/* * Copyright (c) 2001, 2011, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Oracle designates this * particular file as subject to the "Classpath" exception as provided * by Oracle in the LICENSE file that accompanied this code. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ // -*- C++ -*- // Program for unpacking specially compressed Java packages. // John R. Rose /* * When compiling for a 64bit LP64 system (longs and pointers being 64bits), * the printf format %ld is correct and use of %lld will cause warning * errors from some compilers (gcc/g++). * _LP64 can be explicitly set (used on Linux). * Solaris compilers will define __sparcv9 or __x86_64 on 64bit compilations. */ #if defined(_LP64) || defined(__sparcv9) || defined(__x86_64) #define LONG_LONG_FORMAT "%ld" #define LONG_LONG_HEX_FORMAT "%lx" #else #define LONG_LONG_FORMAT "%lld" #define LONG_LONG_HEX_FORMAT "%016llx" #endif #include #include #include #include #include #include #include #include #include #include "defines.h" #include "bytes.h" #include "utils.h" #include "coding.h" #include "bands.h" #include "constants.h" #include "zip.h" #include "unpack.h" // tags, in canonical order: static const byte TAGS_IN_ORDER[] = { CONSTANT_Utf8, CONSTANT_Integer, CONSTANT_Float, CONSTANT_Long, CONSTANT_Double, CONSTANT_String, CONSTANT_Class, CONSTANT_Signature, CONSTANT_NameandType, CONSTANT_Fieldref, CONSTANT_Methodref, CONSTANT_InterfaceMethodref}; #define N_TAGS_IN_ORDER (sizeof TAGS_IN_ORDER) // REQUESTED must be -2 for u2 and REQUESTED_LDC must be -1 for u1 enum { NOT_REQUESTED = 0, REQUESTED = -2, REQUESTED_LDC = -1 }; #define NO_INORD ((uint32_t) - 1) struct entry { byte tag; unsigned short nrefs; // pack w/ tag int outputIndex; uint32_t inord; // &cp.entries[cp.tag_base[this->tag]+this->inord] == this entry **refs; // put last to pack best union { bytes b; int i; int64_t l; } value; void requestOutputIndex(constant_pool &cp, int req = REQUESTED); int getOutputIndex() { assert(outputIndex > NOT_REQUESTED); return outputIndex; } entry *ref(int refnum) { assert((uint32_t)refnum < nrefs); return refs[refnum]; } const char *utf8String() { assert(tagMatches(CONSTANT_Utf8)); assert(value.b.len == strlen((const char *)value.b.ptr)); return (const char *)value.b.ptr; } entry *className() { assert(tagMatches(CONSTANT_Class)); return ref(0); } entry *memberClass() { assert(tagMatches(CONSTANT_Member)); return ref(0); } entry *memberDescr() { assert(tagMatches(CONSTANT_Member)); return ref(1); } entry *descrName() { assert(tagMatches(CONSTANT_NameandType)); return ref(0); } entry *descrType() { assert(tagMatches(CONSTANT_NameandType)); return ref(1); } int typeSize(); bytes &asUtf8(); int asInteger() { assert(tag == CONSTANT_Integer); return value.i; } bool isUtf8(bytes &b) { return tagMatches(CONSTANT_Utf8) && value.b.equals(b); } bool isDoubleWord() { return tag == CONSTANT_Double || tag == CONSTANT_Long; } bool tagMatches(byte tag2) { return (tag2 == tag) || (tag2 == CONSTANT_Utf8 && tag == CONSTANT_Signature) || (tag2 == CONSTANT_Literal && tag >= CONSTANT_Integer && tag <= CONSTANT_String && tag != CONSTANT_Class) || (tag2 == CONSTANT_Member && tag >= CONSTANT_Fieldref && tag <= CONSTANT_InterfaceMethodref); } }; entry *cpindex::get(uint32_t i) { if (i >= len) return nullptr; else if (base1 != nullptr) // primary index return &base1[i]; else // secondary index return base2[i]; } inline bytes &entry::asUtf8() { assert(tagMatches(CONSTANT_Utf8)); return value.b; } int entry::typeSize() { assert(tagMatches(CONSTANT_Utf8)); const char *sigp = (char *)value.b.ptr; switch (*sigp) { case '(': sigp++; break; // skip opening '(' case 'D': case 'J': return 2; // double field default: return 1; // field } int siglen = 0; for (;;) { int ch = *sigp++; switch (ch) { case 'D': case 'J': siglen += 1; break; case '[': // Skip rest of array info. while (ch == '[') { ch = *sigp++; } if (ch != 'L') break; // else fall through case 'L': sigp = strchr(sigp, ';'); if (sigp == nullptr) { unpack_abort("bad data"); return 0; } sigp += 1; break; case ')': // closing ')' return siglen; } siglen += 1; } } inline cpindex *constant_pool::getFieldIndex(entry *classRef) { assert(classRef->tagMatches(CONSTANT_Class)); assert((uint32_t)classRef->inord < (uint32_t)tag_count[CONSTANT_Class]); return &member_indexes[classRef->inord * 2 + 0]; } inline cpindex *constant_pool::getMethodIndex(entry *classRef) { assert(classRef->tagMatches(CONSTANT_Class)); assert((uint32_t)classRef->inord < (uint32_t)tag_count[CONSTANT_Class]); return &member_indexes[classRef->inord * 2 + 1]; } struct inner_class { entry *inner; entry *outer; entry *name; int flags; inner_class *next_sibling; bool requested; }; // Here is where everything gets deallocated: void unpacker::free() { int i; if (jarout != nullptr) jarout->reset(); if (gzin != nullptr) { gzin->free(); gzin = nullptr; } if (free_input) input.free(); /* * free everybody ever allocated with U_NEW or (recently) with T_NEW */ assert(smallbuf.base() == nullptr || mallocs.contains(smallbuf.base())); assert(tsmallbuf.base() == nullptr || tmallocs.contains(tsmallbuf.base())); mallocs.freeAll(); tmallocs.freeAll(); smallbuf.init(); tsmallbuf.init(); bcimap.free(); class_fixup_type.free(); class_fixup_offset.free(); class_fixup_ref.free(); code_fixup_type.free(); code_fixup_offset.free(); code_fixup_source.free(); requested_ics.free(); cur_classfile_head.free(); cur_classfile_tail.free(); for (i = 0; i < ATTR_CONTEXT_LIMIT; i++) attr_defs[i].free(); // free CP state cp.outputEntries.free(); for (i = 0; i < CONSTANT_Limit; i++) cp.tag_extras[i].free(); } // input handling // Attempts to advance rplimit so that (rplimit-rp) is at least 'more'. // Will eagerly read ahead by larger chunks, if possible. // Returns false if (rplimit-rp) is not at least 'more', // unless rplimit hits input.limit(). bool unpacker::ensure_input(int64_t more) { uint64_t want = more - input_remaining(); if ((int64_t)want <= 0) return true; // it's already in the buffer if (rplimit == input.limit()) return true; // not expecting any more if (read_input_fn == nullptr) { // assume it is already all there bytes_read += input.limit() - rplimit; rplimit = input.limit(); return true; } uint64_t remaining = (input.limit() - rplimit); // how much left to read? byte *rpgoal = (want >= remaining) ? input.limit() : rplimit + (size_t)want; enum { CHUNK_SIZE = (1 << 14) }; uint64_t fetch = want; if (fetch < CHUNK_SIZE) fetch = CHUNK_SIZE; if (fetch > remaining * 3 / 4) fetch = remaining; // Try to fetch at least "more" bytes. while ((int64_t)fetch > 0) { int64_t nr = (*read_input_fn)(this, rplimit, fetch, remaining); if (nr <= 0) { return (rplimit >= rpgoal); } remaining -= nr; rplimit += nr; fetch -= nr; bytes_read += nr; assert(remaining == (uint64_t)(input.limit() - rplimit)); } return true; } // output handling fillbytes *unpacker::close_output(fillbytes *which) { assert(wp != nullptr); if (which == nullptr) { if (wpbase == cur_classfile_head.base()) { which = &cur_classfile_head; } else { which = &cur_classfile_tail; } } assert(wpbase == which->base()); assert(wplimit == which->end()); which->setLimit(wp); wp = nullptr; wplimit = nullptr; // wpbase = nullptr; return which; } // maybe_inline void unpacker::ensure_put_space(size_t size) { if (wp + size <= wplimit) return; // Determine which segment needs expanding. fillbytes *which = close_output(); byte *wp0 = which->grow(size); wpbase = which->base(); wplimit = which->end(); wp = wp0; } byte *unpacker::put_space(size_t size) { byte *wp0 = wp; byte *wp1 = wp0 + size; if (wp1 > wplimit) { ensure_put_space(size); wp0 = wp; wp1 = wp0 + size; } wp = wp1; return wp0; } void unpacker::putu2_at(byte *wp, int n) { if (n != (unsigned short)n) { unpack_abort(ERROR_OVERFLOW); return; } wp[0] = (n) >> 8; wp[1] = (n) >> 0; } void unpacker::putu4_at(byte *wp, int n) { wp[0] = (n) >> 24; wp[1] = (n) >> 16; wp[2] = (n) >> 8; wp[3] = (n) >> 0; } void unpacker::putu8_at(byte *wp, int64_t n) { putu4_at(wp + 0, (int)((uint64_t)n >> 32)); putu4_at(wp + 4, (int)((uint64_t)n >> 0)); } void unpacker::putu2(int n) { putu2_at(put_space(2), n); } void unpacker::putu4(int n) { putu4_at(put_space(4), n); } void unpacker::putu8(int64_t n) { putu8_at(put_space(8), n); } int unpacker::putref_index(entry *e, int size) { if (e == nullptr) return 0; else if (e->outputIndex > NOT_REQUESTED) return e->outputIndex; else if (e->tag == CONSTANT_Signature) return putref_index(e->ref(0), size); else { e->requestOutputIndex(cp, -size); // Later on we'll fix the bits. class_fixup_type.addByte(size); class_fixup_offset.add((int)wpoffset()); class_fixup_ref.add(e); return 0; } } void unpacker::putref(entry *e) { int oidx = putref_index(e, 2); putu2_at(put_space(2), oidx); } void unpacker::putu1ref(entry *e) { int oidx = putref_index(e, 1); putu1_at(put_space(1), oidx); } // Allocation of small and large blocks. enum { CHUNK = (1 << 14), SMALL = (1 << 9) }; // Call malloc. Try to combine small blocks and free much later. void *unpacker::alloc_heap(size_t size, bool smallOK, bool temp) { if (!smallOK || size > SMALL) { void *res = must_malloc((int)size); (temp ? &tmallocs : &mallocs)->add(res); return res; } fillbytes &xsmallbuf = *(temp ? &tsmallbuf : &smallbuf); if (!xsmallbuf.canAppend(size + 1)) { xsmallbuf.init(CHUNK); (temp ? &tmallocs : &mallocs)->add(xsmallbuf.base()); } int growBy = (int)size; growBy += -growBy & 7; // round up mod 8 return xsmallbuf.grow(growBy); } void unpacker::saveTo(bytes &b, byte *ptr, size_t len) { b.ptr = U_NEW(byte, add_size(len, 1)); b.len = len; b.copyFrom(ptr, len); } // Read up through band_headers. // Do the archive_size dance to set the size of the input mega-buffer. void unpacker::read_file_header() { // Read file header to determine file type and total size. enum { MAGIC_BYTES = 4, AH_LENGTH_0 = 3, // minver, majver, options are outside of archive_size AH_LENGTH_0_MAX = AH_LENGTH_0 + 1, // options might have 2 bytes AH_LENGTH = 26, // maximum archive header length (w/ all fields) // Length contributions from optional header fields: AH_FILE_HEADER_LEN = 5, // sizehi/lo/next/modtime/files AH_ARCHIVE_SIZE_LEN = 2, // sizehi/lo only; part of AH_FILE_HEADER_LEN AH_CP_NUMBER_LEN = 4, // int/float/long/double AH_SPECIAL_FORMAT_LEN = 2, // layouts/band-headers AH_LENGTH_MIN = AH_LENGTH - (AH_FILE_HEADER_LEN + AH_SPECIAL_FORMAT_LEN + AH_CP_NUMBER_LEN), ARCHIVE_SIZE_MIN = AH_LENGTH_MIN - (AH_LENGTH_0 + AH_ARCHIVE_SIZE_LEN), FIRST_READ = MAGIC_BYTES + AH_LENGTH_MIN }; assert(AH_LENGTH_MIN == 15); // # of UNSIGNED5 fields required after archive_magic assert(ARCHIVE_SIZE_MIN == 10); // # of UNSIGNED5 fields required after archive_size // An absolute minimum nullptr archive is magic[4], {minver,majver,options}[3], // archive_size[0], cp_counts[8], class_counts[4], for a total of 19 bytes. // (Note that archive_size is optional; it may be 0..10 bytes in length.) // The first read must capture everything up through the options field. // This happens to work even if {minver,majver,options} is a pathological // 15 bytes long. Legal pack files limit those three fields to 1+1+2 bytes. assert(FIRST_READ >= MAGIC_BYTES + AH_LENGTH_0 * B_MAX); // Up through archive_size, the largest possible archive header is // magic[4], {minver,majver,options}[4], archive_size[10]. // (Note only the low 12 bits of options are allowed to be non-zero.) // In order to parse archive_size, we need at least this many bytes // in the first read. Of course, if archive_size_hi is more than // a byte, we probably will fail to allocate the buffer, since it // will be many gigabytes long. This is a practical, not an // architectural limit to Pack200 archive sizes. assert(FIRST_READ >= MAGIC_BYTES + AH_LENGTH_0_MAX + 2 * B_MAX); bool foreign_buf = (read_input_fn == nullptr); byte initbuf[(int)FIRST_READ + (int)C_SLOP + 200]; // 200 is for JAR I/O if (foreign_buf) { // inbytes is all there is input.set(inbytes); rp = input.base(); rplimit = input.limit(); } else { // inbytes, if not empty, contains some read-ahead we must use first // ensure_input will take care of copying it into initbuf, // then querying read_input_fn for any additional data needed. // However, the caller must assume that we use up all of inbytes. // There is no way to tell the caller that we used only part of them. // Therefore, the caller must use only a bare minimum of read-ahead. if (inbytes.len > FIRST_READ) { unpack_abort("too much read-ahead"); } input.set(initbuf, sizeof(initbuf)); input.b.clear(); input.b.copyFrom(inbytes); rplimit = rp = input.base(); rplimit += inbytes.len; bytes_read += inbytes.len; } // Read only 19 bytes, which is certain to contain #archive_options fields, // but is certain not to overflow past the archive_header. input.b.len = FIRST_READ; if (!ensure_input(FIRST_READ)) unpack_abort("EOF reading archive magic number"); if (rp[0] == 'P' && rp[1] == 'K') { // In the Unix-style program, we simply simulate a copy command. // Copy until EOF; assume the JAR file is the last segment. fprintf(stderr, "Copy-mode.\n"); for (;;) { jarout->write_data(rp, (int)input_remaining()); if (foreign_buf) break; // one-time use of a passed in buffer if (input.size() < CHUNK) { // Get some breathing room. input.set(U_NEW(byte, (size_t)CHUNK + C_SLOP), (size_t)CHUNK); } rp = rplimit = input.base(); if (!ensure_input(1)) break; } jarout->closeJarFile(false); return; } // Read the magic number. magic = 0; for (int i1 = 0; i1 < (int)sizeof(magic); i1++) { magic <<= 8; magic += (*rp++ & 0xFF); } // Read the first 3 values from the header. value_stream hdr; int hdrVals = 0; int hdrValsSkipped = 0; // debug only hdr.init(rp, rplimit, UNSIGNED5_spec); minver = hdr.getInt(); majver = hdr.getInt(); hdrVals += 2; if (magic != (int)JAVA_PACKAGE_MAGIC || (majver != JAVA5_PACKAGE_MAJOR_VERSION && majver != JAVA6_PACKAGE_MAJOR_VERSION) || (minver != JAVA5_PACKAGE_MINOR_VERSION && minver != JAVA6_PACKAGE_MINOR_VERSION)) { char message[200]; sprintf(message, "@" ERROR_FORMAT ": magic/ver = " "%08X/%d.%d should be %08X/%d.%d OR %08X/%d.%d\n", magic, majver, minver, JAVA_PACKAGE_MAGIC, JAVA5_PACKAGE_MAJOR_VERSION, JAVA5_PACKAGE_MINOR_VERSION, JAVA_PACKAGE_MAGIC, JAVA6_PACKAGE_MAJOR_VERSION, JAVA6_PACKAGE_MINOR_VERSION); unpack_abort(message); } archive_options = hdr.getInt(); hdrVals += 1; assert(hdrVals == AH_LENGTH_0); // first three fields only #define ORBIT(bit) | (bit) int OPTION_LIMIT = (0 ARCHIVE_BIT_DO(ORBIT)); #undef ORBIT if ((archive_options & ~OPTION_LIMIT) != 0) { fprintf(stderr, "Warning: Illegal archive options 0x%x\n", archive_options); unpack_abort("illegal archive options"); return; } if ((archive_options & AO_HAVE_FILE_HEADERS) != 0) { uint32_t hi = hdr.getInt(); uint32_t lo = hdr.getInt(); uint64_t x = band::makeLong(hi, lo); archive_size = (size_t)x; if (archive_size != x) { // Silly size specified; force overflow. archive_size = PSIZE_MAX + 1; } hdrVals += 2; } else { hdrValsSkipped += 2; } // Now we can size the whole archive. // Read everything else into a mega-buffer. rp = hdr.rp; int header_size_0 = (int)(rp - input.base()); // used-up header (4byte + 3int) int header_size_1 = (int)(rplimit - rp); // buffered unused initial fragment int header_size = header_size_0 + header_size_1; unsized_bytes_read = header_size_0; if (foreign_buf) { if (archive_size > (size_t)header_size_1) { unpack_abort("EOF reading fixed input buffer"); return; } } else if (archive_size != 0) { if (archive_size < ARCHIVE_SIZE_MIN) { unpack_abort("impossible archive size"); // bad input data return; } if (archive_size < (size_t)header_size_1) { unpack_abort("too much read-ahead"); // somehow we pre-fetched too much? return; } input.set(U_NEW(byte, add_size(header_size_0, archive_size, C_SLOP)), (size_t)header_size_0 + archive_size); assert(input.limit()[0] == 0); // Move all the bytes we read initially into the real buffer. input.b.copyFrom(initbuf, header_size); rp = input.b.ptr + header_size_0; rplimit = input.b.ptr + header_size; } else { // It's more complicated and painful. // A zero archive_size means that we must read until EOF. input.init(CHUNK * 2); input.b.len = input.allocated; rp = rplimit = input.base(); // Set up input buffer as if we already read the header: input.b.copyFrom(initbuf, header_size); rplimit += header_size; while (ensure_input(input.limit() - rp)) { size_t dataSoFar = input_remaining(); size_t nextSize = add_size(dataSoFar, CHUNK); input.ensureSize(nextSize); input.b.len = input.allocated; rp = rplimit = input.base(); rplimit += dataSoFar; } size_t dataSize = (rplimit - input.base()); input.b.len = dataSize; input.grow(C_SLOP); free_input = true; // free it later input.b.len = dataSize; assert(input.limit()[0] == 0); rp = rplimit = input.base(); rplimit += dataSize; rp += header_size_0; // already scanned these bytes... } live_input = true; // mark as "do not reuse" // read the rest of the header fields ensure_input((AH_LENGTH - AH_LENGTH_0) * B_MAX); hdr.rp = rp; hdr.rplimit = rplimit; if ((archive_options & AO_HAVE_FILE_HEADERS) != 0) { archive_next_count = hdr.getInt(); if (archive_next_count < 0) unpack_abort("bad archive_next_count"); archive_modtime = hdr.getInt(); file_count = hdr.getInt(); if (file_count < 0) unpack_abort("bad file_count"); hdrVals += 3; } else { hdrValsSkipped += 3; } if ((archive_options & AO_HAVE_SPECIAL_FORMATS) != 0) { band_headers_size = hdr.getInt(); if (band_headers_size < 0) unpack_abort("bad band_headers_size"); attr_definition_count = hdr.getInt(); if (attr_definition_count < 0) unpack_abort("bad attr_definition_count"); hdrVals += 2; } else { hdrValsSkipped += 2; } int cp_counts[N_TAGS_IN_ORDER]; for (int k = 0; k < (int)N_TAGS_IN_ORDER; k++) { if (!(archive_options & AO_HAVE_CP_NUMBERS)) { switch (TAGS_IN_ORDER[k]) { case CONSTANT_Integer: case CONSTANT_Float: case CONSTANT_Long: case CONSTANT_Double: cp_counts[k] = 0; hdrValsSkipped += 1; continue; } } cp_counts[k] = hdr.getInt(); if (cp_counts[k] < 0) unpack_abort("bad cp_counts"); hdrVals += 1; } ic_count = hdr.getInt(); if (ic_count < 0) unpack_abort("bad ic_count"); default_class_minver = hdr.getInt(); default_class_majver = hdr.getInt(); class_count = hdr.getInt(); if (class_count < 0) unpack_abort("bad class_count"); hdrVals += 4; // done with archive_header hdrVals += hdrValsSkipped; assert(hdrVals == AH_LENGTH); rp = hdr.rp; if (rp > rplimit) unpack_abort("EOF reading archive header"); // Now size the CP. cp.init(this, cp_counts); default_file_modtime = archive_modtime; if (default_file_modtime == 0 && !(archive_options & AO_HAVE_FILE_MODTIME)) default_file_modtime = DEFAULT_ARCHIVE_MODTIME; // taken from driver if ((archive_options & AO_DEFLATE_HINT) != 0) default_file_options |= FO_DEFLATE_HINT; // meta-bytes, if any, immediately follow archive header // band_headers.readData(band_headers_size); ensure_input(band_headers_size); if (input_remaining() < (size_t)band_headers_size) { unpack_abort("EOF reading band headers"); return; } bytes band_headers; // The "1+" allows an initial byte to be pushed on the front. band_headers.set(1 + U_NEW(byte, 1 + band_headers_size + C_SLOP), band_headers_size); // Start scanning band headers here: band_headers.copyFrom(rp, band_headers.len); rp += band_headers.len; assert(rp <= rplimit); meta_rp = band_headers.ptr; // Put evil meta-codes at the end of the band headers, // so we are sure to throw an error if we run off the end. bytes::of(band_headers.limit(), C_SLOP).clear(_meta_error); } void unpacker::finish() { if (verbose >= 1) { fprintf(stderr, "A total of " LONG_LONG_FORMAT " bytes were read in %d segment(s).\n", (bytes_read_before_reset + bytes_read), segments_read_before_reset + 1); fprintf(stderr, "A total of " LONG_LONG_FORMAT " file content bytes were written.\n", (bytes_written_before_reset + bytes_written)); fprintf(stderr, "A total of %d files (of which %d are classes) were written to output.\n", files_written_before_reset + files_written, classes_written_before_reset + classes_written); } if (jarout != nullptr) jarout->closeJarFile(true); } // Cf. PackageReader.readConstantPoolCounts void constant_pool::init(unpacker *u_, int counts[NUM_COUNTS]) { this->u = u_; // Fill-pointer for CP. int next_entry = 0; // Size the constant pool: for (int k = 0; k < (int)N_TAGS_IN_ORDER; k++) { byte tag = TAGS_IN_ORDER[k]; int len = counts[k]; tag_count[tag] = len; tag_base[tag] = next_entry; next_entry += len; // Detect and defend against constant pool size overflow. // (Pack200 forbids the sum of CP counts to exceed 2^29-1.) enum { CP_SIZE_LIMIT = (1 << 29), IMPLICIT_ENTRY_COUNT = 1 // empty Utf8 string }; if (len >= (1 << 29) || len < 0 || next_entry >= CP_SIZE_LIMIT + IMPLICIT_ENTRY_COUNT) { unpack_abort("archive too large: constant pool limit exceeded"); } } // Close off the end of the CP: nentries = next_entry; // place a limit on future CP growth: int generous = 0; generous = add_size(generous, u->ic_count); // implicit name generous = add_size(generous, u->ic_count); // outer generous = add_size(generous, u->ic_count); // outer.utf8 generous = add_size(generous, 40); // WKUs, misc generous = add_size(generous, u->class_count); // implicit SourceFile strings maxentries = add_size(nentries, generous); // Note that this CP does not include "empty" entries // for longs and doubles. Those are introduced when // the entries are renumbered for classfile output. entries = U_NEW(entry, maxentries); first_extra_entry = &entries[nentries]; // Initialize the standard indexes. tag_count[CONSTANT_All] = nentries; tag_base[CONSTANT_All] = 0; for (int tag = 0; tag < CONSTANT_Limit; tag++) { entry *cpMap = &entries[tag_base[tag]]; tag_index[tag].init(tag_count[tag], cpMap, tag); } // Initialize hashTab to a generous power-of-two size. uint32_t pow2 = 1; uint32_t target = maxentries + maxentries / 2; // 60% full while (pow2 < target) pow2 <<= 1; hashTab = U_NEW(entry *, hashTabLength = pow2); } static byte *store_Utf8_char(byte *cp, unsigned short ch) { if (ch >= 0x001 && ch <= 0x007F) { *cp++ = (byte)ch; } else if (ch <= 0x07FF) { *cp++ = (byte)(0xC0 | ((ch >> 6) & 0x1F)); *cp++ = (byte)(0x80 | ((ch >> 0) & 0x3F)); } else { *cp++ = (byte)(0xE0 | ((ch >> 12) & 0x0F)); *cp++ = (byte)(0x80 | ((ch >> 6) & 0x3F)); *cp++ = (byte)(0x80 | ((ch >> 0) & 0x3F)); } return cp; } static byte *skip_Utf8_chars(byte *cp, int len) { for (;; cp++) { int ch = *cp & 0xFF; if ((ch & 0xC0) != 0x80) { if (len-- == 0) return cp; if (ch < 0x80 && len == 0) return cp + 1; } } } static int compare_Utf8_chars(bytes &b1, bytes &b2) { int l1 = (int)b1.len; int l2 = (int)b2.len; int l0 = (l1 < l2) ? l1 : l2; byte *p1 = b1.ptr; byte *p2 = b2.ptr; int c0 = 0; for (int i = 0; i < l0; i++) { int c1 = p1[i] & 0xFF; int c2 = p2[i] & 0xFF; if (c1 != c2) { // Before returning the obvious answer, // check to see if c1 or c2 is part of a 0x0000, // which encodes as {0xC0,0x80}. The 0x0000 is the // lowest-sorting Java char value, and yet it encodes // as if it were the first char after 0x7F, which causes // strings containing nulls to sort too high. All other // comparisons are consistent between Utf8 and Java chars. if (c1 == 0xC0 && (p1[i + 1] & 0xFF) == 0x80) c1 = 0; if (c2 == 0xC0 && (p2[i + 1] & 0xFF) == 0x80) c2 = 0; if (c0 == 0xC0) { assert(((c1 | c2) & 0xC0) == 0x80); // c1 & c2 are extension chars if (c1 == 0x80) c1 = 0; // will sort below c2 if (c2 == 0x80) c2 = 0; // will sort below c1 } return c1 - c2; } c0 = c1; // save away previous char } // common prefix is identical; return length difference if any return l1 - l2; } // Cf. PackageReader.readUtf8Bands void unpacker::read_Utf8_values(entry *cpMap, int len) { // Implicit first Utf8 string is the empty string. enum { // certain bands begin with implicit zeroes PREFIX_SKIP_2 = 2, SUFFIX_SKIP_1 = 1 }; int i; // First band: Read lengths of shared prefixes. if (len > PREFIX_SKIP_2) cp_Utf8_prefix.readData(len - PREFIX_SKIP_2); // Second band: Read lengths of unshared suffixes: if (len > SUFFIX_SKIP_1) cp_Utf8_suffix.readData(len - SUFFIX_SKIP_1); bytes *allsuffixes = T_NEW(bytes, len); int nbigsuf = 0; fillbytes charbuf; // buffer to allocate small strings charbuf.init(); // Third band: Read the char values in the unshared suffixes: cp_Utf8_chars.readData(cp_Utf8_suffix.getIntTotal()); for (i = 0; i < len; i++) { int suffix = (i < SUFFIX_SKIP_1) ? 0 : cp_Utf8_suffix.getInt(); if (suffix < 0) { unpack_abort("bad utf8 suffix"); } if (suffix == 0 && i >= SUFFIX_SKIP_1) { // chars are packed in cp_Utf8_big_chars nbigsuf += 1; continue; } bytes &chars = allsuffixes[i]; uint32_t size3 = suffix * 3; // max Utf8 length bool isMalloc = (suffix > SMALL); if (isMalloc) { chars.malloc(size3); } else { if (!charbuf.canAppend(size3 + 1)) { assert(charbuf.allocated == 0 || tmallocs.contains(charbuf.base())); charbuf.init(CHUNK); // Reset to new buffer. tmallocs.add(charbuf.base()); } chars.set(charbuf.grow(size3 + 1), size3); } byte *chp = chars.ptr; for (int j = 0; j < suffix; j++) { unsigned short ch = cp_Utf8_chars.getInt(); chp = store_Utf8_char(chp, ch); } // shrink to fit: if (isMalloc) { chars.realloc(chp - chars.ptr); tmallocs.add(chars.ptr); // free it later } else { int shrink = (int)(chars.limit() - chp); chars.len -= shrink; charbuf.b.len -= shrink; // ungrow to reclaim buffer space // Note that we did not reclaim the final '\0'. assert(chars.limit() == charbuf.limit() - 1); assert(strlen((char *)chars.ptr) == chars.len); } } // cp_Utf8_chars.done(); // Fourth band: Go back and size the specially packed strings. int maxlen = 0; cp_Utf8_big_suffix.readData(nbigsuf); cp_Utf8_suffix.rewind(); for (i = 0; i < len; i++) { int suffix = (i < SUFFIX_SKIP_1) ? 0 : cp_Utf8_suffix.getInt(); int prefix = (i < PREFIX_SKIP_2) ? 0 : cp_Utf8_prefix.getInt(); if (prefix < 0 || prefix + suffix < 0) { unpack_abort("bad utf8 prefix"); } bytes &chars = allsuffixes[i]; if (suffix == 0 && i >= SUFFIX_SKIP_1) { suffix = cp_Utf8_big_suffix.getInt(); assert(chars.ptr == nullptr); chars.len = suffix; // just a momentary hack } else { assert(chars.ptr != nullptr); } if (maxlen < prefix + suffix) { maxlen = prefix + suffix; } } // cp_Utf8_suffix.done(); // will use allsuffixes[i].len (ptr!=nullptr) // cp_Utf8_big_suffix.done(); // will use allsuffixes[i].len // Fifth band(s): Get the specially packed characters. cp_Utf8_big_suffix.rewind(); for (i = 0; i < len; i++) { bytes &chars = allsuffixes[i]; if (chars.ptr != nullptr) continue; // already input int suffix = (int)chars.len; // pick up the hack uint32_t size3 = suffix * 3; if (suffix == 0) continue; // done with empty string chars.malloc(size3); byte *chp = chars.ptr; band saved_band = cp_Utf8_big_chars; cp_Utf8_big_chars.readData(suffix); for (int j = 0; j < suffix; j++) { unsigned short ch = cp_Utf8_big_chars.getInt(); chp = store_Utf8_char(chp, ch); } chars.realloc(chp - chars.ptr); tmallocs.add(chars.ptr); // free it later // cp_Utf8_big_chars.done(); cp_Utf8_big_chars = saved_band; // reset the band for the next string } cp_Utf8_big_chars.readData(0); // zero chars // cp_Utf8_big_chars.done(); // Finally, sew together all the prefixes and suffixes. bytes bigbuf; bigbuf.malloc(maxlen * 3 + 1); // max Utf8 length, plus slop for nullptr int prevlen = 0; // previous string length (in chars) tmallocs.add(bigbuf.ptr); // free after this block cp_Utf8_prefix.rewind(); for (i = 0; i < len; i++) { bytes &chars = allsuffixes[i]; int prefix = (i < PREFIX_SKIP_2) ? 0 : cp_Utf8_prefix.getInt(); int suffix = (int)chars.len; byte *fillp; // by induction, the buffer is already filled with the prefix // make sure the prefix value is not corrupted, though: if (prefix > prevlen) { unpack_abort("utf8 prefix overflow"); return; } fillp = skip_Utf8_chars(bigbuf.ptr, prefix); // copy the suffix into the same buffer: fillp = chars.writeTo(fillp); assert(bigbuf.inBounds(fillp)); *fillp = 0; // bigbuf must contain a well-formed Utf8 string int length = (int)(fillp - bigbuf.ptr); bytes &value = cpMap[i].value.b; value.set(U_NEW(byte, add_size(length, 1)), length); value.copyFrom(bigbuf.ptr, length); // Index all Utf8 strings entry *&htref = cp.hashTabRef(CONSTANT_Utf8, value); if (htref == nullptr) { // Note that if two identical strings are transmitted, // the first is taken to be the canonical one. htref = &cpMap[i]; } prevlen = prefix + suffix; } // cp_Utf8_prefix.done(); // Free intermediate buffers. free_temps(); } void unpacker::read_single_words(band &cp_band, entry *cpMap, int len) { cp_band.readData(len); for (int i = 0; i < len; i++) { cpMap[i].value.i = cp_band.getInt(); // coding handles signs OK } } void unpacker::read_double_words(band &cp_bands, entry *cpMap, int len) { band &cp_band_hi = cp_bands; band &cp_band_lo = cp_bands.nextBand(); cp_band_hi.readData(len); cp_band_lo.readData(len); for (int i = 0; i < len; i++) { cpMap[i].value.l = cp_band_hi.getLong(cp_band_lo, true); } // cp_band_hi.done(); // cp_band_lo.done(); } void unpacker::read_single_refs(band &cp_band, byte refTag, entry *cpMap, int len) { assert(refTag == CONSTANT_Utf8); cp_band.setIndexByTag(refTag); cp_band.readData(len); int indexTag = (cp_band.bn == e_cp_Class) ? CONSTANT_Class : 0; for (int i = 0; i < len; i++) { entry &e = cpMap[i]; e.refs = U_NEW(entry *, e.nrefs = 1); entry *utf = cp_band.getRef(); e.refs[0] = utf; e.value.b = utf->value.b; // copy value of Utf8 string to self if (indexTag != 0) { // Maintain cross-reference: entry *&htref = cp.hashTabRef(indexTag, e.value.b); if (htref == nullptr) { // Note that if two identical classes are transmitted, // the first is taken to be the canonical one. htref = &e; } } } // cp_band.done(); } void unpacker::read_double_refs(band &cp_band, byte ref1Tag, byte ref2Tag, entry *cpMap, int len) { band &cp_band1 = cp_band; band &cp_band2 = cp_band.nextBand(); cp_band1.setIndexByTag(ref1Tag); cp_band2.setIndexByTag(ref2Tag); cp_band1.readData(len); cp_band2.readData(len); for (int i = 0; i < len; i++) { entry &e = cpMap[i]; e.refs = U_NEW(entry *, e.nrefs = 2); e.refs[0] = cp_band1.getRef(); e.refs[1] = cp_band2.getRef(); } // cp_band1.done(); // cp_band2.done(); } // Cf. PackageReader.readSignatureBands void unpacker::read_signature_values(entry *cpMap, int len) { cp_Signature_form.setIndexByTag(CONSTANT_Utf8); cp_Signature_form.readData(len); int ncTotal = 0; int i; for (i = 0; i < len; i++) { entry &e = cpMap[i]; entry &form = *cp_Signature_form.getRef(); int nc = 0; for (const char *ncp = form.utf8String(); *ncp; ncp++) { if (*ncp == 'L') nc++; } ncTotal += nc; e.refs = U_NEW(entry *, cpMap[i].nrefs = 1 + nc); e.refs[0] = &form; } // cp_Signature_form.done(); cp_Signature_classes.setIndexByTag(CONSTANT_Class); cp_Signature_classes.readData(ncTotal); for (i = 0; i < len; i++) { entry &e = cpMap[i]; for (int j = 1; j < e.nrefs; j++) { e.refs[j] = cp_Signature_classes.getRef(); } } // cp_Signature_classes.done(); } // Cf. PackageReader.readConstantPool void unpacker::read_cp() { int i; for (int k = 0; k < (int)N_TAGS_IN_ORDER; k++) { byte tag = TAGS_IN_ORDER[k]; int len = cp.tag_count[tag]; int base = cp.tag_base[tag]; entry *cpMap = &cp.entries[base]; for (i = 0; i < len; i++) { cpMap[i].tag = tag; cpMap[i].inord = i; } switch (tag) { case CONSTANT_Utf8: read_Utf8_values(cpMap, len); break; case CONSTANT_Integer: read_single_words(cp_Int, cpMap, len); break; case CONSTANT_Float: read_single_words(cp_Float, cpMap, len); break; case CONSTANT_Long: read_double_words(cp_Long_hi /*& cp_Long_lo*/, cpMap, len); break; case CONSTANT_Double: read_double_words(cp_Double_hi /*& cp_Double_lo*/, cpMap, len); break; case CONSTANT_String: read_single_refs(cp_String, CONSTANT_Utf8, cpMap, len); break; case CONSTANT_Class: read_single_refs(cp_Class, CONSTANT_Utf8, cpMap, len); break; case CONSTANT_Signature: read_signature_values(cpMap, len); break; case CONSTANT_NameandType: read_double_refs(cp_Descr_name /*& cp_Descr_type*/, CONSTANT_Utf8, CONSTANT_Signature, cpMap, len); break; case CONSTANT_Fieldref: read_double_refs(cp_Field_class /*& cp_Field_desc*/, CONSTANT_Class, CONSTANT_NameandType, cpMap, len); break; case CONSTANT_Methodref: read_double_refs(cp_Method_class /*& cp_Method_desc*/, CONSTANT_Class, CONSTANT_NameandType, cpMap, len); break; case CONSTANT_InterfaceMethodref: read_double_refs(cp_Imethod_class /*& cp_Imethod_desc*/, CONSTANT_Class, CONSTANT_NameandType, cpMap, len); break; default: assert(false); break; } } cp.expandSignatures(); cp.initMemberIndexes(); #define SNAME(n, s) #s "\0" const char *symNames = (ALL_ATTR_DO(SNAME) ""); #undef SNAME for (int sn = 0; sn < constant_pool::s_LIMIT; sn++) { assert(symNames[0] >= '0' && symNames[0] <= 'Z'); // sanity bytes name; name.set(symNames); if (name.len > 0 && name.ptr[0] != '0') { cp.sym[sn] = cp.ensureUtf8(name); } symNames += name.len + 1; // skip trailing nullptr to next name } band::initIndexes(this); } static band *no_bands[] = {nullptr}; // shared empty body inline band &unpacker::attr_definitions::fixed_band(int e_class_xxx) { return u->all_bands[xxx_flags_hi_bn + (e_class_xxx - e_class_flags_hi)]; } inline band &unpacker::attr_definitions::xxx_flags_hi() { return fixed_band(e_class_flags_hi); } inline band &unpacker::attr_definitions::xxx_flags_lo() { return fixed_band(e_class_flags_lo); } inline band &unpacker::attr_definitions::xxx_attr_count() { return fixed_band(e_class_attr_count); } inline band &unpacker::attr_definitions::xxx_attr_indexes() { return fixed_band(e_class_attr_indexes); } inline band &unpacker::attr_definitions::xxx_attr_calls() { return fixed_band(e_class_attr_calls); } inline unpacker::layout_definition * unpacker::attr_definitions::defineLayout(int idx, entry *nameEntry, const char *layout) { const char *name = nameEntry->value.b.strval(); layout_definition *lo = defineLayout(idx, name, layout); lo->nameEntry = nameEntry; return lo; } unpacker::layout_definition *unpacker::attr_definitions::defineLayout(int idx, const char *name, const char *layout) { assert(flag_limit != 0); // must be set up already if (idx >= 0) { // Fixed attr. if (idx >= (int)flag_limit) unpack_abort("attribute index too large"); if (isRedefined(idx)) unpack_abort("redefined attribute index"); redef |= ((uint64_t)1 << idx); } else { idx = flag_limit + overflow_count.length(); overflow_count.add(0); // make a new counter } layout_definition *lo = U_NEW(layout_definition, 1); lo->idx = idx; lo->name = name; lo->layout = layout; for (int adds = (idx + 1) - layouts.length(); adds > 0; adds--) { layouts.add(nullptr); } layouts.get(idx) = lo; return lo; } band **unpacker::attr_definitions::buildBands(unpacker::layout_definition *lo) { int i; if (lo->elems != nullptr) return lo->bands(); if (lo->layout[0] == '\0') { lo->elems = no_bands; } else { // Create bands for this attribute by parsing the layout. bool hasCallables = lo->hasCallables(); bands_made = 0x10000; // base number for bands made const char *lp = lo->layout; lp = parseLayout(lp, lo->elems, -1); if (lp[0] != '\0' || band_stack.length() > 0) { unpack_abort("garbage at end of layout"); } band_stack.popTo(0); // Fix up callables to point at their callees. band **bands = lo->elems; assert(bands == lo->bands()); int num_callables = 0; if (hasCallables) { while (bands[num_callables] != nullptr) { if (bands[num_callables]->le_kind != EK_CBLE) { unpack_abort("garbage mixed with callables"); break; } num_callables += 1; } } for (i = 0; i < calls_to_link.length(); i++) { band &call = *(band *)calls_to_link.get(i); assert(call.le_kind == EK_CALL); // Determine the callee. int call_num = call.le_len; if (call_num < 0 || call_num >= num_callables) { unpack_abort("bad call in layout"); break; } band &cble = *bands[call_num]; // Link the call to it. call.le_body[0] = &cble; // Distinguish backward calls and callables: assert(cble.le_kind == EK_CBLE); // FIXME: hit this one // assert(cble.le_len == call_num); cble.le_back |= call.le_back; } calls_to_link.popTo(0); } return lo->elems; } /* attribute layout language parser attribute_layout: ( layout_element )* | ( callable )+ layout_element: ( integral | replication | union | call | reference ) callable: '[' body ']' body: ( layout_element )+ integral: ( unsigned_int | signed_int | bc_index | bc_offset | flag ) unsigned_int: uint_type signed_int: 'S' uint_type any_int: ( unsigned_int | signed_int ) bc_index: ( 'P' uint_type | 'PO' uint_type ) bc_offset: 'O' any_int flag: 'F' uint_type uint_type: ( 'B' | 'H' | 'I' | 'V' ) replication: 'N' uint_type '[' body ']' union: 'T' any_int (union_case)* '(' ')' '[' (body)? ']' union_case: '(' union_case_tag (',' union_case_tag)* ')' '[' (body)? ']' union_case_tag: ( numeral | numeral '-' numeral ) call: '(' numeral ')' reference: reference_type ( 'N' )? uint_type reference_type: ( constant_ref | schema_ref | utf8_ref | untyped_ref ) constant_ref: ( 'KI' | 'KJ' | 'KF' | 'KD' | 'KS' | 'KQ' ) schema_ref: ( 'RC' | 'RS' | 'RD' | 'RF' | 'RM' | 'RI' ) utf8_ref: 'RU' untyped_ref: 'RQ' numeral: '(' ('-')? (digit)+ ')' digit: ( '0' | '1' | '2' | '3' | '4' | '5' | '6' | '7' | '8' | '9' ) */ const char *unpacker::attr_definitions::parseIntLayout(const char *lp, band *&res, byte le_kind, bool can_be_signed) { band *b = U_NEW(band, 1); char le = *lp++; int spec = UNSIGNED5_spec; if (le == 'S' && can_be_signed) { // Note: This is the last use of sign. There is no 'EF_SIGN'. spec = SIGNED5_spec; le = *lp++; } else if (le == 'B') { spec = BYTE1_spec; // unsigned byte } b->init(u, bands_made++, spec); b->le_kind = le_kind; int le_len = 0; switch (le) { case 'B': le_len = 1; break; case 'H': le_len = 2; break; case 'I': le_len = 4; break; case 'V': le_len = 0; break; default: unpack_abort("bad layout element"); } b->le_len = le_len; band_stack.add(b); res = b; return lp; } const char *unpacker::attr_definitions::parseNumeral(const char *lp, int &res) { bool sgn = false; if (*lp == '0') { res = 0; return lp + 1; } // special case '0' if (*lp == '-') { sgn = true; lp++; } const char *dp = lp; int con = 0; while (*dp >= '0' && *dp <= '9') { int con0 = con; con *= 10; con += (*dp++) - '0'; if (con <= con0) { con = -1; break; } // numeral overflow } if (lp == dp) { unpack_abort("missing numeral in layout"); } lp = dp; if (con < 0 && !(sgn && con == -con)) { // (Portability note: Misses the error if int is not 32 bits.) unpack_abort("numeral overflow"); } if (sgn) con = -con; res = con; return lp; } band **unpacker::attr_definitions::popBody(int bs_base) { // Return everything that was pushed, as a nullptr-terminated pointer array. int bs_limit = band_stack.length(); if (bs_base == bs_limit) { return no_bands; } else { int nb = bs_limit - bs_base; band **res = U_NEW(band *, add_size(nb, 1)); for (int i = 0; i < nb; i++) { band *b = (band *)band_stack.get(bs_base + i); res[i] = b; } band_stack.popTo(bs_base); return res; } } const char *unpacker::attr_definitions::parseLayout(const char *lp, band **&res, int curCble) { int bs_base = band_stack.length(); bool top_level = (bs_base == 0); band *b; enum { can_be_signed = true }; // optional arg to parseIntLayout for (bool done = false; !done;) { switch (*lp++) { case 'B': case 'H': case 'I': case 'V': // unsigned_int case 'S': // signed_int --lp; // reparse case 'F': lp = parseIntLayout(lp, b, EK_INT); break; case 'P': { int le_bci = EK_BCI; if (*lp == 'O') { ++lp; le_bci = EK_BCID; } assert(*lp != 'S'); // no PSH, etc. lp = parseIntLayout(lp, b, EK_INT); b->le_bci = le_bci; if (le_bci == EK_BCI) b->defc = coding::findBySpec(BCI5_spec); else b->defc = coding::findBySpec(BRANCH5_spec); } break; case 'O': lp = parseIntLayout(lp, b, EK_INT, can_be_signed); b->le_bci = EK_BCO; b->defc = coding::findBySpec(BRANCH5_spec); break; case 'N': // replication: 'N' uint32_t '[' elem ... ']' lp = parseIntLayout(lp, b, EK_REPL); assert(*lp == '['); ++lp; lp = parseLayout(lp, b->le_body, curCble); break; case 'T': // union: 'T' any_int union_case* '(' ')' '[' body ']' lp = parseIntLayout(lp, b, EK_UN, can_be_signed); { int union_base = band_stack.length(); for (;;) { // for each case band &k_case = *U_NEW(band, 1); band_stack.add(&k_case); k_case.le_kind = EK_CASE; k_case.bn = bands_made++; if (*lp++ != '(') { unpack_abort("bad union case"); return ""; } if (*lp++ != ')') { --lp; // reparse // Read some case values. (Use band_stack for temp. storage.) int case_base = band_stack.length(); for (;;) { int caseval = 0; lp = parseNumeral(lp, caseval); band_stack.add((void *)(size_t)caseval); if (*lp == '-') { // new in version 160, allow (1-5) for (1,2,3,4,5) if (u->majver < JAVA6_PACKAGE_MAJOR_VERSION) { unpack_abort( "bad range in union case label (old archive format)"); return ""; } int caselimit = caseval; lp++; lp = parseNumeral(lp, caselimit); if (caseval >= caselimit || (uint32_t)(caselimit - caseval) > 0x10000) { // Note: 0x10000 is arbitrary implementation restriction. // We can remove it later if it's important to. unpack_abort("bad range in union case label"); } for (;;) { ++caseval; band_stack.add((void *)(size_t)caseval); if (caseval == caselimit) break; } } if (*lp != ',') break; lp++; } if (*lp++ != ')') { unpack_abort("bad case label"); } // save away the case labels int ntags = band_stack.length() - case_base; int *tags = U_NEW(int, add_size(ntags, 1)); k_case.le_casetags = tags; *tags++ = ntags; for (int i = 0; i < ntags; i++) { *tags++ = ptrlowbits(band_stack.get(case_base + i)); } band_stack.popTo(case_base); } // Got le_casetags. Now grab the body. assert(*lp == '['); ++lp; lp = parseLayout(lp, k_case.le_body, curCble); if (k_case.le_casetags == nullptr) break; // done } b->le_body = popBody(union_base); } break; case '(': // call: '(' -?NN* ')' { band &call = *U_NEW(band, 1); band_stack.add(&call); call.le_kind = EK_CALL; call.bn = bands_made++; call.le_body = U_NEW(band *, 2); // fill in later int call_num = 0; lp = parseNumeral(lp, call_num); call.le_back = (call_num <= 0); call_num += curCble; // numeral is self-relative offset call.le_len = call_num; // use le_len as scratch calls_to_link.add(&call); if (*lp++ != ')') { unpack_abort("bad call label"); } } break; case 'K': // reference_type: constant_ref case 'R': // reference_type: schema_ref { int ixTag = CONSTANT_None; if (lp[-1] == 'K') { switch (*lp++) { case 'I': ixTag = CONSTANT_Integer; break; case 'J': ixTag = CONSTANT_Long; break; case 'F': ixTag = CONSTANT_Float; break; case 'D': ixTag = CONSTANT_Double; break; case 'S': ixTag = CONSTANT_String; break; case 'Q': ixTag = CONSTANT_Literal; break; } } else { switch (*lp++) { case 'C': ixTag = CONSTANT_Class; break; case 'S': ixTag = CONSTANT_Signature; break; case 'D': ixTag = CONSTANT_NameandType; break; case 'F': ixTag = CONSTANT_Fieldref; break; case 'M': ixTag = CONSTANT_Methodref; break; case 'I': ixTag = CONSTANT_InterfaceMethodref; break; case 'U': ixTag = CONSTANT_Utf8; break; // utf8_ref case 'Q': ixTag = CONSTANT_All; break; // untyped_ref } } if (ixTag == CONSTANT_None) { unpack_abort("bad reference layout"); break; } bool nullOK = false; if (*lp == 'N') { nullOK = true; lp++; } lp = parseIntLayout(lp, b, EK_REF); b->defc = coding::findBySpec(UNSIGNED5_spec); b->initRef(ixTag, nullOK); } break; case '[': { // [callable1][callable2]... if (!top_level) { unpack_abort("bad nested callable"); break; } curCble += 1; band &cble = *U_NEW(band, 1); band_stack.add(&cble); cble.le_kind = EK_CBLE; cble.bn = bands_made++; lp = parseLayout(lp, cble.le_body, curCble); } break; case ']': // Hit a closing brace. This ends whatever body we were in. done = true; break; case '\0': // Hit a nullptr. Also ends the (top-level) body. --lp; // back up, so caller can see the nullptr also done = true; break; default: unpack_abort("bad layout"); } } // Return the accumulated bands: res = popBody(bs_base); return lp; } void unpacker::read_attr_defs() { int i; // Tell each AD which attrc it is and where its fixed flags are: attr_defs[ATTR_CONTEXT_CLASS].attrc = ATTR_CONTEXT_CLASS; attr_defs[ATTR_CONTEXT_CLASS].xxx_flags_hi_bn = e_class_flags_hi; attr_defs[ATTR_CONTEXT_FIELD].attrc = ATTR_CONTEXT_FIELD; attr_defs[ATTR_CONTEXT_FIELD].xxx_flags_hi_bn = e_field_flags_hi; attr_defs[ATTR_CONTEXT_METHOD].attrc = ATTR_CONTEXT_METHOD; attr_defs[ATTR_CONTEXT_METHOD].xxx_flags_hi_bn = e_method_flags_hi; attr_defs[ATTR_CONTEXT_CODE].attrc = ATTR_CONTEXT_CODE; attr_defs[ATTR_CONTEXT_CODE].xxx_flags_hi_bn = e_code_flags_hi; // Decide whether bands for the optional high flag words are present. attr_defs[ATTR_CONTEXT_CLASS] .setHaveLongFlags((archive_options & AO_HAVE_CLASS_FLAGS_HI) != 0); attr_defs[ATTR_CONTEXT_FIELD] .setHaveLongFlags((archive_options & AO_HAVE_FIELD_FLAGS_HI) != 0); attr_defs[ATTR_CONTEXT_METHOD] .setHaveLongFlags((archive_options & AO_HAVE_METHOD_FLAGS_HI) != 0); attr_defs[ATTR_CONTEXT_CODE] .setHaveLongFlags((archive_options & AO_HAVE_CODE_FLAGS_HI) != 0); // Set up built-in attrs. // (The simple ones are hard-coded. The metadata layouts are not.) const char *md_layout = ( // parameter annotations: #define MDL0 "[NB[(1)]]" MDL0 // annotations: #define MDL1 \ "[NH[(1)]]" \ "[RSHNH[RUH(1)]]" MDL1 // member_value: "[TB" "(66,67,73,83,90)[KIH]" "(68)[KDH]" "(70)[KFH]" "(74)[KJH]" "(99)[RSH]" "(101)[RSHRUH]" "(115)[RUH]" "(91)[NH[(0)]]" "(64)[" // nested annotation: "RSH" "NH[RUH(0)]" "]" "()[]" "]"); const char *md_layout_P = md_layout; const char *md_layout_A = md_layout + strlen(MDL0); const char *md_layout_V = md_layout + strlen(MDL0 MDL1); assert(0 == strncmp(&md_layout_A[-3], ")]][", 4)); assert(0 == strncmp(&md_layout_V[-3], ")]][", 4)); for (i = 0; i < ATTR_CONTEXT_LIMIT; i++) { attr_definitions &ad = attr_defs[i]; ad.defineLayout(X_ATTR_RuntimeVisibleAnnotations, "RuntimeVisibleAnnotations", md_layout_A); ad.defineLayout(X_ATTR_RuntimeInvisibleAnnotations, "RuntimeInvisibleAnnotations", md_layout_A); if (i != ATTR_CONTEXT_METHOD) continue; ad.defineLayout(METHOD_ATTR_RuntimeVisibleParameterAnnotations, "RuntimeVisibleParameterAnnotations", md_layout_P); ad.defineLayout(METHOD_ATTR_RuntimeInvisibleParameterAnnotations, "RuntimeInvisibleParameterAnnotations", md_layout_P); ad.defineLayout(METHOD_ATTR_AnnotationDefault, "AnnotationDefault", md_layout_V); } attr_definition_headers.readData(attr_definition_count); attr_definition_name.readData(attr_definition_count); attr_definition_layout.readData(attr_definition_count); // Initialize correct predef bits, to distinguish predefs from new defs. #define ORBIT(n, s) | ((uint64_t)1 << n) attr_defs[ATTR_CONTEXT_CLASS].predef = (0 X_ATTR_DO(ORBIT) CLASS_ATTR_DO(ORBIT)); attr_defs[ATTR_CONTEXT_FIELD].predef = (0 X_ATTR_DO(ORBIT) FIELD_ATTR_DO(ORBIT)); attr_defs[ATTR_CONTEXT_METHOD].predef = (0 X_ATTR_DO(ORBIT) METHOD_ATTR_DO(ORBIT)); attr_defs[ATTR_CONTEXT_CODE].predef = (0 O_ATTR_DO(ORBIT) CODE_ATTR_DO(ORBIT)); #undef ORBIT // Clear out the redef bits, folding them back into predef. for (i = 0; i < ATTR_CONTEXT_LIMIT; i++) { attr_defs[i].predef |= attr_defs[i].redef; attr_defs[i].redef = 0; } // Now read the transmitted locally defined attrs. // This will set redef bits again. for (i = 0; i < attr_definition_count; i++) { int header = attr_definition_headers.getByte(); int attrc = ADH_BYTE_CONTEXT(header); int idx = ADH_BYTE_INDEX(header); entry *name = attr_definition_name.getRef(); entry *layout = attr_definition_layout.getRef(); attr_defs[attrc].defineLayout(idx, name, layout->value.b.strval()); } } #define NO_ENTRY_YET ((entry *)-1) static bool isDigitString(bytes &x, int beg, int end) { if (beg == end) return false; // nullptr string byte *xptr = x.ptr; for (int i = beg; i < end; i++) { char ch = xptr[i]; if (!(ch >= '0' && ch <= '9')) return false; } return true; } enum { // constants for parsing class names SLASH_MIN = '.', SLASH_MAX = '/', DOLLAR_MIN = 0, DOLLAR_MAX = '-'}; static int lastIndexOf(int chmin, int chmax, bytes &x, int pos) { byte *ptr = x.ptr; for (byte *cp = ptr + pos; --cp >= ptr;) { assert(x.inBounds(cp)); if (*cp >= chmin && *cp <= chmax) return (int)(cp - ptr); } return -1; } inner_class *constant_pool::getIC(entry *inner) { if (inner == nullptr) return nullptr; assert(inner->tag == CONSTANT_Class); if (inner->inord == NO_INORD) return nullptr; inner_class *ic = ic_index[inner->inord]; assert(ic == nullptr || ic->inner == inner); return ic; } inner_class *constant_pool::getFirstChildIC(entry *outer) { if (outer == nullptr) return nullptr; assert(outer->tag == CONSTANT_Class); if (outer->inord == NO_INORD) return nullptr; inner_class *ic = ic_child_index[outer->inord]; assert(ic == nullptr || ic->outer == outer); return ic; } inner_class *constant_pool::getNextChildIC(inner_class *child) { inner_class *ic = child->next_sibling; assert(ic == nullptr || ic->outer == child->outer); return ic; } void unpacker::read_ics() { int i; int index_size = cp.tag_count[CONSTANT_Class]; inner_class **ic_index = U_NEW(inner_class *, index_size); inner_class **ic_child_index = U_NEW(inner_class *, index_size); cp.ic_index = ic_index; cp.ic_child_index = ic_child_index; ics = U_NEW(inner_class, ic_count); ic_this_class.readData(ic_count); ic_flags.readData(ic_count); // Scan flags to get count of long-form bands. int long_forms = 0; for (i = 0; i < ic_count; i++) { int flags = ic_flags.getInt(); // may be long form! if ((flags & ACC_IC_LONG_FORM) != 0) { long_forms += 1; ics[i].name = NO_ENTRY_YET; } flags &= ~ACC_IC_LONG_FORM; entry *inner = ic_this_class.getRef(); uint32_t inord = inner->inord; assert(inord < (uint32_t)cp.tag_count[CONSTANT_Class]); if (ic_index[inord] != nullptr) { unpack_abort("identical inner class"); break; } ic_index[inord] = &ics[i]; ics[i].inner = inner; ics[i].flags = flags; assert(cp.getIC(inner) == &ics[i]); } // ic_this_class.done(); // ic_flags.done(); ic_outer_class.readData(long_forms); ic_name.readData(long_forms); for (i = 0; i < ic_count; i++) { if (ics[i].name == NO_ENTRY_YET) { // Long form. ics[i].outer = ic_outer_class.getRefN(); ics[i].name = ic_name.getRefN(); } else { // Fill in outer and name based on inner. bytes &n = ics[i].inner->value.b; bytes pkgOuter; bytes number; bytes name; // Parse n into pkgOuter and name (and number). int dollar1, dollar2; // pointers to $ in the pattern // parse n = (/)*($)?($)? int nlen = (int)n.len; int pkglen = lastIndexOf(SLASH_MIN, SLASH_MAX, n, nlen) + 1; dollar2 = lastIndexOf(DOLLAR_MIN, DOLLAR_MAX, n, nlen); if (dollar2 < 0) { unpack_abort(); } assert(dollar2 >= pkglen); if (isDigitString(n, dollar2 + 1, nlen)) { // n = (/)*$ number = n.slice(dollar2 + 1, nlen); name.set(nullptr, 0); dollar1 = dollar2; } else if (pkglen < (dollar1 = lastIndexOf(DOLLAR_MIN, DOLLAR_MAX, n, dollar2 - 1)) && isDigitString(n, dollar1 + 1, dollar2)) { // n = (/)*$$ number = n.slice(dollar1 + 1, dollar2); name = n.slice(dollar2 + 1, nlen); } else { // n = (/)*$ dollar1 = dollar2; number.set(nullptr, 0); name = n.slice(dollar2 + 1, nlen); } if (number.ptr == nullptr) pkgOuter = n.slice(0, dollar1); else pkgOuter.set(nullptr, 0); if (pkgOuter.ptr != nullptr) ics[i].outer = cp.ensureClass(pkgOuter); if (name.ptr != nullptr) ics[i].name = cp.ensureUtf8(name); } // update child/sibling list if (ics[i].outer != nullptr) { uint32_t outord = ics[i].outer->inord; if (outord != NO_INORD) { assert(outord < (uint32_t)cp.tag_count[CONSTANT_Class]); ics[i].next_sibling = ic_child_index[outord]; ic_child_index[outord] = &ics[i]; } } } // ic_outer_class.done(); // ic_name.done(); } void unpacker::read_classes() { class_this.readData(class_count); class_super.readData(class_count); class_interface_count.readData(class_count); class_interface.readData(class_interface_count.getIntTotal()); #if 0 int i; // Make a little mark on super-classes. for (i = 0; i < class_count; i++) { entry* e = class_super.getRefN(); if (e != nullptr) e->bits |= entry::EB_SUPER; } class_super.rewind(); #endif // Members. class_field_count.readData(class_count); class_method_count.readData(class_count); int field_count = class_field_count.getIntTotal(); int method_count = class_method_count.getIntTotal(); field_descr.readData(field_count); read_attrs(ATTR_CONTEXT_FIELD, field_count); method_descr.readData(method_count); read_attrs(ATTR_CONTEXT_METHOD, method_count); read_attrs(ATTR_CONTEXT_CLASS, class_count); read_code_headers(); } int unpacker::attr_definitions::predefCount(uint32_t idx) { return isPredefined(idx) ? flag_count[idx] : 0; } void unpacker::read_attrs(int attrc, int obj_count) { attr_definitions &ad = attr_defs[attrc]; assert(ad.attrc == attrc); int i, idx, count; bool haveLongFlags = ad.haveLongFlags(); band &xxx_flags_hi = ad.xxx_flags_hi(); if (haveLongFlags) xxx_flags_hi.readData(obj_count); band &xxx_flags_lo = ad.xxx_flags_lo(); xxx_flags_lo.readData(obj_count); // pre-scan flags, counting occurrences of each index bit uint64_t indexMask = ad.flagIndexMask(); // which flag bits are index bits? for (i = 0; i < obj_count; i++) { uint64_t indexBits = xxx_flags_hi.getLong(xxx_flags_lo, haveLongFlags); if ((indexBits & ~indexMask) > (ushort) - 1) { unpack_abort("undefined attribute flag bit"); return; } indexBits &= indexMask; // ignore classfile flag bits for (idx = 0; indexBits != 0; idx++, indexBits >>= 1) { ad.flag_count[idx] += (int)(indexBits & 1); } } // we'll scan these again later for output: xxx_flags_lo.rewind(); xxx_flags_hi.rewind(); band &xxx_attr_count = ad.xxx_attr_count(); // There is one count element for each 1<<16 bit set in flags: xxx_attr_count.readData(ad.predefCount(X_ATTR_OVERFLOW)); band &xxx_attr_indexes = ad.xxx_attr_indexes(); int overflowIndexCount = xxx_attr_count.getIntTotal(); xxx_attr_indexes.readData(overflowIndexCount); // pre-scan attr indexes, counting occurrences of each value for (i = 0; i < overflowIndexCount; i++) { idx = xxx_attr_indexes.getInt(); if (!ad.isIndex(idx)) { unpack_abort("attribute index out of bounds"); return; } ad.getCount(idx) += 1; } xxx_attr_indexes.rewind(); // we'll scan it again later for output // We will need a backward call count for each used backward callable. int backwardCounts = 0; for (idx = 0; idx < ad.layouts.length(); idx++) { layout_definition *lo = ad.getLayout(idx); if (lo != nullptr && ad.getCount(idx) != 0) { // Build the bands lazily, only when they are used. band **bands = ad.buildBands(lo); if (lo->hasCallables()) { for (i = 0; bands[i] != nullptr; i++) { if (bands[i]->le_back) { assert(bands[i]->le_kind == EK_CBLE); backwardCounts += 1; } } } } } ad.xxx_attr_calls().readData(backwardCounts); // Read built-in bands. // Mostly, these are hand-coded equivalents to readBandData(). switch (attrc) { case ATTR_CONTEXT_CLASS: count = ad.predefCount(CLASS_ATTR_SourceFile); class_SourceFile_RUN.readData(count); count = ad.predefCount(CLASS_ATTR_EnclosingMethod); class_EnclosingMethod_RC.readData(count); class_EnclosingMethod_RDN.readData(count); count = ad.predefCount(X_ATTR_Signature); class_Signature_RS.readData(count); ad.readBandData(X_ATTR_RuntimeVisibleAnnotations); ad.readBandData(X_ATTR_RuntimeInvisibleAnnotations); count = ad.predefCount(CLASS_ATTR_InnerClasses); class_InnerClasses_N.readData(count); count = class_InnerClasses_N.getIntTotal(); class_InnerClasses_RC.readData(count); class_InnerClasses_F.readData(count); // Drop remaining columns wherever flags are zero: count -= class_InnerClasses_F.getIntCount(0); class_InnerClasses_outer_RCN.readData(count); class_InnerClasses_name_RUN.readData(count); count = ad.predefCount(CLASS_ATTR_ClassFile_version); class_ClassFile_version_minor_H.readData(count); class_ClassFile_version_major_H.readData(count); break; case ATTR_CONTEXT_FIELD: count = ad.predefCount(FIELD_ATTR_ConstantValue); field_ConstantValue_KQ.readData(count); count = ad.predefCount(X_ATTR_Signature); field_Signature_RS.readData(count); ad.readBandData(X_ATTR_RuntimeVisibleAnnotations); ad.readBandData(X_ATTR_RuntimeInvisibleAnnotations); break; case ATTR_CONTEXT_METHOD: code_count = ad.predefCount(METHOD_ATTR_Code); // Code attrs are handled very specially below... count = ad.predefCount(METHOD_ATTR_Exceptions); method_Exceptions_N.readData(count); count = method_Exceptions_N.getIntTotal(); method_Exceptions_RC.readData(count); count = ad.predefCount(X_ATTR_Signature); method_Signature_RS.readData(count); ad.readBandData(X_ATTR_RuntimeVisibleAnnotations); ad.readBandData(X_ATTR_RuntimeInvisibleAnnotations); ad.readBandData(METHOD_ATTR_RuntimeVisibleParameterAnnotations); ad.readBandData(METHOD_ATTR_RuntimeInvisibleParameterAnnotations); ad.readBandData(METHOD_ATTR_AnnotationDefault); break; case ATTR_CONTEXT_CODE: // (keep this code aligned with its brother in unpacker::write_attrs) count = ad.predefCount(CODE_ATTR_StackMapTable); // disable this feature in old archives! if (count != 0 && majver < JAVA6_PACKAGE_MAJOR_VERSION) { unpack_abort("undefined StackMapTable attribute (old archive format)"); return; } code_StackMapTable_N.readData(count); count = code_StackMapTable_N.getIntTotal(); code_StackMapTable_frame_T.readData(count); // the rest of it depends in a complicated way on frame tags { int fat_frame_count = 0; int offset_count = 0; int type_count = 0; for (int k = 0; k < count; k++) { int tag = code_StackMapTable_frame_T.getByte(); if (tag <= 127) { // (64-127) [(2)] if (tag >= 64) type_count++; } else if (tag <= 251) { // (247) [(1)(2)] // (248-251) [(1)] if (tag >= 247) offset_count++; if (tag == 247) type_count++; } else if (tag <= 254) { // (252) [(1)(2)] // (253) [(1)(2)(2)] // (254) [(1)(2)(2)(2)] offset_count++; type_count += (tag - 251); } else { // (255) [(1)NH[(2)]NH[(2)]] fat_frame_count++; } } // done pre-scanning frame tags: code_StackMapTable_frame_T.rewind(); // deal completely with fat frames: offset_count += fat_frame_count; code_StackMapTable_local_N.readData(fat_frame_count); type_count += code_StackMapTable_local_N.getIntTotal(); code_StackMapTable_stack_N.readData(fat_frame_count); type_count += code_StackMapTable_stack_N.getIntTotal(); // read the rest: code_StackMapTable_offset.readData(offset_count); code_StackMapTable_T.readData(type_count); // (7) [RCH] count = code_StackMapTable_T.getIntCount(7); code_StackMapTable_RC.readData(count); // (8) [PH] count = code_StackMapTable_T.getIntCount(8); code_StackMapTable_P.readData(count); } count = ad.predefCount(CODE_ATTR_LineNumberTable); code_LineNumberTable_N.readData(count); count = code_LineNumberTable_N.getIntTotal(); code_LineNumberTable_bci_P.readData(count); code_LineNumberTable_line.readData(count); count = ad.predefCount(CODE_ATTR_LocalVariableTable); code_LocalVariableTable_N.readData(count); count = code_LocalVariableTable_N.getIntTotal(); code_LocalVariableTable_bci_P.readData(count); code_LocalVariableTable_span_O.readData(count); code_LocalVariableTable_name_RU.readData(count); code_LocalVariableTable_type_RS.readData(count); code_LocalVariableTable_slot.readData(count); count = ad.predefCount(CODE_ATTR_LocalVariableTypeTable); code_LocalVariableTypeTable_N.readData(count); count = code_LocalVariableTypeTable_N.getIntTotal(); code_LocalVariableTypeTable_bci_P.readData(count); code_LocalVariableTypeTable_span_O.readData(count); code_LocalVariableTypeTable_name_RU.readData(count); code_LocalVariableTypeTable_type_RS.readData(count); code_LocalVariableTypeTable_slot.readData(count); break; } // Read compressor-defined bands. for (idx = 0; idx < ad.layouts.length(); idx++) { if (ad.getLayout(idx) == nullptr) continue; // none at this fixed index <32 if (idx < (int)ad.flag_limit && ad.isPredefined(idx)) continue; // already handled if (ad.getCount(idx) == 0) continue; // no attributes of this type (then why transmit layouts?) ad.readBandData(idx); } } void unpacker::attr_definitions::readBandData(int idx) { int j; uint32_t count = getCount(idx); if (count == 0) return; layout_definition *lo = getLayout(idx); bool hasCallables = lo->hasCallables(); band **bands = lo->bands(); if (!hasCallables) { // Read through the rest of the bands in a regular way. readBandData(bands, count); } else { // Deal with the callables. // First set up the forward entry count for each callable. // This is stored on band::length of the callable. bands[0]->expectMoreLength(count); for (j = 0; bands[j] != nullptr; j++) { band &j_cble = *bands[j]; assert(j_cble.le_kind == EK_CBLE); if (j_cble.le_back) { // Add in the predicted effects of backward calls, too. int back_calls = xxx_attr_calls().getInt(); j_cble.expectMoreLength(back_calls); // In a moment, more forward calls may increment j_cble.length. } } // Now consult whichever callables have non-zero entry counts. readBandData(bands, (uint32_t) - 1); } } // Recursive helper to the previous function: void unpacker::attr_definitions::readBandData(band **body, uint32_t count) { int j, k; for (j = 0; body[j] != nullptr; j++) { band &b = *body[j]; if (b.defc != nullptr) { // It has data, so read it. b.readData(count); } switch (b.le_kind) { case EK_REPL: { int reps = b.getIntTotal(); readBandData(b.le_body, reps); } break; case EK_UN: { int remaining = count; for (k = 0; b.le_body[k] != nullptr; k++) { band &k_case = *b.le_body[k]; int k_count = 0; if (k_case.le_casetags == nullptr) { k_count = remaining; // last (empty) case } else { int *tags = k_case.le_casetags; int ntags = *tags++; // 1st element is length (why not?) while (ntags-- > 0) { int tag = *tags++; k_count += b.getIntCount(tag); } } readBandData(k_case.le_body, k_count); remaining -= k_count; } assert(remaining == 0); } break; case EK_CALL: // Push the count forward, if it is not a backward call. if (!b.le_back) { band &cble = *b.le_body[0]; assert(cble.le_kind == EK_CBLE); cble.expectMoreLength(count); } break; case EK_CBLE: assert((int)count == -1); // incoming count is meaningless k = b.length; assert(k >= 0); // This is intended and required for non production mode. assert((b.length = -1)); // make it unable to accept more calls now. readBandData(b.le_body, k); break; } } } static inline band **findMatchingCase(int matchTag, band **cases) { for (int k = 0; cases[k] != nullptr; k++) { band &k_case = *cases[k]; if (k_case.le_casetags != nullptr) { // If it has tags, it must match a tag. int *tags = k_case.le_casetags; int ntags = *tags++; // 1st element is length for (; ntags > 0; ntags--) { int tag = *tags++; if (tag == matchTag) break; } if (ntags == 0) continue; // does not match } return k_case.le_body; } return nullptr; } // write attribute band data: void unpacker::putlayout(band **body) { int i; int prevBII = -1; int prevBCI = -1; if (body == NULL) { unpack_abort("putlayout: unexpected NULL for body"); return; } for (i = 0; body[i] != nullptr; i++) { band &b = *body[i]; byte le_kind = b.le_kind; // Handle scalar part, if any. int x = 0; entry *e = nullptr; if (b.defc != nullptr) { // It has data, so unparse an element. if (b.ixTag != CONSTANT_None) { assert(le_kind == EK_REF); if (b.ixTag == CONSTANT_Literal) e = b.getRefUsing(cp.getKQIndex()); else e = b.getRefN(); switch (b.le_len) { case 0: break; case 1: putu1ref(e); break; case 2: putref(e); break; case 4: putu2(0); putref(e); break; default: assert(false); } } else { assert(le_kind == EK_INT || le_kind == EK_REPL || le_kind == EK_UN); x = b.getInt(); assert(!b.le_bci || prevBCI == (int)to_bci(prevBII)); switch (b.le_bci) { case EK_BCI: // PH: transmit R(bci), store bci x = to_bci(prevBII = x); prevBCI = x; break; case EK_BCID: // POH: transmit D(R(bci)), store bci x = to_bci(prevBII += x); prevBCI = x; break; case EK_BCO: // OH: transmit D(R(bci)), store D(bci) x = to_bci(prevBII += x) - prevBCI; prevBCI += x; break; } assert(!b.le_bci || prevBCI == (int)to_bci(prevBII)); switch (b.le_len) { case 0: break; case 1: putu1(x); break; case 2: putu2(x); break; case 4: putu4(x); break; default: assert(false); } } } // Handle subparts, if any. switch (le_kind) { case EK_REPL: // x is the repeat count while (x-- > 0) { putlayout(b.le_body); } break; case EK_UN: // x is the tag putlayout(findMatchingCase(x, b.le_body)); break; case EK_CALL: { band &cble = *b.le_body[0]; assert(cble.le_kind == EK_CBLE); // FIXME: hit this one // assert(cble.le_len == b.le_len); putlayout(cble.le_body); } break; case EK_CBLE: case EK_CASE: assert(false); // should not reach here } } } void unpacker::read_files() { file_name.readData(file_count); if ((archive_options & AO_HAVE_FILE_SIZE_HI) != 0) file_size_hi.readData(file_count); file_size_lo.readData(file_count); if ((archive_options & AO_HAVE_FILE_MODTIME) != 0) file_modtime.readData(file_count); int allFiles = file_count + class_count; if ((archive_options & AO_HAVE_FILE_OPTIONS) != 0) { file_options.readData(file_count); // FO_IS_CLASS_STUB might be set, causing overlap between classes and files for (int i = 0; i < file_count; i++) { if ((file_options.getInt() & FO_IS_CLASS_STUB) != 0) { allFiles -= 1; // this one counts as both class and file } } file_options.rewind(); } assert((default_file_options & FO_IS_CLASS_STUB) == 0); files_remaining = allFiles; } void unpacker::get_code_header(int &max_stack, int &max_na_locals, int &handler_count, int &cflags) { int sc = code_headers.getByte(); if (sc == 0) { max_stack = max_na_locals = handler_count = cflags = -1; return; } // Short code header is the usual case: int nh; int mod; if (sc < 1 + 12 * 12) { sc -= 1; nh = 0; mod = 12; } else if (sc < 1 + 12 * 12 + 8 * 8) { sc -= 1 + 12 * 12; nh = 1; mod = 8; } else { assert(sc < 1 + 12 * 12 + 8 * 8 + 7 * 7); sc -= 1 + 12 * 12 + 8 * 8; nh = 2; mod = 7; } max_stack = sc % mod; max_na_locals = sc / mod; // caller must add static, siglen handler_count = nh; if ((archive_options & AO_HAVE_ALL_CODE_FLAGS) != 0) cflags = -1; else cflags = 0; // this one has no attributes } // Cf. PackageReader.readCodeHeaders void unpacker::read_code_headers() { code_headers.readData(code_count); int totalHandlerCount = 0; int totalFlagsCount = 0; for (int i = 0; i < code_count; i++) { int max_stack, max_locals, handler_count, cflags; get_code_header(max_stack, max_locals, handler_count, cflags); if (max_stack < 0) code_max_stack.expectMoreLength(1); if (max_locals < 0) code_max_na_locals.expectMoreLength(1); if (handler_count < 0) code_handler_count.expectMoreLength(1); else totalHandlerCount += handler_count; if (cflags < 0) totalFlagsCount += 1; } code_headers.rewind(); // replay later during writing code_max_stack.readData(); code_max_na_locals.readData(); code_handler_count.readData(); totalHandlerCount += code_handler_count.getIntTotal(); // Read handler specifications. // Cf. PackageReader.readCodeHandlers. code_handler_start_P.readData(totalHandlerCount); code_handler_end_PO.readData(totalHandlerCount); code_handler_catch_PO.readData(totalHandlerCount); code_handler_class_RCN.readData(totalHandlerCount); read_attrs(ATTR_CONTEXT_CODE, totalFlagsCount); } static inline bool is_in_range(uint32_t n, uint32_t min, uint32_t max) { return n - min <= max - min; // unsigned arithmetic! } static inline bool is_field_op(int bc) { return is_in_range(bc, bc_getstatic, bc_putfield); } static inline bool is_invoke_init_op(int bc) { return is_in_range(bc, _invokeinit_op, _invokeinit_limit - 1); } static inline bool is_self_linker_op(int bc) { return is_in_range(bc, _self_linker_op, _self_linker_limit - 1); } static bool is_branch_op(int bc) { return is_in_range(bc, bc_ifeq, bc_jsr) || is_in_range(bc, bc_ifnull, bc_jsr_w); } static bool is_local_slot_op(int bc) { return is_in_range(bc, bc_iload, bc_aload) || is_in_range(bc, bc_istore, bc_astore) || bc == bc_iinc || bc == bc_ret; } band *unpacker::ref_band_for_op(int bc) { switch (bc) { case bc_ildc: case bc_ildc_w: return &bc_intref; case bc_fldc: case bc_fldc_w: return &bc_floatref; case bc_lldc2_w: return &bc_longref; case bc_dldc2_w: return &bc_doubleref; case bc_aldc: case bc_aldc_w: return &bc_stringref; case bc_cldc: case bc_cldc_w: return &bc_classref; case bc_getstatic: case bc_putstatic: case bc_getfield: case bc_putfield: return &bc_fieldref; case bc_invokevirtual: case bc_invokespecial: case bc_invokestatic: return &bc_methodref; case bc_invokeinterface: return &bc_imethodref; case bc_new: case bc_anewarray: case bc_checkcast: case bc_instanceof: case bc_multianewarray: return &bc_classref; } return nullptr; } band *unpacker::ref_band_for_self_op(int bc, bool &isAloadVar, int &origBCVar) { if (!is_self_linker_op(bc)) return nullptr; int idx = (bc - _self_linker_op); bool isSuper = (idx >= _self_linker_super_flag); if (isSuper) idx -= _self_linker_super_flag; bool isAload = (idx >= _self_linker_aload_flag); if (isAload) idx -= _self_linker_aload_flag; int origBC = _first_linker_op + idx; bool isField = is_field_op(origBC); isAloadVar = isAload; origBCVar = _first_linker_op + idx; if (!isSuper) return isField ? &bc_thisfield : &bc_thismethod; else return isField ? &bc_superfield : &bc_supermethod; } // Cf. PackageReader.readByteCodes inline // called exactly once => inline void unpacker::read_bcs() { // read from bc_codes and bc_case_count fillbytes all_switch_ops; all_switch_ops.init(); // Read directly from rp/rplimit. // Do this later: bc_codes.readData(...) byte *rp0 = rp; band *bc_which; byte *opptr = rp; byte *oplimit = rplimit; bool isAload; // passed by ref and then ignored int junkBC; // passed by ref and then ignored for (int k = 0; k < code_count; k++) { // Scan one method: for (;;) { if (opptr + 2 > oplimit) { rp = opptr; ensure_input(2); oplimit = rplimit; rp = rp0; // back up } if (opptr == oplimit) { unpack_abort(); } int bc = *opptr++ & 0xFF; bool isWide = false; if (bc == bc_wide) { if (opptr == oplimit) { unpack_abort(); } bc = *opptr++ & 0xFF; isWide = true; } // Adjust expectations of various band sizes. switch (bc) { case bc_tableswitch: case bc_lookupswitch: all_switch_ops.addByte(bc); break; case bc_iinc: bc_local.expectMoreLength(1); bc_which = isWide ? &bc_short : &bc_byte; bc_which->expectMoreLength(1); break; case bc_sipush: bc_short.expectMoreLength(1); break; case bc_bipush: bc_byte.expectMoreLength(1); break; case bc_newarray: bc_byte.expectMoreLength(1); break; case bc_multianewarray: assert(ref_band_for_op(bc) == &bc_classref); bc_classref.expectMoreLength(1); bc_byte.expectMoreLength(1); break; case bc_ref_escape: bc_escrefsize.expectMoreLength(1); bc_escref.expectMoreLength(1); break; case bc_byte_escape: bc_escsize.expectMoreLength(1); // bc_escbyte will have to be counted too break; default: if (is_invoke_init_op(bc)) { bc_initref.expectMoreLength(1); break; } bc_which = ref_band_for_self_op(bc, isAload, junkBC); if (bc_which != nullptr) { bc_which->expectMoreLength(1); break; } if (is_branch_op(bc)) { bc_label.expectMoreLength(1); break; } bc_which = ref_band_for_op(bc); if (bc_which != nullptr) { bc_which->expectMoreLength(1); assert(bc != bc_multianewarray); // handled elsewhere break; } if (is_local_slot_op(bc)) { bc_local.expectMoreLength(1); break; } break; case bc_end_marker: // Increment k and test against code_count. goto doneScanningMethod; } } doneScanningMethod: { } } // Go through the formality, so we can use it in a regular fashion later: assert(rp == rp0); bc_codes.readData((int)(opptr - rp)); int i = 0; // To size instruction bands correctly, we need info on switches: bc_case_count.readData((int)all_switch_ops.size()); for (i = 0; i < (int)all_switch_ops.size(); i++) { int caseCount = bc_case_count.getInt(); int bc = all_switch_ops.getByte(i); bc_label.expectMoreLength(1 + caseCount); // default label + cases bc_case_value.expectMoreLength(bc == bc_tableswitch ? 1 : caseCount); } bc_case_count.rewind(); // uses again for output all_switch_ops.free(); for (i = e_bc_case_value; i <= e_bc_escsize; i++) { all_bands[i].readData(); } // The bc_escbyte band is counted by the immediately previous band. bc_escbyte.readData(bc_escsize.getIntTotal()); } void unpacker::read_bands() { read_file_header(); if (cp.nentries == 0) { // read_file_header failed to read a CP, because it copied a JAR. return; } // Do this after the file header has been read: check_options(); read_cp(); read_attr_defs(); read_ics(); read_classes(); read_bcs(); read_files(); } /// CP routines entry *&constant_pool::hashTabRef(byte tag, bytes &b) { uint32_t hash = tag + (int)b.len; for (int i = 0; i < (int)b.len; i++) { hash = hash * 31 + (0xFF & b.ptr[i]); } entry **ht = hashTab; int hlen = hashTabLength; assert((hlen & (hlen - 1)) == 0); // must be power of 2 uint32_t hash1 = hash & (hlen - 1); // == hash % hlen uint32_t hash2 = 0; // lazily computed (requires mod op.) int probes = 0; while (ht[hash1] != nullptr) { entry &e = *ht[hash1]; if (e.value.b.equals(b) && e.tag == tag) break; if (hash2 == 0) // Note: hash2 must be relatively prime to hlen, hence the "|1". hash2 = (((hash % 499) & (hlen - 1)) | 1); hash1 += hash2; if (hash1 >= (uint32_t)hlen) hash1 -= hlen; assert(hash1 < (uint32_t)hlen); assert(++probes < hlen); } return ht[hash1]; } static void insert_extra(entry *e, ptrlist &extras) { // This ordering helps implement the Pack200 requirement // of a predictable CP order in the class files produced. e->inord = NO_INORD; // mark as an "extra" extras.add(e); // Note: We will sort the list (by string-name) later. } entry *constant_pool::ensureUtf8(bytes &b) { entry *&ix = hashTabRef(CONSTANT_Utf8, b); if (ix != nullptr) return ix; // Make one. if (nentries == maxentries) { unpack_abort("cp utf8 overflow"); return &entries[tag_base[CONSTANT_Utf8]]; // return something } entry &e = entries[nentries++]; e.tag = CONSTANT_Utf8; u->saveTo(e.value.b, b); assert(&e >= first_extra_entry); insert_extra(&e, tag_extras[CONSTANT_Utf8]); return ix = &e; } entry *constant_pool::ensureClass(bytes &b) { entry *&ix = hashTabRef(CONSTANT_Class, b); if (ix != nullptr) return ix; // Make one. if (nentries == maxentries) { unpack_abort("cp class overflow"); return &entries[tag_base[CONSTANT_Class]]; // return something } entry &e = entries[nentries++]; e.tag = CONSTANT_Class; e.nrefs = 1; e.refs = U_NEW(entry *, 1); ix = &e; // hold my spot in the index entry *utf = ensureUtf8(b); e.refs[0] = utf; e.value.b = utf->value.b; assert(&e >= first_extra_entry); insert_extra(&e, tag_extras[CONSTANT_Class]); return &e; } void constant_pool::expandSignatures() { int i; int nsigs = 0; int nreused = 0; int first_sig = tag_base[CONSTANT_Signature]; int sig_limit = tag_count[CONSTANT_Signature] + first_sig; fillbytes buf; buf.init(1 << 10); for (i = first_sig; i < sig_limit; i++) { entry &e = entries[i]; assert(e.tag == CONSTANT_Signature); int refnum = 0; bytes form = e.refs[refnum++]->asUtf8(); buf.empty(); for (int j = 0; j < (int)form.len; j++) { int c = form.ptr[j]; buf.addByte(c); if (c == 'L') { entry *cls = e.refs[refnum++]; buf.append(cls->className()->asUtf8()); } } assert(refnum == e.nrefs); bytes &sig = buf.b; // try to find a pre-existing Utf8: entry *&e2 = hashTabRef(CONSTANT_Utf8, sig); if (e2 != nullptr) { assert(e2->isUtf8(sig)); e.value.b = e2->value.b; e.refs[0] = e2; e.nrefs = 1; nreused++; } else { // there is no other replacement; reuse this CP entry as a Utf8 u->saveTo(e.value.b, sig); e.tag = CONSTANT_Utf8; e.nrefs = 0; e2 = &e; } nsigs++; } buf.free(); // go expunge all references to remaining signatures: for (i = 0; i < (int)nentries; i++) { entry &e = entries[i]; for (int j = 0; j < e.nrefs; j++) { entry *&e2 = e.refs[j]; if (e2 != nullptr && e2->tag == CONSTANT_Signature) e2 = e2->refs[0]; } } } void constant_pool::initMemberIndexes() { // This function does NOT refer to any class schema. // It is totally internal to the cpool. int i, j; // Get the pre-existing indexes: int nclasses = tag_count[CONSTANT_Class]; // entry *classes = tag_base[CONSTANT_Class] + entries; // UNUSED int nfields = tag_count[CONSTANT_Fieldref]; entry *fields = tag_base[CONSTANT_Fieldref] + entries; int nmethods = tag_count[CONSTANT_Methodref]; entry *methods = tag_base[CONSTANT_Methodref] + entries; int *field_counts = T_NEW(int, nclasses); int *method_counts = T_NEW(int, nclasses); cpindex *all_indexes = U_NEW(cpindex, nclasses * 2); entry **field_ix = U_NEW(entry *, add_size(nfields, nclasses)); entry **method_ix = U_NEW(entry *, add_size(nmethods, nclasses)); for (j = 0; j < nfields; j++) { entry &f = fields[j]; i = f.memberClass()->inord; assert(i < nclasses); field_counts[i]++; } for (j = 0; j < nmethods; j++) { entry &m = methods[j]; i = m.memberClass()->inord; assert(i < nclasses); method_counts[i]++; } int fbase = 0, mbase = 0; for (i = 0; i < nclasses; i++) { int fc = field_counts[i]; int mc = method_counts[i]; all_indexes[i * 2 + 0].init(fc, field_ix + fbase, CONSTANT_Fieldref + SUBINDEX_BIT); all_indexes[i * 2 + 1].init(mc, method_ix + mbase, CONSTANT_Methodref + SUBINDEX_BIT); // reuse field_counts and member_counts as fill pointers: field_counts[i] = fbase; method_counts[i] = mbase; fbase += fc + 1; mbase += mc + 1; // (the +1 leaves a space between every subarray) } assert(fbase == nfields + nclasses); assert(mbase == nmethods + nclasses); for (j = 0; j < nfields; j++) { entry &f = fields[j]; i = f.memberClass()->inord; field_ix[field_counts[i]++] = &f; } for (j = 0; j < nmethods; j++) { entry &m = methods[j]; i = m.memberClass()->inord; method_ix[method_counts[i]++] = &m; } member_indexes = all_indexes; // Free intermediate buffers. u->free_temps(); } void entry::requestOutputIndex(constant_pool &cp, int req) { assert(outputIndex <= NOT_REQUESTED); // must not have assigned indexes yet if (tag == CONSTANT_Signature) { ref(0)->requestOutputIndex(cp, req); return; } assert(req == REQUESTED || req == REQUESTED_LDC); if (outputIndex != NOT_REQUESTED) { if (req == REQUESTED_LDC) outputIndex = req; // this kind has precedence return; } outputIndex = req; // assert(!cp.outputEntries.contains(this)); assert(tag != CONSTANT_Signature); cp.outputEntries.add(this); for (int j = 0; j < nrefs; j++) { ref(j)->requestOutputIndex(cp); } } void constant_pool::resetOutputIndexes() { int i; int noes = outputEntries.length(); entry **oes = (entry **)outputEntries.base(); for (i = 0; i < noes; i++) { entry &e = *oes[i]; e.outputIndex = NOT_REQUESTED; } outputIndexLimit = 0; outputEntries.empty(); } static const byte TAG_ORDER[CONSTANT_Limit] = {0, 1, 0, 2, 3, 4, 5, 7, 6, 10, 11, 12, 9, 8}; extern "C" int outputEntry_cmp(const void *e1p, const void *e2p) { // Sort entries according to the Pack200 rules for deterministic // constant pool ordering. // // The four sort keys as follows, in order of decreasing importance: // 1. ldc first, then non-ldc guys // 2. normal cp_All entries by input order (i.e., address order) // 3. after that, extra entries by lexical order (as in tag_extras[*]) entry &e1 = *(entry *)*(void **)e1p; entry &e2 = *(entry *)*(void **)e2p; int oi1 = e1.outputIndex; int oi2 = e2.outputIndex; assert(oi1 == REQUESTED || oi1 == REQUESTED_LDC); assert(oi2 == REQUESTED || oi2 == REQUESTED_LDC); if (oi1 != oi2) { if (oi1 == REQUESTED_LDC) return 0 - 1; if (oi2 == REQUESTED_LDC) return 1 - 0; // Else fall through; neither is an ldc request. } if (e1.inord != NO_INORD || e2.inord != NO_INORD) { // One or both is normal. Use input order. if (&e1 > &e2) return 1 - 0; if (&e1 < &e2) return 0 - 1; return 0; // equal pointers } // Both are extras. Sort by tag and then by value. if (e1.tag != e2.tag) { return TAG_ORDER[e1.tag] - TAG_ORDER[e2.tag]; } // If the tags are the same, use string comparison. return compare_Utf8_chars(e1.value.b, e2.value.b); } void constant_pool::computeOutputIndexes() { int i; int noes = outputEntries.length(); entry **oes = (entry **)outputEntries.base(); // Sort the output constant pool into the order required by Pack200. PTRLIST_QSORT(outputEntries, outputEntry_cmp); // Allocate a new index for each entry that needs one. // We do this in two passes, one for LDC entries and one for the rest. int nextIndex = 1; // always skip index #0 in output cpool for (i = 0; i < noes; i++) { entry &e = *oes[i]; assert(e.outputIndex == REQUESTED || e.outputIndex == REQUESTED_LDC); e.outputIndex = nextIndex++; if (e.isDoubleWord()) nextIndex++; // do not use the next index } outputIndexLimit = nextIndex; } // Unpacker Start // Deallocate all internal storage and reset to a clean state. // Do not disturb any input or output connections, including // infileptr, inbytes, read_input_fn, jarout, or errstrm. // Do not reset any unpack options. void unpacker::reset() { bytes_read_before_reset += bytes_read; bytes_written_before_reset += bytes_written; files_written_before_reset += files_written; classes_written_before_reset += classes_written; segments_read_before_reset += 1; if (verbose >= 2) { fprintf(stderr, "After segment %d, " LONG_LONG_FORMAT " bytes read and " LONG_LONG_FORMAT " bytes written.\n", segments_read_before_reset - 1, bytes_read_before_reset, bytes_written_before_reset); fprintf(stderr, "After segment %d, %d files (of which %d are classes) written to output.\n", segments_read_before_reset - 1, files_written_before_reset, classes_written_before_reset); if (archive_next_count != 0) { fprintf(stderr, "After segment %d, %d segment%s remaining (estimated).\n", segments_read_before_reset - 1, archive_next_count, archive_next_count == 1 ? "" : "s"); } } unpacker save_u = (*this); // save bytewise image infileptr = nullptr; // make asserts happy jarout = nullptr; // do not close the output jar gzin = nullptr; // do not close the input gzip stream this->free(); this->init(read_input_fn); // restore selected interface state: infileptr = save_u.infileptr; inbytes = save_u.inbytes; jarout = save_u.jarout; gzin = save_u.gzin; verbose = save_u.verbose; deflate_hint_or_zero = save_u.deflate_hint_or_zero; modification_time_or_zero = save_u.modification_time_or_zero; bytes_read_before_reset = save_u.bytes_read_before_reset; bytes_written_before_reset = save_u.bytes_written_before_reset; files_written_before_reset = save_u.files_written_before_reset; classes_written_before_reset = save_u.classes_written_before_reset; segments_read_before_reset = save_u.segments_read_before_reset; // Note: If we use strip_names, watch out: They get nuked here. } void unpacker::init(read_input_fn_t input_fn) { int i; BYTES_OF(*this).clear(); this->u = this; // self-reference for U_NEW macro read_input_fn = input_fn; all_bands = band::makeBands(this); // Make a default jar buffer; caller may safely overwrite it. jarout = U_NEW(jar, 1); jarout->init(this); for (i = 0; i < ATTR_CONTEXT_LIMIT; i++) attr_defs[i].u = u; // set up outer ptr } // Usage: unpack a byte buffer // packptr is a reference to byte buffer containing a // packed file and len is the length of the buffer. // If nullptr, the callback is used to fill an internal buffer. void unpacker::start(void *packptr, size_t len) { if (packptr != nullptr && len != 0) { inbytes.set((byte *)packptr, len); } read_bands(); } void unpacker::check_options() { if (deflate_hint_or_zero != 0) { bool force_deflate_hint = (deflate_hint_or_zero > 0); if (force_deflate_hint) default_file_options |= FO_DEFLATE_HINT; else default_file_options &= ~FO_DEFLATE_HINT; // Turn off per-file deflate hint by force. suppress_file_options |= FO_DEFLATE_HINT; } if (modification_time_or_zero != 0) { default_file_modtime = modification_time_or_zero; // Turn off per-file modtime by force. archive_options &= ~AO_HAVE_FILE_MODTIME; } } // classfile writing void unpacker::reset_cur_classfile() { // set defaults cur_class_minver = default_class_minver; cur_class_majver = default_class_majver; // reset constant pool state cp.resetOutputIndexes(); // reset fixups class_fixup_type.empty(); class_fixup_offset.empty(); class_fixup_ref.empty(); requested_ics.empty(); } cpindex *constant_pool::getKQIndex() { char ch = '?'; if (u->cur_descr != nullptr) { entry *type = u->cur_descr->descrType(); ch = type->value.b.ptr[0]; } byte tag = CONSTANT_Integer; switch (ch) { case 'L': tag = CONSTANT_String; break; case 'I': tag = CONSTANT_Integer; break; case 'J': tag = CONSTANT_Long; break; case 'F': tag = CONSTANT_Float; break; case 'D': tag = CONSTANT_Double; break; case 'B': case 'S': case 'C': case 'Z': tag = CONSTANT_Integer; break; default: unpack_abort("bad KQ reference"); break; } return getIndex(tag); } uint32_t unpacker::to_bci(uint32_t bii) { uint32_t len = bcimap.length(); uint32_t *map = (uint32_t *)bcimap.base(); assert(len > 0); // must be initialized before using to_bci if (bii < len) return map[bii]; // Else it's a fractional or out-of-range BCI. uint32_t key = bii - len; for (int i = len;; i--) { if (map[i - 1] - (i - 1) <= key) break; else --bii; } return bii; } void unpacker::put_stackmap_type() { int tag = code_StackMapTable_T.getByte(); putu1(tag); switch (tag) { case 7: // (7) [RCH] putref(code_StackMapTable_RC.getRef()); break; case 8: // (8) [PH] putu2(to_bci(code_StackMapTable_P.getInt())); break; } } // Functions for writing code. void unpacker::put_label(int curIP, int size) { code_fixup_type.addByte(size); code_fixup_offset.add((int)put_empty(size)); code_fixup_source.add(curIP); } inline // called exactly once => inline void unpacker::write_bc_ops() { bcimap.empty(); code_fixup_type.empty(); code_fixup_offset.empty(); code_fixup_source.empty(); band *bc_which; byte *opptr = bc_codes.curRP(); // No need for oplimit, since the codes are pre-counted. size_t codeBase = wpoffset(); bool isAload; // copy-out result int origBC; entry *thisClass = cur_class; entry *superClass = cur_super; entry *newClass = nullptr; // class of last _new opcode // overwrite any prior index on these bands; it changes w/ current class: bc_thisfield.setIndex(cp.getFieldIndex(thisClass)); bc_thismethod.setIndex(cp.getMethodIndex(thisClass)); if (superClass != nullptr) { bc_superfield.setIndex(cp.getFieldIndex(superClass)); bc_supermethod.setIndex(cp.getMethodIndex(superClass)); } for (int curIP = 0;; curIP++) { int curPC = (int)(wpoffset() - codeBase); bcimap.add(curPC); ensure_put_space(10); // covers most instrs w/o further bounds check int bc = *opptr++ & 0xFF; putu1_fast(bc); // Note: See '--wp' below for pseudo-bytecodes like bc_end_marker. bool isWide = false; if (bc == bc_wide) { bc = *opptr++ & 0xFF; putu1_fast(bc); isWide = true; } switch (bc) { case bc_end_marker: --wp; // not really part of the code assert(opptr <= bc_codes.maxRP()); bc_codes.curRP() = opptr; // advance over this in bc_codes goto doneScanningMethod; case bc_tableswitch: // apc: (df, lo, hi, (hi-lo+1)*(label)) case bc_lookupswitch: // apc: (df, nc, nc*(case, label)) { int caseCount = bc_case_count.getInt(); while (((wpoffset() - codeBase) % 4) != 0) putu1_fast(0); ensure_put_space(30 + caseCount * 8); put_label(curIP, 4); // int df = bc_label.getInt(); if (bc == bc_tableswitch) { int lo = bc_case_value.getInt(); int hi = lo + caseCount - 1; putu4(lo); putu4(hi); for (int j = 0; j < caseCount; j++) { put_label(curIP, 4); // int lVal = bc_label.getInt(); // int cVal = lo + j; } } else { putu4(caseCount); for (int j = 0; j < caseCount; j++) { int cVal = bc_case_value.getInt(); putu4(cVal); put_label(curIP, 4); // int lVal = bc_label.getInt(); } } assert((int)to_bci(curIP) == curPC); continue; } case bc_iinc: { int local = bc_local.getInt(); int delta = (isWide ? bc_short : bc_byte).getInt(); if (isWide) { putu2(local); putu2(delta); } else { putu1_fast(local); putu1_fast(delta); } continue; } case bc_sipush: { int val = bc_short.getInt(); putu2(val); continue; } case bc_bipush: case bc_newarray: { int val = bc_byte.getByte(); putu1_fast(val); continue; } case bc_ref_escape: { // Note that insnMap has one entry for this. --wp; // not really part of the code int size = bc_escrefsize.getInt(); entry *ref = bc_escref.getRefN(); switch (size) { case 1: putu1ref(ref); break; case 2: putref(ref); break; default: assert(false); } continue; } case bc_byte_escape: { // Note that insnMap has one entry for all these bytes. --wp; // not really part of the code int size = bc_escsize.getInt(); ensure_put_space(size); for (int j = 0; j < size; j++) putu1_fast(bc_escbyte.getByte()); continue; } default: if (is_invoke_init_op(bc)) { origBC = bc_invokespecial; entry *classRef; switch (bc - _invokeinit_op) { case _invokeinit_self_option: classRef = thisClass; break; case _invokeinit_super_option: classRef = superClass; break; default: assert(bc == _invokeinit_op + _invokeinit_new_option); case _invokeinit_new_option: classRef = newClass; break; } wp[-1] = origBC; // overwrite with origBC int coding = bc_initref.getInt(); // Find the nth overloading of in classRef. entry *ref = nullptr; cpindex *ix = (classRef == nullptr) ? nullptr : cp.getMethodIndex(classRef); for (int j = 0, which_init = 0;; j++) { ref = (ix == nullptr) ? nullptr : ix->get(j); if (ref == nullptr) break; // oops, bad input assert(ref->tag == CONSTANT_Methodref); if (ref->memberDescr()->descrName() == cp.sym[constant_pool::s_lt_init_gt]) { if (which_init++ == coding) break; } } putref(ref); continue; } bc_which = ref_band_for_self_op(bc, isAload, origBC); if (bc_which != nullptr) { if (!isAload) { wp[-1] = origBC; // overwrite with origBC } else { wp[-1] = bc_aload_0; // overwrite with _aload_0 // Note: insnMap keeps the _aload_0 separate. bcimap.add(++curPC); ++curIP; putu1_fast(origBC); } entry *ref = bc_which->getRef(); putref(ref); continue; } if (is_branch_op(bc)) { // int lVal = bc_label.getInt(); if (bc < bc_goto_w) { put_label(curIP, 2); // putu2(lVal & 0xFFFF); } else { assert(bc <= bc_jsr_w); put_label(curIP, 4); // putu4(lVal); } assert((int)to_bci(curIP) == curPC); continue; } bc_which = ref_band_for_op(bc); if (bc_which != nullptr) { entry *ref = bc_which->getRefCommon(bc_which->ix, bc_which->nullOK); if (ref == nullptr && bc_which == &bc_classref) { // Shorthand for class self-references. ref = thisClass; } origBC = bc; switch (bc) { case bc_ildc: case bc_cldc: case bc_fldc: case bc_aldc: origBC = bc_ldc; break; case bc_ildc_w: case bc_cldc_w: case bc_fldc_w: case bc_aldc_w: origBC = bc_ldc_w; break; case bc_lldc2_w: case bc_dldc2_w: origBC = bc_ldc2_w; break; case bc_new: newClass = ref; break; } wp[-1] = origBC; // overwrite with origBC if (origBC == bc_ldc) { putu1ref(ref); } else { putref(ref); } if (origBC == bc_multianewarray) { // Copy the trailing byte also. int val = bc_byte.getByte(); putu1_fast(val); } else if (origBC == bc_invokeinterface) { int argSize = ref->memberDescr()->descrType()->typeSize(); putu1_fast(1 + argSize); putu1_fast(0); } continue; } if (is_local_slot_op(bc)) { int local = bc_local.getInt(); if (isWide) { putu2(local); if (bc == bc_iinc) { int iVal = bc_short.getInt(); putu2(iVal); } } else { putu1_fast(local); if (bc == bc_iinc) { int iVal = bc_byte.getByte(); putu1_fast(iVal); } } continue; } // Random bytecode. Just copy it. assert(bc < bc_bytecode_limit); } } doneScanningMethod: { } // bcimap.add(curPC); // PC limit is already also in map, from bc_end_marker // Armed with a bcimap, we can now fix up all the labels. for (int i = 0; i < (int)code_fixup_type.size(); i++) { int type = code_fixup_type.getByte(i); byte *bp = wp_at(code_fixup_offset.get(i)); int curIP = code_fixup_source.get(i); int destIP = curIP + bc_label.getInt(); int span = to_bci(destIP) - to_bci(curIP); switch (type) { case 2: putu2_at(bp, (ushort)span); break; case 4: putu4_at(bp, span); break; default: assert(false); } } } inline // called exactly once => inline void unpacker::write_code() { int j; int max_stack, max_locals, handler_count, cflags; get_code_header(max_stack, max_locals, handler_count, cflags); if (max_stack < 0) max_stack = code_max_stack.getInt(); if (max_locals < 0) max_locals = code_max_na_locals.getInt(); if (handler_count < 0) handler_count = code_handler_count.getInt(); int siglen = cur_descr->descrType()->typeSize(); if ((cur_descr_flags & ACC_STATIC) == 0) siglen++; max_locals += siglen; putu2(max_stack); putu2(max_locals); size_t bcbase = put_empty(4); // Write the bytecodes themselves. write_bc_ops(); byte *bcbasewp = wp_at(bcbase); putu4_at(bcbasewp, (int)(wp - (bcbasewp + 4))); // size of code attr putu2(handler_count); for (j = 0; j < handler_count; j++) { int bii = code_handler_start_P.getInt(); putu2(to_bci(bii)); bii += code_handler_end_PO.getInt(); putu2(to_bci(bii)); bii += code_handler_catch_PO.getInt(); putu2(to_bci(bii)); putref(code_handler_class_RCN.getRefN()); } uint64_t indexBits = cflags; if (cflags < 0) { bool haveLongFlags = attr_defs[ATTR_CONTEXT_CODE].haveLongFlags(); indexBits = code_flags_hi.getLong(code_flags_lo, haveLongFlags); } write_attrs(ATTR_CONTEXT_CODE, indexBits); } int unpacker::write_attrs(int attrc, uint64_t indexBits) { if (indexBits == 0) { // Quick short-circuit. putu2(0); return 0; } attr_definitions &ad = attr_defs[attrc]; int i, j, j2, idx, count; int oiCount = 0; if (ad.isPredefined(X_ATTR_OVERFLOW) && (indexBits & ((uint64_t)1 << X_ATTR_OVERFLOW)) != 0) { indexBits -= ((uint64_t)1 << X_ATTR_OVERFLOW); oiCount = ad.xxx_attr_count().getInt(); } int bitIndexes[X_ATTR_LIMIT_FLAGS_HI]; int biCount = 0; // Fill bitIndexes with index bits, in order. for (idx = 0; indexBits != 0; idx++, indexBits >>= 1) { if ((indexBits & 1) != 0) bitIndexes[biCount++] = idx; } assert(biCount <= (int)lengthof(bitIndexes)); // Write a provisional attribute count, perhaps to be corrected later. int naOffset = (int)wpoffset(); int na0 = biCount + oiCount; putu2(na0); int na = 0; for (i = 0; i < na0; i++) { if (i < biCount) idx = bitIndexes[i]; else idx = ad.xxx_attr_indexes().getInt(); assert(ad.isIndex(idx)); entry *aname = nullptr; entry *ref; // scratch size_t abase = put_empty(2 + 4); if (idx < (int)ad.flag_limit && ad.isPredefined(idx)) { // Switch on the attrc and idx simultaneously. switch (ADH_BYTE(attrc, idx)) { case ADH_BYTE(ATTR_CONTEXT_CLASS, X_ATTR_OVERFLOW) : case ADH_BYTE(ATTR_CONTEXT_FIELD, X_ATTR_OVERFLOW) : case ADH_BYTE(ATTR_CONTEXT_METHOD, X_ATTR_OVERFLOW) : case ADH_BYTE(ATTR_CONTEXT_CODE, X_ATTR_OVERFLOW) : // no attribute at all, so back up on this one wp = wp_at(abase); continue; case ADH_BYTE(ATTR_CONTEXT_CLASS, CLASS_ATTR_ClassFile_version) : cur_class_minver = class_ClassFile_version_minor_H.getInt(); cur_class_majver = class_ClassFile_version_major_H.getInt(); // back up; not a real attribute wp = wp_at(abase); continue; case ADH_BYTE(ATTR_CONTEXT_CLASS, CLASS_ATTR_InnerClasses) : // note the existence of this attr, but save for later if (cur_class_has_local_ics) unpack_abort("too many InnerClasses attrs"); cur_class_has_local_ics = true; wp = wp_at(abase); continue; case ADH_BYTE(ATTR_CONTEXT_CLASS, CLASS_ATTR_SourceFile) : aname = cp.sym[constant_pool::s_SourceFile]; ref = class_SourceFile_RUN.getRefN(); if (ref == nullptr) { bytes &n = cur_class->ref(0)->value.b; // parse n = (/)*?($)* int pkglen = lastIndexOf(SLASH_MIN, SLASH_MAX, n, (int)n.len) + 1; bytes prefix = n.slice(pkglen, n.len); for (;;) { // Work backwards, finding all '$', '#', etc. int dollar = lastIndexOf(DOLLAR_MIN, DOLLAR_MAX, prefix, (int)prefix.len); if (dollar < 0) break; prefix = prefix.slice(0, dollar); } const char *suffix = ".java"; int len = (int)(prefix.len + strlen(suffix)); bytes name; name.set(T_NEW(byte, add_size(len, 1)), len); name.strcat(prefix).strcat(suffix); ref = cp.ensureUtf8(name); } putref(ref); break; case ADH_BYTE(ATTR_CONTEXT_CLASS, CLASS_ATTR_EnclosingMethod) : aname = cp.sym[constant_pool::s_EnclosingMethod]; putref(class_EnclosingMethod_RC.getRefN()); putref(class_EnclosingMethod_RDN.getRefN()); break; case ADH_BYTE(ATTR_CONTEXT_FIELD, FIELD_ATTR_ConstantValue) : aname = cp.sym[constant_pool::s_ConstantValue]; putref(field_ConstantValue_KQ.getRefUsing(cp.getKQIndex())); break; case ADH_BYTE(ATTR_CONTEXT_METHOD, METHOD_ATTR_Code) : aname = cp.sym[constant_pool::s_Code]; write_code(); break; case ADH_BYTE(ATTR_CONTEXT_METHOD, METHOD_ATTR_Exceptions) : aname = cp.sym[constant_pool::s_Exceptions]; putu2(count = method_Exceptions_N.getInt()); for (j = 0; j < count; j++) { putref(method_Exceptions_RC.getRefN()); } break; case ADH_BYTE(ATTR_CONTEXT_CODE, CODE_ATTR_StackMapTable) : aname = cp.sym[constant_pool::s_StackMapTable]; // (keep this code aligned with its brother in unpacker::read_attrs) putu2(count = code_StackMapTable_N.getInt()); for (j = 0; j < count; j++) { int tag = code_StackMapTable_frame_T.getByte(); putu1(tag); if (tag <= 127) { // (64-127) [(2)] if (tag >= 64) put_stackmap_type(); } else if (tag <= 251) { // (247) [(1)(2)] // (248-251) [(1)] if (tag >= 247) putu2(code_StackMapTable_offset.getInt()); if (tag == 247) put_stackmap_type(); } else if (tag <= 254) { // (252) [(1)(2)] // (253) [(1)(2)(2)] // (254) [(1)(2)(2)(2)] putu2(code_StackMapTable_offset.getInt()); for (int k = (tag - 251); k > 0; k--) { put_stackmap_type(); } } else { // (255) [(1)NH[(2)]NH[(2)]] putu2(code_StackMapTable_offset.getInt()); putu2(j2 = code_StackMapTable_local_N.getInt()); while (j2-- > 0) put_stackmap_type(); putu2(j2 = code_StackMapTable_stack_N.getInt()); while (j2-- > 0) put_stackmap_type(); } } break; case ADH_BYTE(ATTR_CONTEXT_CODE, CODE_ATTR_LineNumberTable) : aname = cp.sym[constant_pool::s_LineNumberTable]; putu2(count = code_LineNumberTable_N.getInt()); for (j = 0; j < count; j++) { putu2(to_bci(code_LineNumberTable_bci_P.getInt())); putu2(code_LineNumberTable_line.getInt()); } break; case ADH_BYTE(ATTR_CONTEXT_CODE, CODE_ATTR_LocalVariableTable) : aname = cp.sym[constant_pool::s_LocalVariableTable]; putu2(count = code_LocalVariableTable_N.getInt()); for (j = 0; j < count; j++) { int bii = code_LocalVariableTable_bci_P.getInt(); int bci = to_bci(bii); putu2(bci); bii += code_LocalVariableTable_span_O.getInt(); putu2(to_bci(bii) - bci); putref(code_LocalVariableTable_name_RU.getRefN()); putref(code_LocalVariableTable_type_RS.getRefN()); putu2(code_LocalVariableTable_slot.getInt()); } break; case ADH_BYTE(ATTR_CONTEXT_CODE, CODE_ATTR_LocalVariableTypeTable) : aname = cp.sym[constant_pool::s_LocalVariableTypeTable]; putu2(count = code_LocalVariableTypeTable_N.getInt()); for (j = 0; j < count; j++) { int bii = code_LocalVariableTypeTable_bci_P.getInt(); int bci = to_bci(bii); putu2(bci); bii += code_LocalVariableTypeTable_span_O.getInt(); putu2(to_bci(bii) - bci); putref(code_LocalVariableTypeTable_name_RU.getRefN()); putref(code_LocalVariableTypeTable_type_RS.getRefN()); putu2(code_LocalVariableTypeTable_slot.getInt()); } break; case ADH_BYTE(ATTR_CONTEXT_CLASS, X_ATTR_Signature) : aname = cp.sym[constant_pool::s_Signature]; putref(class_Signature_RS.getRefN()); break; case ADH_BYTE(ATTR_CONTEXT_FIELD, X_ATTR_Signature) : aname = cp.sym[constant_pool::s_Signature]; putref(field_Signature_RS.getRefN()); break; case ADH_BYTE(ATTR_CONTEXT_METHOD, X_ATTR_Signature) : aname = cp.sym[constant_pool::s_Signature]; putref(method_Signature_RS.getRefN()); break; case ADH_BYTE(ATTR_CONTEXT_CLASS, X_ATTR_Deprecated) : case ADH_BYTE(ATTR_CONTEXT_FIELD, X_ATTR_Deprecated) : case ADH_BYTE(ATTR_CONTEXT_METHOD, X_ATTR_Deprecated) : aname = cp.sym[constant_pool::s_Deprecated]; // no data break; } } if (aname == nullptr) { // Unparse a compressor-defined attribute. layout_definition *lo = ad.getLayout(idx); if (lo == nullptr) { unpack_abort("bad layout index"); break; } assert((int)lo->idx == idx); aname = lo->nameEntry; if (aname == nullptr) { bytes nameb; nameb.set(lo->name); aname = cp.ensureUtf8(nameb); // Cache the name entry for next time. lo->nameEntry = aname; } // Execute all the layout elements. band **bands = lo->bands(); if (lo->hasCallables()) { band &cble = *bands[0]; assert(cble.le_kind == EK_CBLE); bands = cble.le_body; } putlayout(bands); } if (aname == nullptr) unpack_abort("bad attribute index"); byte *wp1 = wp; wp = wp_at(abase); // DTRT if this attr is on the strip-list. // (Note that we emptied the data out of the band first.) if (ad.strip_names.contains(aname)) { continue; } // patch the name and length putref(aname); putu4((int)(wp1 - (wp + 4))); // put the attr size wp = wp1; na++; // count the attrs actually written } if (na != na0) // Refresh changed count. putu2_at(wp_at(naOffset), na); return na; } void unpacker::write_members(int num, int attrc) { attr_definitions &ad = attr_defs[attrc]; band &member_flags_hi = ad.xxx_flags_hi(); band &member_flags_lo = ad.xxx_flags_lo(); band &member_descr = (&member_flags_hi)[e_field_descr - e_field_flags_hi]; bool haveLongFlags = ad.haveLongFlags(); putu2(num); uint64_t indexMask = attr_defs[attrc].flagIndexMask(); for (int i = 0; i < num; i++) { uint64_t mflags = member_flags_hi.getLong(member_flags_lo, haveLongFlags); entry *mdescr = member_descr.getRef(); cur_descr = mdescr; putu2(cur_descr_flags = (ushort)(mflags & ~indexMask)); putref(mdescr->descrName()); putref(mdescr->descrType()); write_attrs(attrc, (mflags & indexMask)); } cur_descr = nullptr; } extern "C" int raw_address_cmp(const void *p1p, const void *p2p) { void *p1 = *(void **)p1p; void *p2 = *(void **)p2p; return (p1 > p2) ? 1 : (p1 < p2) ? -1 : 0; } void unpacker::write_classfile_tail() { cur_classfile_tail.empty(); set_output(&cur_classfile_tail); int i, num; attr_definitions &ad = attr_defs[ATTR_CONTEXT_CLASS]; bool haveLongFlags = ad.haveLongFlags(); uint64_t kflags = class_flags_hi.getLong(class_flags_lo, haveLongFlags); uint64_t indexMask = ad.flagIndexMask(); cur_class = class_this.getRef(); cur_super = class_super.getRef(); if (cur_super == cur_class) cur_super = nullptr; // special representation for java/lang/Object putu2((ushort)(kflags & ~indexMask)); putref(cur_class); putref(cur_super); putu2(num = class_interface_count.getInt()); for (i = 0; i < num; i++) { putref(class_interface.getRef()); } write_members(class_field_count.getInt(), ATTR_CONTEXT_FIELD); write_members(class_method_count.getInt(), ATTR_CONTEXT_METHOD); cur_class_has_local_ics = false; // may be set true by write_attrs int naOffset = (int)wpoffset(); int na = write_attrs(ATTR_CONTEXT_CLASS, (kflags & indexMask)); // at the very last, choose which inner classes (if any) pertain to k: #ifdef ASSERT for (i = 0; i < ic_count; i++) { assert(!ics[i].requested); } #endif // First, consult the global table and the local constant pool, // and decide on the globally implied inner classes. // (Note that we read the cpool's outputIndex fields, but we // do not yet write them, since the local IC attribute might // reverse a global decision to declare an IC.) assert(requested_ics.length() == 0); // must start out empty // Always include all members of the current class. for (inner_class *child = cp.getFirstChildIC(cur_class); child != nullptr; child = cp.getNextChildIC(child)) { child->requested = true; requested_ics.add(child); } // And, for each inner class mentioned in the constant pool, // include it and all its outers. int noes = cp.outputEntries.length(); entry **oes = (entry **)cp.outputEntries.base(); for (i = 0; i < noes; i++) { entry &e = *oes[i]; if (e.tag != CONSTANT_Class) continue; // wrong sort for (inner_class *ic = cp.getIC(&e); ic != nullptr; ic = cp.getIC(ic->outer)) { if (ic->requested) break; // already processed ic->requested = true; requested_ics.add(ic); } } int local_ics = requested_ics.length(); // Second, consult a local attribute (if any) and adjust the global set. inner_class *extra_ics = nullptr; int num_extra_ics = 0; if (cur_class_has_local_ics) { // adjust the set of ICs by symmetric set difference w/ the locals num_extra_ics = class_InnerClasses_N.getInt(); if (num_extra_ics == 0) { // Explicit zero count has an irregular meaning: It deletes the attr. local_ics = 0; // (short-circuit all tests of requested bits) } else { extra_ics = T_NEW(inner_class, num_extra_ics); // Note: extra_ics will be freed up by next call to get_next_file(). } } for (i = 0; i < num_extra_ics; i++) { inner_class &extra_ic = extra_ics[i]; extra_ic.inner = class_InnerClasses_RC.getRef(); // Find the corresponding equivalent global IC: inner_class *global_ic = cp.getIC(extra_ic.inner); int flags = class_InnerClasses_F.getInt(); if (flags == 0) { // The extra IC is simply a copy of a global IC. if (global_ic == nullptr) { unpack_abort("bad reference to inner class"); break; } extra_ic = (*global_ic); // fill in rest of fields } else { flags &= ~ACC_IC_LONG_FORM; // clear high bit if set to get clean zero extra_ic.flags = flags; extra_ic.outer = class_InnerClasses_outer_RCN.getRefN(); extra_ic.name = class_InnerClasses_name_RUN.getRefN(); // Detect if this is an exact copy of the global tuple. if (global_ic != nullptr) { if (global_ic->flags != extra_ic.flags || global_ic->outer != extra_ic.outer || global_ic->name != extra_ic.name) { global_ic = nullptr; // not really the same, so break the link } } } if (global_ic != nullptr && global_ic->requested) { // This local repetition reverses the globally implied request. global_ic->requested = false; extra_ic.requested = false; local_ics -= 1; } else { // The global either does not exist, or is not yet requested. extra_ic.requested = true; local_ics += 1; } } // Finally, if there are any that survived, put them into an attribute. // (Note that a zero-count attribute is always deleted.) // The putref calls below will tell the constant pool to add any // necessary local CP references to support the InnerClasses attribute. // This step must be the last round of additions to the local CP. if (local_ics > 0) { // append the new attribute: putref(cp.sym[constant_pool::s_InnerClasses]); putu4(2 + 2 * 4 * local_ics); putu2(local_ics); PTRLIST_QSORT(requested_ics, raw_address_cmp); int num_global_ics = requested_ics.length(); for (i = -num_global_ics; i < num_extra_ics; i++) { inner_class *ic; if (i < 0) ic = (inner_class *)requested_ics.get(num_global_ics + i); else ic = &extra_ics[i]; if (ic->requested) { putref(ic->inner); putref(ic->outer); putref(ic->name); putu2(ic->flags); } } putu2_at(wp_at(naOffset), ++na); // increment class attr count } // Tidy up global 'requested' bits: for (i = requested_ics.length(); --i >= 0;) { inner_class *ic = (inner_class *)requested_ics.get(i); ic->requested = false; } requested_ics.empty(); close_output(); // rewrite CP references in the tail cp.computeOutputIndexes(); int nextref = 0; for (i = 0; i < (int)class_fixup_type.size(); i++) { int type = class_fixup_type.getByte(i); byte *fixp = wp_at(class_fixup_offset.get(i)); entry *e = (entry *)class_fixup_ref.get(nextref++); int idx = e->getOutputIndex(); switch (type) { case 1: putu1_at(fixp, idx); break; case 2: putu2_at(fixp, idx); break; default: assert(false); // should not reach here } } } void unpacker::write_classfile_head() { cur_classfile_head.empty(); set_output(&cur_classfile_head); putu4(JAVA_MAGIC); putu2(cur_class_minver); putu2(cur_class_majver); putu2(cp.outputIndexLimit); int checkIndex = 1; int noes = cp.outputEntries.length(); entry **oes = (entry **)cp.outputEntries.base(); for (int i = 0; i < noes; i++) { entry &e = *oes[i]; assert(e.getOutputIndex() == checkIndex++); byte tag = e.tag; assert(tag != CONSTANT_Signature); putu1(tag); switch (tag) { case CONSTANT_Utf8: putu2((int)e.value.b.len); put_bytes(e.value.b); break; case CONSTANT_Integer: case CONSTANT_Float: putu4(e.value.i); break; case CONSTANT_Long: case CONSTANT_Double: putu8(e.value.l); assert(checkIndex++); break; case CONSTANT_Class: case CONSTANT_String: // just write the ref putu2(e.refs[0]->getOutputIndex()); break; case CONSTANT_Fieldref: case CONSTANT_Methodref: case CONSTANT_InterfaceMethodref: case CONSTANT_NameandType: putu2(e.refs[0]->getOutputIndex()); putu2(e.refs[1]->getOutputIndex()); break; default: unpack_abort(ERROR_INTERNAL); } } close_output(); } unpacker::file *unpacker::get_next_file() { free_temps(); if (files_remaining == 0) { // Leave a clue that we're exhausted. cur_file.name = nullptr; cur_file.size = 0; if (archive_size != 0) { uint64_t predicted_size = unsized_bytes_read + archive_size; if (predicted_size != bytes_read) unpack_abort("archive header had incorrect size"); } return nullptr; } files_remaining -= 1; assert(files_written < file_count || classes_written < class_count); cur_file.name = ""; cur_file.size = 0; cur_file.modtime = default_file_modtime; cur_file.options = default_file_options; cur_file.data[0].set(nullptr, 0); cur_file.data[1].set(nullptr, 0); if (files_written < file_count) { entry *e = file_name.getRef(); cur_file.name = e->utf8String(); bool haveLongSize = ((archive_options & AO_HAVE_FILE_SIZE_HI) != 0); cur_file.size = file_size_hi.getLong(file_size_lo, haveLongSize); if ((archive_options & AO_HAVE_FILE_MODTIME) != 0) cur_file.modtime += file_modtime.getInt(); // relative to archive modtime if ((archive_options & AO_HAVE_FILE_OPTIONS) != 0) cur_file.options |= file_options.getInt() & ~suppress_file_options; } else if (classes_written < class_count) { // there is a class for a missing file record cur_file.options |= FO_IS_CLASS_STUB; } if ((cur_file.options & FO_IS_CLASS_STUB) != 0) { assert(classes_written < class_count); classes_written += 1; if (cur_file.size != 0) { unpack_abort("class file size transmitted"); } reset_cur_classfile(); // write the meat of the classfile: write_classfile_tail(); cur_file.data[1] = cur_classfile_tail.b; // write the CP of the classfile, second: write_classfile_head(); cur_file.data[0] = cur_classfile_head.b; cur_file.size += cur_file.data[0].len; cur_file.size += cur_file.data[1].len; if (cur_file.name[0] == '\0') { bytes &prefix = cur_class->ref(0)->value.b; const char *suffix = ".class"; int len = (int)(prefix.len + strlen(suffix)); bytes name; name.set(T_NEW(byte, add_size(len, 1)), len); cur_file.name = name.strcat(prefix).strcat(suffix).strval(); } } else { // If there is buffered file data, produce a pointer to it. if (cur_file.size != (size_t)cur_file.size) { // Silly size specified. unpack_abort("resource file too large"); } size_t rpleft = input_remaining(); if (rpleft > 0) { if (rpleft > cur_file.size) rpleft = (size_t)cur_file.size; cur_file.data[0].set(rp, rpleft); rp += rpleft; } if (rpleft < cur_file.size) { // Caller must read the rest. size_t fleft = (size_t)cur_file.size - rpleft; bytes_read += fleft; // Credit it to the overall archive size. } } bytes_written += cur_file.size; files_written += 1; return &cur_file; } // Write a file to jarout. void unpacker::write_file_to_jar(unpacker::file *f) { size_t htsize = f->data[0].len + f->data[1].len; uint64_t fsize = f->size; if (htsize == fsize) { jarout->addJarEntry(f->name, f->deflate_hint(), f->modtime, f->data[0], f->data[1]); } else { assert(input_remaining() == 0); bytes part1, part2; part1.len = f->data[0].len; part1.set(T_NEW(byte, part1.len), part1.len); part1.copyFrom(f->data[0]); assert(f->data[1].len == 0); part2.set(nullptr, 0); size_t fleft = (size_t)fsize - part1.len; assert(bytes_read > fleft); // part2 already credited by get_next_file bytes_read -= fleft; if (fleft > 0) { // Must read some more. if (live_input) { // Stop using the input buffer. Make a new one: if (free_input) input.free(); input.init(fleft > (1 << 12) ? fleft : (1 << 12)); free_input = true; live_input = false; } else { // Make it large enough. assert(free_input); // must be reallocable input.ensureSize(fleft); } rplimit = rp = input.base(); input.setLimit(rp + fleft); if (!ensure_input(fleft)) unpack_abort("EOF reading resource file"); part2.ptr = input_scan(); part2.len = input_remaining(); rplimit = rp = input.base(); } jarout->addJarEntry(f->name, f->deflate_hint(), f->modtime, part1, part2); } if (verbose >= 3) { fprintf(stderr, "Wrote " LONG_LONG_FORMAT " bytes to: %s\n", fsize, f->name); } }