[32 +2 +1]) << 8)) << 16)) &0xffffffffUL)) | (((jlong)((((((unsigned char *)(p ))[32 +4]) | ((((unsigned char *)(p))[32 +4 +1]) << 8)) | (((((unsigned char *)(p))[32 +4 +2]) | ((((unsigned char * )(p))[32 +4 +2 +1]) << 8)) << 16)) &0xffffffffUL )) << 32)); |
182 | return (censiz64 == censiz || censiz == ZIP64_MAGICVAL0xffffffffLL) |
183 | && (cenoff64 == cenoff || cenoff == ZIP64_MAGICVAL0xffffffffLL) |
184 | && (entries64 == entries || entries == ZIP64_MAGICCOUNT0xffff) |
185 | && is_valid_end_header(fd, end64pos, censiz64, cenoff64, entries64); |
186 | } |
187 | return JNI_FALSE0; |
188 | } |
189 | |
190 | /* |
191 | * Given a non-ZIP64 end header located at endhdr and endpos, look for |
192 | * an adjacent ZIP64 end header, finding the base offset and censtart |
193 | * from the ZIP64 header if available, else from the non-ZIP64 header. |
194 | * @return 0 if successful, -1 in case of failure |
195 | */ |
196 | static int |
197 | find_positions64(int fd, const Byte * const endhdr, const jlong endpos, |
198 | jlong* base_offset, jlong* censtart) |
199 | { |
200 | jlong censiz = ENDSIZ(endhdr)((((((unsigned char *)(endhdr))[12]) | ((((unsigned char *)(endhdr ))[12 +1]) << 8)) | (((((unsigned char *)(endhdr))[12 + 2]) | ((((unsigned char *)(endhdr))[12 +2 +1]) << 8)) << 16)) &0xffffffffUL); |
201 | jlong cenoff = ENDOFF(endhdr)((((((unsigned char *)(endhdr))[16]) | ((((unsigned char *)(endhdr ))[16 +1]) << 8)) | (((((unsigned char *)(endhdr))[16 + 2]) | ((((unsigned char *)(endhdr))[16 +2 +1]) << 8)) << 16)) &0xffffffffUL); |
202 | jlong entries = ENDTOT(endhdr)((((unsigned char *)(endhdr))[10]) | ((((unsigned char *)(endhdr ))[10 +1]) << 8)); |
203 | jlong end64pos; |
204 | Byte buf[ZIP64_ENDHDR56 + ZIP64_LOCHDR20]; |
205 | if (censiz + cenoff != endpos |
206 | && (end64pos = endpos - sizeof(buf)) >= (jlong)0 |
207 | && readAt(fd, end64pos, sizeof(buf), buf) |
208 | && ZIP64_LOCSIG_AT(buf + ZIP64_ENDHDR)(((buf + 56)[0] == 'P') & ((buf + 56)[1] == 'K') & (( buf + 56)[2] == 6) & ((buf + 56)[3] == 7)) |
209 | && (jlong) ZIP64_LOCDSK(buf + ZIP64_ENDHDR)((((((unsigned char *)(buf + 56))[4]) | ((((unsigned char *)( buf + 56))[4 +1]) << 8)) | (((((unsigned char *)(buf + 56 ))[4 +2]) | ((((unsigned char *)(buf + 56))[4 +2 +1]) << 8)) << 16)) &0xffffffffUL) == ENDDSK(endhdr)((((unsigned char *)(endhdr))[6]) | ((((unsigned char *)(endhdr ))[6 +1]) << 8)) |
210 | && (is_zip64_endhdr(fd, buf, end64pos, censiz, cenoff, entries) |
211 | || // A variable sized "zip64 extensible data sector" ? |
212 | ((end64pos = ZIP64_LOCOFF(buf + ZIP64_ENDHDR)(((jlong)((((((unsigned char *)(buf + 56))[8]) | ((((unsigned char *)(buf + 56))[8 +1]) << 8)) | (((((unsigned char * )(buf + 56))[8 +2]) | ((((unsigned char *)(buf + 56))[8 +2 +1 ]) << 8)) << 16)) &0xffffffffUL)) | (((jlong) ((((((unsigned char *)(buf + 56))[8 +4]) | ((((unsigned char * )(buf + 56))[8 +4 +1]) << 8)) | (((((unsigned char *)(buf + 56))[8 +4 +2]) | ((((unsigned char *)(buf + 56))[8 +4 +2 + 1]) << 8)) << 16)) &0xffffffffUL)) << 32 ))) >= (jlong)0 |
213 | && readAt(fd, end64pos, ZIP64_ENDHDR56, buf) |
214 | && is_zip64_endhdr(fd, buf, end64pos, censiz, cenoff, entries))) |
215 | ) { |
216 | *censtart = end64pos - ZIP64_ENDSIZ(buf)(((jlong)((((((unsigned char *)(buf))[40]) | ((((unsigned char *)(buf))[40 +1]) << 8)) | (((((unsigned char *)(buf))[ 40 +2]) | ((((unsigned char *)(buf))[40 +2 +1]) << 8)) << 16)) &0xffffffffUL)) | (((jlong)((((((unsigned char *)(buf ))[40 +4]) | ((((unsigned char *)(buf))[40 +4 +1]) << 8 )) | (((((unsigned char *)(buf))[40 +4 +2]) | ((((unsigned char *)(buf))[40 +4 +2 +1]) << 8)) << 16)) &0xffffffffUL )) << 32)); |
217 | *base_offset = *censtart - ZIP64_ENDOFF(buf)(((jlong)((((((unsigned char *)(buf))[48]) | ((((unsigned char *)(buf))[48 +1]) << 8)) | (((((unsigned char *)(buf))[ 48 +2]) | ((((unsigned char *)(buf))[48 +2 +1]) << 8)) << 16)) &0xffffffffUL)) | (((jlong)((((((unsigned char *)(buf ))[48 +4]) | ((((unsigned char *)(buf))[48 +4 +1]) << 8 )) | (((((unsigned char *)(buf))[48 +4 +2]) | ((((unsigned char *)(buf))[48 +4 +2 +1]) << 8)) << 16)) &0xffffffffUL )) << 32)); |
218 | } else { |
219 | if (!is_valid_end_header(fd, endpos, censiz, cenoff, entries)) |
220 | return -1; |
221 | *censtart = endpos - censiz; |
222 | *base_offset = *censtart - cenoff; |
223 | } |
224 | return 0; |
225 | } |
226 | |
227 | /* |
228 | * Finds the base offset and censtart of the zip file. |
229 | * |
230 | * @param fd file descriptor of the jar file |
231 | * @param eb scratch buffer |
232 | * @return 0 if successful, -1 in case of failure |
233 | */ |
234 | static int |
235 | find_positions(int fd, Byte *eb, jlong* base_offset, jlong* censtart) |
236 | { |
237 | jlong len; |
238 | jlong pos; |
239 | jlong flen; |
240 | int bytes; |
241 | Byte *cp; |
242 | Byte *endpos; |
243 | Byte *buffer; |
244 | |
245 | /* |
246 | * 99.44% (or more) of the time, there will be no comment at the |
247 | * end of the zip file. Try reading just enough to read the END |
248 | * record from the end of the file, at this time we should also |
249 | * check to see if we have a ZIP64 archive. |
250 | */ |
251 | if ((pos = JLI_Lseeklseek64(fd, -ENDHDR22, SEEK_END2)) < (jlong)0) |
252 | return (-1); |
253 | if (read(fd, eb, ENDHDR22) < 0) |
254 | return (-1); |
255 | if (ENDSIG_AT(eb)(((eb)[0] == 'P') & ((eb)[1] == 'K') & ((eb)[2] == 5) & ((eb)[3] == 6))) { |
256 | return find_positions64(fd, eb, pos, base_offset, censtart); |
257 | } |
258 | |
259 | /* |
260 | * Shucky-Darn,... There is a comment at the end of the zip file. |
261 | * |
262 | * Allocate and fill a buffer with enough of the zip file |
263 | * to meet the specification for a maximal comment length. |
264 | */ |
265 | if ((flen = JLI_Lseeklseek64(fd, 0, SEEK_END2)) < (jlong)0) |
266 | return (-1); |
267 | len = (flen < END_MAXLEN(0xFFFF + 22)) ? flen : END_MAXLEN(0xFFFF + 22); |
268 | if (JLI_Lseeklseek64(fd, -len, SEEK_END2) < (jlong)0) |
269 | return (-1); |
270 | if ((buffer = malloc(END_MAXLEN(0xFFFF + 22))) == NULL((void*)0)) |
271 | return (-1); |
272 | |
273 | /* |
274 | * read() on windows takes an unsigned int for count. Casting len |
275 | * to an unsigned int here is safe since it is guaranteed to be |
276 | * less than END_MAXLEN. |
277 | */ |
278 | if ((bytes = read(fd, buffer, (unsigned int)len)) < 0) { |
279 | free(buffer); |
280 | return (-1); |
281 | } |
282 | |
283 | /* |
284 | * Search backwards from the end of file stopping when the END header |
285 | * signature is found. |
286 | */ |
287 | endpos = &buffer[bytes]; |
288 | for (cp = &buffer[bytes - ENDHDR22]; cp >= &buffer[0]; cp--) |
289 | if (ENDSIG_AT(cp)(((cp)[0] == 'P') & ((cp)[1] == 'K') & ((cp)[2] == 5) & ((cp)[3] == 6)) && (cp + ENDHDR22 + ENDCOM(cp)((((unsigned char *)(cp))[20]) | ((((unsigned char *)(cp))[20 +1]) << 8)) == endpos)) { |
290 | (void) memcpy(eb, cp, ENDHDR22); |
291 | free(buffer); |
292 | pos = flen - (endpos - cp); |
293 | return find_positions64(fd, eb, pos, base_offset, censtart); |
294 | } |
295 | free(buffer); |
296 | return (-1); |
297 | } |
298 | |
299 | #define BUFSIZE(3 * 65536 + 46 + 4) (3 * 65536 + CENHDR46 + SIGSIZ4) |
300 | #define MINREAD1024 1024 |
301 | |
302 | /* |
303 | * Locate the manifest file with the zip/jar file. |
304 | * |
305 | * fd: File descriptor of the jar file. |
306 | * entry: To be populated with the information necessary to perform |
307 | * the inflation (the compressed and uncompressed sizes and |
308 | * the offset in the file where the compressed data is located). |
309 | * |
310 | * Returns zero upon success. Returns a negative value upon failure. |
311 | * |
312 | * The buffer for reading the Central Directory if the zip/jar file needs |
313 | * to be large enough to accommodate the largest possible single record |
314 | * and the signature of the next record which is: |
315 | * |
316 | * 3*2**16 + CENHDR + SIGSIZ |
317 | * |
318 | * Each of the three variable sized fields (name, comment and extension) |
319 | * has a maximum possible size of 64k. |
320 | * |
321 | * Typically, only a small bit of this buffer is used with bytes shuffled |
322 | * down to the beginning of the buffer. It is one thing to allocate such |
323 | * a large buffer and another thing to actually start faulting it in. |
324 | * |
325 | * In most cases, all that needs to be read are the first two entries in |
326 | * a typical jar file (META-INF and META-INF/MANIFEST.MF). Keep this factoid |
327 | * in mind when optimizing this code. |
328 | */ |
329 | static int |
330 | find_file(int fd, zentry *entry, const char *file_name) |
331 | { |
332 | int bytes; |
333 | int res; |
334 | int entry_size; |
335 | int read_size; |
336 | |
337 | /* |
338 | * The (imaginary) position within the file relative to which |
339 | * offsets within the zip file refer. This is usually the |
340 | * location of the first local header (the start of the zip data) |
341 | * (which in turn is usually 0), but if the zip file has content |
342 | * prepended, then it will be either 0 or the length of the |
343 | * prepended content, depending on whether or not internal offsets |
344 | * have been adjusted (via e.g. zip -A). May be negative if |
345 | * content is prepended, zip -A is run, then the prefix is |
346 | * detached! |
347 | */ |
348 | jlong base_offset; |
349 | |
350 | /** The position within the file of the start of the central directory. */ |
351 | jlong censtart; |
352 | |
353 | Byte *p; |
354 | Byte *bp; |
355 | Byte *buffer; |
356 | Byte locbuf[LOCHDR30]; |
357 | |
358 | if ((buffer = (Byte*)malloc(BUFSIZE(3 * 65536 + 46 + 4))) == NULL((void*)0)) { |
359 | return(-1); |
360 | } |
361 | |
362 | bp = buffer; |
363 | |
364 | if (find_positions(fd, bp, &base_offset, &censtart) == -1) { |
365 | free(buffer); |
366 | return -1; |
367 | } |
368 | if (JLI_Lseeklseek64(fd, censtart, SEEK_SET0) < (jlong) 0) { |
369 | free(buffer); |
370 | return -1; |
371 | } |
372 | |
373 | if ((bytes = read(fd, bp, MINREAD1024)) < 0) { |
374 | free(buffer); |
375 | return (-1); |
376 | } |
377 | p = bp; |
378 | /* |
379 | * Loop through the Central Directory Headers. Note that a valid zip/jar |
380 | * must have an ENDHDR (with ENDSIG) after the Central Directory. |
381 | */ |
382 | while (CENSIG_AT(p)(((p)[0] == 'P') & ((p)[1] == 'K') & ((p)[2] == 1) & ((p)[3] == 2))) { |
383 | |
384 | /* |
385 | * If a complete header isn't in the buffer, shift the contents |
386 | * of the buffer down and refill the buffer. Note that the check |
387 | * for "bytes < CENHDR" must be made before the test for the entire |
388 | * size of the header, because if bytes is less than CENHDR, the |
389 | * actual size of the header can't be determined. The addition of |
390 | * SIGSIZ guarantees that the next signature is also in the buffer |
391 | * for proper loop termination. |
392 | */ |
393 | if (bytes < CENHDR46) { |
394 | p = memmove(bp, p, bytes); |
395 | if ((res = read(fd, bp + bytes, MINREAD1024)) <= 0) { |
396 | free(buffer); |
397 | return (-1); |
398 | } |
399 | bytes += res; |
400 | } |
401 | entry_size = CENHDR46 + CENNAM(p)((((unsigned char *)(p))[28]) | ((((unsigned char *)(p))[28 + 1]) << 8)) + CENEXT(p)((((unsigned char *)(p))[30]) | ((((unsigned char *)(p))[30 + 1]) << 8)) + CENCOM(p)((((unsigned char *)(p))[32]) | ((((unsigned char *)(p))[32 + 1]) << 8)); |
402 | if (bytes < entry_size + SIGSIZ4) { |
403 | if (p != bp) |
404 | p = memmove(bp, p, bytes); |
405 | read_size = entry_size - bytes + SIGSIZ4; |
406 | read_size = (read_size < MINREAD1024) ? MINREAD1024 : read_size; |
407 | if ((res = read(fd, bp + bytes, read_size)) <= 0) { |
408 | free(buffer); |
409 | return (-1); |
410 | } |
411 | bytes += res; |
412 | } |
413 | |
414 | /* |
415 | * Check if the name is the droid we are looking for; the jar file |
416 | * manifest. If so, build the entry record from the data found in |
417 | * the header located and return success. |
418 | */ |
419 | if ((size_t)CENNAM(p)((((unsigned char *)(p))[28]) | ((((unsigned char *)(p))[28 + 1]) << 8)) == JLI_StrLen(file_name)strlen((file_name)) && |
420 | memcmp((p + CENHDR46), file_name, JLI_StrLen(file_name)strlen((file_name))) == 0) { |
421 | if (JLI_Lseeklseek64(fd, base_offset + CENOFF(p)((((((unsigned char *)(p))[42]) | ((((unsigned char *)(p))[42 +1]) << 8)) | (((((unsigned char *)(p))[42 +2]) | (((( unsigned char *)(p))[42 +2 +1]) << 8)) << 16)) & 0xffffffffUL), SEEK_SET0) < (jlong)0) { |
422 | free(buffer); |
423 | return (-1); |
424 | } |
425 | if (read(fd, locbuf, LOCHDR30) < 0) { |
426 | free(buffer); |
427 | return (-1); |
428 | } |
429 | if (!LOCSIG_AT(locbuf)(((locbuf)[0] == 'P') & ((locbuf)[1] == 'K') & ((locbuf )[2] == 3) & ((locbuf)[3] == 4))) { |
430 | free(buffer); |
431 | return (-1); |
432 | } |
433 | entry->isize = CENLEN(p)((((((unsigned char *)(p))[24]) | ((((unsigned char *)(p))[24 +1]) << 8)) | (((((unsigned char *)(p))[24 +2]) | (((( unsigned char *)(p))[24 +2 +1]) << 8)) << 16)) & 0xffffffffUL); |
434 | entry->csize = CENSIZ(p)((((((unsigned char *)(p))[20]) | ((((unsigned char *)(p))[20 +1]) << 8)) | (((((unsigned char *)(p))[20 +2]) | (((( unsigned char *)(p))[20 +2 +1]) << 8)) << 16)) & 0xffffffffUL); |
435 | entry->offset = base_offset + CENOFF(p)((((((unsigned char *)(p))[42]) | ((((unsigned char *)(p))[42 +1]) << 8)) | (((((unsigned char *)(p))[42 +2]) | (((( unsigned char *)(p))[42 +2 +1]) << 8)) << 16)) & 0xffffffffUL) + LOCHDR30 + |
436 | LOCNAM(locbuf)((((unsigned char *)(locbuf))[26]) | ((((unsigned char *)(locbuf ))[26 +1]) << 8)) + LOCEXT(locbuf)((((unsigned char *)(locbuf))[28]) | ((((unsigned char *)(locbuf ))[28 +1]) << 8)); |
437 | entry->how = CENHOW(p)((((unsigned char *)(p))[10]) | ((((unsigned char *)(p))[10 + 1]) << 8)); |
438 | free(buffer); |
439 | return (0); |
440 | } |
441 | |
442 | /* |
443 | * Point to the next entry and decrement the count of valid remaining |
444 | * bytes. |
445 | */ |
446 | bytes -= entry_size; |
447 | p += entry_size; |
448 | } |
449 | free(buffer); |
450 | return (-1); /* Fell off the end the loop without a Manifest */ |
451 | } |
452 | |
453 | /* |
454 | * Parse a Manifest file header entry into a distinct "name" and "value". |
455 | * Continuation lines are joined into a single "value". The documented |
456 | * syntax for a header entry is: |
457 | * |
458 | * header: name ":" value |
459 | * |
460 | * name: alphanum *headerchar |
461 | * |
462 | * value: SPACE *otherchar newline *continuation |
463 | * |
464 | * continuation: SPACE *otherchar newline |
465 | * |
466 | * newline: CR LF | LF | CR (not followed by LF) |
467 | * |
468 | * alphanum: {"A"-"Z"} | {"a"-"z"} | {"0"-"9"} |
469 | * |
470 | * headerchar: alphanum | "-" | "_" |
471 | * |
472 | * otherchar: any UTF-8 character except NUL, CR and LF |
473 | * |
474 | * Note that a manifest file may be composed of multiple sections, |
475 | * each of which may contain multiple headers. |
476 | * |
477 | * section: *header +newline |
478 | * |
479 | * nonempty-section: +header +newline |
480 | * |
481 | * (Note that the point of "nonempty-section" is unclear, because it isn't |
482 | * referenced elsewhere in the full specification for the Manifest file.) |
483 | * |
484 | * Arguments: |
485 | * lp pointer to a character pointer which points to the start |
486 | * of a valid header. |
487 | * name pointer to a character pointer which will be set to point |
488 | * to the name portion of the header (nul terminated). |
489 | * value pointer to a character pointer which will be set to point |
490 | * to the value portion of the header (nul terminated). |
491 | * |
492 | * Returns: |
493 | * 1 Successful parsing of an NV pair. lp is updated to point to the |
494 | * next character after the terminating newline in the string |
495 | * representing the Manifest file. name and value are updated to |
496 | * point to the strings parsed. |
497 | * 0 A valid end of section indicator was encountered. lp, name, and |
498 | * value are not modified. |
499 | * -1 lp does not point to a valid header. Upon return, the values of |
500 | * lp, name, and value are undefined. |
501 | */ |
502 | static int |
503 | parse_nv_pair(char **lp, char **name, char **value) |
504 | { |
505 | char *nl; |
506 | char *cp; |
507 | |
508 | /* |
509 | * End of the section - return 0. The end of section condition is |
510 | * indicated by either encountering a blank line or the end of the |
511 | * Manifest "string" (EOF). |
512 | */ |
513 | if (**lp == '\0' || **lp == '\n' || **lp == '\r') |
514 | return (0); |
515 | |
516 | /* |
517 | * Getting to here, indicates that *lp points to an "otherchar". |
518 | * Turn the "header" into a string on its own. |
519 | */ |
520 | nl = JLI_StrPBrk(*lp, "\n\r")strpbrk((*lp), ("\n\r")); |
521 | if (nl == NULL((void*)0)) { |
522 | nl = JLI_StrChr(*lp, (int)'\0')strchr((*lp), ((int)'\0')); |
523 | } else { |
524 | cp = nl; /* For merging continuation lines */ |
525 | if (*nl == '\r' && *(nl+1) == '\n') |
526 | *nl++ = '\0'; |
527 | *nl++ = '\0'; |
528 | |
529 | /* |
530 | * Process any "continuation" line(s), by making them part of the |
531 | * "header" line. Yes, I know that we are "undoing" the NULs we |
532 | * just placed here, but continuation lines are the fairly rare |
533 | * case, so we shouldn't unnecessarily complicate the code above. |
534 | * |
535 | * Note that an entire continuation line is processed each iteration |
536 | * through the outer while loop. |
537 | */ |
538 | while (*nl == ' ') { |
539 | nl++; /* First character to be moved */ |
540 | while (*nl != '\n' && *nl != '\r' && *nl != '\0') |
541 | *cp++ = *nl++; /* Shift string */ |
542 | if (*nl == '\0') |
543 | return (-1); /* Error: newline required */ |
544 | *cp = '\0'; |
545 | if (*nl == '\r' && *(nl+1) == '\n') |
546 | *nl++ = '\0'; |
547 | *nl++ = '\0'; |
548 | } |
549 | } |
550 | |
551 | /* |
552 | * Separate the name from the value; |
553 | */ |
554 | cp = JLI_StrChr(*lp, (int)':')strchr((*lp), ((int)':')); |
555 | if (cp == NULL((void*)0)) |
556 | return (-1); |
557 | *cp++ = '\0'; /* The colon terminates the name */ |
558 | if (*cp != ' ') |
559 | return (-1); |
560 | *cp++ = '\0'; /* Eat the required space */ |
561 | *name = *lp; |
562 | *value = cp; |
563 | *lp = nl; |
564 | return (1); |
565 | } |
566 | |
567 | /* |
568 | * Read the manifest from the specified jar file and fill in the manifest_info |
569 | * structure with the information found within. |
570 | * |
571 | * Error returns are as follows: |
572 | * 0 Success |
573 | * -1 Unable to open jarfile |
574 | * -2 Error accessing the manifest from within the jarfile (most likely |
575 | * a manifest is not present, or this isn't a valid zip/jar file). |
576 | */ |
577 | int |
578 | JLI_ParseManifest(char *jarfile, manifest_info *info) |
579 | { |
580 | int fd; |
581 | zentry entry; |
582 | char *lp; |
583 | char *name; |
584 | char *value; |
585 | int rc; |
586 | char *splashscreen_name = NULL((void*)0); |
587 | |
588 | if ((fd = JLI_Openopen(jarfile, O_RDONLY00 |
589 | #ifdef O_LARGEFILE0 |
590 | | O_LARGEFILE0 /* large file mode */ |
591 | #endif |
592 | #ifdef O_BINARY |
593 | | O_BINARY /* use binary mode on windows */ |
594 | #endif |
595 | )) == -1) { |
596 | return (-1); |
597 | } |
598 | info->manifest_version = NULL((void*)0); |
599 | info->main_class = NULL((void*)0); |
600 | info->jre_version = NULL((void*)0); |
601 | info->jre_restrict_search = 0; |
602 | info->splashscreen_image_file_name = NULL((void*)0); |
603 | if ((rc = find_file(fd, &entry, manifest_name)) != 0) { |
Although the value stored to 'rc' is used in the enclosing expression, the value is never actually read from 'rc' | |
604 | close(fd); |
605 | return (-2); |
606 | } |
607 | manifest = inflate_file(fd, &entry, NULL((void*)0)); |
608 | if (manifest == NULL((void*)0)) { |
609 | close(fd); |
610 | return (-2); |
611 | } |
612 | lp = manifest; |
613 | while ((rc = parse_nv_pair(&lp, &name, &value)) > 0) { |
614 | if (JLI_StrCaseCmp(name, "Manifest-Version")strcasecmp((name), ("Manifest-Version")) == 0) { |
615 | info->manifest_version = value; |
616 | } else if (JLI_StrCaseCmp(name, "Main-Class")strcasecmp((name), ("Main-Class")) == 0) { |
617 | info->main_class = value; |
618 | } else if (JLI_StrCaseCmp(name, "JRE-Version")strcasecmp((name), ("JRE-Version")) == 0) { |
619 | /* |
620 | * Manifest specification overridden by command line option |
621 | * so we will silently override there with no specification. |
622 | */ |
623 | info->jre_version = 0; |
624 | } else if (JLI_StrCaseCmp(name, "Splashscreen-Image")strcasecmp((name), ("Splashscreen-Image")) == 0) { |
625 | info->splashscreen_image_file_name = value; |
626 | } |
627 | } |
628 | close(fd); |
629 | if (rc == 0) |
630 | return (0); |
631 | else |
632 | return (-2); |
633 | } |
634 | |
635 | /* |
636 | * Opens the jar file and unpacks the specified file from its contents. |
637 | * Returns NULL on failure. |
638 | */ |
639 | void * |
640 | JLI_JarUnpackFile(const char *jarfile, const char *filename, int *size) { |
641 | int fd; |
642 | zentry entry; |
643 | void *data = NULL((void*)0); |
644 | |
645 | if ((fd = JLI_Openopen(jarfile, O_RDONLY00 |
646 | #ifdef O_LARGEFILE0 |
647 | | O_LARGEFILE0 /* large file mode */ |
648 | #endif |
649 | #ifdef O_BINARY |
650 | | O_BINARY /* use binary mode on windows */ |
651 | #endif |
652 | )) == -1) { |
653 | return NULL((void*)0); |
654 | } |
655 | if (find_file(fd, &entry, filename) == 0) { |
656 | data = inflate_file(fd, &entry, size); |
657 | } |
658 | close(fd); |
659 | return (data); |
660 | } |
661 | |
662 | /* |
663 | * Specialized "free" function. |
664 | */ |
665 | void |
666 | JLI_FreeManifest() |
667 | { |
668 | if (manifest) |
669 | free(manifest); |
670 | } |
671 | |
672 | /* |
673 | * Iterate over the manifest of the specified jar file and invoke the provided |
674 | * closure function for each attribute encountered. |
675 | * |
676 | * Error returns are as follows: |
677 | * 0 Success |
678 | * -1 Unable to open jarfile |
679 | * -2 Error accessing the manifest from within the jarfile (most likely |
680 | * this means a manifest is not present, or it isn't a valid zip/jar file). |
681 | */ |
682 | JNIEXPORT__attribute__((visibility("default"))) int JNICALL |
683 | JLI_ManifestIterate(const char *jarfile, attribute_closure ac, void *user_data) |
684 | { |
685 | int fd; |
686 | zentry entry; |
687 | char *mp; /* manifest pointer */ |
688 | char *lp; /* pointer into manifest, updated during iteration */ |
689 | char *name; |
690 | char *value; |
691 | int rc; |
692 | |
693 | if ((fd = JLI_Openopen(jarfile, O_RDONLY00 |
694 | #ifdef O_LARGEFILE0 |
695 | | O_LARGEFILE0 /* large file mode */ |
696 | #endif |
697 | #ifdef O_BINARY |
698 | | O_BINARY /* use binary mode on windows */ |
699 | #endif |
700 | )) == -1) { |
701 | return (-1); |
702 | } |
703 | |
704 | if ((rc = find_file(fd, &entry, manifest_name)) != 0) { |
705 | close(fd); |
706 | return (-2); |
707 | } |
708 | |
709 | mp = inflate_file(fd, &entry, NULL((void*)0)); |
710 | if (mp == NULL((void*)0)) { |
711 | close(fd); |
712 | return (-2); |
713 | } |
714 | |
715 | lp = mp; |
716 | while ((rc = parse_nv_pair(&lp, &name, &value)) > 0) { |
717 | (*ac)(name, value, user_data); |
718 | } |
719 | free(mp); |
720 | close(fd); |
721 | return (rc == 0) ? 0 : -2; |
722 | } |