From 04f4ee89d89fba5bf2b358f8402443f4d2b385bb Mon Sep 17 00:00:00 2001 From: CentOS Sources Date: Jan 21 2020 23:45:44 +0000 Subject: import zlib-1.2.11-13.el8 --- diff --git a/SOURCES/zlib-1.2.11-IBM-Z-hw-accelrated-deflate-s390x.patch b/SOURCES/zlib-1.2.11-IBM-Z-hw-accelrated-deflate-s390x.patch new file mode 100644 index 0000000..002a0d5 --- /dev/null +++ b/SOURCES/zlib-1.2.11-IBM-Z-hw-accelrated-deflate-s390x.patch @@ -0,0 +1,1709 @@ +From 4e65ca20fc242e4a03471558a357d7809adeb9c4 Mon Sep 17 00:00:00 2001 +From: IBM developers +Date: Thu, 1 Aug 2019 09:02:01 +0200 +Subject: [PATCH] Add support for IBM Z hardware-accelerated deflate + +Future versions of IBM Z mainframes will provide DFLTCC instruction, +which implements deflate algorithm in hardware with estimated +compression and decompression performance orders of magnitude faster +than the current zlib and ratio comparable with that of level 1. + +This patch adds DFLTCC support to zlib. In order to enable it, the +following build commands should be used: + + $ CFLAGS=-DDFLTCC ./configure + $ make OBJA=dfltcc.o PIC_OBJA=dfltcc.lo + +When built like this, zlib would compress in hardware on level 1, and in +software on all other levels. Decompression will always happen in +hardware. In order to enable DFLTCC compression for levels 1-6 (i.e. to +make it used by default) one could either add -DDFLTCC_LEVEL_MASK=0x7e +at compile time, or set the environment variable DFLTCC_LEVEL_MASK to +0x7e at run time. + +Two DFLTCC compression calls produce the same results only when they +both are made on machines of the same generation, and when the +respective buffers have the same offset relative to the start of the +page. Therefore care should be taken when using hardware compression +when reproducible results are desired. One such use case - reproducible +software builds - is handled explicitly: when SOURCE_DATE_EPOCH +environment variable is set, the hardware compression is disabled. + +DFLTCC does not support every single zlib feature, in particular: + + * inflate(Z_BLOCK) and inflate(Z_TREES) + * inflateMark() + * inflatePrime() + * deflateParams() after the first deflate() call + +When used, these functions will either switch to software, or, in case +this is not possible, gracefully fail. + +This patch tries to add DFLTCC support in a least intrusive way. +All SystemZ-specific code was placed into a separate file, but +unfortunately there is still a noticeable amount of changes in the +main zlib code. Below is the summary of those changes. + +DFLTCC takes as arguments a parameter block, an input buffer, an output +buffer and a window. Since DFLTCC requires parameter block to be +doubleword-aligned, and it's reasonable to allocate it alongside +deflate and inflate states, ZALLOC_STATE, ZFREE_STATE and ZCOPY_STATE +macros were introduced in order to encapsulate the allocation details. +The same is true for window, for which ZALLOC_WINDOW and +TRY_FREE_WINDOW macros were introduced. + +While for inflate software and hardware window formats match, this is +not the case for deflate. Therefore, deflateSetDictionary and +deflateGetDictionary need special handling, which is triggered using the +new DEFLATE_SET_DICTIONARY_HOOK and DEFLATE_GET_DICTIONARY_HOOK macros. + +deflateResetKeep() and inflateResetKeep() now update the DFLTCC +parameter block, which is allocated alongside zlib state, using +the new DEFLATE_RESET_KEEP_HOOK and INFLATE_RESET_KEEP_HOOK macros. + +In order to make unsupported deflateParams(), inflatePrime() and +inflateMark() calls to fail gracefully, the new DEFLATE_PARAMS_HOOK, +INFLATE_PRIME_HOOK and INFLATE_MARK_HOOK macros were introduced. + +The algorithm implemented in hardware has different compression ratio +than the one implemented in software. In order for deflateBound() to +return the correct results for the hardware implementation, the new +DEFLATE_BOUND_ADJUST_COMPLEN and DEFLATE_NEED_CONSERVATIVE_BOUND macros +were introduced. + +Actual compression and decompression are handled by the new DEFLATE_HOOK +and INFLATE_TYPEDO_HOOK macros. Since inflation with DFLTCC manages the +window on its own, calling updatewindow() is suppressed using the new +INFLATE_NEED_UPDATEWINDOW() macro. + +In addition to compression, DFLTCC computes CRC-32 and Adler-32 +checksums, therefore, whenever it's used, software checksumming needs to +be suppressed using the new DEFLATE_NEED_CHECKSUM and +INFLATE_NEED_CHECKSUM macros. + +DFLTCC will refuse to write an End-of-block Symbol if there is no input +data, thus in some cases it is necessary to do this manually. In order +to achieve this, send_bits, bi_reverse, bi_windup and flush_pending +were promoted from local to ZLIB_INTERNAL. Furthermore, since block and +stream termination must be handled in software as well, block_state enum +was moved to deflate.h. + +Since the first call to dfltcc_inflate already needs the window, and it +might be not allocated yet, inflate_ensure_window was factored out of +updatewindow and made ZLIB_INTERNAL. +--- + Makefile.in | 8 + + configure | 13 + + contrib/README.contrib | 4 + + contrib/s390/dfltcc.c | 901 ++++++++++++++++++++++++++++++++++ + contrib/s390/dfltcc.h | 55 +++ + contrib/s390/dfltcc_deflate.h | 50 ++ + deflate.c | 60 ++- + deflate.h | 12 + + gzguts.h | 4 + + inflate.c | 84 +++- + inflate.h | 2 + + test/infcover.c | 2 +- + test/minigzip.c | 4 + + trees.c | 13 +- + 14 files changed, 1161 insertions(+), 51 deletions(-) + create mode 100644 contrib/s390/dfltcc.c + create mode 100644 contrib/s390/dfltcc.h + create mode 100644 contrib/s390/dfltcc_deflate.h + +diff --git a/Makefile.in b/Makefile.in +index 5a77949..e756e2f 100644 +--- a/Makefile.in ++++ b/Makefile.in +@@ -143,6 +143,14 @@ match.lo: match.S + mv _match.o match.lo + rm -f _match.s + ++dfltcc.o: $(SRCDIR)contrib/s390/dfltcc.c $(SRCDIR)zlib.h zconf.h ++ $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)contrib/s390/dfltcc.c ++ ++dfltcc.lo: $(SRCDIR)contrib/s390/dfltcc.c $(SRCDIR)zlib.h zconf.h ++ -@mkdir objs 2>/dev/null || test -d objs ++ $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/dfltcc.o $(SRCDIR)contrib/s390/dfltcc.c ++ -@mv objs/dfltcc.o $@ ++ + example.o: $(SRCDIR)test/example.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/example.c + +diff --git a/configure b/configure +index e974d1f..8fab355 100755 +--- a/configure ++++ b/configure +@@ -826,6 +826,19 @@ EOF + fi + fi + ++# Check whether sys/sdt.h is available ++cat > $test.c << EOF ++#include ++int main() { return 0; } ++EOF ++if try ${CC} ${CFLAGS} $test.c; then ++ echo "Checking for sys/sdt.h ... Yes." | tee -a configure.log ++ CFLAGS="$CFLAGS -DHAVE_SYS_SDT_H" ++ SFLAGS="$SFLAGS -DHAVE_SYS_SDT_H" ++else ++ echo "Checking for sys/sdt.h ... No." | tee -a configure.log ++fi ++ + # show the results in the log + echo >> configure.log + echo ALL = $ALL >> configure.log +diff --git a/contrib/README.contrib b/contrib/README.contrib +index a411d5c..b4d3b18 100644 +--- a/contrib/README.contrib ++++ b/contrib/README.contrib +@@ -67,6 +67,10 @@ puff/ by Mark Adler + Small, low memory usage inflate. Also serves to provide an + unambiguous description of the deflate format. + ++s390/ by Ilya Leoshkevich ++ Hardware-accelerated deflate on IBM Z with DEFLATE CONVERSION CALL ++ instruction. ++ + testzlib/ by Gilles Vollant + Example of the use of zlib + +diff --git a/contrib/s390/dfltcc.c b/contrib/s390/dfltcc.c +new file mode 100644 +index 0000000..d187796 +--- /dev/null ++++ b/contrib/s390/dfltcc.c +@@ -0,0 +1,901 @@ ++/* dfltcc.c - SystemZ DEFLATE CONVERSION CALL support. */ ++ ++/* ++ Use the following commands to build zlib with DFLTCC support: ++ $ CFLAGS=-DDFLTCC ./configure ++ $ make OBJA=dfltcc.o PIC_OBJA=dfltcc.lo ++*/ ++ ++#define _GNU_SOURCE ++#include ++#include ++#include ++#include ++#include ++#include ++#include "../../zutil.h" ++#include "../../deflate.h" ++#include "../../inftrees.h" ++#include "../../inflate.h" ++#include "dfltcc.h" ++#include "dfltcc_deflate.h" ++#ifdef HAVE_SYS_SDT_H ++#include ++#endif ++ ++/* ++ C wrapper for the DEFLATE CONVERSION CALL instruction. ++ */ ++typedef enum { ++ DFLTCC_CC_OK = 0, ++ DFLTCC_CC_OP1_TOO_SHORT = 1, ++ DFLTCC_CC_OP2_TOO_SHORT = 2, ++ DFLTCC_CC_OP2_CORRUPT = 2, ++ DFLTCC_CC_AGAIN = 3, ++} dfltcc_cc; ++ ++#define DFLTCC_QAF 0 ++#define DFLTCC_GDHT 1 ++#define DFLTCC_CMPR 2 ++#define DFLTCC_XPND 4 ++#define HBT_CIRCULAR (1 << 7) ++#define HB_BITS 15 ++#define HB_SIZE (1 << HB_BITS) ++#define DFLTCC_FACILITY 151 ++ ++local inline dfltcc_cc dfltcc OF((int fn, void *param, ++ Bytef **op1, size_t *len1, ++ z_const Bytef **op2, size_t *len2, ++ void *hist)); ++local inline dfltcc_cc dfltcc(fn, param, op1, len1, op2, len2, hist) ++ int fn; ++ void *param; ++ Bytef **op1; ++ size_t *len1; ++ z_const Bytef **op2; ++ size_t *len2; ++ void *hist; ++{ ++ Bytef *t2 = op1 ? *op1 : NULL; ++ size_t t3 = len1 ? *len1 : 0; ++ z_const Bytef *t4 = op2 ? *op2 : NULL; ++ size_t t5 = len2 ? *len2 : 0; ++ register int r0 __asm__("r0") = fn; ++ register void *r1 __asm__("r1") = param; ++ register Bytef *r2 __asm__("r2") = t2; ++ register size_t r3 __asm__("r3") = t3; ++ register z_const Bytef *r4 __asm__("r4") = t4; ++ register size_t r5 __asm__("r5") = t5; ++ int cc; ++ ++ __asm__ volatile( ++#ifdef HAVE_SYS_SDT_H ++ STAP_PROBE_ASM(zlib, dfltcc_entry, ++ STAP_PROBE_ASM_TEMPLATE(5)) ++#endif ++ ".insn rrf,0xb9390000,%[r2],%[r4],%[hist],0\n" ++#ifdef HAVE_SYS_SDT_H ++ STAP_PROBE_ASM(zlib, dfltcc_exit, ++ STAP_PROBE_ASM_TEMPLATE(5)) ++#endif ++ "ipm %[cc]\n" ++ : [r2] "+r" (r2) ++ , [r3] "+r" (r3) ++ , [r4] "+r" (r4) ++ , [r5] "+r" (r5) ++ , [cc] "=r" (cc) ++ : [r0] "r" (r0) ++ , [r1] "r" (r1) ++ , [hist] "r" (hist) ++#ifdef HAVE_SYS_SDT_H ++ , STAP_PROBE_ASM_OPERANDS(5, r2, r3, r4, r5, hist) ++#endif ++ : "cc", "memory"); ++ t2 = r2; t3 = r3; t4 = r4; t5 = r5; ++ ++ if (op1) ++ *op1 = t2; ++ if (len1) ++ *len1 = t3; ++ if (op2) ++ *op2 = t4; ++ if (len2) ++ *len2 = t5; ++ return (cc >> 28) & 3; ++} ++ ++/* ++ Parameter Block for Query Available Functions. ++ */ ++#define static_assert(c, msg) \ ++ __attribute__((unused)) \ ++ static char static_assert_failed_ ## msg[c ? 1 : -1] ++ ++struct dfltcc_qaf_param { ++ char fns[16]; ++ char reserved1[8]; ++ char fmts[2]; ++ char reserved2[6]; ++}; ++ ++static_assert(sizeof(struct dfltcc_qaf_param) == 32, ++ sizeof_struct_dfltcc_qaf_param_is_32); ++ ++local inline int is_bit_set OF((const char *bits, int n)); ++local inline int is_bit_set(bits, n) ++ const char *bits; ++ int n; ++{ ++ return bits[n / 8] & (1 << (7 - (n % 8))); ++} ++ ++local inline void clear_bit OF((char *bits, int n)); ++local inline void clear_bit(bits, n) ++ char *bits; ++ int n; ++{ ++ bits[n / 8] &= ~(1 << (7 - (n % 8))); ++} ++ ++#define DFLTCC_FMT0 0 ++ ++/* ++ Parameter Block for Generate Dynamic-Huffman Table, Compress and Expand. ++ */ ++#define CVT_CRC32 0 ++#define CVT_ADLER32 1 ++#define HTT_FIXED 0 ++#define HTT_DYNAMIC 1 ++ ++struct dfltcc_param_v0 { ++ uint16_t pbvn; /* Parameter-Block-Version Number */ ++ uint8_t mvn; /* Model-Version Number */ ++ uint8_t ribm; /* Reserved for IBM use */ ++ unsigned reserved32 : 31; ++ unsigned cf : 1; /* Continuation Flag */ ++ uint8_t reserved64[8]; ++ unsigned nt : 1; /* New Task */ ++ unsigned reserved129 : 1; ++ unsigned cvt : 1; /* Check Value Type */ ++ unsigned reserved131 : 1; ++ unsigned htt : 1; /* Huffman-Table Type */ ++ unsigned bcf : 1; /* Block-Continuation Flag */ ++ unsigned bcc : 1; /* Block Closing Control */ ++ unsigned bhf : 1; /* Block Header Final */ ++ unsigned reserved136 : 1; ++ unsigned reserved137 : 1; ++ unsigned dhtgc : 1; /* DHT Generation Control */ ++ unsigned reserved139 : 5; ++ unsigned reserved144 : 5; ++ unsigned sbb : 3; /* Sub-Byte Boundary */ ++ uint8_t oesc; /* Operation-Ending-Supplemental Code */ ++ unsigned reserved160 : 12; ++ unsigned ifs : 4; /* Incomplete-Function Status */ ++ uint16_t ifl; /* Incomplete-Function Length */ ++ uint8_t reserved192[8]; ++ uint8_t reserved256[8]; ++ uint8_t reserved320[4]; ++ uint16_t hl; /* History Length */ ++ unsigned reserved368 : 1; ++ uint16_t ho : 15; /* History Offset */ ++ uint32_t cv; /* Check Value */ ++ unsigned eobs : 15; /* End-of-block Symbol */ ++ unsigned reserved431: 1; ++ uint8_t eobl : 4; /* End-of-block Length */ ++ unsigned reserved436 : 12; ++ unsigned reserved448 : 4; ++ uint16_t cdhtl : 12; /* Compressed-Dynamic-Huffman Table ++ Length */ ++ uint8_t reserved464[6]; ++ uint8_t cdht[288]; ++ uint8_t reserved[32]; ++ uint8_t csb[1152]; ++}; ++ ++static_assert(sizeof(struct dfltcc_param_v0) == 1536, ++ sizeof_struct_dfltcc_param_v0_is_1536); ++ ++local z_const char *oesc_msg OF((char *buf, int oesc)); ++local z_const char *oesc_msg(buf, oesc) ++ char *buf; ++ int oesc; ++{ ++ if (oesc == 0x00) ++ return NULL; /* Successful completion */ ++ else { ++ sprintf(buf, "Operation-Ending-Supplemental Code is 0x%.2X", oesc); ++ return buf; ++ } ++} ++ ++/* ++ Extension of inflate_state and deflate_state. Must be doubleword-aligned. ++*/ ++struct dfltcc_state { ++ struct dfltcc_param_v0 param; /* Parameter block. */ ++ struct dfltcc_qaf_param af; /* Available functions. */ ++ uLong level_mask; /* Levels on which to use DFLTCC */ ++ uLong block_size; /* New block each X bytes */ ++ uLong block_threshold; /* New block after total_in > X */ ++ uLong dht_threshold; /* New block only if avail_in >= X */ ++ char msg[64]; /* Buffer for strm->msg */ ++}; ++ ++#define ALIGN_UP(p, size) \ ++ (__typeof__(p))(((uintptr_t)(p) + ((size) - 1)) & ~((size) - 1)) ++ ++#define GET_DFLTCC_STATE(state) ((struct dfltcc_state FAR *)( \ ++ (char FAR *)(state) + ALIGN_UP(sizeof(*state), 8))) ++ ++/* ++ Compress. ++ */ ++local inline int dfltcc_are_params_ok(int level, ++ uInt window_bits, ++ int strategy, ++ uLong level_mask); ++local inline int dfltcc_are_params_ok(level, window_bits, strategy, level_mask) ++ int level; ++ uInt window_bits; ++ int strategy; ++ uLong level_mask; ++{ ++ return (level_mask & (1 << level)) != 0 && ++ (window_bits == HB_BITS) && ++ (strategy == Z_FIXED || strategy == Z_DEFAULT_STRATEGY); ++} ++ ++ ++int ZLIB_INTERNAL dfltcc_can_deflate(strm) ++ z_streamp strm; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ ++ /* Unsupported compression settings */ ++ if (!dfltcc_are_params_ok(state->level, state->w_bits, state->strategy, ++ dfltcc_state->level_mask)) ++ return 0; ++ ++ /* Unsupported hardware */ ++ if (!is_bit_set(dfltcc_state->af.fns, DFLTCC_GDHT) || ++ !is_bit_set(dfltcc_state->af.fns, DFLTCC_CMPR) || ++ !is_bit_set(dfltcc_state->af.fmts, DFLTCC_FMT0)) ++ return 0; ++ ++ return 1; ++} ++ ++local void dfltcc_gdht OF((z_streamp strm)); ++local void dfltcc_gdht(strm) ++ z_streamp strm; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_param_v0 FAR *param = &GET_DFLTCC_STATE(state)->param; ++ size_t avail_in = avail_in = strm->avail_in; ++ ++ dfltcc(DFLTCC_GDHT, ++ param, NULL, NULL, ++ &strm->next_in, &avail_in, NULL); ++} ++ ++local dfltcc_cc dfltcc_cmpr OF((z_streamp strm)); ++local dfltcc_cc dfltcc_cmpr(strm) ++ z_streamp strm; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_param_v0 FAR *param = &GET_DFLTCC_STATE(state)->param; ++ size_t avail_in = strm->avail_in; ++ size_t avail_out = strm->avail_out; ++ dfltcc_cc cc; ++ ++ cc = dfltcc(DFLTCC_CMPR | HBT_CIRCULAR, ++ param, &strm->next_out, &avail_out, ++ &strm->next_in, &avail_in, state->window); ++ strm->total_in += (strm->avail_in - avail_in); ++ strm->total_out += (strm->avail_out - avail_out); ++ strm->avail_in = avail_in; ++ strm->avail_out = avail_out; ++ return cc; ++} ++ ++local void send_eobs OF((z_streamp strm, ++ z_const struct dfltcc_param_v0 FAR *param)); ++local void send_eobs(strm, param) ++ z_streamp strm; ++ z_const struct dfltcc_param_v0 FAR *param; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ ++ _tr_send_bits( ++ state, ++ bi_reverse(param->eobs >> (15 - param->eobl), param->eobl), ++ param->eobl); ++ flush_pending(strm); ++ if (state->pending != 0) { ++ /* The remaining data is located in pending_out[0:pending]. If someone ++ * calls put_byte() - this might happen in deflate() - the byte will be ++ * placed into pending_buf[pending], which is incorrect. Move the ++ * remaining data to the beginning of pending_buf so that put_byte() is ++ * usable again. ++ */ ++ memmove(state->pending_buf, state->pending_out, state->pending); ++ state->pending_out = state->pending_buf; ++ } ++#ifdef ZLIB_DEBUG ++ state->compressed_len += param->eobl; ++#endif ++} ++ ++int ZLIB_INTERNAL dfltcc_deflate(strm, flush, result) ++ z_streamp strm; ++ int flush; ++ block_state *result; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ struct dfltcc_param_v0 FAR *param = &dfltcc_state->param; ++ uInt masked_avail_in; ++ dfltcc_cc cc; ++ int need_empty_block; ++ int soft_bcc; ++ int no_flush; ++ ++ if (!dfltcc_can_deflate(strm)) ++ return 0; ++ ++again: ++ masked_avail_in = 0; ++ soft_bcc = 0; ++ no_flush = flush == Z_NO_FLUSH; ++ ++ /* Trailing empty block. Switch to software, except when Continuation Flag ++ * is set, which means that DFLTCC has buffered some output in the ++ * parameter block and needs to be called again in order to flush it. ++ */ ++ if (flush == Z_FINISH && strm->avail_in == 0 && !param->cf) { ++ if (param->bcf) { ++ /* A block is still open, and the hardware does not support closing ++ * blocks without adding data. Thus, close it manually. ++ */ ++ send_eobs(strm, param); ++ param->bcf = 0; ++ } ++ return 0; ++ } ++ ++ if (strm->avail_in == 0 && !param->cf) { ++ *result = need_more; ++ return 1; ++ } ++ ++ /* There is an open non-BFINAL block, we are not going to close it just ++ * yet, we have compressed more than DFLTCC_BLOCK_SIZE bytes and we see ++ * more than DFLTCC_DHT_MIN_SAMPLE_SIZE bytes. Open a new block with a new ++ * DHT in order to adapt to a possibly changed input data distribution. ++ */ ++ if (param->bcf && no_flush && ++ strm->total_in > dfltcc_state->block_threshold && ++ strm->avail_in >= dfltcc_state->dht_threshold) { ++ if (param->cf) { ++ /* We need to flush the DFLTCC buffer before writing the ++ * End-of-block Symbol. Mask the input data and proceed as usual. ++ */ ++ masked_avail_in += strm->avail_in; ++ strm->avail_in = 0; ++ no_flush = 0; ++ } else { ++ /* DFLTCC buffer is empty, so we can manually write the ++ * End-of-block Symbol right away. ++ */ ++ send_eobs(strm, param); ++ param->bcf = 0; ++ dfltcc_state->block_threshold = ++ strm->total_in + dfltcc_state->block_size; ++ if (strm->avail_out == 0) { ++ *result = need_more; ++ return 1; ++ } ++ } ++ } ++ ++ /* The caller gave us too much data. Pass only one block worth of ++ * uncompressed data to DFLTCC and mask the rest, so that on the next ++ * iteration we start a new block. ++ */ ++ if (no_flush && strm->avail_in > dfltcc_state->block_size) { ++ masked_avail_in += (strm->avail_in - dfltcc_state->block_size); ++ strm->avail_in = dfltcc_state->block_size; ++ } ++ ++ /* When we have an open non-BFINAL deflate block and caller indicates that ++ * the stream is ending, we need to close an open deflate block and open a ++ * BFINAL one. ++ */ ++ need_empty_block = flush == Z_FINISH && param->bcf && !param->bhf; ++ ++ /* Translate stream to parameter block */ ++ param->cvt = state->wrap == 2 ? CVT_CRC32 : CVT_ADLER32; ++ if (!no_flush) ++ /* We need to close a block. Always do this in software - when there is ++ * no input data, the hardware will not nohor BCC. */ ++ soft_bcc = 1; ++ if (flush == Z_FINISH && !param->bcf) ++ /* We are about to open a BFINAL block, set Block Header Final bit ++ * until the stream ends. ++ */ ++ param->bhf = 1; ++ /* DFLTCC-CMPR will write to next_out, so make sure that buffers with ++ * higher precedence are empty. ++ */ ++ Assert(state->pending == 0, "There must be no pending bytes"); ++ Assert(state->bi_valid < 8, "There must be less than 8 pending bits"); ++ param->sbb = (unsigned int)state->bi_valid; ++ if (param->sbb > 0) ++ *strm->next_out = (Bytef)state->bi_buf; ++ if (param->hl) ++ param->nt = 0; /* Honor history */ ++ param->cv = state->wrap == 2 ? ZSWAP32(strm->adler) : strm->adler; ++ ++ /* When opening a block, choose a Huffman-Table Type */ ++ if (!param->bcf) { ++ if (state->strategy == Z_FIXED || ++ (strm->total_in == 0 && dfltcc_state->block_threshold > 0)) ++ param->htt = HTT_FIXED; ++ else { ++ param->htt = HTT_DYNAMIC; ++ dfltcc_gdht(strm); ++ } ++ } ++ ++ /* Deflate */ ++ do { ++ cc = dfltcc_cmpr(strm); ++ if (strm->avail_in < 4096 && masked_avail_in > 0) ++ /* We are about to call DFLTCC with a small input buffer, which is ++ * inefficient. Since there is masked data, there will be at least ++ * one more DFLTCC call, so skip the current one and make the next ++ * one handle more data. ++ */ ++ break; ++ } while (cc == DFLTCC_CC_AGAIN); ++ ++ /* Translate parameter block to stream */ ++ strm->msg = oesc_msg(dfltcc_state->msg, param->oesc); ++ state->bi_valid = param->sbb; ++ if (state->bi_valid == 0) ++ state->bi_buf = 0; /* Avoid accessing next_out */ ++ else ++ state->bi_buf = *strm->next_out & ((1 << state->bi_valid) - 1); ++ strm->adler = state->wrap == 2 ? ZSWAP32(param->cv) : param->cv; ++ ++ /* Unmask the input data */ ++ strm->avail_in += masked_avail_in; ++ masked_avail_in = 0; ++ ++ /* If we encounter an error, it means there is a bug in DFLTCC call */ ++ Assert(cc != DFLTCC_CC_OP2_CORRUPT || param->oesc == 0, "BUG"); ++ ++ /* Update Block-Continuation Flag. It will be used to check whether to call ++ * GDHT the next time. ++ */ ++ if (cc == DFLTCC_CC_OK) { ++ if (soft_bcc) { ++ send_eobs(strm, param); ++ param->bcf = 0; ++ dfltcc_state->block_threshold = ++ strm->total_in + dfltcc_state->block_size; ++ } else ++ param->bcf = 1; ++ if (flush == Z_FINISH) { ++ if (need_empty_block) ++ /* Make the current deflate() call also close the stream */ ++ return 0; ++ else { ++ bi_windup(state); ++ *result = finish_done; ++ } ++ } else { ++ if (flush == Z_FULL_FLUSH) ++ param->hl = 0; /* Clear history */ ++ *result = flush == Z_NO_FLUSH ? need_more : block_done; ++ } ++ } else { ++ param->bcf = 1; ++ *result = need_more; ++ } ++ if (strm->avail_in != 0 && strm->avail_out != 0) ++ goto again; /* deflate() must use all input or all output */ ++ return 1; ++} ++ ++/* ++ Expand. ++ */ ++int ZLIB_INTERNAL dfltcc_can_inflate(strm) ++ z_streamp strm; ++{ ++ struct inflate_state FAR *state = (struct inflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ ++ /* Unsupported compression settings */ ++ if (state->wbits != HB_BITS) ++ return 0; ++ ++ /* Unsupported hardware */ ++ return is_bit_set(dfltcc_state->af.fns, DFLTCC_XPND) && ++ is_bit_set(dfltcc_state->af.fmts, DFLTCC_FMT0); ++} ++ ++local dfltcc_cc dfltcc_xpnd OF((z_streamp strm)); ++local dfltcc_cc dfltcc_xpnd(strm) ++ z_streamp strm; ++{ ++ struct inflate_state FAR *state = (struct inflate_state FAR *)strm->state; ++ struct dfltcc_param_v0 FAR *param = &GET_DFLTCC_STATE(state)->param; ++ size_t avail_in = strm->avail_in; ++ size_t avail_out = strm->avail_out; ++ dfltcc_cc cc; ++ ++ cc = dfltcc(DFLTCC_XPND | HBT_CIRCULAR, ++ param, &strm->next_out, &avail_out, ++ &strm->next_in, &avail_in, state->window); ++ strm->avail_in = avail_in; ++ strm->avail_out = avail_out; ++ return cc; ++} ++ ++dfltcc_inflate_action ZLIB_INTERNAL dfltcc_inflate(strm, flush, ret) ++ z_streamp strm; ++ int flush; ++ int *ret; ++{ ++ struct inflate_state FAR *state = (struct inflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ struct dfltcc_param_v0 FAR *param = &dfltcc_state->param; ++ dfltcc_cc cc; ++ ++ if (flush == Z_BLOCK || flush == Z_TREES) { ++ /* DFLTCC does not support stopping on block boundaries */ ++ if (dfltcc_inflate_disable(strm)) { ++ *ret = Z_STREAM_ERROR; ++ return DFLTCC_INFLATE_BREAK; ++ } else ++ return DFLTCC_INFLATE_SOFTWARE; ++ } ++ ++ if (state->last) { ++ if (state->bits != 0) { ++ strm->next_in++; ++ strm->avail_in--; ++ state->bits = 0; ++ } ++ state->mode = CHECK; ++ return DFLTCC_INFLATE_CONTINUE; ++ } ++ ++ if (strm->avail_in == 0 && !param->cf) ++ return DFLTCC_INFLATE_BREAK; ++ ++ if (inflate_ensure_window(state)) { ++ state->mode = MEM; ++ return DFLTCC_INFLATE_CONTINUE; ++ } ++ ++ /* Translate stream to parameter block */ ++ param->cvt = state->flags ? CVT_CRC32 : CVT_ADLER32; ++ param->sbb = state->bits; ++ param->hl = state->whave; /* Software and hardware history formats match */ ++ param->ho = (state->wnext - state->whave) & ((1 << HB_BITS) - 1); ++ if (param->hl) ++ param->nt = 0; /* Honor history for the first block */ ++ param->cv = state->flags ? ZSWAP32(state->check) : state->check; ++ ++ /* Inflate */ ++ do { ++ cc = dfltcc_xpnd(strm); ++ } while (cc == DFLTCC_CC_AGAIN); ++ ++ /* Translate parameter block to stream */ ++ strm->msg = oesc_msg(dfltcc_state->msg, param->oesc); ++ state->last = cc == DFLTCC_CC_OK; ++ state->bits = param->sbb; ++ state->whave = param->hl; ++ state->wnext = (param->ho + param->hl) & ((1 << HB_BITS) - 1); ++ state->check = state->flags ? ZSWAP32(param->cv) : param->cv; ++ if (cc == DFLTCC_CC_OP2_CORRUPT && param->oesc != 0) { ++ /* Report an error if stream is corrupted */ ++ state->mode = BAD; ++ return DFLTCC_INFLATE_CONTINUE; ++ } ++ state->mode = TYPEDO; ++ /* Break if operands are exhausted, otherwise continue looping */ ++ return (cc == DFLTCC_CC_OP1_TOO_SHORT || cc == DFLTCC_CC_OP2_TOO_SHORT) ? ++ DFLTCC_INFLATE_BREAK : DFLTCC_INFLATE_CONTINUE; ++} ++ ++int ZLIB_INTERNAL dfltcc_was_inflate_used(strm) ++ z_streamp strm; ++{ ++ struct inflate_state FAR *state = (struct inflate_state FAR *)strm->state; ++ struct dfltcc_param_v0 FAR *param = &GET_DFLTCC_STATE(state)->param; ++ ++ return !param->nt; ++} ++ ++int ZLIB_INTERNAL dfltcc_inflate_disable(strm) ++ z_streamp strm; ++{ ++ struct inflate_state FAR *state = (struct inflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ ++ if (!dfltcc_can_inflate(strm)) ++ return 0; ++ if (dfltcc_was_inflate_used(strm)) ++ /* DFLTCC has already decompressed some data. Since there is not ++ * enough information to resume decompression in software, the call ++ * must fail. ++ */ ++ return 1; ++ /* DFLTCC was not used yet - decompress in software */ ++ memset(&dfltcc_state->af, 0, sizeof(dfltcc_state->af)); ++ return 0; ++} ++ ++/* ++ Memory management. ++ DFLTCC requires parameter blocks and window to be aligned. zlib allows ++ users to specify their own allocation functions, so using e.g. ++ `posix_memalign' is not an option. Thus, we overallocate and take the ++ aligned portion of the buffer. ++*/ ++local inline int is_dfltcc_enabled OF((void)); ++local inline int is_dfltcc_enabled(void) ++{ ++ const char *env; ++ uint64_t facilities[(DFLTCC_FACILITY / 64) + 1]; ++ register char r0 __asm__("r0"); ++ ++ env = secure_getenv("DFLTCC"); ++ if (env && !strcmp(env, "0")) ++ /* User has explicitly disabled DFLTCC. */ ++ return 0; ++ ++ memset(facilities, 0, sizeof(facilities)); ++ r0 = sizeof(facilities) / sizeof(facilities[0]) - 1; ++ /* STFLE is supported since z9-109 and only in z/Architecture mode. When ++ * compiling with -m31, gcc defaults to ESA mode, however, since the kernel ++ * is 64-bit, it's always z/Architecture mode at runtime. ++ */ ++ __asm__ volatile(".machinemode push\n" ++ ".machinemode zarch\n" ++ "stfle %[facilities]\n" ++ ".machinemode pop\n" ++ : [facilities] "=Q" (facilities) ++ , [r0] "+r" (r0) ++ : ++ : "cc"); ++ return is_bit_set((const char *)facilities, DFLTCC_FACILITY); ++} ++ ++void ZLIB_INTERNAL dfltcc_reset(strm, size) ++ z_streamp strm; ++ uInt size; ++{ ++ struct dfltcc_state *dfltcc_state = ++ (struct dfltcc_state *)((char FAR *)strm->state + ALIGN_UP(size, 8)); ++ struct dfltcc_qaf_param *param = ++ (struct dfltcc_qaf_param *)&dfltcc_state->param; ++ const char *s; ++ ++ /* Initialize available functions */ ++ if (is_dfltcc_enabled()) { ++ dfltcc(DFLTCC_QAF, param, NULL, NULL, NULL, NULL, NULL); ++ memmove(&dfltcc_state->af, param, sizeof(dfltcc_state->af)); ++ } else ++ memset(&dfltcc_state->af, 0, sizeof(dfltcc_state->af)); ++ ++ if (secure_getenv("SOURCE_DATE_EPOCH")) ++ /* User needs reproducible results, but the output of DFLTCC_CMPR ++ * depends on buffers' page offsets. ++ */ ++ clear_bit(dfltcc_state->af.fns, DFLTCC_CMPR); ++ ++ /* Initialize parameter block */ ++ memset(&dfltcc_state->param, 0, sizeof(dfltcc_state->param)); ++ dfltcc_state->param.nt = 1; ++ ++ /* Initialize tuning parameters */ ++#ifndef DFLTCC_LEVEL_MASK ++#define DFLTCC_LEVEL_MASK 0x2 ++#endif ++ s = secure_getenv("DFLTCC_LEVEL_MASK"); ++ dfltcc_state->level_mask = (s && *s) ? strtoul(s, NULL, 0) : ++ DFLTCC_LEVEL_MASK; ++#ifndef DFLTCC_BLOCK_SIZE ++#define DFLTCC_BLOCK_SIZE 1048576 ++#endif ++ s = secure_getenv("DFLTCC_BLOCK_SIZE"); ++ dfltcc_state->block_size = (s && *s) ? strtoul(s, NULL, 0) : ++ DFLTCC_BLOCK_SIZE; ++#ifndef DFLTCC_FIRST_FHT_BLOCK_SIZE ++#define DFLTCC_FIRST_FHT_BLOCK_SIZE 4096 ++#endif ++ s = secure_getenv("DFLTCC_FIRST_FHT_BLOCK_SIZE"); ++ dfltcc_state->block_threshold = (s && *s) ? strtoul(s, NULL, 0) : ++ DFLTCC_FIRST_FHT_BLOCK_SIZE; ++#ifndef DFLTCC_DHT_MIN_SAMPLE_SIZE ++#define DFLTCC_DHT_MIN_SAMPLE_SIZE 4096 ++#endif ++ s = secure_getenv("DFLTCC_DHT_MIN_SAMPLE_SIZE"); ++ dfltcc_state->dht_threshold = (s && *s) ? strtoul(s, NULL, 0) : ++ DFLTCC_DHT_MIN_SAMPLE_SIZE; ++#ifndef DFLTCC_RIBM ++#define DFLTCC_RIBM 0 ++#endif ++ s = secure_getenv("DFLTCC_RIBM"); ++ dfltcc_state->param.ribm = (s && *s) ? strtoul(s, NULL, 0) : ++ DFLTCC_RIBM; ++} ++ ++voidpf ZLIB_INTERNAL dfltcc_alloc_state(strm, items, size) ++ z_streamp strm; ++ uInt items; ++ uInt size; ++{ ++ return ZALLOC(strm, ++ ALIGN_UP(items * size, 8) + sizeof(struct dfltcc_state), ++ sizeof(unsigned char)); ++} ++ ++void ZLIB_INTERNAL dfltcc_copy_state(dst, src, size) ++ voidpf dst; ++ const voidpf src; ++ uInt size; ++{ ++ zmemcpy(dst, src, ALIGN_UP(size, 8) + sizeof(struct dfltcc_state)); ++} ++ ++static const int PAGE_ALIGN = 0x1000; ++ ++voidpf ZLIB_INTERNAL dfltcc_alloc_window(strm, items, size) ++ z_streamp strm; ++ uInt items; ++ uInt size; ++{ ++ voidpf p, w; ++ ++ /* To simplify freeing, we store the pointer to the allocated buffer right ++ * before the window. ++ */ ++ p = ZALLOC(strm, sizeof(voidpf) + items * size + PAGE_ALIGN, ++ sizeof(unsigned char)); ++ if (p == NULL) ++ return NULL; ++ w = ALIGN_UP((char FAR *)p + sizeof(voidpf), PAGE_ALIGN); ++ *(voidpf *)((char FAR *)w - sizeof(voidpf)) = p; ++ return w; ++} ++ ++void ZLIB_INTERNAL dfltcc_free_window(strm, w) ++ z_streamp strm; ++ voidpf w; ++{ ++ if (w) ++ ZFREE(strm, *(voidpf *)((unsigned char FAR *)w - sizeof(voidpf))); ++} ++ ++/* ++ Switching between hardware and software compression. ++ DFLTCC does not support all zlib settings, e.g. generation of non-compressed ++ blocks or alternative window sizes. When such settings are applied on the ++ fly with deflateParams, we need to convert between hardware and software ++ window formats. ++*/ ++int ZLIB_INTERNAL dfltcc_deflate_params(strm, level, strategy) ++ z_streamp strm; ++ int level; ++ int strategy; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ struct dfltcc_param_v0 FAR *param = &dfltcc_state->param; ++ int could_deflate = dfltcc_can_deflate(strm); ++ int can_deflate = dfltcc_are_params_ok(level, state->w_bits, strategy, ++ dfltcc_state->level_mask); ++ ++ if (can_deflate == could_deflate) ++ /* We continue to work in the same mode - no changes needed */ ++ return Z_OK; ++ ++ if (strm->total_in == 0 && param->nt == 1 && param->hl == 0) ++ /* DFLTCC was not used yet - no changes needed */ ++ return Z_OK; ++ ++ /* Switching between hardware and software is not implemented */ ++ return Z_STREAM_ERROR; ++} ++ ++/* ++ Preloading history. ++*/ ++local void append_history OF((struct dfltcc_param_v0 FAR *param, ++ Bytef *history, ++ const Bytef *buf, ++ uInt count)); ++local void append_history(param, history, buf, count) ++ struct dfltcc_param_v0 FAR *param; ++ Bytef *history; ++ const Bytef *buf; ++ uInt count; ++{ ++ size_t offset; ++ size_t n; ++ ++ /* Do not use more than 32K */ ++ if (count > HB_SIZE) { ++ buf += count - HB_SIZE; ++ count = HB_SIZE; ++ } ++ offset = (param->ho + param->hl) % HB_SIZE; ++ if (offset + count <= HB_SIZE) ++ /* Circular history buffer does not wrap - copy one chunk */ ++ zmemcpy(history + offset, buf, count); ++ else { ++ /* Circular history buffer wraps - copy two chunks */ ++ n = HB_SIZE - offset; ++ zmemcpy(history + offset, buf, n); ++ zmemcpy(history, buf + n, count - n); ++ } ++ n = param->hl + count; ++ if (n <= HB_SIZE) ++ /* All history fits into buffer - no need to discard anything */ ++ param->hl = n; ++ else { ++ /* History does not fit into buffer - discard extra bytes */ ++ param->ho = (param->ho + (n - HB_SIZE)) % HB_SIZE; ++ param->hl = HB_SIZE; ++ } ++} ++ ++int ZLIB_INTERNAL dfltcc_deflate_set_dictionary(strm, dictionary, dict_length) ++ z_streamp strm; ++ const Bytef *dictionary; ++ uInt dict_length; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ struct dfltcc_param_v0 FAR *param = &dfltcc_state->param; ++ ++ append_history(param, state->window, dictionary, dict_length); ++ state->strstart = 1; /* Add FDICT to zlib header */ ++ return Z_OK; ++} ++ ++int ZLIB_INTERNAL dfltcc_deflate_get_dictionary(strm, dictionary, dict_length) ++ z_streamp strm; ++ Bytef *dictionary; ++ uInt *dict_length; ++{ ++ deflate_state FAR *state = (deflate_state FAR *)strm->state; ++ struct dfltcc_state FAR *dfltcc_state = GET_DFLTCC_STATE(state); ++ struct dfltcc_param_v0 FAR *param = &dfltcc_state->param; ++ ++ if (dictionary) { ++ if (param->ho + param->hl <= HB_SIZE) ++ /* Circular history buffer does not wrap - copy one chunk */ ++ zmemcpy(dictionary, state->window + param->ho, param->hl); ++ else { ++ /* Circular history buffer wraps - copy two chunks */ ++ zmemcpy(dictionary, ++ state->window + param->ho, ++ HB_SIZE - param->ho); ++ zmemcpy(dictionary + HB_SIZE - param->ho, ++ state->window, ++ param->ho + param->hl - HB_SIZE); ++ } ++ } ++ if (dict_length) ++ *dict_length = param->hl; ++ return Z_OK; ++} +\ No newline at end of file +diff --git a/contrib/s390/dfltcc.h b/contrib/s390/dfltcc.h +new file mode 100644 +index 0000000..574e84c +--- /dev/null ++++ b/contrib/s390/dfltcc.h +@@ -0,0 +1,55 @@ ++#ifndef DFLTCC_H ++#define DFLTCC_H ++ ++#include "../../zlib.h" ++#include "../../zutil.h" ++ ++voidpf ZLIB_INTERNAL dfltcc_alloc_state OF((z_streamp strm, uInt items, ++ uInt size)); ++void ZLIB_INTERNAL dfltcc_copy_state OF((voidpf dst, const voidpf src, ++ uInt size)); ++void ZLIB_INTERNAL dfltcc_reset OF((z_streamp strm, uInt size)); ++voidpf ZLIB_INTERNAL dfltcc_alloc_window OF((z_streamp strm, uInt items, ++ uInt size)); ++void ZLIB_INTERNAL dfltcc_free_window OF((z_streamp strm, voidpf w)); ++int ZLIB_INTERNAL dfltcc_can_inflate OF((z_streamp strm)); ++typedef enum { ++ DFLTCC_INFLATE_CONTINUE, ++ DFLTCC_INFLATE_BREAK, ++ DFLTCC_INFLATE_SOFTWARE, ++} dfltcc_inflate_action; ++dfltcc_inflate_action ZLIB_INTERNAL dfltcc_inflate OF((z_streamp strm, ++ int flush, int *ret)); ++int ZLIB_INTERNAL dfltcc_was_inflate_used OF((z_streamp strm)); ++int ZLIB_INTERNAL dfltcc_inflate_disable OF((z_streamp strm)); ++ ++#define ZALLOC_STATE dfltcc_alloc_state ++#define ZFREE_STATE ZFREE ++#define ZCOPY_STATE dfltcc_copy_state ++#define ZALLOC_WINDOW dfltcc_alloc_window ++#define ZFREE_WINDOW dfltcc_free_window ++#define TRY_FREE_WINDOW dfltcc_free_window ++#define INFLATE_RESET_KEEP_HOOK(strm) \ ++ dfltcc_reset((strm), sizeof(struct inflate_state)) ++#define INFLATE_PRIME_HOOK(strm, bits, value) \ ++ do { if (dfltcc_inflate_disable((strm))) return Z_STREAM_ERROR; } while (0) ++#define INFLATE_TYPEDO_HOOK(strm, flush) \ ++ if (dfltcc_can_inflate((strm))) { \ ++ dfltcc_inflate_action action; \ ++\ ++ RESTORE(); \ ++ action = dfltcc_inflate((strm), (flush), &ret); \ ++ LOAD(); \ ++ if (action == DFLTCC_INFLATE_CONTINUE) \ ++ break; \ ++ else if (action == DFLTCC_INFLATE_BREAK) \ ++ goto inf_leave; \ ++ } ++#define INFLATE_NEED_CHECKSUM(strm) (!dfltcc_can_inflate((strm))) ++#define INFLATE_NEED_UPDATEWINDOW(strm) (!dfltcc_can_inflate((strm))) ++#define INFLATE_MARK_HOOK(strm) \ ++ do { \ ++ if (dfltcc_was_inflate_used((strm))) return -(1L << 16); \ ++ } while (0) ++ ++#endif +\ No newline at end of file +diff --git a/contrib/s390/dfltcc_deflate.h b/contrib/s390/dfltcc_deflate.h +new file mode 100644 +index 0000000..a129a91 +--- /dev/null ++++ b/contrib/s390/dfltcc_deflate.h +@@ -0,0 +1,50 @@ ++#ifndef DFLTCC_DEFLATE_H ++#define DFLTCC_DEFLATE_H ++ ++#include "dfltcc.h" ++ ++int ZLIB_INTERNAL dfltcc_can_deflate OF((z_streamp strm)); ++int ZLIB_INTERNAL dfltcc_deflate OF((z_streamp strm, ++ int flush, ++ block_state *result)); ++int ZLIB_INTERNAL dfltcc_deflate_params OF((z_streamp strm, ++ int level, ++ int strategy)); ++int ZLIB_INTERNAL dfltcc_deflate_set_dictionary OF((z_streamp strm, ++ const Bytef *dictionary, ++ uInt dict_length)); ++int ZLIB_INTERNAL dfltcc_deflate_get_dictionary OF((z_streamp strm, ++ Bytef *dictionary, ++ uInt* dict_length)); ++ ++#define DEFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) \ ++ do { \ ++ if (dfltcc_can_deflate((strm))) \ ++ return dfltcc_deflate_set_dictionary((strm), (dict), (dict_len)); \ ++ } while (0) ++#define DEFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) \ ++ do { \ ++ if (dfltcc_can_deflate((strm))) \ ++ return dfltcc_deflate_get_dictionary((strm), (dict), (dict_len)); \ ++ } while (0) ++#define DEFLATE_RESET_KEEP_HOOK(strm) \ ++ dfltcc_reset((strm), sizeof(deflate_state)) ++#define DEFLATE_PARAMS_HOOK(strm, level, strategy) \ ++ do { \ ++ int err; \ ++\ ++ err = dfltcc_deflate_params((strm), (level), (strategy)); \ ++ if (err == Z_STREAM_ERROR) \ ++ return err; \ ++ } while (0) ++#define DEFLATE_BOUND_ADJUST_COMPLEN(strm, complen, source_len) \ ++ do { \ ++ if (dfltcc_can_deflate((strm))) \ ++ (complen) = (3 + 5 + 5 + 4 + 19 * 3 + (286 + 30) * 7 + \ ++ (source_len) * 16 + 15 + 7) >> 3; \ ++ } while (0) ++#define DEFLATE_NEED_CONSERVATIVE_BOUND(strm) (dfltcc_can_deflate((strm))) ++#define DEFLATE_HOOK dfltcc_deflate ++#define DEFLATE_NEED_CHECKSUM(strm) (!dfltcc_can_deflate((strm))) ++ ++#endif +\ No newline at end of file +diff --git a/deflate.c b/deflate.c +index 1ec7614..089285a 100644 +--- a/deflate.c ++++ b/deflate.c +@@ -61,15 +61,29 @@ const char deflate_copyright[] = + */ + + /* =========================================================================== +- * Function prototypes. ++ * Architecture-specific bits. + */ +-typedef enum { +- need_more, /* block not completed, need more input or more output */ +- block_done, /* block flush performed */ +- finish_started, /* finish started, need only more output at next deflate */ +- finish_done /* finish done, accept no more input or output */ +-} block_state; ++#ifdef DFLTCC ++# include "contrib/s390/dfltcc_deflate.h" ++#else ++#define ZALLOC_STATE ZALLOC ++#define ZFREE_STATE ZFREE ++#define ZCOPY_STATE zmemcpy ++#define ZALLOC_WINDOW ZALLOC ++#define TRY_FREE_WINDOW TRY_FREE ++#define DEFLATE_SET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) ++#define DEFLATE_GET_DICTIONARY_HOOK(strm, dict, dict_len) do {} while (0) ++#define DEFLATE_RESET_KEEP_HOOK(strm) do {} while (0) ++#define DEFLATE_PARAMS_HOOK(strm, level, strategy) do {} while (0) ++#define DEFLATE_BOUND_ADJUST_COMPLEN(strm, complen, sourceLen) do {} while (0) ++#define DEFLATE_NEED_CONSERVATIVE_BOUND(strm) 0 ++#define DEFLATE_HOOK(strm, flush, bstate) 0 ++#define DEFLATE_NEED_CHECKSUM(strm) 1 ++#endif + ++/* =========================================================================== ++ * Function prototypes. ++ */ + typedef block_state (*compress_func) OF((deflate_state *s, int flush)); + /* Compression function. Returns the block state after the call. */ + +@@ -85,7 +99,6 @@ local block_state deflate_rle OF((deflate_state *s, int flush)); + local block_state deflate_huff OF((deflate_state *s, int flush)); + local void lm_init OF((deflate_state *s)); + local void putShortMSB OF((deflate_state *s, uInt b)); +-local void flush_pending OF((z_streamp strm)); + local unsigned read_buf OF((z_streamp strm, Bytef *buf, unsigned size)); + #ifdef ASMV + # pragma message("Assembler code may have bugs -- use at your own risk") +@@ -301,7 +314,7 @@ int ZEXPORT deflateInit2_(strm, level, method, windowBits, memLevel, strategy, + return Z_STREAM_ERROR; + } + if (windowBits == 8) windowBits = 9; /* until 256-byte window bug fixed */ +- s = (deflate_state *) ZALLOC(strm, 1, sizeof(deflate_state)); ++ s = (deflate_state *) ZALLOC_STATE(strm, 1, sizeof(deflate_state)); + if (s == Z_NULL) return Z_MEM_ERROR; + strm->state = (struct internal_state FAR *)s; + s->strm = strm; +@@ -318,7 +331,7 @@ int ZEXPORT deflateInit2_(strm, level, method, windowBits, memLevel, strategy, + s->hash_mask = s->hash_size - 1; + s->hash_shift = ((s->hash_bits+MIN_MATCH-1)/MIN_MATCH); + +- s->window = (Bytef *) ZALLOC(strm, s->w_size, 2*sizeof(Byte)); ++ s->window = (Bytef *) ZALLOC_WINDOW(strm, s->w_size, 2*sizeof(Byte)); + s->prev = (Posf *) ZALLOC(strm, s->w_size, sizeof(Pos)); + s->head = (Posf *) ZALLOC(strm, s->hash_size, sizeof(Pos)); + +@@ -394,6 +407,7 @@ int ZEXPORT deflateSetDictionary (strm, dictionary, dictLength) + /* when using zlib wrappers, compute Adler-32 for provided dictionary */ + if (wrap == 1) + strm->adler = adler32(strm->adler, dictionary, dictLength); ++ DEFLATE_SET_DICTIONARY_HOOK(strm, dictionary, dictLength); + s->wrap = 0; /* avoid computing Adler-32 in read_buf */ + + /* if dictionary would fill window, just replace the history */ +@@ -452,6 +466,7 @@ int ZEXPORT deflateGetDictionary (strm, dictionary, dictLength) + + if (deflateStateCheck(strm)) + return Z_STREAM_ERROR; ++ DEFLATE_GET_DICTIONARY_HOOK(strm, dictionary, dictLength); + s = strm->state; + len = s->strstart + s->lookahead; + if (len > s->w_size) +@@ -498,6 +513,8 @@ int ZEXPORT deflateResetKeep (strm) + + _tr_init(s); + ++ DEFLATE_RESET_KEEP_HOOK(strm); ++ + return Z_OK; + } + +@@ -584,6 +601,7 @@ int ZEXPORT deflateParams(strm, level, strategy) + if (level < 0 || level > 9 || strategy < 0 || strategy > Z_FIXED) { + return Z_STREAM_ERROR; + } ++ DEFLATE_PARAMS_HOOK(strm, level, strategy); + func = configuration_table[s->level].func; + + if ((strategy != s->strategy || func != configuration_table[level].func) && +@@ -659,6 +677,7 @@ uLong ZEXPORT deflateBound(strm, sourceLen) + /* conservative upper bound for compressed data */ + complen = sourceLen + + ((sourceLen + 7) >> 3) + ((sourceLen + 63) >> 6) + 5; ++ DEFLATE_BOUND_ADJUST_COMPLEN(strm, complen, sourceLen); + + /* if can't get parameters, return conservative bound plus zlib wrapper */ + if (deflateStateCheck(strm)) +@@ -700,7 +719,8 @@ uLong ZEXPORT deflateBound(strm, sourceLen) + } + + /* if not default parameters, return conservative bound */ +- if (s->w_bits != 15 || s->hash_bits != 8 + 7) ++ if (DEFLATE_NEED_CONSERVATIVE_BOUND(strm) || ++ s->w_bits != 15 || s->hash_bits != 8 + 7) + return complen + wraplen; + + /* default settings: return tight bound for that case */ +@@ -727,7 +747,7 @@ local void putShortMSB (s, b) + * applications may wish to modify it to avoid allocating a large + * strm->next_out buffer and copying into it. (See also read_buf()). + */ +-local void flush_pending(strm) ++void ZLIB_INTERNAL flush_pending(strm) + z_streamp strm; + { + unsigned len; +@@ -997,7 +1017,8 @@ int ZEXPORT deflate (strm, flush) + (flush != Z_NO_FLUSH && s->status != FINISH_STATE)) { + block_state bstate; + +- bstate = s->level == 0 ? deflate_stored(s, flush) : ++ bstate = DEFLATE_HOOK(strm, flush, &bstate) ? bstate : ++ s->level == 0 ? deflate_stored(s, flush) : + s->strategy == Z_HUFFMAN_ONLY ? deflate_huff(s, flush) : + s->strategy == Z_RLE ? deflate_rle(s, flush) : + (*(configuration_table[s->level].func))(s, flush); +@@ -1086,9 +1107,9 @@ int ZEXPORT deflateEnd (strm) + TRY_FREE(strm, strm->state->pending_buf); + TRY_FREE(strm, strm->state->head); + TRY_FREE(strm, strm->state->prev); +- TRY_FREE(strm, strm->state->window); ++ TRY_FREE_WINDOW(strm, strm->state->window); + +- ZFREE(strm, strm->state); ++ ZFREE_STATE(strm, strm->state); + strm->state = Z_NULL; + + return status == BUSY_STATE ? Z_DATA_ERROR : Z_OK; +@@ -1119,13 +1140,13 @@ int ZEXPORT deflateCopy (dest, source) + + zmemcpy((voidpf)dest, (voidpf)source, sizeof(z_stream)); + +- ds = (deflate_state *) ZALLOC(dest, 1, sizeof(deflate_state)); ++ ds = (deflate_state *) ZALLOC_STATE(dest, 1, sizeof(deflate_state)); + if (ds == Z_NULL) return Z_MEM_ERROR; + dest->state = (struct internal_state FAR *) ds; +- zmemcpy((voidpf)ds, (voidpf)ss, sizeof(deflate_state)); ++ ZCOPY_STATE((voidpf)ds, (voidpf)ss, sizeof(deflate_state)); + ds->strm = dest; + +- ds->window = (Bytef *) ZALLOC(dest, ds->w_size, 2*sizeof(Byte)); ++ ds->window = (Bytef *) ZALLOC_WINDOW(dest, ds->w_size, 2*sizeof(Byte)); + ds->prev = (Posf *) ZALLOC(dest, ds->w_size, sizeof(Pos)); + ds->head = (Posf *) ZALLOC(dest, ds->hash_size, sizeof(Pos)); + overlay = (ushf *) ZALLOC(dest, ds->lit_bufsize, sizeof(ush)+2); +@@ -1174,7 +1195,8 @@ local unsigned read_buf(strm, buf, size) + strm->avail_in -= len; + + zmemcpy(buf, strm->next_in, len); +- if (strm->state->wrap == 1) { ++ if (!DEFLATE_NEED_CHECKSUM(strm)) {} ++ else if (strm->state->wrap == 1) { + strm->adler = adler32(strm->adler, buf, len); + } + #ifdef GZIP +diff --git a/deflate.h b/deflate.h +index 23ecdd3..821a4b9 100644 +--- a/deflate.h ++++ b/deflate.h +@@ -304,6 +304,7 @@ void ZLIB_INTERNAL _tr_flush_bits OF((deflate_state *s)); + void ZLIB_INTERNAL _tr_align OF((deflate_state *s)); + void ZLIB_INTERNAL _tr_stored_block OF((deflate_state *s, charf *buf, + ulg stored_len, int last)); ++void ZLIB_INTERNAL _tr_send_bits OF((deflate_state *s, int value, int length)); + + #define d_code(dist) \ + ((dist) < 256 ? _dist_code[dist] : _dist_code[256+((dist)>>7)]) +@@ -346,4 +347,15 @@ void ZLIB_INTERNAL _tr_stored_block OF((deflate_state *s, charf *buf, + flush = _tr_tally(s, distance, length) + #endif + ++typedef enum { ++ need_more, /* block not completed, need more input or more output */ ++ block_done, /* block flush performed */ ++ finish_started, /* finish started, need only more output at next deflate */ ++ finish_done /* finish done, accept no more input or output */ ++} block_state; ++ ++unsigned ZLIB_INTERNAL bi_reverse OF((unsigned code, int len)); ++void ZLIB_INTERNAL bi_windup OF((deflate_state *s)); ++void ZLIB_INTERNAL flush_pending OF((z_streamp strm)); ++ + #endif /* DEFLATE_H */ +diff --git a/gzguts.h b/gzguts.h +index 990a4d2..3218395 100644 +--- a/gzguts.h ++++ b/gzguts.h +@@ -153,7 +153,11 @@ + + /* default i/o buffer size -- double this for output when reading (this and + twice this must be able to fit in an unsigned type) */ ++#ifdef DFLTCC ++#define GZBUFSIZE 131072 ++#else + #define GZBUFSIZE 8192 ++#endif + + /* gzip modes, also provide a little integrity check on the passed structure */ + #define GZ_NONE 0 +diff --git a/inflate.c b/inflate.c +index ac333e8..f77c2ae 100644 +--- a/inflate.c ++++ b/inflate.c +@@ -85,6 +85,23 @@ + #include "inflate.h" + #include "inffast.h" + ++/* architecture-specific bits */ ++#ifdef DFLTCC ++# include "contrib/s390/dfltcc.h" ++#else ++#define ZALLOC_STATE ZALLOC ++#define ZFREE_STATE ZFREE ++#define ZCOPY_STATE zmemcpy ++#define ZALLOC_WINDOW ZALLOC ++#define ZFREE_WINDOW ZFREE ++#define INFLATE_RESET_KEEP_HOOK(strm) do {} while (0) ++#define INFLATE_PRIME_HOOK(strm, bits, value) do {} while (0) ++#define INFLATE_TYPEDO_HOOK(strm, flush) do {} while (0) ++#define INFLATE_NEED_CHECKSUM(strm) 1 ++#define INFLATE_NEED_UPDATEWINDOW(strm) 1 ++#define INFLATE_MARK_HOOK(strm) do {} while (0) ++#endif ++ + #ifdef MAKEFIXED + # ifndef BUILDFIXED + # define BUILDFIXED +@@ -137,6 +154,7 @@ z_streamp strm; + state->lencode = state->distcode = state->next = state->codes; + state->sane = 1; + state->back = -1; ++ INFLATE_RESET_KEEP_HOOK(strm); + Tracev((stderr, "inflate: reset\n")); + return Z_OK; + } +@@ -182,7 +200,7 @@ int windowBits; + if (windowBits && (windowBits < 8 || windowBits > 15)) + return Z_STREAM_ERROR; + if (state->window != Z_NULL && state->wbits != (unsigned)windowBits) { +- ZFREE(strm, state->window); ++ ZFREE_WINDOW(strm, state->window); + state->window = Z_NULL; + } + +@@ -221,7 +239,7 @@ int stream_size; + strm->zfree = zcfree; + #endif + state = (struct inflate_state FAR *) +- ZALLOC(strm, 1, sizeof(struct inflate_state)); ++ ZALLOC_STATE(strm, 1, sizeof(struct inflate_state)); + if (state == Z_NULL) return Z_MEM_ERROR; + Tracev((stderr, "inflate: allocated\n")); + strm->state = (struct internal_state FAR *)state; +@@ -230,7 +248,7 @@ int stream_size; + state->mode = HEAD; /* to pass state test in inflateReset2() */ + ret = inflateReset2(strm, windowBits); + if (ret != Z_OK) { +- ZFREE(strm, state); ++ ZFREE_STATE(strm, state); + strm->state = Z_NULL; + } + return ret; +@@ -252,6 +270,7 @@ int value; + struct inflate_state FAR *state; + + if (inflateStateCheck(strm)) return Z_STREAM_ERROR; ++ INFLATE_PRIME_HOOK(strm, bits, value); + state = (struct inflate_state FAR *)strm->state; + if (bits < 0) { + state->hold = 0; +@@ -379,6 +398,27 @@ void makefixed() + } + #endif /* MAKEFIXED */ + ++int ZLIB_INTERNAL inflate_ensure_window(state) ++ struct inflate_state *state; ++{ ++ /* if it hasn't been done already, allocate space for the window */ ++ if (state->window == Z_NULL) { ++ state->window = (unsigned char FAR *) ++ ZALLOC_WINDOW(state->strm, 1U << state->wbits, ++ sizeof(unsigned char)); ++ if (state->window == Z_NULL) return 1; ++ } ++ ++ /* if window not in use yet, initialize */ ++ if (state->wsize == 0) { ++ state->wsize = 1U << state->wbits; ++ state->wnext = 0; ++ state->whave = 0; ++ } ++ ++ return 0; ++} ++ + /* + Update the window with the last wsize (normally 32K) bytes written before + returning. If window does not exist yet, create it. This is only called +@@ -403,20 +443,7 @@ unsigned copy; + + state = (struct inflate_state FAR *)strm->state; + +- /* if it hasn't been done already, allocate space for the window */ +- if (state->window == Z_NULL) { +- state->window = (unsigned char FAR *) +- ZALLOC(strm, 1U << state->wbits, +- sizeof(unsigned char)); +- if (state->window == Z_NULL) return 1; +- } +- +- /* if window not in use yet, initialize */ +- if (state->wsize == 0) { +- state->wsize = 1U << state->wbits; +- state->wnext = 0; +- state->whave = 0; +- } ++ if (inflate_ensure_window(state)) return 1; + + /* copy state->wsize or less output bytes into the circular window */ + if (copy >= state->wsize) { +@@ -849,6 +876,7 @@ int flush; + case TYPE: + if (flush == Z_BLOCK || flush == Z_TREES) goto inf_leave; + case TYPEDO: ++ INFLATE_TYPEDO_HOOK(strm, flush); + if (state->last) { + BYTEBITS(); + state->mode = CHECK; +@@ -1200,7 +1228,7 @@ int flush; + out -= left; + strm->total_out += out; + state->total += out; +- if ((state->wrap & 4) && out) ++ if (INFLATE_NEED_CHECKSUM(strm) && (state->wrap & 4) && out) + strm->adler = state->check = + UPDATE(state->check, put - out, out); + out = left; +@@ -1252,8 +1280,9 @@ int flush; + */ + inf_leave: + RESTORE(); +- if (state->wsize || (out != strm->avail_out && state->mode < BAD && +- (state->mode < CHECK || flush != Z_FINISH))) ++ if (INFLATE_NEED_UPDATEWINDOW(strm) && ++ (state->wsize || (out != strm->avail_out && state->mode < BAD && ++ (state->mode < CHECK || flush != Z_FINISH)))) + if (updatewindow(strm, strm->next_out, out - strm->avail_out)) { + state->mode = MEM; + return Z_MEM_ERROR; +@@ -1263,7 +1292,7 @@ int flush; + strm->total_in += in; + strm->total_out += out; + state->total += out; +- if ((state->wrap & 4) && out) ++ if (INFLATE_NEED_CHECKSUM(strm) && (state->wrap & 4) && out) + strm->adler = state->check = + UPDATE(state->check, strm->next_out - out, out); + strm->data_type = (int)state->bits + (state->last ? 64 : 0) + +@@ -1281,8 +1310,8 @@ z_streamp strm; + if (inflateStateCheck(strm)) + return Z_STREAM_ERROR; + state = (struct inflate_state FAR *)strm->state; +- if (state->window != Z_NULL) ZFREE(strm, state->window); +- ZFREE(strm, strm->state); ++ if (state->window != Z_NULL) ZFREE_WINDOW(strm, state->window); ++ ZFREE_STATE(strm, strm->state); + strm->state = Z_NULL; + Tracev((stderr, "inflate: end\n")); + return Z_OK; +@@ -1474,21 +1503,21 @@ z_streamp source; + + /* allocate space */ + copy = (struct inflate_state FAR *) +- ZALLOC(source, 1, sizeof(struct inflate_state)); ++ ZALLOC_STATE(source, 1, sizeof(struct inflate_state)); + if (copy == Z_NULL) return Z_MEM_ERROR; + window = Z_NULL; + if (state->window != Z_NULL) { + window = (unsigned char FAR *) +- ZALLOC(source, 1U << state->wbits, sizeof(unsigned char)); ++ ZALLOC_WINDOW(source, 1U << state->wbits, sizeof(unsigned char)); + if (window == Z_NULL) { +- ZFREE(source, copy); ++ ZFREE_STATE(source, copy); + return Z_MEM_ERROR; + } + } + + /* copy state */ + zmemcpy((voidpf)dest, (voidpf)source, sizeof(z_stream)); +- zmemcpy((voidpf)copy, (voidpf)state, sizeof(struct inflate_state)); ++ ZCOPY_STATE((voidpf)copy, (voidpf)state, sizeof(struct inflate_state)); + copy->strm = dest; + if (state->lencode >= state->codes && + state->lencode <= state->codes + ENOUGH - 1) { +@@ -1545,6 +1574,7 @@ z_streamp strm; + + if (inflateStateCheck(strm)) + return -(1L << 16); ++ INFLATE_MARK_HOOK(strm); + state = (struct inflate_state FAR *)strm->state; + return (long)(((unsigned long)((long)state->back)) << 16) + + (state->mode == COPY ? state->length : +diff --git a/inflate.h b/inflate.h +index a46cce6..7b19617 100644 +--- a/inflate.h ++++ b/inflate.h +@@ -123,3 +123,5 @@ struct inflate_state { + int back; /* bits back of last unprocessed length/lit */ + unsigned was; /* initial length of match */ + }; ++ ++int ZLIB_INTERNAL inflate_ensure_window OF((struct inflate_state *state)); +diff --git a/test/infcover.c b/test/infcover.c +index 2be0164..a34cd17 100644 +--- a/test/infcover.c ++++ b/test/infcover.c +@@ -444,7 +444,7 @@ local void cover_wrap(void) + } + + /* input and output functions for inflateBack() */ +-local unsigned pull(void *desc, unsigned char **buf) ++local unsigned pull(void *desc, z_const unsigned char **buf) + { + static unsigned int next = 0; + static unsigned char dat[] = {0x63, 0, 2, 0}; +diff --git a/test/minigzip.c b/test/minigzip.c +index e22fb08..4b5f4ef 100644 +--- a/test/minigzip.c ++++ b/test/minigzip.c +@@ -132,7 +132,11 @@ static void pwinerror (s) + #endif + #define SUFFIX_LEN (sizeof(GZ_SUFFIX)-1) + ++#ifdef DFLTCC ++#define BUFLEN 262144 ++#else + #define BUFLEN 16384 ++#endif + #define MAX_NAME_LEN 1024 + + #ifdef MAXSEG_64K +diff --git a/trees.c b/trees.c +index 50cf4b4..ad51207 100644 +--- a/trees.c ++++ b/trees.c +@@ -149,8 +149,6 @@ local void send_all_trees OF((deflate_state *s, int lcodes, int dcodes, + local void compress_block OF((deflate_state *s, const ct_data *ltree, + const ct_data *dtree)); + local int detect_data_type OF((deflate_state *s)); +-local unsigned bi_reverse OF((unsigned value, int length)); +-local void bi_windup OF((deflate_state *s)); + local void bi_flush OF((deflate_state *s)); + + #ifdef GEN_TREES_H +@@ -223,6 +221,13 @@ local void send_bits(s, value, length) + } + #endif /* ZLIB_DEBUG */ + ++void ZLIB_INTERNAL _tr_send_bits(s, value, length) ++ deflate_state *s; ++ int value; ++ int length; ++{ ++ send_bits(s, value, length); ++} + + /* the arguments must not have side effects */ + +@@ -1155,7 +1160,7 @@ local int detect_data_type(s) + * method would use a table) + * IN assertion: 1 <= len <= 15 + */ +-local unsigned bi_reverse(code, len) ++unsigned ZLIB_INTERNAL bi_reverse(code, len) + unsigned code; /* the value to invert */ + int len; /* its bit length */ + { +@@ -1187,7 +1192,7 @@ local void bi_flush(s) + /* =========================================================================== + * Flush the bit buffer and align the output on a byte boundary + */ +-local void bi_windup(s) ++void ZLIB_INTERNAL bi_windup(s) + deflate_state *s; + { + if (s->bi_valid > 8) { +-- +2.19.1 + diff --git a/SOURCES/zlib-1.2.11-covscan-issues.patch b/SOURCES/zlib-1.2.11-covscan-issues.patch new file mode 100644 index 0000000..28e8604 --- /dev/null +++ b/SOURCES/zlib-1.2.11-covscan-issues.patch @@ -0,0 +1,74 @@ +From f776e1609cc63bf486634ee9bc6226dac2c0d2f3 Mon Sep 17 00:00:00 2001 +From: Ondrej Dubaj +Date: Tue, 15 Oct 2019 11:27:15 +0200 +Subject: [PATCH] fixed covscan issues + +--- + crc32.c | 2 +- + deflate.c | 2 +- + test/crc32_test.c | 8 ++++---- + 3 files changed, 6 insertions(+), 6 deletions(-) + +diff --git a/crc32.c b/crc32.c +index 406d350..34132ea 100644 +--- a/crc32.c ++++ b/crc32.c +@@ -302,7 +302,7 @@ unsigned long ZEXPORT crc32_z(crc, buf, len) + + if (!crc32_func) + crc32_func = crc32_z_ifunc(); +- return (*crc32_func)(crc, buf, len); ++ return (*crc32_func)(crc, buf, len); + } + + #endif /* defined(Z_IFUNC_ASM) || defined(Z_IFUNC_NATIVE) */ +diff --git a/deflate.c b/deflate.c +index 089285a..9b09718 100644 +--- a/deflate.c ++++ b/deflate.c +@@ -1015,7 +1015,7 @@ int ZEXPORT deflate (strm, flush) + */ + if (strm->avail_in != 0 || s->lookahead != 0 || + (flush != Z_NO_FLUSH && s->status != FINISH_STATE)) { +- block_state bstate; ++ block_state bstate = 0; + + bstate = DEFLATE_HOOK(strm, flush, &bstate) ? bstate : + s->level == 0 ? deflate_stored(s, flush) : +diff --git a/test/crc32_test.c b/test/crc32_test.c +index 5d73128..2d2a6c7 100644 +--- a/test/crc32_test.c ++++ b/test/crc32_test.c +@@ -11,25 +11,25 @@ + # include + #endif + +-void test_crc32 OF((uLong crc, Byte* buf, z_size_t len, uLong chk, int line)); ++void test_crc32 OF((uLong crc, char* buf, z_size_t len, uLong chk, int line)); + int main OF((void)); + + typedef struct { + int line; + uLong crc; +- Byte* buf; ++ char* buf; + int len; + uLong expect; + } crc32_test; + + void test_crc32(crc, buf, len, chk, line) + uLong crc; +- Byte *buf; ++ char *buf; + z_size_t len; + uLong chk; + int line; + { +- uLong res = crc32(crc, buf, len); ++ uLong res = crc32(crc, (Bytef *) buf, len); + if (res != chk) { + fprintf(stderr, "FAIL [%d]: crc32 returned 0x%08X expected 0x%08X\n", + line, (unsigned int)res, (unsigned int)chk); +-- +2.19.1 + diff --git a/SOURCES/zlib-1.2.11-firefox-crash-fix.patch b/SOURCES/zlib-1.2.11-firefox-crash-fix.patch new file mode 100644 index 0000000..27068bb --- /dev/null +++ b/SOURCES/zlib-1.2.11-firefox-crash-fix.patch @@ -0,0 +1,365 @@ +From 27a84de4a30cd35f8565937397f6d1205b912818 Mon Sep 17 00:00:00 2001 +From: Ondrej Dubaj +Date: Thu, 5 Sep 2019 09:16:35 +0200 +Subject: [PATCH 1/2] fix: power8 crc32 - return 0 with 0 ptr passed + +--- + contrib/power8-crc/vec_crc32.c | 1 + + 1 file changed, 1 insertion(+) + +diff --git a/contrib/power8-crc/vec_crc32.c b/contrib/power8-crc/vec_crc32.c +index bb2204b..5ce9cd2 100644 +--- a/contrib/power8-crc/vec_crc32.c ++++ b/contrib/power8-crc/vec_crc32.c +@@ -74,6 +74,7 @@ unsigned int CRC32_FUNCTION(unsigned int crc, const unsigned char *p, + unsigned int prealign; + unsigned int tail; + ++ if (p == (const unsigned char *) 0x0) return 0; + #ifdef CRC_XOR + crc ^= 0xffffffff; + #endif +-- +2.19.1 + + +From c066ac92982a2ffe5b1e9bd36000058927437bd5 Mon Sep 17 00:00:00 2001 +From: Ondrej Dubaj +Date: Thu, 5 Sep 2019 09:36:47 +0200 +Subject: [PATCH 2/2] Add CRC32 tests (crc32_test) + +This commit includes a CRC32 test (crc32_test). This tests are important +since some architectures may want include CPU dependent optimizations for +CRC32 algorithm like using vector instructions and we may want to +validate those. +--- + Makefile.in | 35 +++++--- + test/crc32_test.c | 205 ++++++++++++++++++++++++++++++++++++++++++++++ + 2 files changed, 230 insertions(+), 10 deletions(-) + create mode 100644 test/crc32_test.c + +diff --git a/Makefile.in b/Makefile.in +index 40b5cfb..6070dcc 100644 +--- a/Makefile.in ++++ b/Makefile.in +@@ -75,11 +75,11 @@ PIC_OBJS = $(PIC_OBJC) $(PIC_OBJA) + + all: static shared + +-static: example$(EXE) minigzip$(EXE) ++static: crc32_test$(EXE) example$(EXE) minigzip$(EXE) + +-shared: examplesh$(EXE) minigzipsh$(EXE) ++shared: crc32_testsh$(EXE) examplesh$(EXE) minigzipsh$(EXE) + +-all64: example64$(EXE) minigzip64$(EXE) ++all64: crc32_test64$(EXE) example64$(EXE) minigzip64$(EXE) + + check: test + +@@ -87,7 +87,7 @@ test: all teststatic testshared + + teststatic: static + @TMPST=tmpst_$$; \ +- if echo hello world | ./minigzip | ./minigzip -d && ./example $$TMPST ; then \ ++ if echo hello world | ./minigzip | ./minigzip -d && ./example $$TMPST && ./crc32_test; then \ + echo ' *** zlib test OK ***'; \ + else \ + echo ' *** zlib test FAILED ***'; false; \ +@@ -100,7 +100,7 @@ testshared: shared + DYLD_LIBRARY_PATH=`pwd`:$(DYLD_LIBRARY_PATH) ; export DYLD_LIBRARY_PATH; \ + SHLIB_PATH=`pwd`:$(SHLIB_PATH) ; export SHLIB_PATH; \ + TMPSH=tmpsh_$$; \ +- if echo hello world | ./minigzipsh | ./minigzipsh -d && ./examplesh $$TMPSH; then \ ++ if echo hello world | ./minigzipsh | ./minigzipsh -d && ./examplesh $$TMPSH && ./crc32_testsh; then \ + echo ' *** zlib shared test OK ***'; \ + else \ + echo ' *** zlib shared test FAILED ***'; false; \ +@@ -109,7 +109,7 @@ testshared: shared + + test64: all64 + @TMP64=tmp64_$$; \ +- if echo hello world | ./minigzip64 | ./minigzip64 -d && ./example64 $$TMP64; then \ ++ if echo hello world | ./minigzip64 | ./minigzip64 -d && ./example64 $$TMP64 && ./crc32_test64; then \ + echo ' *** zlib 64-bit test OK ***'; \ + else \ + echo ' *** zlib 64-bit test FAILED ***'; false; \ +@@ -157,6 +157,12 @@ example.o: $(SRCDIR)test/example.c $(SRCDIR)zlib.h zconf.h + minigzip.o: $(SRCDIR)test/minigzip.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/minigzip.c + ++crc32_test.o: $(SRCDIR)test/crc32_test.c $(SRCDIR)zlib.h zconf.h ++ $(CC) $(CFLAGS) $(ZINCOUT) -c -o $@ $(SRCDIR)test/crc32_test.c ++ ++crc32_test64.o: $(SRCDIR)test/crc32_test.c $(SRCDIR)zlib.h zconf.h ++ $(CC) $(CFLAGS) $(ZINCOUT) -D_FILE_OFFSET_BITS=64 -c -o $@ $(SRCDIR)test/crc32_test.c ++ + example64.o: $(SRCDIR)test/example.c $(SRCDIR)zlib.h zconf.h + $(CC) $(CFLAGS) $(ZINCOUT) -D_FILE_OFFSET_BITS=64 -c -o $@ $(SRCDIR)test/example.c + +@@ -307,12 +313,21 @@ example$(EXE): example.o $(STATICLIB) + minigzip$(EXE): minigzip.o $(STATICLIB) + $(CC) $(CFLAGS) -o $@ minigzip.o $(TEST_LDFLAGS) + ++crc32_test$(EXE): crc32_test.o $(STATICLIB) ++ $(CC) $(CFLAGS) -o $@ crc32_test.o $(TEST_LDFLAGS) ++ ++crc32_testsh$(EXE): crc32_test.o $(SHAREDLIBV) ++ $(CC) $(CFLAGS) -o $@ crc32_test.o -L. $(SHAREDLIBV) ++ + examplesh$(EXE): example.o $(SHAREDLIBV) + $(CC) $(CFLAGS) -o $@ example.o -L. $(SHAREDLIBV) + + minigzipsh$(EXE): minigzip.o $(SHAREDLIBV) + $(CC) $(CFLAGS) -o $@ minigzip.o -L. $(SHAREDLIBV) + ++crc32_test64$(EXE): crc32_test64.o $(STATICLIB) ++ $(CC) $(CFLAGS) -o $@ crc32_test64.o $(TEST_LDFLAGS) ++ + example64$(EXE): example64.o $(STATICLIB) + $(CC) $(CFLAGS) -o $@ example64.o $(TEST_LDFLAGS) + +@@ -382,8 +397,8 @@ zconf: $(SRCDIR)zconf.h.in + mostlyclean: clean + clean: + rm -f *.o *.lo *~ \ +- example$(EXE) minigzip$(EXE) examplesh$(EXE) minigzipsh$(EXE) \ +- example64$(EXE) minigzip64$(EXE) \ ++ crc32_test$(EXE) example$(EXE) minigzip$(EXE) crc32_testsh$(EXE) examplesh$(EXE) minigzipsh$(EXE) \ ++ crc32_test64$(EXE) example64$(EXE) minigzip64$(EXE) \ + infcover \ + libz.* foo.gz so_locations \ + _match.s maketree contrib/infback9/*.o +@@ -407,7 +422,7 @@ tags: + + adler32.o zutil.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h + gzclose.o gzlib.o gzread.o gzwrite.o: $(SRCDIR)zlib.h zconf.h $(SRCDIR)gzguts.h +-compress.o example.o minigzip.o uncompr.o: $(SRCDIR)zlib.h zconf.h ++compress.o crc32_test.o example.o minigzip.o uncompr.o: $(SRCDIR)zlib.h zconf.h + crc32.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)crc32.h + deflate.o: $(SRCDIR)deflate.h $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h + infback.o inflate.o: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)inftrees.h $(SRCDIR)inflate.h $(SRCDIR)inffast.h $(SRCDIR)inffixed.h +@@ -417,7 +432,7 @@ trees.o: $(SRCDIR)deflate.h $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)tr + + adler32.lo zutil.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h + gzclose.lo gzlib.lo gzread.lo gzwrite.lo: $(SRCDIR)zlib.h zconf.h $(SRCDIR)gzguts.h +-compress.lo example.lo minigzip.lo uncompr.lo: $(SRCDIR)zlib.h zconf.h ++compress.lo crc32_test.lo example.lo minigzip.lo uncompr.lo: $(SRCDIR)zlib.h zconf.h + crc32.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)crc32.h + deflate.lo: $(SRCDIR)deflate.h $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h + infback.lo inflate.lo: $(SRCDIR)zutil.h $(SRCDIR)zlib.h zconf.h $(SRCDIR)inftrees.h $(SRCDIR)inflate.h $(SRCDIR)inffast.h $(SRCDIR)inffixed.h +diff --git a/test/crc32_test.c b/test/crc32_test.c +new file mode 100644 +index 0000000..5d73128 +--- /dev/null ++++ b/test/crc32_test.c +@@ -0,0 +1,205 @@ ++/* crc32_tes.c -- unit test for crc32 in the zlib compression library ++ * Copyright (C) 1995-2006, 2010, 2011, 2016, 2019 Rogerio Alves ++ * For conditions of distribution and use, see copyright notice in zlib.h ++ */ ++ ++#include "zlib.h" ++#include ++ ++#ifdef STDC ++# include ++# include ++#endif ++ ++void test_crc32 OF((uLong crc, Byte* buf, z_size_t len, uLong chk, int line)); ++int main OF((void)); ++ ++typedef struct { ++ int line; ++ uLong crc; ++ Byte* buf; ++ int len; ++ uLong expect; ++} crc32_test; ++ ++void test_crc32(crc, buf, len, chk, line) ++ uLong crc; ++ Byte *buf; ++ z_size_t len; ++ uLong chk; ++ int line; ++{ ++ uLong res = crc32(crc, buf, len); ++ if (res != chk) { ++ fprintf(stderr, "FAIL [%d]: crc32 returned 0x%08X expected 0x%08X\n", ++ line, (unsigned int)res, (unsigned int)chk); ++ exit(1); ++ } ++} ++ ++static const crc32_test tests[] = { ++ {__LINE__, 0x0, 0x0, 0, 0x0}, ++ {__LINE__, 0xffffffff, 0x0, 0, 0x0}, ++ {__LINE__, 0x0, 0x0, 255, 0x0}, /* BZ 174799. */ ++ {__LINE__, 0x0, 0x0, 256, 0x0}, ++ {__LINE__, 0x0, 0x0, 257, 0x0}, ++ {__LINE__, 0x0, 0x0, 32767, 0x0}, ++ {__LINE__, 0x0, 0x0, 32768, 0x0}, ++ {__LINE__, 0x0, 0x0, 32769, 0x0}, ++ {__LINE__, 0x0, "", 0, 0x0}, ++ {__LINE__, 0xffffffff, "", 0, 0xffffffff}, ++ {__LINE__, 0x0, "abacus", 6, 0xc3d7115b}, ++ {__LINE__, 0x0, "backlog", 7, 0x269205}, ++ {__LINE__, 0x0, "campfire", 8, 0x22a515f8}, ++ {__LINE__, 0x0, "delta", 5, 0x9643fed9}, ++ {__LINE__, 0x0, "executable", 10, 0xd68eda01}, ++ {__LINE__, 0x0, "file", 4, 0x8c9f3610}, ++ {__LINE__, 0x0, "greatest", 8, 0xc1abd6cd}, ++ {__LINE__, 0x0, "hello", 5, 0x3610a686}, ++ {__LINE__, 0x0, "inverter", 8, 0xc9e962c9}, ++ {__LINE__, 0x0, "jigsaw", 6, 0xce4e3f69}, ++ {__LINE__, 0x0, "karate", 6, 0x890be0e2}, ++ {__LINE__, 0x0, "landscape", 9, 0xc4e0330b}, ++ {__LINE__, 0x0, "machine", 7, 0x1505df84}, ++ {__LINE__, 0x0, "nanometer", 9, 0xd4e19f39}, ++ {__LINE__, 0x0, "oblivion", 8, 0xdae9de77}, ++ {__LINE__, 0x0, "panama", 6, 0x66b8979c}, ++ {__LINE__, 0x0, "quest", 5, 0x4317f817}, ++ {__LINE__, 0x0, "resource", 8, 0xbc91f416}, ++ {__LINE__, 0x0, "secret", 6, 0x5ca2e8e5}, ++ {__LINE__, 0x0, "test", 4, 0xd87f7e0c}, ++ {__LINE__, 0x0, "ultimate", 8, 0x3fc79b0b}, ++ {__LINE__, 0x0, "vector", 6, 0x1b6e485b}, ++ {__LINE__, 0x0, "walrus", 6, 0xbe769b97}, ++ {__LINE__, 0x0, "xeno", 4, 0xe7a06444}, ++ {__LINE__, 0x0, "yelling", 7, 0xfe3944e5}, ++ {__LINE__, 0x0, "zlib", 4, 0x73887d3a}, ++ {__LINE__, 0x0, "4BJD7PocN1VqX0jXVpWB", 20, 0xd487a5a1}, ++ {__LINE__, 0x0, "F1rPWI7XvDs6nAIRx41l", 20, 0x61a0132e}, ++ {__LINE__, 0x0, "ldhKlsVkPFOveXgkGtC2", 20, 0xdf02f76}, ++ {__LINE__, 0x0, "5KKnGOOrs8BvJ35iKTOS", 20, 0x579b2b0a}, ++ {__LINE__, 0x0, "0l1tw7GOcem06Ddu7yn4", 20, 0xf7d16e2d}, ++ {__LINE__, 0x0, "MCr47CjPIn9R1IvE1Tm5", 20, 0x731788f5}, ++ {__LINE__, 0x0, "UcixbzPKTIv0SvILHVdO", 20, 0x7112bb11}, ++ {__LINE__, 0x0, "dGnAyAhRQDsWw0ESou24", 20, 0xf32a0dac}, ++ {__LINE__, 0x0, "di0nvmY9UYMYDh0r45XT", 20, 0x625437bb}, ++ {__LINE__, 0x0, "2XKDwHfAhFsV0RhbqtvH", 20, 0x896930f9}, ++ {__LINE__, 0x0, "ZhrANFIiIvRnqClIVyeD", 20, 0x8579a37}, ++ {__LINE__, 0x0, "v7Q9ehzioTOVeDIZioT1", 20, 0x632aa8e0}, ++ {__LINE__, 0x0, "Yod5hEeKcYqyhfXbhxj2", 20, 0xc829af29}, ++ {__LINE__, 0x0, "GehSWY2ay4uUKhehXYb0", 20, 0x1b08b7e8}, ++ {__LINE__, 0x0, "kwytJmq6UqpflV8Y8GoE", 20, 0x4e33b192}, ++ {__LINE__, 0x0, "70684206568419061514", 20, 0x59a179f0}, ++ {__LINE__, 0x0, "42015093765128581010", 20, 0xcd1013d7}, ++ {__LINE__, 0x0, "88214814356148806939", 20, 0xab927546}, ++ {__LINE__, 0x0, "43472694284527343838", 20, 0x11f3b20c}, ++ {__LINE__, 0x0, "49769333513942933689", 20, 0xd562d4ca}, ++ {__LINE__, 0x0, "54979784887993251199", 20, 0x233395f7}, ++ {__LINE__, 0x0, "58360544869206793220", 20, 0x2d167fd5}, ++ {__LINE__, 0x0, "27347953487840714234", 20, 0x8b5108ba}, ++ {__LINE__, 0x0, "07650690295365319082", 20, 0xc46b3cd8}, ++ {__LINE__, 0x0, "42655507906821911703", 20, 0xc10b2662}, ++ {__LINE__, 0x0, "29977409200786225655", 20, 0xc9a0f9d2}, ++ {__LINE__, 0x0, "85181542907229116674", 20, 0x9341357b}, ++ {__LINE__, 0x0, "87963594337989416799", 20, 0xf0424937}, ++ {__LINE__, 0x0, "21395988329504168551", 20, 0xd7c4c31f}, ++ {__LINE__, 0x0, "51991013580943379423", 20, 0xf11edcc4}, ++ {__LINE__, 0x0, "*]+@!);({_$;}[_},?{?;(_?,=-][@", 30, 0x40795df4}, ++ {__LINE__, 0x0, "_@:_).&(#.[:[{[:)$++-($_;@[)}+", 30, 0xdd61a631}, ++ {__LINE__, 0x0, "&[!,[$_==}+.]@!;*(+},[;:)$;)-@", 30, 0xca907a99}, ++ {__LINE__, 0x0, "]{.[.+?+[[=;[?}_#&;[=)__$$:+=_", 30, 0xf652deac}, ++ {__LINE__, 0x0, "-%.)=/[@].:.(:,()$;=%@-$?]{%+%", 30, 0xaf39a5a9}, ++ {__LINE__, 0x0, "+]#$(@&.=:,*];/.!]%/{:){:@(;)$", 30, 0x6bebb4cf}, ++ {__LINE__, 0x0, ")-._.:?[&:.=+}(*$/=!.${;(=$@!}", 30, 0x76430bac}, ++ {__LINE__, 0x0, ":(_*&%/[[}+,?#$&*+#[([*-/#;%(]", 30, 0x6c80c388}, ++ {__LINE__, 0x0, "{[#-;:$/{)(+[}#]/{&!%(@)%:@-$:", 30, 0xd54d977d}, ++ {__LINE__, 0x0, "_{$*,}(&,@.)):=!/%(&(,,-?$}}}!", 30, 0xe3966ad5}, ++ {__LINE__, 0x0, "e$98KNzqaV)Y:2X?]77].{gKRD4G5{mHZk,Z)SpU%L3FSgv!Wb8MLAFdi{+fp)c,@8m6v)yXg@]HBDFk?.4&}g5_udE*JHCiH=aL", 100, 0xe7c71db9}, ++ {__LINE__, 0x0, "r*Fd}ef+5RJQ;+W=4jTR9)R*p!B;]Ed7tkrLi;88U7g@3v!5pk2X6D)vt,.@N8c]@yyEcKi[vwUu@.Ppm@C6%Mv*3Nw}Y,58_aH)", 100, 0xeaa52777}, ++ {__LINE__, 0x0, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 100, 0xcd472048}, ++ {__LINE__, 0x7a30360d, "abacus", 6, 0xf8655a84}, ++ {__LINE__, 0x6fd767ee, "backlog", 7, 0x1ed834b1}, ++ {__LINE__, 0xefeb7589, "campfire", 8, 0x686cfca}, ++ {__LINE__, 0x61cf7e6b, "delta", 5, 0x1554e4b1}, ++ {__LINE__, 0xdc712e2, "executable", 10, 0x761b4254}, ++ {__LINE__, 0xad23c7fd, "file", 4, 0x7abdd09b}, ++ {__LINE__, 0x85cb2317, "greatest", 8, 0x4ba91c6b}, ++ {__LINE__, 0x9eed31b0, "inverter", 8, 0xd5e78ba5}, ++ {__LINE__, 0xb94f34ca, "jigsaw", 6, 0x23649109}, ++ {__LINE__, 0xab058a2, "karate", 6, 0xc5591f41}, ++ {__LINE__, 0x5bff2b7a, "landscape", 9, 0xf10eb644}, ++ {__LINE__, 0x605c9a5f, "machine", 7, 0xbaa0a636}, ++ {__LINE__, 0x51bdeea5, "nanometer", 9, 0x6af89afb}, ++ {__LINE__, 0x85c21c79, "oblivion", 8, 0xecae222b}, ++ {__LINE__, 0x97216f56, "panama", 6, 0x47dffac4}, ++ {__LINE__, 0x18444af2, "quest", 5, 0x70c2fe36}, ++ {__LINE__, 0xbe6ce359, "resource", 8, 0x1471d925}, ++ {__LINE__, 0x843071f1, "secret", 6, 0x50c9a0db}, ++ {__LINE__, 0xf2480c60, "ultimate", 8, 0xf973daf8}, ++ {__LINE__, 0x2d2feb3d, "vector", 6, 0x344ac03d}, ++ {__LINE__, 0x7490310a, "walrus", 6, 0x6d1408ef}, ++ {__LINE__, 0x97d247d4, "xeno", 4, 0xe62670b5}, ++ {__LINE__, 0x93cf7599, "yelling", 7, 0x1b36da38}, ++ {__LINE__, 0x73c84278, "zlib", 4, 0x6432d127}, ++ {__LINE__, 0x228a87d1, "4BJD7PocN1VqX0jXVpWB", 20, 0x997107d0}, ++ {__LINE__, 0xa7a048d0, "F1rPWI7XvDs6nAIRx41l", 20, 0xdc567274}, ++ {__LINE__, 0x1f0ded40, "ldhKlsVkPFOveXgkGtC2", 20, 0xdcc63870}, ++ {__LINE__, 0xa804a62f, "5KKnGOOrs8BvJ35iKTOS", 20, 0x6926cffd}, ++ {__LINE__, 0x508fae6a, "0l1tw7GOcem06Ddu7yn4", 20, 0xb52b38bc}, ++ {__LINE__, 0xe5adaf4f, "MCr47CjPIn9R1IvE1Tm5", 20, 0xf83b8178}, ++ {__LINE__, 0x67136a40, "UcixbzPKTIv0SvILHVdO", 20, 0xc5213070}, ++ {__LINE__, 0xb00c4a10, "dGnAyAhRQDsWw0ESou24", 20, 0xbc7648b0}, ++ {__LINE__, 0x2e0c84b5, "di0nvmY9UYMYDh0r45XT", 20, 0xd8123a72}, ++ {__LINE__, 0x81238d44, "2XKDwHfAhFsV0RhbqtvH", 20, 0xd5ac5620}, ++ {__LINE__, 0xf853aa92, "ZhrANFIiIvRnqClIVyeD", 20, 0xceae099d}, ++ {__LINE__, 0x5a692325, "v7Q9ehzioTOVeDIZioT1", 20, 0xb07d2b24}, ++ {__LINE__, 0x3275b9f, "Yod5hEeKcYqyhfXbhxj2", 20, 0x24ce91df}, ++ {__LINE__, 0x38371feb, "GehSWY2ay4uUKhehXYb0", 20, 0x707b3b30}, ++ {__LINE__, 0xafc8bf62, "kwytJmq6UqpflV8Y8GoE", 20, 0x16abc6a9}, ++ {__LINE__, 0x9b07db73, "70684206568419061514", 20, 0xae1fb7b7}, ++ {__LINE__, 0xe75b214, "42015093765128581010", 20, 0xd4eecd2d}, ++ {__LINE__, 0x72d0fe6f, "88214814356148806939", 20, 0x4660ec7}, ++ {__LINE__, 0xf857a4b1, "43472694284527343838", 20, 0xfd8afdf7}, ++ {__LINE__, 0x54b8e14, "49769333513942933689", 20, 0xc6d1b5f2}, ++ {__LINE__, 0xd6aa5616, "54979784887993251199", 20, 0x32476461}, ++ {__LINE__, 0x11e63098, "58360544869206793220", 20, 0xd917cf1a}, ++ {__LINE__, 0xbe92385, "27347953487840714234", 20, 0x4ad14a12}, ++ {__LINE__, 0x49511de0, "07650690295365319082", 20, 0xe37b5c6c}, ++ {__LINE__, 0x3db13bc1, "42655507906821911703", 20, 0x7cc497f1}, ++ {__LINE__, 0xbb899bea, "29977409200786225655", 20, 0x99781bb2}, ++ {__LINE__, 0xf6cd9436, "85181542907229116674", 20, 0x132256a1}, ++ {__LINE__, 0x9109e6c3, "87963594337989416799", 20, 0xbfdb2c83}, ++ {__LINE__, 0x75770fc, "21395988329504168551", 20, 0x8d9d1e81}, ++ {__LINE__, 0x69b1d19b, "51991013580943379423", 20, 0x7b6d4404}, ++ {__LINE__, 0xc6132975, "*]+@!);({_$;}[_},?{?;(_?,=-][@", 30, 0x8619f010}, ++ {__LINE__, 0xd58cb00c, "_@:_).&(#.[:[{[:)$++-($_;@[)}+", 30, 0x15746ac3}, ++ {__LINE__, 0xb63b8caa, "&[!,[$_==}+.]@!;*(+},[;:)$;)-@", 30, 0xaccf812f}, ++ {__LINE__, 0x8a45a2b8, "]{.[.+?+[[=;[?}_#&;[=)__$$:+=_", 30, 0x78af45de}, ++ {__LINE__, 0xcbe95b78, "-%.)=/[@].:.(:,()$;=%@-$?]{%+%", 30, 0x25b06b59}, ++ {__LINE__, 0x4ef8a54b, "+]#$(@&.=:,*];/.!]%/{:){:@(;)$", 30, 0x4ba0d08f}, ++ {__LINE__, 0x76ad267a, ")-._.:?[&:.=+}(*$/=!.${;(=$@!}", 30, 0xe26b6aac}, ++ {__LINE__, 0x569e613c, ":(_*&%/[[}+,?#$&*+#[([*-/#;%(]", 30, 0x7e2b0a66}, ++ {__LINE__, 0x36aa61da, "{[#-;:$/{)(+[}#]/{&!%(@)%:@-$:", 30, 0xb3430dc7}, ++ {__LINE__, 0xf67222df, "_{$*,}(&,@.)):=!/%(&(,,-?$}}}!", 30, 0x626c17a}, ++ {__LINE__, 0x74b34fd3, "e$98KNzqaV)Y:2X?]77].{gKRD4G5{mHZk,Z)SpU%L3FSgv!Wb8MLAFdi{+fp)c,@8m6v)yXg@]HBDFk?.4&}g5_udE*JHCiH=aL", 100, 0xccf98060}, ++ {__LINE__, 0x351fd770, "r*Fd}ef+5RJQ;+W=4jTR9)R*p!B;]Ed7tkrLi;88U7g@3v!5pk2X6D)vt,.@N8c]@yyEcKi[vwUu@.Ppm@C6%Mv*3Nw}Y,58_aH)", 100, 0xd8b95312}, ++ {__LINE__, 0xc45aef77, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 100, 0xbb1c9912}, ++ {__LINE__, 0xc45aef77, "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" ++ "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" ++ "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" ++ "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" ++ "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&" ++ "h{bcmdC+a;t+Cf{6Y_dFq-{X4Yu&7uNfVDh?q&_u.UWJU],-GiH7ADzb7-V.Q%4=+v!$L9W+T=bP]$_:]Vyg}A.ygD.r;h-D]m%&", 600, 0x888AFA5B} ++}; ++ ++static const int test_size = sizeof(tests) / sizeof(tests[0]); ++ ++int main(void) ++{ ++ int i; ++ for (i = 0; i < test_size; i++) { ++ test_crc32(tests[i].crc, tests[i].buf, tests[i].len, ++ tests[i].expect, tests[i].line); ++ } ++ return 0; ++} +\ No newline at end of file +-- +2.19.1 + diff --git a/SOURCES/zlib-1.2.11-optimized-CRC32-framework.patch b/SOURCES/zlib-1.2.11-optimized-CRC32-framework.patch new file mode 100644 index 0000000..18255fa --- /dev/null +++ b/SOURCES/zlib-1.2.11-optimized-CRC32-framework.patch @@ -0,0 +1,2258 @@ +From d1155b9ab9a2ef643ec82285d1fb767dcfd00d16 Mon Sep 17 00:00:00 2001 +From: Ondrej Dubaj +Date: Thu, 1 Aug 2019 12:17:06 +0200 +Subject: [PATCH] Optimized CRC32 for POWER 8+ architectures. + +--- + Makefile.in | 8 + + configure | 77 ++ + contrib/power8-crc/clang_workaround.h | 82 ++ + contrib/power8-crc/crc32_constants.h | 1206 +++++++++++++++++++++++++ + contrib/power8-crc/vec_crc32.c | 674 ++++++++++++++ + crc32.c | 100 +- + 6 files changed, 2135 insertions(+), 12 deletions(-) + create mode 100644 contrib/power8-crc/clang_workaround.h + create mode 100644 contrib/power8-crc/crc32_constants.h + create mode 100644 contrib/power8-crc/vec_crc32.c + +diff --git a/Makefile.in b/Makefile.in +index b7bdbf2..55f6489 100644 +--- a/Makefile.in ++++ b/Makefile.in +@@ -167,6 +167,9 @@ minigzip64.o: $(SRCDIR)test/minigzip.c $(SRCDIR)zlib.h zconf.h + adler32.o: $(SRCDIR)adler32.c + $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)adler32.c + ++crc32_power8.o: $(SRCDIR)contrib/power8-crc/vec_crc32.c ++ $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)contrib/power8-crc/vec_crc32.c ++ + crc32.o: $(SRCDIR)crc32.c + $(CC) $(CFLAGS) $(ZINC) -c -o $@ $(SRCDIR)crc32.c + +@@ -215,6 +218,11 @@ adler32.lo: $(SRCDIR)adler32.c + $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/adler32.o $(SRCDIR)adler32.c + -@mv objs/adler32.o $@ + ++crc32_power8.lo: $(SRCDIR)contrib/power8-crc/vec_crc32.c ++ -@mkdir objs 2>/dev/null || test -d objs ++ $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/crc32_power8.o $(SRCDIR)contrib/power8-crc/vec_crc32.c ++ -@mv objs/crc32_power8.o $@ ++ + crc32.lo: $(SRCDIR)crc32.c + -@mkdir objs 2>/dev/null || test -d objs + $(CC) $(SFLAGS) $(ZINC) -DPIC -c -o objs/crc32.o $(SRCDIR)crc32.c +diff --git a/configure b/configure +index cd9eeef..e93ff99 100755 +--- a/configure ++++ b/configure +@@ -839,6 +839,83 @@ else + echo "Checking for sys/sdt.h ... No." | tee -a configure.log + fi + ++# test to see if Power8+ implementation is compile time possible ++echo >> configure.log ++cat > $test.c < ++#include ++int main() ++{ ++ return (getauxval(AT_HWCAP2) & PPC_FEATURE2_ARCH_2_07); ++} ++#endif ++#else ++#error No Power 8 or newer architecture, may need -mcpu=power8 ++#endif ++EOF ++ ++if tryboth $CC -c $CFLAGS $test.c; then ++ OBJC="$OBJC crc32_power8.o" ++ PIC_OBJC="$PIC_OBJC crc32_power8.lo" ++ echo "Checking for runtime cpu detection and Power 8 (or newer) Architecture support... Yes." | tee -a configure.log ++else ++ echo "Checking for runtime cpu detection and Power 8 (or newer) Architecture support... No." | tee -a configure.log ++fi ++ ++# test to see if we can use a gnu indirection function to detect and load optimized code at runtime ++echo >> configure.log ++cat > $test.c <> configure.log ++ cat > $test.c <> configure.log + echo ALL = $ALL >> configure.log +diff --git a/contrib/power8-crc/clang_workaround.h b/contrib/power8-crc/clang_workaround.h +new file mode 100644 +index 0000000..09c411b +--- /dev/null ++++ b/contrib/power8-crc/clang_workaround.h +@@ -0,0 +1,82 @@ ++#ifndef CLANG_WORKAROUNDS_H ++#define CLANG_WORKAROUNDS_H ++ ++/* ++ * These stubs fix clang incompatibilities with GCC builtins. ++ */ ++ ++#ifndef __builtin_crypto_vpmsumw ++#define __builtin_crypto_vpmsumw __builtin_crypto_vpmsumb ++#endif ++#ifndef __builtin_crypto_vpmsumd ++#define __builtin_crypto_vpmsumd __builtin_crypto_vpmsumb ++#endif ++ ++static inline ++__vector unsigned long long __attribute__((overloadable)) ++vec_ld(int __a, const __vector unsigned long long* __b) ++{ ++ return (__vector unsigned long long)__builtin_altivec_lvx(__a, __b); ++} ++ ++/* ++ * GCC __builtin_pack_vector_int128 returns a vector __int128_t but Clang ++ * does not recognize this type. On GCC this builtin is translated to a ++ * xxpermdi instruction that only moves the registers __a, __b instead generates ++ * a load. ++ * ++ * Clang has vec_xxpermdi intrinsics. It was implemented in 4.0.0. ++ */ ++static inline ++__vector unsigned long long __builtin_pack_vector (unsigned long __a, ++ unsigned long __b) ++{ ++ #if defined(__BIG_ENDIAN__) ++ __vector unsigned long long __v = {__a, __b}; ++ #else ++ __vector unsigned long long __v = {__b, __a}; ++ #endif ++ return __v; ++} ++ ++#ifndef vec_xxpermdi ++ ++static inline ++unsigned long __builtin_unpack_vector (__vector unsigned long long __v, ++ int __o) ++{ ++ return __v[__o]; ++} ++ ++#if defined(__BIG_ENDIAN__) ++#define __builtin_unpack_vector_0(a) __builtin_unpack_vector ((a), 0) ++#define __builtin_unpack_vector_1(a) __builtin_unpack_vector ((a), 1) ++#else ++#define __builtin_unpack_vector_0(a) __builtin_unpack_vector ((a), 1) ++#define __builtin_unpack_vector_1(a) __builtin_unpack_vector ((a), 0) ++#endif ++ ++#else ++ ++static inline ++unsigned long __builtin_unpack_vector_0 (__vector unsigned long long __v) ++{ ++ #if defined(__BIG_ENDIAN__) ++ return vec_xxpermdi(__v, __v, 0x0)[1]; ++ #else ++ return vec_xxpermdi(__v, __v, 0x0)[0]; ++ #endif ++} ++ ++static inline ++unsigned long __builtin_unpack_vector_1 (__vector unsigned long long __v) ++{ ++ #if defined(__BIG_ENDIAN__) ++ return vec_xxpermdi(__v, __v, 0x3)[1]; ++ #else ++ return vec_xxpermdi(__v, __v, 0x3)[0]; ++ #endif ++} ++#endif /* vec_xxpermdi */ ++ ++#endif +\ No newline at end of file +diff --git a/contrib/power8-crc/crc32_constants.h b/contrib/power8-crc/crc32_constants.h +new file mode 100644 +index 0000000..58088dc +--- /dev/null ++++ b/contrib/power8-crc/crc32_constants.h +@@ -0,0 +1,1206 @@ ++/* ++* ++* THIS FILE IS GENERATED WITH ++./crc32_constants -c -r -x 0x04C11DB7 ++ ++* This is from https://github.com/antonblanchard/crc32-vpmsum/ ++* DO NOT MODIFY IT MANUALLY! ++* ++*/ ++ ++#define CRC 0x4c11db7 ++#define CRC_XOR ++#define REFLECT ++#define MAX_SIZE 32768 ++ ++#ifndef __ASSEMBLER__ ++#ifdef CRC_TABLE ++static const unsigned int crc_table[] = { ++ 0x00000000, 0x77073096, 0xee0e612c, 0x990951ba, ++ 0x076dc419, 0x706af48f, 0xe963a535, 0x9e6495a3, ++ 0x0edb8832, 0x79dcb8a4, 0xe0d5e91e, 0x97d2d988, ++ 0x09b64c2b, 0x7eb17cbd, 0xe7b82d07, 0x90bf1d91, ++ 0x1db71064, 0x6ab020f2, 0xf3b97148, 0x84be41de, ++ 0x1adad47d, 0x6ddde4eb, 0xf4d4b551, 0x83d385c7, ++ 0x136c9856, 0x646ba8c0, 0xfd62f97a, 0x8a65c9ec, ++ 0x14015c4f, 0x63066cd9, 0xfa0f3d63, 0x8d080df5, ++ 0x3b6e20c8, 0x4c69105e, 0xd56041e4, 0xa2677172, ++ 0x3c03e4d1, 0x4b04d447, 0xd20d85fd, 0xa50ab56b, ++ 0x35b5a8fa, 0x42b2986c, 0xdbbbc9d6, 0xacbcf940, ++ 0x32d86ce3, 0x45df5c75, 0xdcd60dcf, 0xabd13d59, ++ 0x26d930ac, 0x51de003a, 0xc8d75180, 0xbfd06116, ++ 0x21b4f4b5, 0x56b3c423, 0xcfba9599, 0xb8bda50f, ++ 0x2802b89e, 0x5f058808, 0xc60cd9b2, 0xb10be924, ++ 0x2f6f7c87, 0x58684c11, 0xc1611dab, 0xb6662d3d, ++ 0x76dc4190, 0x01db7106, 0x98d220bc, 0xefd5102a, ++ 0x71b18589, 0x06b6b51f, 0x9fbfe4a5, 0xe8b8d433, ++ 0x7807c9a2, 0x0f00f934, 0x9609a88e, 0xe10e9818, ++ 0x7f6a0dbb, 0x086d3d2d, 0x91646c97, 0xe6635c01, ++ 0x6b6b51f4, 0x1c6c6162, 0x856530d8, 0xf262004e, ++ 0x6c0695ed, 0x1b01a57b, 0x8208f4c1, 0xf50fc457, ++ 0x65b0d9c6, 0x12b7e950, 0x8bbeb8ea, 0xfcb9887c, ++ 0x62dd1ddf, 0x15da2d49, 0x8cd37cf3, 0xfbd44c65, ++ 0x4db26158, 0x3ab551ce, 0xa3bc0074, 0xd4bb30e2, ++ 0x4adfa541, 0x3dd895d7, 0xa4d1c46d, 0xd3d6f4fb, ++ 0x4369e96a, 0x346ed9fc, 0xad678846, 0xda60b8d0, ++ 0x44042d73, 0x33031de5, 0xaa0a4c5f, 0xdd0d7cc9, ++ 0x5005713c, 0x270241aa, 0xbe0b1010, 0xc90c2086, ++ 0x5768b525, 0x206f85b3, 0xb966d409, 0xce61e49f, ++ 0x5edef90e, 0x29d9c998, 0xb0d09822, 0xc7d7a8b4, ++ 0x59b33d17, 0x2eb40d81, 0xb7bd5c3b, 0xc0ba6cad, ++ 0xedb88320, 0x9abfb3b6, 0x03b6e20c, 0x74b1d29a, ++ 0xead54739, 0x9dd277af, 0x04db2615, 0x73dc1683, ++ 0xe3630b12, 0x94643b84, 0x0d6d6a3e, 0x7a6a5aa8, ++ 0xe40ecf0b, 0x9309ff9d, 0x0a00ae27, 0x7d079eb1, ++ 0xf00f9344, 0x8708a3d2, 0x1e01f268, 0x6906c2fe, ++ 0xf762575d, 0x806567cb, 0x196c3671, 0x6e6b06e7, ++ 0xfed41b76, 0x89d32be0, 0x10da7a5a, 0x67dd4acc, ++ 0xf9b9df6f, 0x8ebeeff9, 0x17b7be43, 0x60b08ed5, ++ 0xd6d6a3e8, 0xa1d1937e, 0x38d8c2c4, 0x4fdff252, ++ 0xd1bb67f1, 0xa6bc5767, 0x3fb506dd, 0x48b2364b, ++ 0xd80d2bda, 0xaf0a1b4c, 0x36034af6, 0x41047a60, ++ 0xdf60efc3, 0xa867df55, 0x316e8eef, 0x4669be79, ++ 0xcb61b38c, 0xbc66831a, 0x256fd2a0, 0x5268e236, ++ 0xcc0c7795, 0xbb0b4703, 0x220216b9, 0x5505262f, ++ 0xc5ba3bbe, 0xb2bd0b28, 0x2bb45a92, 0x5cb36a04, ++ 0xc2d7ffa7, 0xb5d0cf31, 0x2cd99e8b, 0x5bdeae1d, ++ 0x9b64c2b0, 0xec63f226, 0x756aa39c, 0x026d930a, ++ 0x9c0906a9, 0xeb0e363f, 0x72076785, 0x05005713, ++ 0x95bf4a82, 0xe2b87a14, 0x7bb12bae, 0x0cb61b38, ++ 0x92d28e9b, 0xe5d5be0d, 0x7cdcefb7, 0x0bdbdf21, ++ 0x86d3d2d4, 0xf1d4e242, 0x68ddb3f8, 0x1fda836e, ++ 0x81be16cd, 0xf6b9265b, 0x6fb077e1, 0x18b74777, ++ 0x88085ae6, 0xff0f6a70, 0x66063bca, 0x11010b5c, ++ 0x8f659eff, 0xf862ae69, 0x616bffd3, 0x166ccf45, ++ 0xa00ae278, 0xd70dd2ee, 0x4e048354, 0x3903b3c2, ++ 0xa7672661, 0xd06016f7, 0x4969474d, 0x3e6e77db, ++ 0xaed16a4a, 0xd9d65adc, 0x40df0b66, 0x37d83bf0, ++ 0xa9bcae53, 0xdebb9ec5, 0x47b2cf7f, 0x30b5ffe9, ++ 0xbdbdf21c, 0xcabac28a, 0x53b39330, 0x24b4a3a6, ++ 0xbad03605, 0xcdd70693, 0x54de5729, 0x23d967bf, ++ 0xb3667a2e, 0xc4614ab8, 0x5d681b02, 0x2a6f2b94, ++ 0xb40bbe37, 0xc30c8ea1, 0x5a05df1b, 0x2d02ef8d,}; ++ ++#endif /* CRC_TABLE */ ++#ifdef POWER8_INTRINSICS ++ ++/* Constants */ ++ ++/* Reduce 262144 kbits to 1024 bits */ ++static const __vector unsigned long long vcrc_const[255] ++ __attribute__((aligned (16))) = { ++#ifdef __LITTLE_ENDIAN__ ++ /* x^261120 mod p(x)` << 1, x^261184 mod p(x)` << 1 */ ++ { 0x0000000099ea94a8, 0x00000001651797d2 }, ++ /* x^260096 mod p(x)` << 1, x^260160 mod p(x)` << 1 */ ++ { 0x00000000945a8420, 0x0000000021e0d56c }, ++ /* x^259072 mod p(x)` << 1, x^259136 mod p(x)` << 1 */ ++ { 0x0000000030762706, 0x000000000f95ecaa }, ++ /* x^258048 mod p(x)` << 1, x^258112 mod p(x)` << 1 */ ++ { 0x00000001a52fc582, 0x00000001ebd224ac }, ++ /* x^257024 mod p(x)` << 1, x^257088 mod p(x)` << 1 */ ++ { 0x00000001a4a7167a, 0x000000000ccb97ca }, ++ /* x^256000 mod p(x)` << 1, x^256064 mod p(x)` << 1 */ ++ { 0x000000000c18249a, 0x00000001006ec8a8 }, ++ /* x^254976 mod p(x)` << 1, x^255040 mod p(x)` << 1 */ ++ { 0x00000000a924ae7c, 0x000000014f58f196 }, ++ /* x^253952 mod p(x)` << 1, x^254016 mod p(x)` << 1 */ ++ { 0x00000001e12ccc12, 0x00000001a7192ca6 }, ++ /* x^252928 mod p(x)` << 1, x^252992 mod p(x)` << 1 */ ++ { 0x00000000a0b9d4ac, 0x000000019a64bab2 }, ++ /* x^251904 mod p(x)` << 1, x^251968 mod p(x)` << 1 */ ++ { 0x0000000095e8ddfe, 0x0000000014f4ed2e }, ++ /* x^250880 mod p(x)` << 1, x^250944 mod p(x)` << 1 */ ++ { 0x00000000233fddc4, 0x000000011092b6a2 }, ++ /* x^249856 mod p(x)` << 1, x^249920 mod p(x)` << 1 */ ++ { 0x00000001b4529b62, 0x00000000c8a1629c }, ++ /* x^248832 mod p(x)` << 1, x^248896 mod p(x)` << 1 */ ++ { 0x00000001a7fa0e64, 0x000000017bf32e8e }, ++ /* x^247808 mod p(x)` << 1, x^247872 mod p(x)` << 1 */ ++ { 0x00000001b5334592, 0x00000001f8cc6582 }, ++ /* x^246784 mod p(x)` << 1, x^246848 mod p(x)` << 1 */ ++ { 0x000000011f8ee1b4, 0x000000008631ddf0 }, ++ /* x^245760 mod p(x)` << 1, x^245824 mod p(x)` << 1 */ ++ { 0x000000006252e632, 0x000000007e5a76d0 }, ++ /* x^244736 mod p(x)` << 1, x^244800 mod p(x)` << 1 */ ++ { 0x00000000ab973e84, 0x000000002b09b31c }, ++ /* x^243712 mod p(x)` << 1, x^243776 mod p(x)` << 1 */ ++ { 0x000000007734f5ec, 0x00000001b2df1f84 }, ++ /* x^242688 mod p(x)` << 1, x^242752 mod p(x)` << 1 */ ++ { 0x000000007c547798, 0x00000001d6f56afc }, ++ /* x^241664 mod p(x)` << 1, x^241728 mod p(x)` << 1 */ ++ { 0x000000007ec40210, 0x00000001b9b5e70c }, ++ /* x^240640 mod p(x)` << 1, x^240704 mod p(x)` << 1 */ ++ { 0x00000001ab1695a8, 0x0000000034b626d2 }, ++ /* x^239616 mod p(x)` << 1, x^239680 mod p(x)` << 1 */ ++ { 0x0000000090494bba, 0x000000014c53479a }, ++ /* x^238592 mod p(x)` << 1, x^238656 mod p(x)` << 1 */ ++ { 0x00000001123fb816, 0x00000001a6d179a4 }, ++ /* x^237568 mod p(x)` << 1, x^237632 mod p(x)` << 1 */ ++ { 0x00000001e188c74c, 0x000000015abd16b4 }, ++ /* x^236544 mod p(x)` << 1, x^236608 mod p(x)` << 1 */ ++ { 0x00000001c2d3451c, 0x00000000018f9852 }, ++ /* x^235520 mod p(x)` << 1, x^235584 mod p(x)` << 1 */ ++ { 0x00000000f55cf1ca, 0x000000001fb3084a }, ++ /* x^234496 mod p(x)` << 1, x^234560 mod p(x)` << 1 */ ++ { 0x00000001a0531540, 0x00000000c53dfb04 }, ++ /* x^233472 mod p(x)` << 1, x^233536 mod p(x)` << 1 */ ++ { 0x0000000132cd7ebc, 0x00000000e10c9ad6 }, ++ /* x^232448 mod p(x)` << 1, x^232512 mod p(x)` << 1 */ ++ { 0x0000000073ab7f36, 0x0000000025aa994a }, ++ /* x^231424 mod p(x)` << 1, x^231488 mod p(x)` << 1 */ ++ { 0x0000000041aed1c2, 0x00000000fa3a74c4 }, ++ /* x^230400 mod p(x)` << 1, x^230464 mod p(x)` << 1 */ ++ { 0x0000000136c53800, 0x0000000033eb3f40 }, ++ /* x^229376 mod p(x)` << 1, x^229440 mod p(x)` << 1 */ ++ { 0x0000000126835a30, 0x000000017193f296 }, ++ /* x^228352 mod p(x)` << 1, x^228416 mod p(x)` << 1 */ ++ { 0x000000006241b502, 0x0000000043f6c86a }, ++ /* x^227328 mod p(x)` << 1, x^227392 mod p(x)` << 1 */ ++ { 0x00000000d5196ad4, 0x000000016b513ec6 }, ++ /* x^226304 mod p(x)` << 1, x^226368 mod p(x)` << 1 */ ++ { 0x000000009cfa769a, 0x00000000c8f25b4e }, ++ /* x^225280 mod p(x)` << 1, x^225344 mod p(x)` << 1 */ ++ { 0x00000000920e5df4, 0x00000001a45048ec }, ++ /* x^224256 mod p(x)` << 1, x^224320 mod p(x)` << 1 */ ++ { 0x0000000169dc310e, 0x000000000c441004 }, ++ /* x^223232 mod p(x)` << 1, x^223296 mod p(x)` << 1 */ ++ { 0x0000000009fc331c, 0x000000000e17cad6 }, ++ /* x^222208 mod p(x)` << 1, x^222272 mod p(x)` << 1 */ ++ { 0x000000010d94a81e, 0x00000001253ae964 }, ++ /* x^221184 mod p(x)` << 1, x^221248 mod p(x)` << 1 */ ++ { 0x0000000027a20ab2, 0x00000001d7c88ebc }, ++ /* x^220160 mod p(x)` << 1, x^220224 mod p(x)` << 1 */ ++ { 0x0000000114f87504, 0x00000001e7ca913a }, ++ /* x^219136 mod p(x)` << 1, x^219200 mod p(x)` << 1 */ ++ { 0x000000004b076d96, 0x0000000033ed078a }, ++ /* x^218112 mod p(x)` << 1, x^218176 mod p(x)` << 1 */ ++ { 0x00000000da4d1e74, 0x00000000e1839c78 }, ++ /* x^217088 mod p(x)` << 1, x^217152 mod p(x)` << 1 */ ++ { 0x000000001b81f672, 0x00000001322b267e }, ++ /* x^216064 mod p(x)` << 1, x^216128 mod p(x)` << 1 */ ++ { 0x000000009367c988, 0x00000000638231b6 }, ++ /* x^215040 mod p(x)` << 1, x^215104 mod p(x)` << 1 */ ++ { 0x00000001717214ca, 0x00000001ee7f16f4 }, ++ /* x^214016 mod p(x)` << 1, x^214080 mod p(x)` << 1 */ ++ { 0x000000009f47d820, 0x0000000117d9924a }, ++ /* x^212992 mod p(x)` << 1, x^213056 mod p(x)` << 1 */ ++ { 0x000000010d9a47d2, 0x00000000e1a9e0c4 }, ++ /* x^211968 mod p(x)` << 1, x^212032 mod p(x)` << 1 */ ++ { 0x00000000a696c58c, 0x00000001403731dc }, ++ /* x^210944 mod p(x)` << 1, x^211008 mod p(x)` << 1 */ ++ { 0x000000002aa28ec6, 0x00000001a5ea9682 }, ++ /* x^209920 mod p(x)` << 1, x^209984 mod p(x)` << 1 */ ++ { 0x00000001fe18fd9a, 0x0000000101c5c578 }, ++ /* x^208896 mod p(x)` << 1, x^208960 mod p(x)` << 1 */ ++ { 0x000000019d4fc1ae, 0x00000000dddf6494 }, ++ /* x^207872 mod p(x)` << 1, x^207936 mod p(x)` << 1 */ ++ { 0x00000001ba0e3dea, 0x00000000f1c3db28 }, ++ /* x^206848 mod p(x)` << 1, x^206912 mod p(x)` << 1 */ ++ { 0x0000000074b59a5e, 0x000000013112fb9c }, ++ /* x^205824 mod p(x)` << 1, x^205888 mod p(x)` << 1 */ ++ { 0x00000000f2b5ea98, 0x00000000b680b906 }, ++ /* x^204800 mod p(x)` << 1, x^204864 mod p(x)` << 1 */ ++ { 0x0000000187132676, 0x000000001a282932 }, ++ /* x^203776 mod p(x)` << 1, x^203840 mod p(x)` << 1 */ ++ { 0x000000010a8c6ad4, 0x0000000089406e7e }, ++ /* x^202752 mod p(x)` << 1, x^202816 mod p(x)` << 1 */ ++ { 0x00000001e21dfe70, 0x00000001def6be8c }, ++ /* x^201728 mod p(x)` << 1, x^201792 mod p(x)` << 1 */ ++ { 0x00000001da0050e4, 0x0000000075258728 }, ++ /* x^200704 mod p(x)` << 1, x^200768 mod p(x)` << 1 */ ++ { 0x00000000772172ae, 0x000000019536090a }, ++ /* x^199680 mod p(x)` << 1, x^199744 mod p(x)` << 1 */ ++ { 0x00000000e47724aa, 0x00000000f2455bfc }, ++ /* x^198656 mod p(x)` << 1, x^198720 mod p(x)` << 1 */ ++ { 0x000000003cd63ac4, 0x000000018c40baf4 }, ++ /* x^197632 mod p(x)` << 1, x^197696 mod p(x)` << 1 */ ++ { 0x00000001bf47d352, 0x000000004cd390d4 }, ++ /* x^196608 mod p(x)` << 1, x^196672 mod p(x)` << 1 */ ++ { 0x000000018dc1d708, 0x00000001e4ece95a }, ++ /* x^195584 mod p(x)` << 1, x^195648 mod p(x)` << 1 */ ++ { 0x000000002d4620a4, 0x000000001a3ee918 }, ++ /* x^194560 mod p(x)` << 1, x^194624 mod p(x)` << 1 */ ++ { 0x0000000058fd1740, 0x000000007c652fb8 }, ++ /* x^193536 mod p(x)` << 1, x^193600 mod p(x)` << 1 */ ++ { 0x00000000dadd9bfc, 0x000000011c67842c }, ++ /* x^192512 mod p(x)` << 1, x^192576 mod p(x)` << 1 */ ++ { 0x00000001ea2140be, 0x00000000254f759c }, ++ /* x^191488 mod p(x)` << 1, x^191552 mod p(x)` << 1 */ ++ { 0x000000009de128ba, 0x000000007ece94ca }, ++ /* x^190464 mod p(x)` << 1, x^190528 mod p(x)` << 1 */ ++ { 0x000000013ac3aa8e, 0x0000000038f258c2 }, ++ /* x^189440 mod p(x)` << 1, x^189504 mod p(x)` << 1 */ ++ { 0x0000000099980562, 0x00000001cdf17b00 }, ++ /* x^188416 mod p(x)` << 1, x^188480 mod p(x)` << 1 */ ++ { 0x00000001c1579c86, 0x000000011f882c16 }, ++ /* x^187392 mod p(x)` << 1, x^187456 mod p(x)` << 1 */ ++ { 0x0000000068dbbf94, 0x0000000100093fc8 }, ++ /* x^186368 mod p(x)` << 1, x^186432 mod p(x)` << 1 */ ++ { 0x000000004509fb04, 0x00000001cd684f16 }, ++ /* x^185344 mod p(x)` << 1, x^185408 mod p(x)` << 1 */ ++ { 0x00000001202f6398, 0x000000004bc6a70a }, ++ /* x^184320 mod p(x)` << 1, x^184384 mod p(x)` << 1 */ ++ { 0x000000013aea243e, 0x000000004fc7e8e4 }, ++ /* x^183296 mod p(x)` << 1, x^183360 mod p(x)` << 1 */ ++ { 0x00000001b4052ae6, 0x0000000130103f1c }, ++ /* x^182272 mod p(x)` << 1, x^182336 mod p(x)` << 1 */ ++ { 0x00000001cd2a0ae8, 0x0000000111b0024c }, ++ /* x^181248 mod p(x)` << 1, x^181312 mod p(x)` << 1 */ ++ { 0x00000001fe4aa8b4, 0x000000010b3079da }, ++ /* x^180224 mod p(x)` << 1, x^180288 mod p(x)` << 1 */ ++ { 0x00000001d1559a42, 0x000000010192bcc2 }, ++ /* x^179200 mod p(x)` << 1, x^179264 mod p(x)` << 1 */ ++ { 0x00000001f3e05ecc, 0x0000000074838d50 }, ++ /* x^178176 mod p(x)` << 1, x^178240 mod p(x)` << 1 */ ++ { 0x0000000104ddd2cc, 0x000000001b20f520 }, ++ /* x^177152 mod p(x)` << 1, x^177216 mod p(x)` << 1 */ ++ { 0x000000015393153c, 0x0000000050c3590a }, ++ /* x^176128 mod p(x)` << 1, x^176192 mod p(x)` << 1 */ ++ { 0x0000000057e942c6, 0x00000000b41cac8e }, ++ /* x^175104 mod p(x)` << 1, x^175168 mod p(x)` << 1 */ ++ { 0x000000012c633850, 0x000000000c72cc78 }, ++ /* x^174080 mod p(x)` << 1, x^174144 mod p(x)` << 1 */ ++ { 0x00000000ebcaae4c, 0x0000000030cdb032 }, ++ /* x^173056 mod p(x)` << 1, x^173120 mod p(x)` << 1 */ ++ { 0x000000013ee532a6, 0x000000013e09fc32 }, ++ /* x^172032 mod p(x)` << 1, x^172096 mod p(x)` << 1 */ ++ { 0x00000001bf0cbc7e, 0x000000001ed624d2 }, ++ /* x^171008 mod p(x)` << 1, x^171072 mod p(x)` << 1 */ ++ { 0x00000000d50b7a5a, 0x00000000781aee1a }, ++ /* x^169984 mod p(x)` << 1, x^170048 mod p(x)` << 1 */ ++ { 0x0000000002fca6e8, 0x00000001c4d8348c }, ++ /* x^168960 mod p(x)` << 1, x^169024 mod p(x)` << 1 */ ++ { 0x000000007af40044, 0x0000000057a40336 }, ++ /* x^167936 mod p(x)` << 1, x^168000 mod p(x)` << 1 */ ++ { 0x0000000016178744, 0x0000000085544940 }, ++ /* x^166912 mod p(x)` << 1, x^166976 mod p(x)` << 1 */ ++ { 0x000000014c177458, 0x000000019cd21e80 }, ++ /* x^165888 mod p(x)` << 1, x^165952 mod p(x)` << 1 */ ++ { 0x000000011b6ddf04, 0x000000013eb95bc0 }, ++ /* x^164864 mod p(x)` << 1, x^164928 mod p(x)` << 1 */ ++ { 0x00000001f3e29ccc, 0x00000001dfc9fdfc }, ++ /* x^163840 mod p(x)` << 1, x^163904 mod p(x)` << 1 */ ++ { 0x0000000135ae7562, 0x00000000cd028bc2 }, ++ /* x^162816 mod p(x)` << 1, x^162880 mod p(x)` << 1 */ ++ { 0x0000000190ef812c, 0x0000000090db8c44 }, ++ /* x^161792 mod p(x)` << 1, x^161856 mod p(x)` << 1 */ ++ { 0x0000000067a2c786, 0x000000010010a4ce }, ++ /* x^160768 mod p(x)` << 1, x^160832 mod p(x)` << 1 */ ++ { 0x0000000048b9496c, 0x00000001c8f4c72c }, ++ /* x^159744 mod p(x)` << 1, x^159808 mod p(x)` << 1 */ ++ { 0x000000015a422de6, 0x000000001c26170c }, ++ /* x^158720 mod p(x)` << 1, x^158784 mod p(x)` << 1 */ ++ { 0x00000001ef0e3640, 0x00000000e3fccf68 }, ++ /* x^157696 mod p(x)` << 1, x^157760 mod p(x)` << 1 */ ++ { 0x00000001006d2d26, 0x00000000d513ed24 }, ++ /* x^156672 mod p(x)` << 1, x^156736 mod p(x)` << 1 */ ++ { 0x00000001170d56d6, 0x00000000141beada }, ++ /* x^155648 mod p(x)` << 1, x^155712 mod p(x)` << 1 */ ++ { 0x00000000a5fb613c, 0x000000011071aea0 }, ++ /* x^154624 mod p(x)` << 1, x^154688 mod p(x)` << 1 */ ++ { 0x0000000040bbf7fc, 0x000000012e19080a }, ++ /* x^153600 mod p(x)` << 1, x^153664 mod p(x)` << 1 */ ++ { 0x000000016ac3a5b2, 0x0000000100ecf826 }, ++ /* x^152576 mod p(x)` << 1, x^152640 mod p(x)` << 1 */ ++ { 0x00000000abf16230, 0x0000000069b09412 }, ++ /* x^151552 mod p(x)` << 1, x^151616 mod p(x)` << 1 */ ++ { 0x00000001ebe23fac, 0x0000000122297bac }, ++ /* x^150528 mod p(x)` << 1, x^150592 mod p(x)` << 1 */ ++ { 0x000000008b6a0894, 0x00000000e9e4b068 }, ++ /* x^149504 mod p(x)` << 1, x^149568 mod p(x)` << 1 */ ++ { 0x00000001288ea478, 0x000000004b38651a }, ++ /* x^148480 mod p(x)` << 1, x^148544 mod p(x)` << 1 */ ++ { 0x000000016619c442, 0x00000001468360e2 }, ++ /* x^147456 mod p(x)` << 1, x^147520 mod p(x)` << 1 */ ++ { 0x0000000086230038, 0x00000000121c2408 }, ++ /* x^146432 mod p(x)` << 1, x^146496 mod p(x)` << 1 */ ++ { 0x000000017746a756, 0x00000000da7e7d08 }, ++ /* x^145408 mod p(x)` << 1, x^145472 mod p(x)` << 1 */ ++ { 0x0000000191b8f8f8, 0x00000001058d7652 }, ++ /* x^144384 mod p(x)` << 1, x^144448 mod p(x)` << 1 */ ++ { 0x000000008e167708, 0x000000014a098a90 }, ++ /* x^143360 mod p(x)` << 1, x^143424 mod p(x)` << 1 */ ++ { 0x0000000148b22d54, 0x0000000020dbe72e }, ++ /* x^142336 mod p(x)` << 1, x^142400 mod p(x)` << 1 */ ++ { 0x0000000044ba2c3c, 0x000000011e7323e8 }, ++ /* x^141312 mod p(x)` << 1, x^141376 mod p(x)` << 1 */ ++ { 0x00000000b54d2b52, 0x00000000d5d4bf94 }, ++ /* x^140288 mod p(x)` << 1, x^140352 mod p(x)` << 1 */ ++ { 0x0000000005a4fd8a, 0x0000000199d8746c }, ++ /* x^139264 mod p(x)` << 1, x^139328 mod p(x)` << 1 */ ++ { 0x0000000139f9fc46, 0x00000000ce9ca8a0 }, ++ /* x^138240 mod p(x)` << 1, x^138304 mod p(x)` << 1 */ ++ { 0x000000015a1fa824, 0x00000000136edece }, ++ /* x^137216 mod p(x)` << 1, x^137280 mod p(x)` << 1 */ ++ { 0x000000000a61ae4c, 0x000000019b92a068 }, ++ /* x^136192 mod p(x)` << 1, x^136256 mod p(x)` << 1 */ ++ { 0x0000000145e9113e, 0x0000000071d62206 }, ++ /* x^135168 mod p(x)` << 1, x^135232 mod p(x)` << 1 */ ++ { 0x000000006a348448, 0x00000000dfc50158 }, ++ /* x^134144 mod p(x)` << 1, x^134208 mod p(x)` << 1 */ ++ { 0x000000004d80a08c, 0x00000001517626bc }, ++ /* x^133120 mod p(x)` << 1, x^133184 mod p(x)` << 1 */ ++ { 0x000000014b6837a0, 0x0000000148d1e4fa }, ++ /* x^132096 mod p(x)` << 1, x^132160 mod p(x)` << 1 */ ++ { 0x000000016896a7fc, 0x0000000094d8266e }, ++ /* x^131072 mod p(x)` << 1, x^131136 mod p(x)` << 1 */ ++ { 0x000000014f187140, 0x00000000606c5e34 }, ++ /* x^130048 mod p(x)` << 1, x^130112 mod p(x)` << 1 */ ++ { 0x000000019581b9da, 0x000000019766beaa }, ++ /* x^129024 mod p(x)` << 1, x^129088 mod p(x)` << 1 */ ++ { 0x00000001091bc984, 0x00000001d80c506c }, ++ /* x^128000 mod p(x)` << 1, x^128064 mod p(x)` << 1 */ ++ { 0x000000001067223c, 0x000000001e73837c }, ++ /* x^126976 mod p(x)` << 1, x^127040 mod p(x)` << 1 */ ++ { 0x00000001ab16ea02, 0x0000000064d587de }, ++ /* x^125952 mod p(x)` << 1, x^126016 mod p(x)` << 1 */ ++ { 0x000000013c4598a8, 0x00000000f4a507b0 }, ++ /* x^124928 mod p(x)` << 1, x^124992 mod p(x)` << 1 */ ++ { 0x00000000b3735430, 0x0000000040e342fc }, ++ /* x^123904 mod p(x)` << 1, x^123968 mod p(x)` << 1 */ ++ { 0x00000001bb3fc0c0, 0x00000001d5ad9c3a }, ++ /* x^122880 mod p(x)` << 1, x^122944 mod p(x)` << 1 */ ++ { 0x00000001570ae19c, 0x0000000094a691a4 }, ++ /* x^121856 mod p(x)` << 1, x^121920 mod p(x)` << 1 */ ++ { 0x00000001ea910712, 0x00000001271ecdfa }, ++ /* x^120832 mod p(x)` << 1, x^120896 mod p(x)` << 1 */ ++ { 0x0000000167127128, 0x000000009e54475a }, ++ /* x^119808 mod p(x)` << 1, x^119872 mod p(x)` << 1 */ ++ { 0x0000000019e790a2, 0x00000000c9c099ee }, ++ /* x^118784 mod p(x)` << 1, x^118848 mod p(x)` << 1 */ ++ { 0x000000003788f710, 0x000000009a2f736c }, ++ /* x^117760 mod p(x)` << 1, x^117824 mod p(x)` << 1 */ ++ { 0x00000001682a160e, 0x00000000bb9f4996 }, ++ /* x^116736 mod p(x)` << 1, x^116800 mod p(x)` << 1 */ ++ { 0x000000007f0ebd2e, 0x00000001db688050 }, ++ /* x^115712 mod p(x)` << 1, x^115776 mod p(x)` << 1 */ ++ { 0x000000002b032080, 0x00000000e9b10af4 }, ++ /* x^114688 mod p(x)` << 1, x^114752 mod p(x)` << 1 */ ++ { 0x00000000cfd1664a, 0x000000012d4545e4 }, ++ /* x^113664 mod p(x)` << 1, x^113728 mod p(x)` << 1 */ ++ { 0x00000000aa1181c2, 0x000000000361139c }, ++ /* x^112640 mod p(x)` << 1, x^112704 mod p(x)` << 1 */ ++ { 0x00000000ddd08002, 0x00000001a5a1a3a8 }, ++ /* x^111616 mod p(x)` << 1, x^111680 mod p(x)` << 1 */ ++ { 0x00000000e8dd0446, 0x000000006844e0b0 }, ++ /* x^110592 mod p(x)` << 1, x^110656 mod p(x)` << 1 */ ++ { 0x00000001bbd94a00, 0x00000000c3762f28 }, ++ /* x^109568 mod p(x)` << 1, x^109632 mod p(x)` << 1 */ ++ { 0x00000000ab6cd180, 0x00000001d26287a2 }, ++ /* x^108544 mod p(x)` << 1, x^108608 mod p(x)` << 1 */ ++ { 0x0000000031803ce2, 0x00000001f6f0bba8 }, ++ /* x^107520 mod p(x)` << 1, x^107584 mod p(x)` << 1 */ ++ { 0x0000000024f40b0c, 0x000000002ffabd62 }, ++ /* x^106496 mod p(x)` << 1, x^106560 mod p(x)` << 1 */ ++ { 0x00000001ba1d9834, 0x00000000fb4516b8 }, ++ /* x^105472 mod p(x)` << 1, x^105536 mod p(x)` << 1 */ ++ { 0x0000000104de61aa, 0x000000018cfa961c }, ++ /* x^104448 mod p(x)` << 1, x^104512 mod p(x)` << 1 */ ++ { 0x0000000113e40d46, 0x000000019e588d52 }, ++ /* x^103424 mod p(x)` << 1, x^103488 mod p(x)` << 1 */ ++ { 0x00000001415598a0, 0x00000001180f0bbc }, ++ /* x^102400 mod p(x)` << 1, x^102464 mod p(x)` << 1 */ ++ { 0x00000000bf6c8c90, 0x00000000e1d9177a }, ++ /* x^101376 mod p(x)` << 1, x^101440 mod p(x)` << 1 */ ++ { 0x00000001788b0504, 0x0000000105abc27c }, ++ /* x^100352 mod p(x)` << 1, x^100416 mod p(x)` << 1 */ ++ { 0x0000000038385d02, 0x00000000972e4a58 }, ++ /* x^99328 mod p(x)` << 1, x^99392 mod p(x)` << 1 */ ++ { 0x00000001b6c83844, 0x0000000183499a5e }, ++ /* x^98304 mod p(x)` << 1, x^98368 mod p(x)` << 1 */ ++ { 0x0000000051061a8a, 0x00000001c96a8cca }, ++ /* x^97280 mod p(x)` << 1, x^97344 mod p(x)` << 1 */ ++ { 0x000000017351388a, 0x00000001a1a5b60c }, ++ /* x^96256 mod p(x)` << 1, x^96320 mod p(x)` << 1 */ ++ { 0x0000000132928f92, 0x00000000e4b6ac9c }, ++ /* x^95232 mod p(x)` << 1, x^95296 mod p(x)` << 1 */ ++ { 0x00000000e6b4f48a, 0x00000001807e7f5a }, ++ /* x^94208 mod p(x)` << 1, x^94272 mod p(x)` << 1 */ ++ { 0x0000000039d15e90, 0x000000017a7e3bc8 }, ++ /* x^93184 mod p(x)` << 1, x^93248 mod p(x)` << 1 */ ++ { 0x00000000312d6074, 0x00000000d73975da }, ++ /* x^92160 mod p(x)` << 1, x^92224 mod p(x)` << 1 */ ++ { 0x000000017bbb2cc4, 0x000000017375d038 }, ++ /* x^91136 mod p(x)` << 1, x^91200 mod p(x)` << 1 */ ++ { 0x000000016ded3e18, 0x00000000193680bc }, ++ /* x^90112 mod p(x)` << 1, x^90176 mod p(x)` << 1 */ ++ { 0x00000000f1638b16, 0x00000000999b06f6 }, ++ /* x^89088 mod p(x)` << 1, x^89152 mod p(x)` << 1 */ ++ { 0x00000001d38b9ecc, 0x00000001f685d2b8 }, ++ /* x^88064 mod p(x)` << 1, x^88128 mod p(x)` << 1 */ ++ { 0x000000018b8d09dc, 0x00000001f4ecbed2 }, ++ /* x^87040 mod p(x)` << 1, x^87104 mod p(x)` << 1 */ ++ { 0x00000000e7bc27d2, 0x00000000ba16f1a0 }, ++ /* x^86016 mod p(x)` << 1, x^86080 mod p(x)` << 1 */ ++ { 0x00000000275e1e96, 0x0000000115aceac4 }, ++ /* x^84992 mod p(x)` << 1, x^85056 mod p(x)` << 1 */ ++ { 0x00000000e2e3031e, 0x00000001aeff6292 }, ++ /* x^83968 mod p(x)` << 1, x^84032 mod p(x)` << 1 */ ++ { 0x00000001041c84d8, 0x000000009640124c }, ++ /* x^82944 mod p(x)` << 1, x^83008 mod p(x)` << 1 */ ++ { 0x00000000706ce672, 0x0000000114f41f02 }, ++ /* x^81920 mod p(x)` << 1, x^81984 mod p(x)` << 1 */ ++ { 0x000000015d5070da, 0x000000009c5f3586 }, ++ /* x^80896 mod p(x)` << 1, x^80960 mod p(x)` << 1 */ ++ { 0x0000000038f9493a, 0x00000001878275fa }, ++ /* x^79872 mod p(x)` << 1, x^79936 mod p(x)` << 1 */ ++ { 0x00000000a3348a76, 0x00000000ddc42ce8 }, ++ /* x^78848 mod p(x)` << 1, x^78912 mod p(x)` << 1 */ ++ { 0x00000001ad0aab92, 0x0000000181d2c73a }, ++ /* x^77824 mod p(x)` << 1, x^77888 mod p(x)` << 1 */ ++ { 0x000000019e85f712, 0x0000000141c9320a }, ++ /* x^76800 mod p(x)` << 1, x^76864 mod p(x)` << 1 */ ++ { 0x000000005a871e76, 0x000000015235719a }, ++ /* x^75776 mod p(x)` << 1, x^75840 mod p(x)` << 1 */ ++ { 0x000000017249c662, 0x00000000be27d804 }, ++ /* x^74752 mod p(x)` << 1, x^74816 mod p(x)` << 1 */ ++ { 0x000000003a084712, 0x000000006242d45a }, ++ /* x^73728 mod p(x)` << 1, x^73792 mod p(x)` << 1 */ ++ { 0x00000000ed438478, 0x000000009a53638e }, ++ /* x^72704 mod p(x)` << 1, x^72768 mod p(x)` << 1 */ ++ { 0x00000000abac34cc, 0x00000001001ecfb6 }, ++ /* x^71680 mod p(x)` << 1, x^71744 mod p(x)` << 1 */ ++ { 0x000000005f35ef3e, 0x000000016d7c2d64 }, ++ /* x^70656 mod p(x)` << 1, x^70720 mod p(x)` << 1 */ ++ { 0x0000000047d6608c, 0x00000001d0ce46c0 }, ++ /* x^69632 mod p(x)` << 1, x^69696 mod p(x)` << 1 */ ++ { 0x000000002d01470e, 0x0000000124c907b4 }, ++ /* x^68608 mod p(x)` << 1, x^68672 mod p(x)` << 1 */ ++ { 0x0000000158bbc7b0, 0x0000000018a555ca }, ++ /* x^67584 mod p(x)` << 1, x^67648 mod p(x)` << 1 */ ++ { 0x00000000c0a23e8e, 0x000000006b0980bc }, ++ /* x^66560 mod p(x)` << 1, x^66624 mod p(x)` << 1 */ ++ { 0x00000001ebd85c88, 0x000000008bbba964 }, ++ /* x^65536 mod p(x)` << 1, x^65600 mod p(x)` << 1 */ ++ { 0x000000019ee20bb2, 0x00000001070a5a1e }, ++ /* x^64512 mod p(x)` << 1, x^64576 mod p(x)` << 1 */ ++ { 0x00000001acabf2d6, 0x000000002204322a }, ++ /* x^63488 mod p(x)` << 1, x^63552 mod p(x)` << 1 */ ++ { 0x00000001b7963d56, 0x00000000a27524d0 }, ++ /* x^62464 mod p(x)` << 1, x^62528 mod p(x)` << 1 */ ++ { 0x000000017bffa1fe, 0x0000000020b1e4ba }, ++ /* x^61440 mod p(x)` << 1, x^61504 mod p(x)` << 1 */ ++ { 0x000000001f15333e, 0x0000000032cc27fc }, ++ /* x^60416 mod p(x)` << 1, x^60480 mod p(x)` << 1 */ ++ { 0x000000018593129e, 0x0000000044dd22b8 }, ++ /* x^59392 mod p(x)` << 1, x^59456 mod p(x)` << 1 */ ++ { 0x000000019cb32602, 0x00000000dffc9e0a }, ++ /* x^58368 mod p(x)` << 1, x^58432 mod p(x)` << 1 */ ++ { 0x0000000142b05cc8, 0x00000001b7a0ed14 }, ++ /* x^57344 mod p(x)` << 1, x^57408 mod p(x)` << 1 */ ++ { 0x00000001be49e7a4, 0x00000000c7842488 }, ++ /* x^56320 mod p(x)` << 1, x^56384 mod p(x)` << 1 */ ++ { 0x0000000108f69d6c, 0x00000001c02a4fee }, ++ /* x^55296 mod p(x)` << 1, x^55360 mod p(x)` << 1 */ ++ { 0x000000006c0971f0, 0x000000003c273778 }, ++ /* x^54272 mod p(x)` << 1, x^54336 mod p(x)` << 1 */ ++ { 0x000000005b16467a, 0x00000001d63f8894 }, ++ /* x^53248 mod p(x)` << 1, x^53312 mod p(x)` << 1 */ ++ { 0x00000001551a628e, 0x000000006be557d6 }, ++ /* x^52224 mod p(x)` << 1, x^52288 mod p(x)` << 1 */ ++ { 0x000000019e42ea92, 0x000000006a7806ea }, ++ /* x^51200 mod p(x)` << 1, x^51264 mod p(x)` << 1 */ ++ { 0x000000012fa83ff2, 0x000000016155aa0c }, ++ /* x^50176 mod p(x)` << 1, x^50240 mod p(x)` << 1 */ ++ { 0x000000011ca9cde0, 0x00000000908650ac }, ++ /* x^49152 mod p(x)` << 1, x^49216 mod p(x)` << 1 */ ++ { 0x00000000c8e5cd74, 0x00000000aa5a8084 }, ++ /* x^48128 mod p(x)` << 1, x^48192 mod p(x)` << 1 */ ++ { 0x0000000096c27f0c, 0x0000000191bb500a }, ++ /* x^47104 mod p(x)` << 1, x^47168 mod p(x)` << 1 */ ++ { 0x000000002baed926, 0x0000000064e9bed0 }, ++ /* x^46080 mod p(x)` << 1, x^46144 mod p(x)` << 1 */ ++ { 0x000000017c8de8d2, 0x000000009444f302 }, ++ /* x^45056 mod p(x)` << 1, x^45120 mod p(x)` << 1 */ ++ { 0x00000000d43d6068, 0x000000019db07d3c }, ++ /* x^44032 mod p(x)` << 1, x^44096 mod p(x)` << 1 */ ++ { 0x00000000cb2c4b26, 0x00000001359e3e6e }, ++ /* x^43008 mod p(x)` << 1, x^43072 mod p(x)` << 1 */ ++ { 0x0000000145b8da26, 0x00000001e4f10dd2 }, ++ /* x^41984 mod p(x)` << 1, x^42048 mod p(x)` << 1 */ ++ { 0x000000018fff4b08, 0x0000000124f5735e }, ++ /* x^40960 mod p(x)` << 1, x^41024 mod p(x)` << 1 */ ++ { 0x0000000150b58ed0, 0x0000000124760a4c }, ++ /* x^39936 mod p(x)` << 1, x^40000 mod p(x)` << 1 */ ++ { 0x00000001549f39bc, 0x000000000f1fc186 }, ++ /* x^38912 mod p(x)` << 1, x^38976 mod p(x)` << 1 */ ++ { 0x00000000ef4d2f42, 0x00000000150e4cc4 }, ++ /* x^37888 mod p(x)` << 1, x^37952 mod p(x)` << 1 */ ++ { 0x00000001b1468572, 0x000000002a6204e8 }, ++ /* x^36864 mod p(x)` << 1, x^36928 mod p(x)` << 1 */ ++ { 0x000000013d7403b2, 0x00000000beb1d432 }, ++ /* x^35840 mod p(x)` << 1, x^35904 mod p(x)` << 1 */ ++ { 0x00000001a4681842, 0x0000000135f3f1f0 }, ++ /* x^34816 mod p(x)` << 1, x^34880 mod p(x)` << 1 */ ++ { 0x0000000167714492, 0x0000000074fe2232 }, ++ /* x^33792 mod p(x)` << 1, x^33856 mod p(x)` << 1 */ ++ { 0x00000001e599099a, 0x000000001ac6e2ba }, ++ /* x^32768 mod p(x)` << 1, x^32832 mod p(x)` << 1 */ ++ { 0x00000000fe128194, 0x0000000013fca91e }, ++ /* x^31744 mod p(x)` << 1, x^31808 mod p(x)` << 1 */ ++ { 0x0000000077e8b990, 0x0000000183f4931e }, ++ /* x^30720 mod p(x)` << 1, x^30784 mod p(x)` << 1 */ ++ { 0x00000001a267f63a, 0x00000000b6d9b4e4 }, ++ /* x^29696 mod p(x)` << 1, x^29760 mod p(x)` << 1 */ ++ { 0x00000001945c245a, 0x00000000b5188656 }, ++ /* x^28672 mod p(x)` << 1, x^28736 mod p(x)` << 1 */ ++ { 0x0000000149002e76, 0x0000000027a81a84 }, ++ /* x^27648 mod p(x)` << 1, x^27712 mod p(x)` << 1 */ ++ { 0x00000001bb8310a4, 0x0000000125699258 }, ++ /* x^26624 mod p(x)` << 1, x^26688 mod p(x)` << 1 */ ++ { 0x000000019ec60bcc, 0x00000001b23de796 }, ++ /* x^25600 mod p(x)` << 1, x^25664 mod p(x)` << 1 */ ++ { 0x000000012d8590ae, 0x00000000fe4365dc }, ++ /* x^24576 mod p(x)` << 1, x^24640 mod p(x)` << 1 */ ++ { 0x0000000065b00684, 0x00000000c68f497a }, ++ /* x^23552 mod p(x)` << 1, x^23616 mod p(x)` << 1 */ ++ { 0x000000015e5aeadc, 0x00000000fbf521ee }, ++ /* x^22528 mod p(x)` << 1, x^22592 mod p(x)` << 1 */ ++ { 0x00000000b77ff2b0, 0x000000015eac3378 }, ++ /* x^21504 mod p(x)` << 1, x^21568 mod p(x)` << 1 */ ++ { 0x0000000188da2ff6, 0x0000000134914b90 }, ++ /* x^20480 mod p(x)` << 1, x^20544 mod p(x)` << 1 */ ++ { 0x0000000063da929a, 0x0000000016335cfe }, ++ /* x^19456 mod p(x)` << 1, x^19520 mod p(x)` << 1 */ ++ { 0x00000001389caa80, 0x000000010372d10c }, ++ /* x^18432 mod p(x)` << 1, x^18496 mod p(x)` << 1 */ ++ { 0x000000013db599d2, 0x000000015097b908 }, ++ /* x^17408 mod p(x)` << 1, x^17472 mod p(x)` << 1 */ ++ { 0x0000000122505a86, 0x00000001227a7572 }, ++ /* x^16384 mod p(x)` << 1, x^16448 mod p(x)` << 1 */ ++ { 0x000000016bd72746, 0x000000009a8f75c0 }, ++ /* x^15360 mod p(x)` << 1, x^15424 mod p(x)` << 1 */ ++ { 0x00000001c3faf1d4, 0x00000000682c77a2 }, ++ /* x^14336 mod p(x)` << 1, x^14400 mod p(x)` << 1 */ ++ { 0x00000001111c826c, 0x00000000231f091c }, ++ /* x^13312 mod p(x)` << 1, x^13376 mod p(x)` << 1 */ ++ { 0x00000000153e9fb2, 0x000000007d4439f2 }, ++ /* x^12288 mod p(x)` << 1, x^12352 mod p(x)` << 1 */ ++ { 0x000000002b1f7b60, 0x000000017e221efc }, ++ /* x^11264 mod p(x)` << 1, x^11328 mod p(x)` << 1 */ ++ { 0x00000000b1dba570, 0x0000000167457c38 }, ++ /* x^10240 mod p(x)` << 1, x^10304 mod p(x)` << 1 */ ++ { 0x00000001f6397b76, 0x00000000bdf081c4 }, ++ /* x^9216 mod p(x)` << 1, x^9280 mod p(x)` << 1 */ ++ { 0x0000000156335214, 0x000000016286d6b0 }, ++ /* x^8192 mod p(x)` << 1, x^8256 mod p(x)` << 1 */ ++ { 0x00000001d70e3986, 0x00000000c84f001c }, ++ /* x^7168 mod p(x)` << 1, x^7232 mod p(x)` << 1 */ ++ { 0x000000003701a774, 0x0000000064efe7c0 }, ++ /* x^6144 mod p(x)` << 1, x^6208 mod p(x)` << 1 */ ++ { 0x00000000ac81ef72, 0x000000000ac2d904 }, ++ /* x^5120 mod p(x)` << 1, x^5184 mod p(x)` << 1 */ ++ { 0x0000000133212464, 0x00000000fd226d14 }, ++ /* x^4096 mod p(x)` << 1, x^4160 mod p(x)` << 1 */ ++ { 0x00000000e4e45610, 0x000000011cfd42e0 }, ++ /* x^3072 mod p(x)` << 1, x^3136 mod p(x)` << 1 */ ++ { 0x000000000c1bd370, 0x000000016e5a5678 }, ++ /* x^2048 mod p(x)` << 1, x^2112 mod p(x)` << 1 */ ++ { 0x00000001a7b9e7a6, 0x00000001d888fe22 }, ++ /* x^1024 mod p(x)` << 1, x^1088 mod p(x)` << 1 */ ++ { 0x000000007d657a10, 0x00000001af77fcd4 } ++#else /* __LITTLE_ENDIAN__ */ ++ /* x^261120 mod p(x)` << 1, x^261184 mod p(x)` << 1 */ ++ { 0x00000001651797d2, 0x0000000099ea94a8 }, ++ /* x^260096 mod p(x)` << 1, x^260160 mod p(x)` << 1 */ ++ { 0x0000000021e0d56c, 0x00000000945a8420 }, ++ /* x^259072 mod p(x)` << 1, x^259136 mod p(x)` << 1 */ ++ { 0x000000000f95ecaa, 0x0000000030762706 }, ++ /* x^258048 mod p(x)` << 1, x^258112 mod p(x)` << 1 */ ++ { 0x00000001ebd224ac, 0x00000001a52fc582 }, ++ /* x^257024 mod p(x)` << 1, x^257088 mod p(x)` << 1 */ ++ { 0x000000000ccb97ca, 0x00000001a4a7167a }, ++ /* x^256000 mod p(x)` << 1, x^256064 mod p(x)` << 1 */ ++ { 0x00000001006ec8a8, 0x000000000c18249a }, ++ /* x^254976 mod p(x)` << 1, x^255040 mod p(x)` << 1 */ ++ { 0x000000014f58f196, 0x00000000a924ae7c }, ++ /* x^253952 mod p(x)` << 1, x^254016 mod p(x)` << 1 */ ++ { 0x00000001a7192ca6, 0x00000001e12ccc12 }, ++ /* x^252928 mod p(x)` << 1, x^252992 mod p(x)` << 1 */ ++ { 0x000000019a64bab2, 0x00000000a0b9d4ac }, ++ /* x^251904 mod p(x)` << 1, x^251968 mod p(x)` << 1 */ ++ { 0x0000000014f4ed2e, 0x0000000095e8ddfe }, ++ /* x^250880 mod p(x)` << 1, x^250944 mod p(x)` << 1 */ ++ { 0x000000011092b6a2, 0x00000000233fddc4 }, ++ /* x^249856 mod p(x)` << 1, x^249920 mod p(x)` << 1 */ ++ { 0x00000000c8a1629c, 0x00000001b4529b62 }, ++ /* x^248832 mod p(x)` << 1, x^248896 mod p(x)` << 1 */ ++ { 0x000000017bf32e8e, 0x00000001a7fa0e64 }, ++ /* x^247808 mod p(x)` << 1, x^247872 mod p(x)` << 1 */ ++ { 0x00000001f8cc6582, 0x00000001b5334592 }, ++ /* x^246784 mod p(x)` << 1, x^246848 mod p(x)` << 1 */ ++ { 0x000000008631ddf0, 0x000000011f8ee1b4 }, ++ /* x^245760 mod p(x)` << 1, x^245824 mod p(x)` << 1 */ ++ { 0x000000007e5a76d0, 0x000000006252e632 }, ++ /* x^244736 mod p(x)` << 1, x^244800 mod p(x)` << 1 */ ++ { 0x000000002b09b31c, 0x00000000ab973e84 }, ++ /* x^243712 mod p(x)` << 1, x^243776 mod p(x)` << 1 */ ++ { 0x00000001b2df1f84, 0x000000007734f5ec }, ++ /* x^242688 mod p(x)` << 1, x^242752 mod p(x)` << 1 */ ++ { 0x00000001d6f56afc, 0x000000007c547798 }, ++ /* x^241664 mod p(x)` << 1, x^241728 mod p(x)` << 1 */ ++ { 0x00000001b9b5e70c, 0x000000007ec40210 }, ++ /* x^240640 mod p(x)` << 1, x^240704 mod p(x)` << 1 */ ++ { 0x0000000034b626d2, 0x00000001ab1695a8 }, ++ /* x^239616 mod p(x)` << 1, x^239680 mod p(x)` << 1 */ ++ { 0x000000014c53479a, 0x0000000090494bba }, ++ /* x^238592 mod p(x)` << 1, x^238656 mod p(x)` << 1 */ ++ { 0x00000001a6d179a4, 0x00000001123fb816 }, ++ /* x^237568 mod p(x)` << 1, x^237632 mod p(x)` << 1 */ ++ { 0x000000015abd16b4, 0x00000001e188c74c }, ++ /* x^236544 mod p(x)` << 1, x^236608 mod p(x)` << 1 */ ++ { 0x00000000018f9852, 0x00000001c2d3451c }, ++ /* x^235520 mod p(x)` << 1, x^235584 mod p(x)` << 1 */ ++ { 0x000000001fb3084a, 0x00000000f55cf1ca }, ++ /* x^234496 mod p(x)` << 1, x^234560 mod p(x)` << 1 */ ++ { 0x00000000c53dfb04, 0x00000001a0531540 }, ++ /* x^233472 mod p(x)` << 1, x^233536 mod p(x)` << 1 */ ++ { 0x00000000e10c9ad6, 0x0000000132cd7ebc }, ++ /* x^232448 mod p(x)` << 1, x^232512 mod p(x)` << 1 */ ++ { 0x0000000025aa994a, 0x0000000073ab7f36 }, ++ /* x^231424 mod p(x)` << 1, x^231488 mod p(x)` << 1 */ ++ { 0x00000000fa3a74c4, 0x0000000041aed1c2 }, ++ /* x^230400 mod p(x)` << 1, x^230464 mod p(x)` << 1 */ ++ { 0x0000000033eb3f40, 0x0000000136c53800 }, ++ /* x^229376 mod p(x)` << 1, x^229440 mod p(x)` << 1 */ ++ { 0x000000017193f296, 0x0000000126835a30 }, ++ /* x^228352 mod p(x)` << 1, x^228416 mod p(x)` << 1 */ ++ { 0x0000000043f6c86a, 0x000000006241b502 }, ++ /* x^227328 mod p(x)` << 1, x^227392 mod p(x)` << 1 */ ++ { 0x000000016b513ec6, 0x00000000d5196ad4 }, ++ /* x^226304 mod p(x)` << 1, x^226368 mod p(x)` << 1 */ ++ { 0x00000000c8f25b4e, 0x000000009cfa769a }, ++ /* x^225280 mod p(x)` << 1, x^225344 mod p(x)` << 1 */ ++ { 0x00000001a45048ec, 0x00000000920e5df4 }, ++ /* x^224256 mod p(x)` << 1, x^224320 mod p(x)` << 1 */ ++ { 0x000000000c441004, 0x0000000169dc310e }, ++ /* x^223232 mod p(x)` << 1, x^223296 mod p(x)` << 1 */ ++ { 0x000000000e17cad6, 0x0000000009fc331c }, ++ /* x^222208 mod p(x)` << 1, x^222272 mod p(x)` << 1 */ ++ { 0x00000001253ae964, 0x000000010d94a81e }, ++ /* x^221184 mod p(x)` << 1, x^221248 mod p(x)` << 1 */ ++ { 0x00000001d7c88ebc, 0x0000000027a20ab2 }, ++ /* x^220160 mod p(x)` << 1, x^220224 mod p(x)` << 1 */ ++ { 0x00000001e7ca913a, 0x0000000114f87504 }, ++ /* x^219136 mod p(x)` << 1, x^219200 mod p(x)` << 1 */ ++ { 0x0000000033ed078a, 0x000000004b076d96 }, ++ /* x^218112 mod p(x)` << 1, x^218176 mod p(x)` << 1 */ ++ { 0x00000000e1839c78, 0x00000000da4d1e74 }, ++ /* x^217088 mod p(x)` << 1, x^217152 mod p(x)` << 1 */ ++ { 0x00000001322b267e, 0x000000001b81f672 }, ++ /* x^216064 mod p(x)` << 1, x^216128 mod p(x)` << 1 */ ++ { 0x00000000638231b6, 0x000000009367c988 }, ++ /* x^215040 mod p(x)` << 1, x^215104 mod p(x)` << 1 */ ++ { 0x00000001ee7f16f4, 0x00000001717214ca }, ++ /* x^214016 mod p(x)` << 1, x^214080 mod p(x)` << 1 */ ++ { 0x0000000117d9924a, 0x000000009f47d820 }, ++ /* x^212992 mod p(x)` << 1, x^213056 mod p(x)` << 1 */ ++ { 0x00000000e1a9e0c4, 0x000000010d9a47d2 }, ++ /* x^211968 mod p(x)` << 1, x^212032 mod p(x)` << 1 */ ++ { 0x00000001403731dc, 0x00000000a696c58c }, ++ /* x^210944 mod p(x)` << 1, x^211008 mod p(x)` << 1 */ ++ { 0x00000001a5ea9682, 0x000000002aa28ec6 }, ++ /* x^209920 mod p(x)` << 1, x^209984 mod p(x)` << 1 */ ++ { 0x0000000101c5c578, 0x00000001fe18fd9a }, ++ /* x^208896 mod p(x)` << 1, x^208960 mod p(x)` << 1 */ ++ { 0x00000000dddf6494, 0x000000019d4fc1ae }, ++ /* x^207872 mod p(x)` << 1, x^207936 mod p(x)` << 1 */ ++ { 0x00000000f1c3db28, 0x00000001ba0e3dea }, ++ /* x^206848 mod p(x)` << 1, x^206912 mod p(x)` << 1 */ ++ { 0x000000013112fb9c, 0x0000000074b59a5e }, ++ /* x^205824 mod p(x)` << 1, x^205888 mod p(x)` << 1 */ ++ { 0x00000000b680b906, 0x00000000f2b5ea98 }, ++ /* x^204800 mod p(x)` << 1, x^204864 mod p(x)` << 1 */ ++ { 0x000000001a282932, 0x0000000187132676 }, ++ /* x^203776 mod p(x)` << 1, x^203840 mod p(x)` << 1 */ ++ { 0x0000000089406e7e, 0x000000010a8c6ad4 }, ++ /* x^202752 mod p(x)` << 1, x^202816 mod p(x)` << 1 */ ++ { 0x00000001def6be8c, 0x00000001e21dfe70 }, ++ /* x^201728 mod p(x)` << 1, x^201792 mod p(x)` << 1 */ ++ { 0x0000000075258728, 0x00000001da0050e4 }, ++ /* x^200704 mod p(x)` << 1, x^200768 mod p(x)` << 1 */ ++ { 0x000000019536090a, 0x00000000772172ae }, ++ /* x^199680 mod p(x)` << 1, x^199744 mod p(x)` << 1 */ ++ { 0x00000000f2455bfc, 0x00000000e47724aa }, ++ /* x^198656 mod p(x)` << 1, x^198720 mod p(x)` << 1 */ ++ { 0x000000018c40baf4, 0x000000003cd63ac4 }, ++ /* x^197632 mod p(x)` << 1, x^197696 mod p(x)` << 1 */ ++ { 0x000000004cd390d4, 0x00000001bf47d352 }, ++ /* x^196608 mod p(x)` << 1, x^196672 mod p(x)` << 1 */ ++ { 0x00000001e4ece95a, 0x000000018dc1d708 }, ++ /* x^195584 mod p(x)` << 1, x^195648 mod p(x)` << 1 */ ++ { 0x000000001a3ee918, 0x000000002d4620a4 }, ++ /* x^194560 mod p(x)` << 1, x^194624 mod p(x)` << 1 */ ++ { 0x000000007c652fb8, 0x0000000058fd1740 }, ++ /* x^193536 mod p(x)` << 1, x^193600 mod p(x)` << 1 */ ++ { 0x000000011c67842c, 0x00000000dadd9bfc }, ++ /* x^192512 mod p(x)` << 1, x^192576 mod p(x)` << 1 */ ++ { 0x00000000254f759c, 0x00000001ea2140be }, ++ /* x^191488 mod p(x)` << 1, x^191552 mod p(x)` << 1 */ ++ { 0x000000007ece94ca, 0x000000009de128ba }, ++ /* x^190464 mod p(x)` << 1, x^190528 mod p(x)` << 1 */ ++ { 0x0000000038f258c2, 0x000000013ac3aa8e }, ++ /* x^189440 mod p(x)` << 1, x^189504 mod p(x)` << 1 */ ++ { 0x00000001cdf17b00, 0x0000000099980562 }, ++ /* x^188416 mod p(x)` << 1, x^188480 mod p(x)` << 1 */ ++ { 0x000000011f882c16, 0x00000001c1579c86 }, ++ /* x^187392 mod p(x)` << 1, x^187456 mod p(x)` << 1 */ ++ { 0x0000000100093fc8, 0x0000000068dbbf94 }, ++ /* x^186368 mod p(x)` << 1, x^186432 mod p(x)` << 1 */ ++ { 0x00000001cd684f16, 0x000000004509fb04 }, ++ /* x^185344 mod p(x)` << 1, x^185408 mod p(x)` << 1 */ ++ { 0x000000004bc6a70a, 0x00000001202f6398 }, ++ /* x^184320 mod p(x)` << 1, x^184384 mod p(x)` << 1 */ ++ { 0x000000004fc7e8e4, 0x000000013aea243e }, ++ /* x^183296 mod p(x)` << 1, x^183360 mod p(x)` << 1 */ ++ { 0x0000000130103f1c, 0x00000001b4052ae6 }, ++ /* x^182272 mod p(x)` << 1, x^182336 mod p(x)` << 1 */ ++ { 0x0000000111b0024c, 0x00000001cd2a0ae8 }, ++ /* x^181248 mod p(x)` << 1, x^181312 mod p(x)` << 1 */ ++ { 0x000000010b3079da, 0x00000001fe4aa8b4 }, ++ /* x^180224 mod p(x)` << 1, x^180288 mod p(x)` << 1 */ ++ { 0x000000010192bcc2, 0x00000001d1559a42 }, ++ /* x^179200 mod p(x)` << 1, x^179264 mod p(x)` << 1 */ ++ { 0x0000000074838d50, 0x00000001f3e05ecc }, ++ /* x^178176 mod p(x)` << 1, x^178240 mod p(x)` << 1 */ ++ { 0x000000001b20f520, 0x0000000104ddd2cc }, ++ /* x^177152 mod p(x)` << 1, x^177216 mod p(x)` << 1 */ ++ { 0x0000000050c3590a, 0x000000015393153c }, ++ /* x^176128 mod p(x)` << 1, x^176192 mod p(x)` << 1 */ ++ { 0x00000000b41cac8e, 0x0000000057e942c6 }, ++ /* x^175104 mod p(x)` << 1, x^175168 mod p(x)` << 1 */ ++ { 0x000000000c72cc78, 0x000000012c633850 }, ++ /* x^174080 mod p(x)` << 1, x^174144 mod p(x)` << 1 */ ++ { 0x0000000030cdb032, 0x00000000ebcaae4c }, ++ /* x^173056 mod p(x)` << 1, x^173120 mod p(x)` << 1 */ ++ { 0x000000013e09fc32, 0x000000013ee532a6 }, ++ /* x^172032 mod p(x)` << 1, x^172096 mod p(x)` << 1 */ ++ { 0x000000001ed624d2, 0x00000001bf0cbc7e }, ++ /* x^171008 mod p(x)` << 1, x^171072 mod p(x)` << 1 */ ++ { 0x00000000781aee1a, 0x00000000d50b7a5a }, ++ /* x^169984 mod p(x)` << 1, x^170048 mod p(x)` << 1 */ ++ { 0x00000001c4d8348c, 0x0000000002fca6e8 }, ++ /* x^168960 mod p(x)` << 1, x^169024 mod p(x)` << 1 */ ++ { 0x0000000057a40336, 0x000000007af40044 }, ++ /* x^167936 mod p(x)` << 1, x^168000 mod p(x)` << 1 */ ++ { 0x0000000085544940, 0x0000000016178744 }, ++ /* x^166912 mod p(x)` << 1, x^166976 mod p(x)` << 1 */ ++ { 0x000000019cd21e80, 0x000000014c177458 }, ++ /* x^165888 mod p(x)` << 1, x^165952 mod p(x)` << 1 */ ++ { 0x000000013eb95bc0, 0x000000011b6ddf04 }, ++ /* x^164864 mod p(x)` << 1, x^164928 mod p(x)` << 1 */ ++ { 0x00000001dfc9fdfc, 0x00000001f3e29ccc }, ++ /* x^163840 mod p(x)` << 1, x^163904 mod p(x)` << 1 */ ++ { 0x00000000cd028bc2, 0x0000000135ae7562 }, ++ /* x^162816 mod p(x)` << 1, x^162880 mod p(x)` << 1 */ ++ { 0x0000000090db8c44, 0x0000000190ef812c }, ++ /* x^161792 mod p(x)` << 1, x^161856 mod p(x)` << 1 */ ++ { 0x000000010010a4ce, 0x0000000067a2c786 }, ++ /* x^160768 mod p(x)` << 1, x^160832 mod p(x)` << 1 */ ++ { 0x00000001c8f4c72c, 0x0000000048b9496c }, ++ /* x^159744 mod p(x)` << 1, x^159808 mod p(x)` << 1 */ ++ { 0x000000001c26170c, 0x000000015a422de6 }, ++ /* x^158720 mod p(x)` << 1, x^158784 mod p(x)` << 1 */ ++ { 0x00000000e3fccf68, 0x00000001ef0e3640 }, ++ /* x^157696 mod p(x)` << 1, x^157760 mod p(x)` << 1 */ ++ { 0x00000000d513ed24, 0x00000001006d2d26 }, ++ /* x^156672 mod p(x)` << 1, x^156736 mod p(x)` << 1 */ ++ { 0x00000000141beada, 0x00000001170d56d6 }, ++ /* x^155648 mod p(x)` << 1, x^155712 mod p(x)` << 1 */ ++ { 0x000000011071aea0, 0x00000000a5fb613c }, ++ /* x^154624 mod p(x)` << 1, x^154688 mod p(x)` << 1 */ ++ { 0x000000012e19080a, 0x0000000040bbf7fc }, ++ /* x^153600 mod p(x)` << 1, x^153664 mod p(x)` << 1 */ ++ { 0x0000000100ecf826, 0x000000016ac3a5b2 }, ++ /* x^152576 mod p(x)` << 1, x^152640 mod p(x)` << 1 */ ++ { 0x0000000069b09412, 0x00000000abf16230 }, ++ /* x^151552 mod p(x)` << 1, x^151616 mod p(x)` << 1 */ ++ { 0x0000000122297bac, 0x00000001ebe23fac }, ++ /* x^150528 mod p(x)` << 1, x^150592 mod p(x)` << 1 */ ++ { 0x00000000e9e4b068, 0x000000008b6a0894 }, ++ /* x^149504 mod p(x)` << 1, x^149568 mod p(x)` << 1 */ ++ { 0x000000004b38651a, 0x00000001288ea478 }, ++ /* x^148480 mod p(x)` << 1, x^148544 mod p(x)` << 1 */ ++ { 0x00000001468360e2, 0x000000016619c442 }, ++ /* x^147456 mod p(x)` << 1, x^147520 mod p(x)` << 1 */ ++ { 0x00000000121c2408, 0x0000000086230038 }, ++ /* x^146432 mod p(x)` << 1, x^146496 mod p(x)` << 1 */ ++ { 0x00000000da7e7d08, 0x000000017746a756 }, ++ /* x^145408 mod p(x)` << 1, x^145472 mod p(x)` << 1 */ ++ { 0x00000001058d7652, 0x0000000191b8f8f8 }, ++ /* x^144384 mod p(x)` << 1, x^144448 mod p(x)` << 1 */ ++ { 0x000000014a098a90, 0x000000008e167708 }, ++ /* x^143360 mod p(x)` << 1, x^143424 mod p(x)` << 1 */ ++ { 0x0000000020dbe72e, 0x0000000148b22d54 }, ++ /* x^142336 mod p(x)` << 1, x^142400 mod p(x)` << 1 */ ++ { 0x000000011e7323e8, 0x0000000044ba2c3c }, ++ /* x^141312 mod p(x)` << 1, x^141376 mod p(x)` << 1 */ ++ { 0x00000000d5d4bf94, 0x00000000b54d2b52 }, ++ /* x^140288 mod p(x)` << 1, x^140352 mod p(x)` << 1 */ ++ { 0x0000000199d8746c, 0x0000000005a4fd8a }, ++ /* x^139264 mod p(x)` << 1, x^139328 mod p(x)` << 1 */ ++ { 0x00000000ce9ca8a0, 0x0000000139f9fc46 }, ++ /* x^138240 mod p(x)` << 1, x^138304 mod p(x)` << 1 */ ++ { 0x00000000136edece, 0x000000015a1fa824 }, ++ /* x^137216 mod p(x)` << 1, x^137280 mod p(x)` << 1 */ ++ { 0x000000019b92a068, 0x000000000a61ae4c }, ++ /* x^136192 mod p(x)` << 1, x^136256 mod p(x)` << 1 */ ++ { 0x0000000071d62206, 0x0000000145e9113e }, ++ /* x^135168 mod p(x)` << 1, x^135232 mod p(x)` << 1 */ ++ { 0x00000000dfc50158, 0x000000006a348448 }, ++ /* x^134144 mod p(x)` << 1, x^134208 mod p(x)` << 1 */ ++ { 0x00000001517626bc, 0x000000004d80a08c }, ++ /* x^133120 mod p(x)` << 1, x^133184 mod p(x)` << 1 */ ++ { 0x0000000148d1e4fa, 0x000000014b6837a0 }, ++ /* x^132096 mod p(x)` << 1, x^132160 mod p(x)` << 1 */ ++ { 0x0000000094d8266e, 0x000000016896a7fc }, ++ /* x^131072 mod p(x)` << 1, x^131136 mod p(x)` << 1 */ ++ { 0x00000000606c5e34, 0x000000014f187140 }, ++ /* x^130048 mod p(x)` << 1, x^130112 mod p(x)` << 1 */ ++ { 0x000000019766beaa, 0x000000019581b9da }, ++ /* x^129024 mod p(x)` << 1, x^129088 mod p(x)` << 1 */ ++ { 0x00000001d80c506c, 0x00000001091bc984 }, ++ /* x^128000 mod p(x)` << 1, x^128064 mod p(x)` << 1 */ ++ { 0x000000001e73837c, 0x000000001067223c }, ++ /* x^126976 mod p(x)` << 1, x^127040 mod p(x)` << 1 */ ++ { 0x0000000064d587de, 0x00000001ab16ea02 }, ++ /* x^125952 mod p(x)` << 1, x^126016 mod p(x)` << 1 */ ++ { 0x00000000f4a507b0, 0x000000013c4598a8 }, ++ /* x^124928 mod p(x)` << 1, x^124992 mod p(x)` << 1 */ ++ { 0x0000000040e342fc, 0x00000000b3735430 }, ++ /* x^123904 mod p(x)` << 1, x^123968 mod p(x)` << 1 */ ++ { 0x00000001d5ad9c3a, 0x00000001bb3fc0c0 }, ++ /* x^122880 mod p(x)` << 1, x^122944 mod p(x)` << 1 */ ++ { 0x0000000094a691a4, 0x00000001570ae19c }, ++ /* x^121856 mod p(x)` << 1, x^121920 mod p(x)` << 1 */ ++ { 0x00000001271ecdfa, 0x00000001ea910712 }, ++ /* x^120832 mod p(x)` << 1, x^120896 mod p(x)` << 1 */ ++ { 0x000000009e54475a, 0x0000000167127128 }, ++ /* x^119808 mod p(x)` << 1, x^119872 mod p(x)` << 1 */ ++ { 0x00000000c9c099ee, 0x0000000019e790a2 }, ++ /* x^118784 mod p(x)` << 1, x^118848 mod p(x)` << 1 */ ++ { 0x000000009a2f736c, 0x000000003788f710 }, ++ /* x^117760 mod p(x)` << 1, x^117824 mod p(x)` << 1 */ ++ { 0x00000000bb9f4996, 0x00000001682a160e }, ++ /* x^116736 mod p(x)` << 1, x^116800 mod p(x)` << 1 */ ++ { 0x00000001db688050, 0x000000007f0ebd2e }, ++ /* x^115712 mod p(x)` << 1, x^115776 mod p(x)` << 1 */ ++ { 0x00000000e9b10af4, 0x000000002b032080 }, ++ /* x^114688 mod p(x)` << 1, x^114752 mod p(x)` << 1 */ ++ { 0x000000012d4545e4, 0x00000000cfd1664a }, ++ /* x^113664 mod p(x)` << 1, x^113728 mod p(x)` << 1 */ ++ { 0x000000000361139c, 0x00000000aa1181c2 }, ++ /* x^112640 mod p(x)` << 1, x^112704 mod p(x)` << 1 */ ++ { 0x00000001a5a1a3a8, 0x00000000ddd08002 }, ++ /* x^111616 mod p(x)` << 1, x^111680 mod p(x)` << 1 */ ++ { 0x000000006844e0b0, 0x00000000e8dd0446 }, ++ /* x^110592 mod p(x)` << 1, x^110656 mod p(x)` << 1 */ ++ { 0x00000000c3762f28, 0x00000001bbd94a00 }, ++ /* x^109568 mod p(x)` << 1, x^109632 mod p(x)` << 1 */ ++ { 0x00000001d26287a2, 0x00000000ab6cd180 }, ++ /* x^108544 mod p(x)` << 1, x^108608 mod p(x)` << 1 */ ++ { 0x00000001f6f0bba8, 0x0000000031803ce2 }, ++ /* x^107520 mod p(x)` << 1, x^107584 mod p(x)` << 1 */ ++ { 0x000000002ffabd62, 0x0000000024f40b0c }, ++ /* x^106496 mod p(x)` << 1, x^106560 mod p(x)` << 1 */ ++ { 0x00000000fb4516b8, 0x00000001ba1d9834 }, ++ /* x^105472 mod p(x)` << 1, x^105536 mod p(x)` << 1 */ ++ { 0x000000018cfa961c, 0x0000000104de61aa }, ++ /* x^104448 mod p(x)` << 1, x^104512 mod p(x)` << 1 */ ++ { 0x000000019e588d52, 0x0000000113e40d46 }, ++ /* x^103424 mod p(x)` << 1, x^103488 mod p(x)` << 1 */ ++ { 0x00000001180f0bbc, 0x00000001415598a0 }, ++ /* x^102400 mod p(x)` << 1, x^102464 mod p(x)` << 1 */ ++ { 0x00000000e1d9177a, 0x00000000bf6c8c90 }, ++ /* x^101376 mod p(x)` << 1, x^101440 mod p(x)` << 1 */ ++ { 0x0000000105abc27c, 0x00000001788b0504 }, ++ /* x^100352 mod p(x)` << 1, x^100416 mod p(x)` << 1 */ ++ { 0x00000000972e4a58, 0x0000000038385d02 }, ++ /* x^99328 mod p(x)` << 1, x^99392 mod p(x)` << 1 */ ++ { 0x0000000183499a5e, 0x00000001b6c83844 }, ++ /* x^98304 mod p(x)` << 1, x^98368 mod p(x)` << 1 */ ++ { 0x00000001c96a8cca, 0x0000000051061a8a }, ++ /* x^97280 mod p(x)` << 1, x^97344 mod p(x)` << 1 */ ++ { 0x00000001a1a5b60c, 0x000000017351388a }, ++ /* x^96256 mod p(x)` << 1, x^96320 mod p(x)` << 1 */ ++ { 0x00000000e4b6ac9c, 0x0000000132928f92 }, ++ /* x^95232 mod p(x)` << 1, x^95296 mod p(x)` << 1 */ ++ { 0x00000001807e7f5a, 0x00000000e6b4f48a }, ++ /* x^94208 mod p(x)` << 1, x^94272 mod p(x)` << 1 */ ++ { 0x000000017a7e3bc8, 0x0000000039d15e90 }, ++ /* x^93184 mod p(x)` << 1, x^93248 mod p(x)` << 1 */ ++ { 0x00000000d73975da, 0x00000000312d6074 }, ++ /* x^92160 mod p(x)` << 1, x^92224 mod p(x)` << 1 */ ++ { 0x000000017375d038, 0x000000017bbb2cc4 }, ++ /* x^91136 mod p(x)` << 1, x^91200 mod p(x)` << 1 */ ++ { 0x00000000193680bc, 0x000000016ded3e18 }, ++ /* x^90112 mod p(x)` << 1, x^90176 mod p(x)` << 1 */ ++ { 0x00000000999b06f6, 0x00000000f1638b16 }, ++ /* x^89088 mod p(x)` << 1, x^89152 mod p(x)` << 1 */ ++ { 0x00000001f685d2b8, 0x00000001d38b9ecc }, ++ /* x^88064 mod p(x)` << 1, x^88128 mod p(x)` << 1 */ ++ { 0x00000001f4ecbed2, 0x000000018b8d09dc }, ++ /* x^87040 mod p(x)` << 1, x^87104 mod p(x)` << 1 */ ++ { 0x00000000ba16f1a0, 0x00000000e7bc27d2 }, ++ /* x^86016 mod p(x)` << 1, x^86080 mod p(x)` << 1 */ ++ { 0x0000000115aceac4, 0x00000000275e1e96 }, ++ /* x^84992 mod p(x)` << 1, x^85056 mod p(x)` << 1 */ ++ { 0x00000001aeff6292, 0x00000000e2e3031e }, ++ /* x^83968 mod p(x)` << 1, x^84032 mod p(x)` << 1 */ ++ { 0x000000009640124c, 0x00000001041c84d8 }, ++ /* x^82944 mod p(x)` << 1, x^83008 mod p(x)` << 1 */ ++ { 0x0000000114f41f02, 0x00000000706ce672 }, ++ /* x^81920 mod p(x)` << 1, x^81984 mod p(x)` << 1 */ ++ { 0x000000009c5f3586, 0x000000015d5070da }, ++ /* x^80896 mod p(x)` << 1, x^80960 mod p(x)` << 1 */ ++ { 0x00000001878275fa, 0x0000000038f9493a }, ++ /* x^79872 mod p(x)` << 1, x^79936 mod p(x)` << 1 */ ++ { 0x00000000ddc42ce8, 0x00000000a3348a76 }, ++ /* x^78848 mod p(x)` << 1, x^78912 mod p(x)` << 1 */ ++ { 0x0000000181d2c73a, 0x00000001ad0aab92 }, ++ /* x^77824 mod p(x)` << 1, x^77888 mod p(x)` << 1 */ ++ { 0x0000000141c9320a, 0x000000019e85f712 }, ++ /* x^76800 mod p(x)` << 1, x^76864 mod p(x)` << 1 */ ++ { 0x000000015235719a, 0x000000005a871e76 }, ++ /* x^75776 mod p(x)` << 1, x^75840 mod p(x)` << 1 */ ++ { 0x00000000be27d804, 0x000000017249c662 }, ++ /* x^74752 mod p(x)` << 1, x^74816 mod p(x)` << 1 */ ++ { 0x000000006242d45a, 0x000000003a084712 }, ++ /* x^73728 mod p(x)` << 1, x^73792 mod p(x)` << 1 */ ++ { 0x000000009a53638e, 0x00000000ed438478 }, ++ /* x^72704 mod p(x)` << 1, x^72768 mod p(x)` << 1 */ ++ { 0x00000001001ecfb6, 0x00000000abac34cc }, ++ /* x^71680 mod p(x)` << 1, x^71744 mod p(x)` << 1 */ ++ { 0x000000016d7c2d64, 0x000000005f35ef3e }, ++ /* x^70656 mod p(x)` << 1, x^70720 mod p(x)` << 1 */ ++ { 0x00000001d0ce46c0, 0x0000000047d6608c }, ++ /* x^69632 mod p(x)` << 1, x^69696 mod p(x)` << 1 */ ++ { 0x0000000124c907b4, 0x000000002d01470e }, ++ /* x^68608 mod p(x)` << 1, x^68672 mod p(x)` << 1 */ ++ { 0x0000000018a555ca, 0x0000000158bbc7b0 }, ++ /* x^67584 mod p(x)` << 1, x^67648 mod p(x)` << 1 */ ++ { 0x000000006b0980bc, 0x00000000c0a23e8e }, ++ /* x^66560 mod p(x)` << 1, x^66624 mod p(x)` << 1 */ ++ { 0x000000008bbba964, 0x00000001ebd85c88 }, ++ /* x^65536 mod p(x)` << 1, x^65600 mod p(x)` << 1 */ ++ { 0x00000001070a5a1e, 0x000000019ee20bb2 }, ++ /* x^64512 mod p(x)` << 1, x^64576 mod p(x)` << 1 */ ++ { 0x000000002204322a, 0x00000001acabf2d6 }, ++ /* x^63488 mod p(x)` << 1, x^63552 mod p(x)` << 1 */ ++ { 0x00000000a27524d0, 0x00000001b7963d56 }, ++ /* x^62464 mod p(x)` << 1, x^62528 mod p(x)` << 1 */ ++ { 0x0000000020b1e4ba, 0x000000017bffa1fe }, ++ /* x^61440 mod p(x)` << 1, x^61504 mod p(x)` << 1 */ ++ { 0x0000000032cc27fc, 0x000000001f15333e }, ++ /* x^60416 mod p(x)` << 1, x^60480 mod p(x)` << 1 */ ++ { 0x0000000044dd22b8, 0x000000018593129e }, ++ /* x^59392 mod p(x)` << 1, x^59456 mod p(x)` << 1 */ ++ { 0x00000000dffc9e0a, 0x000000019cb32602 }, ++ /* x^58368 mod p(x)` << 1, x^58432 mod p(x)` << 1 */ ++ { 0x00000001b7a0ed14, 0x0000000142b05cc8 }, ++ /* x^57344 mod p(x)` << 1, x^57408 mod p(x)` << 1 */ ++ { 0x00000000c7842488, 0x00000001be49e7a4 }, ++ /* x^56320 mod p(x)` << 1, x^56384 mod p(x)` << 1 */ ++ { 0x00000001c02a4fee, 0x0000000108f69d6c }, ++ /* x^55296 mod p(x)` << 1, x^55360 mod p(x)` << 1 */ ++ { 0x000000003c273778, 0x000000006c0971f0 }, ++ /* x^54272 mod p(x)` << 1, x^54336 mod p(x)` << 1 */ ++ { 0x00000001d63f8894, 0x000000005b16467a }, ++ /* x^53248 mod p(x)` << 1, x^53312 mod p(x)` << 1 */ ++ { 0x000000006be557d6, 0x00000001551a628e }, ++ /* x^52224 mod p(x)` << 1, x^52288 mod p(x)` << 1 */ ++ { 0x000000006a7806ea, 0x000000019e42ea92 }, ++ /* x^51200 mod p(x)` << 1, x^51264 mod p(x)` << 1 */ ++ { 0x000000016155aa0c, 0x000000012fa83ff2 }, ++ /* x^50176 mod p(x)` << 1, x^50240 mod p(x)` << 1 */ ++ { 0x00000000908650ac, 0x000000011ca9cde0 }, ++ /* x^49152 mod p(x)` << 1, x^49216 mod p(x)` << 1 */ ++ { 0x00000000aa5a8084, 0x00000000c8e5cd74 }, ++ /* x^48128 mod p(x)` << 1, x^48192 mod p(x)` << 1 */ ++ { 0x0000000191bb500a, 0x0000000096c27f0c }, ++ /* x^47104 mod p(x)` << 1, x^47168 mod p(x)` << 1 */ ++ { 0x0000000064e9bed0, 0x000000002baed926 }, ++ /* x^46080 mod p(x)` << 1, x^46144 mod p(x)` << 1 */ ++ { 0x000000009444f302, 0x000000017c8de8d2 }, ++ /* x^45056 mod p(x)` << 1, x^45120 mod p(x)` << 1 */ ++ { 0x000000019db07d3c, 0x00000000d43d6068 }, ++ /* x^44032 mod p(x)` << 1, x^44096 mod p(x)` << 1 */ ++ { 0x00000001359e3e6e, 0x00000000cb2c4b26 }, ++ /* x^43008 mod p(x)` << 1, x^43072 mod p(x)` << 1 */ ++ { 0x00000001e4f10dd2, 0x0000000145b8da26 }, ++ /* x^41984 mod p(x)` << 1, x^42048 mod p(x)` << 1 */ ++ { 0x0000000124f5735e, 0x000000018fff4b08 }, ++ /* x^40960 mod p(x)` << 1, x^41024 mod p(x)` << 1 */ ++ { 0x0000000124760a4c, 0x0000000150b58ed0 }, ++ /* x^39936 mod p(x)` << 1, x^40000 mod p(x)` << 1 */ ++ { 0x000000000f1fc186, 0x00000001549f39bc }, ++ /* x^38912 mod p(x)` << 1, x^38976 mod p(x)` << 1 */ ++ { 0x00000000150e4cc4, 0x00000000ef4d2f42 }, ++ /* x^37888 mod p(x)` << 1, x^37952 mod p(x)` << 1 */ ++ { 0x000000002a6204e8, 0x00000001b1468572 }, ++ /* x^36864 mod p(x)` << 1, x^36928 mod p(x)` << 1 */ ++ { 0x00000000beb1d432, 0x000000013d7403b2 }, ++ /* x^35840 mod p(x)` << 1, x^35904 mod p(x)` << 1 */ ++ { 0x0000000135f3f1f0, 0x00000001a4681842 }, ++ /* x^34816 mod p(x)` << 1, x^34880 mod p(x)` << 1 */ ++ { 0x0000000074fe2232, 0x0000000167714492 }, ++ /* x^33792 mod p(x)` << 1, x^33856 mod p(x)` << 1 */ ++ { 0x000000001ac6e2ba, 0x00000001e599099a }, ++ /* x^32768 mod p(x)` << 1, x^32832 mod p(x)` << 1 */ ++ { 0x0000000013fca91e, 0x00000000fe128194 }, ++ /* x^31744 mod p(x)` << 1, x^31808 mod p(x)` << 1 */ ++ { 0x0000000183f4931e, 0x0000000077e8b990 }, ++ /* x^30720 mod p(x)` << 1, x^30784 mod p(x)` << 1 */ ++ { 0x00000000b6d9b4e4, 0x00000001a267f63a }, ++ /* x^29696 mod p(x)` << 1, x^29760 mod p(x)` << 1 */ ++ { 0x00000000b5188656, 0x00000001945c245a }, ++ /* x^28672 mod p(x)` << 1, x^28736 mod p(x)` << 1 */ ++ { 0x0000000027a81a84, 0x0000000149002e76 }, ++ /* x^27648 mod p(x)` << 1, x^27712 mod p(x)` << 1 */ ++ { 0x0000000125699258, 0x00000001bb8310a4 }, ++ /* x^26624 mod p(x)` << 1, x^26688 mod p(x)` << 1 */ ++ { 0x00000001b23de796, 0x000000019ec60bcc }, ++ /* x^25600 mod p(x)` << 1, x^25664 mod p(x)` << 1 */ ++ { 0x00000000fe4365dc, 0x000000012d8590ae }, ++ /* x^24576 mod p(x)` << 1, x^24640 mod p(x)` << 1 */ ++ { 0x00000000c68f497a, 0x0000000065b00684 }, ++ /* x^23552 mod p(x)` << 1, x^23616 mod p(x)` << 1 */ ++ { 0x00000000fbf521ee, 0x000000015e5aeadc }, ++ /* x^22528 mod p(x)` << 1, x^22592 mod p(x)` << 1 */ ++ { 0x000000015eac3378, 0x00000000b77ff2b0 }, ++ /* x^21504 mod p(x)` << 1, x^21568 mod p(x)` << 1 */ ++ { 0x0000000134914b90, 0x0000000188da2ff6 }, ++ /* x^20480 mod p(x)` << 1, x^20544 mod p(x)` << 1 */ ++ { 0x0000000016335cfe, 0x0000000063da929a }, ++ /* x^19456 mod p(x)` << 1, x^19520 mod p(x)` << 1 */ ++ { 0x000000010372d10c, 0x00000001389caa80 }, ++ /* x^18432 mod p(x)` << 1, x^18496 mod p(x)` << 1 */ ++ { 0x000000015097b908, 0x000000013db599d2 }, ++ /* x^17408 mod p(x)` << 1, x^17472 mod p(x)` << 1 */ ++ { 0x00000001227a7572, 0x0000000122505a86 }, ++ /* x^16384 mod p(x)` << 1, x^16448 mod p(x)` << 1 */ ++ { 0x000000009a8f75c0, 0x000000016bd72746 }, ++ /* x^15360 mod p(x)` << 1, x^15424 mod p(x)` << 1 */ ++ { 0x00000000682c77a2, 0x00000001c3faf1d4 }, ++ /* x^14336 mod p(x)` << 1, x^14400 mod p(x)` << 1 */ ++ { 0x00000000231f091c, 0x00000001111c826c }, ++ /* x^13312 mod p(x)` << 1, x^13376 mod p(x)` << 1 */ ++ { 0x000000007d4439f2, 0x00000000153e9fb2 }, ++ /* x^12288 mod p(x)` << 1, x^12352 mod p(x)` << 1 */ ++ { 0x000000017e221efc, 0x000000002b1f7b60 }, ++ /* x^11264 mod p(x)` << 1, x^11328 mod p(x)` << 1 */ ++ { 0x0000000167457c38, 0x00000000b1dba570 }, ++ /* x^10240 mod p(x)` << 1, x^10304 mod p(x)` << 1 */ ++ { 0x00000000bdf081c4, 0x00000001f6397b76 }, ++ /* x^9216 mod p(x)` << 1, x^9280 mod p(x)` << 1 */ ++ { 0x000000016286d6b0, 0x0000000156335214 }, ++ /* x^8192 mod p(x)` << 1, x^8256 mod p(x)` << 1 */ ++ { 0x00000000c84f001c, 0x00000001d70e3986 }, ++ /* x^7168 mod p(x)` << 1, x^7232 mod p(x)` << 1 */ ++ { 0x0000000064efe7c0, 0x000000003701a774 }, ++ /* x^6144 mod p(x)` << 1, x^6208 mod p(x)` << 1 */ ++ { 0x000000000ac2d904, 0x00000000ac81ef72 }, ++ /* x^5120 mod p(x)` << 1, x^5184 mod p(x)` << 1 */ ++ { 0x00000000fd226d14, 0x0000000133212464 }, ++ /* x^4096 mod p(x)` << 1, x^4160 mod p(x)` << 1 */ ++ { 0x000000011cfd42e0, 0x00000000e4e45610 }, ++ /* x^3072 mod p(x)` << 1, x^3136 mod p(x)` << 1 */ ++ { 0x000000016e5a5678, 0x000000000c1bd370 }, ++ /* x^2048 mod p(x)` << 1, x^2112 mod p(x)` << 1 */ ++ { 0x00000001d888fe22, 0x00000001a7b9e7a6 }, ++ /* x^1024 mod p(x)` << 1, x^1088 mod p(x)` << 1 */ ++ { 0x00000001af77fcd4, 0x000000007d657a10 } ++#endif /* __LITTLE_ENDIAN__ */ ++ }; ++ ++/* Reduce final 1024-2048 bits to 64 bits, shifting 32 bits to include the trailing 32 bits of zeros */ ++ ++static const __vector unsigned long long vcrc_short_const[16] ++ __attribute__((aligned (16))) = { ++#ifdef __LITTLE_ENDIAN__ ++ /* x^1952 mod p(x) , x^1984 mod p(x) , x^2016 mod p(x) , x^2048 mod p(x) */ ++ { 0x99168a18ec447f11, 0xed837b2613e8221e }, ++ /* x^1824 mod p(x) , x^1856 mod p(x) , x^1888 mod p(x) , x^1920 mod p(x) */ ++ { 0xe23e954e8fd2cd3c, 0xc8acdd8147b9ce5a }, ++ /* x^1696 mod p(x) , x^1728 mod p(x) , x^1760 mod p(x) , x^1792 mod p(x) */ ++ { 0x92f8befe6b1d2b53, 0xd9ad6d87d4277e25 }, ++ /* x^1568 mod p(x) , x^1600 mod p(x) , x^1632 mod p(x) , x^1664 mod p(x) */ ++ { 0xf38a3556291ea462, 0xc10ec5e033fbca3b }, ++ /* x^1440 mod p(x) , x^1472 mod p(x) , x^1504 mod p(x) , x^1536 mod p(x) */ ++ { 0x974ac56262b6ca4b, 0xc0b55b0e82e02e2f }, ++ /* x^1312 mod p(x) , x^1344 mod p(x) , x^1376 mod p(x) , x^1408 mod p(x) */ ++ { 0x855712b3784d2a56, 0x71aa1df0e172334d }, ++ /* x^1184 mod p(x) , x^1216 mod p(x) , x^1248 mod p(x) , x^1280 mod p(x) */ ++ { 0xa5abe9f80eaee722, 0xfee3053e3969324d }, ++ /* x^1056 mod p(x) , x^1088 mod p(x) , x^1120 mod p(x) , x^1152 mod p(x) */ ++ { 0x1fa0943ddb54814c, 0xf44779b93eb2bd08 }, ++ /* x^928 mod p(x) , x^960 mod p(x) , x^992 mod p(x) , x^1024 mod p(x) */ ++ { 0xa53ff440d7bbfe6a, 0xf5449b3f00cc3374 }, ++ /* x^800 mod p(x) , x^832 mod p(x) , x^864 mod p(x) , x^896 mod p(x) */ ++ { 0xebe7e3566325605c, 0x6f8346e1d777606e }, ++ /* x^672 mod p(x) , x^704 mod p(x) , x^736 mod p(x) , x^768 mod p(x) */ ++ { 0xc65a272ce5b592b8, 0xe3ab4f2ac0b95347 }, ++ /* x^544 mod p(x) , x^576 mod p(x) , x^608 mod p(x) , x^640 mod p(x) */ ++ { 0x5705a9ca4721589f, 0xaa2215ea329ecc11 }, ++ /* x^416 mod p(x) , x^448 mod p(x) , x^480 mod p(x) , x^512 mod p(x) */ ++ { 0xe3720acb88d14467, 0x1ed8f66ed95efd26 }, ++ /* x^288 mod p(x) , x^320 mod p(x) , x^352 mod p(x) , x^384 mod p(x) */ ++ { 0xba1aca0315141c31, 0x78ed02d5a700e96a }, ++ /* x^160 mod p(x) , x^192 mod p(x) , x^224 mod p(x) , x^256 mod p(x) */ ++ { 0xad2a31b3ed627dae, 0xba8ccbe832b39da3 }, ++ /* x^32 mod p(x) , x^64 mod p(x) , x^96 mod p(x) , x^128 mod p(x) */ ++ { 0x6655004fa06a2517, 0xedb88320b1e6b092 } ++#else /* __LITTLE_ENDIAN__ */ ++ /* x^1952 mod p(x) , x^1984 mod p(x) , x^2016 mod p(x) , x^2048 mod p(x) */ ++ { 0xed837b2613e8221e, 0x99168a18ec447f11 }, ++ /* x^1824 mod p(x) , x^1856 mod p(x) , x^1888 mod p(x) , x^1920 mod p(x) */ ++ { 0xc8acdd8147b9ce5a, 0xe23e954e8fd2cd3c }, ++ /* x^1696 mod p(x) , x^1728 mod p(x) , x^1760 mod p(x) , x^1792 mod p(x) */ ++ { 0xd9ad6d87d4277e25, 0x92f8befe6b1d2b53 }, ++ /* x^1568 mod p(x) , x^1600 mod p(x) , x^1632 mod p(x) , x^1664 mod p(x) */ ++ { 0xc10ec5e033fbca3b, 0xf38a3556291ea462 }, ++ /* x^1440 mod p(x) , x^1472 mod p(x) , x^1504 mod p(x) , x^1536 mod p(x) */ ++ { 0xc0b55b0e82e02e2f, 0x974ac56262b6ca4b }, ++ /* x^1312 mod p(x) , x^1344 mod p(x) , x^1376 mod p(x) , x^1408 mod p(x) */ ++ { 0x71aa1df0e172334d, 0x855712b3784d2a56 }, ++ /* x^1184 mod p(x) , x^1216 mod p(x) , x^1248 mod p(x) , x^1280 mod p(x) */ ++ { 0xfee3053e3969324d, 0xa5abe9f80eaee722 }, ++ /* x^1056 mod p(x) , x^1088 mod p(x) , x^1120 mod p(x) , x^1152 mod p(x) */ ++ { 0xf44779b93eb2bd08, 0x1fa0943ddb54814c }, ++ /* x^928 mod p(x) , x^960 mod p(x) , x^992 mod p(x) , x^1024 mod p(x) */ ++ { 0xf5449b3f00cc3374, 0xa53ff440d7bbfe6a }, ++ /* x^800 mod p(x) , x^832 mod p(x) , x^864 mod p(x) , x^896 mod p(x) */ ++ { 0x6f8346e1d777606e, 0xebe7e3566325605c }, ++ /* x^672 mod p(x) , x^704 mod p(x) , x^736 mod p(x) , x^768 mod p(x) */ ++ { 0xe3ab4f2ac0b95347, 0xc65a272ce5b592b8 }, ++ /* x^544 mod p(x) , x^576 mod p(x) , x^608 mod p(x) , x^640 mod p(x) */ ++ { 0xaa2215ea329ecc11, 0x5705a9ca4721589f }, ++ /* x^416 mod p(x) , x^448 mod p(x) , x^480 mod p(x) , x^512 mod p(x) */ ++ { 0x1ed8f66ed95efd26, 0xe3720acb88d14467 }, ++ /* x^288 mod p(x) , x^320 mod p(x) , x^352 mod p(x) , x^384 mod p(x) */ ++ { 0x78ed02d5a700e96a, 0xba1aca0315141c31 }, ++ /* x^160 mod p(x) , x^192 mod p(x) , x^224 mod p(x) , x^256 mod p(x) */ ++ { 0xba8ccbe832b39da3, 0xad2a31b3ed627dae }, ++ /* x^32 mod p(x) , x^64 mod p(x) , x^96 mod p(x) , x^128 mod p(x) */ ++ { 0xedb88320b1e6b092, 0x6655004fa06a2517 } ++#endif /* __LITTLE_ENDIAN__ */ ++ }; ++ ++/* Barrett constants */ ++/* 33 bit reflected Barrett constant m - (4^32)/n */ ++ ++static const __vector unsigned long long v_Barrett_const[2] ++ __attribute__((aligned (16))) = { ++ /* x^64 div p(x) */ ++#ifdef __LITTLE_ENDIAN__ ++ { 0x00000001f7011641, 0x0000000000000000 }, ++ { 0x00000001db710641, 0x0000000000000000 } ++#else /* __LITTLE_ENDIAN__ */ ++ { 0x0000000000000000, 0x00000001f7011641 }, ++ { 0x0000000000000000, 0x00000001db710641 } ++#endif /* __LITTLE_ENDIAN__ */ ++ }; ++#endif /* POWER8_INTRINSICS */ ++ ++#endif /* __ASSEMBLER__ */ +diff --git a/contrib/power8-crc/vec_crc32.c b/contrib/power8-crc/vec_crc32.c +new file mode 100644 +index 0000000..bb2204b +--- /dev/null ++++ b/contrib/power8-crc/vec_crc32.c +@@ -0,0 +1,674 @@ ++/* ++ * Calculate the checksum of data that is 16 byte aligned and a multiple of ++ * 16 bytes. ++ * ++ * The first step is to reduce it to 1024 bits. We do this in 8 parallel ++ * chunks in order to mask the latency of the vpmsum instructions. If we ++ * have more than 32 kB of data to checksum we repeat this step multiple ++ * times, passing in the previous 1024 bits. ++ * ++ * The next step is to reduce the 1024 bits to 64 bits. This step adds ++ * 32 bits of 0s to the end - this matches what a CRC does. We just ++ * calculate constants that land the data in this 32 bits. ++ * ++ * We then use fixed point Barrett reduction to compute a mod n over GF(2) ++ * for n = CRC using POWER8 instructions. We use x = 32. ++ * ++ * http://en.wikipedia.org/wiki/Barrett_reduction ++ * ++ * This code uses gcc vector builtins instead using assembly directly. ++ * ++ * Copyright (C) 2017 Rogerio Alves , IBM ++ * ++ * This program is free software; you can redistribute it and/or ++ * modify it under the terms of either: ++ * ++ * a) the GNU General Public License as published by the Free Software ++ * Foundation; either version 2 of the License, or (at your option) ++ * any later version, or ++ * b) the Apache License, Version 2.0 ++ */ ++ ++#include ++ ++#define POWER8_INTRINSICS ++#define CRC_TABLE ++ ++#ifdef CRC32_CONSTANTS_HEADER ++#include CRC32_CONSTANTS_HEADER ++#else ++#include "crc32_constants.h" ++#endif ++ ++#define VMX_ALIGN 16 ++#define VMX_ALIGN_MASK (VMX_ALIGN-1) ++ ++#ifdef REFLECT ++static unsigned int crc32_align(unsigned int crc, const unsigned char *p, ++ unsigned long len) ++{ ++ while (len--) ++ crc = crc_table[(crc ^ *p++) & 0xff] ^ (crc >> 8); ++ return crc; ++} ++#else ++static unsigned int crc32_align(unsigned int crc, const unsigned char *p, ++ unsigned long len) ++{ ++ while (len--) ++ crc = crc_table[((crc >> 24) ^ *p++) & 0xff] ^ (crc << 8); ++ return crc; ++} ++#endif ++ ++static unsigned int __attribute__ ((aligned (32))) ++__crc32_vpmsum(unsigned int crc, const void* p, unsigned long len); ++ ++#ifndef CRC32_FUNCTION ++#define CRC32_FUNCTION crc32_vpmsum ++#endif ++ ++unsigned int CRC32_FUNCTION(unsigned int crc, const unsigned char *p, ++ unsigned long len) ++{ ++ unsigned int prealign; ++ unsigned int tail; ++ ++#ifdef CRC_XOR ++ crc ^= 0xffffffff; ++#endif ++ ++ if (len < VMX_ALIGN + VMX_ALIGN_MASK) { ++ crc = crc32_align(crc, p, len); ++ goto out; ++ } ++ ++ if ((unsigned long)p & VMX_ALIGN_MASK) { ++ prealign = VMX_ALIGN - ((unsigned long)p & VMX_ALIGN_MASK); ++ crc = crc32_align(crc, p, prealign); ++ len -= prealign; ++ p += prealign; ++ } ++ ++ crc = __crc32_vpmsum(crc, p, len & ~VMX_ALIGN_MASK); ++ ++ tail = len & VMX_ALIGN_MASK; ++ if (tail) { ++ p += len & ~VMX_ALIGN_MASK; ++ crc = crc32_align(crc, p, tail); ++ } ++ ++out: ++#ifdef CRC_XOR ++ crc ^= 0xffffffff; ++#endif ++ ++ return crc; ++} ++ ++#if defined (__clang__) ++#include "clang_workaround.h" ++#else ++#define __builtin_pack_vector(a, b) __builtin_pack_vector_int128 ((a), (b)) ++#define __builtin_unpack_vector_0(a) __builtin_unpack_vector_int128 ((vector __int128_t)(a), 0) ++#define __builtin_unpack_vector_1(a) __builtin_unpack_vector_int128 ((vector __int128_t)(a), 1) ++#endif ++ ++/* When we have a load-store in a single-dispatch group and address overlap ++ * such that foward is not allowed (load-hit-store) the group must be flushed. ++ * A group ending NOP prevents the flush. ++ */ ++#define GROUP_ENDING_NOP asm("ori 2,2,0" ::: "memory") ++ ++#if defined(__BIG_ENDIAN__) && defined (REFLECT) ++#define BYTESWAP_DATA ++#elif defined(__LITTLE_ENDIAN__) && !defined(REFLECT) ++#define BYTESWAP_DATA ++#endif ++ ++#ifdef BYTESWAP_DATA ++#define VEC_PERM(vr, va, vb, vc) vr = vec_perm(va, vb,\ ++ (__vector unsigned char) vc) ++#if defined(__LITTLE_ENDIAN__) ++/* Byte reverse permute constant LE. */ ++static const __vector unsigned long long vperm_const ++ __attribute__ ((aligned(16))) = { 0x08090A0B0C0D0E0FUL, ++ 0x0001020304050607UL }; ++#else ++static const __vector unsigned long long vperm_const ++ __attribute__ ((aligned(16))) = { 0x0F0E0D0C0B0A0908UL, ++ 0X0706050403020100UL }; ++#endif ++#else ++#define VEC_PERM(vr, va, vb, vc) ++#endif ++ ++static unsigned int __attribute__ ((aligned (32))) ++__crc32_vpmsum(unsigned int crc, const void* p, unsigned long len) { ++ ++ const __vector unsigned long long vzero = {0,0}; ++ const __vector unsigned long long vones = {0xffffffffffffffffUL, ++ 0xffffffffffffffffUL}; ++ ++#ifdef REFLECT ++ const __vector unsigned long long vmask_32bit = ++ (__vector unsigned long long)vec_sld((__vector unsigned char)vzero, ++ (__vector unsigned char)vones, 4); ++#endif ++ ++ const __vector unsigned long long vmask_64bit = ++ (__vector unsigned long long)vec_sld((__vector unsigned char)vzero, ++ (__vector unsigned char)vones, 8); ++ ++ __vector unsigned long long vcrc; ++ ++ __vector unsigned long long vconst1, vconst2; ++ ++ /* vdata0-vdata7 will contain our data (p). */ ++ __vector unsigned long long vdata0, vdata1, vdata2, vdata3, vdata4, ++ vdata5, vdata6, vdata7; ++ ++ /* v0-v7 will contain our checksums */ ++ __vector unsigned long long v0 = {0,0}; ++ __vector unsigned long long v1 = {0,0}; ++ __vector unsigned long long v2 = {0,0}; ++ __vector unsigned long long v3 = {0,0}; ++ __vector unsigned long long v4 = {0,0}; ++ __vector unsigned long long v5 = {0,0}; ++ __vector unsigned long long v6 = {0,0}; ++ __vector unsigned long long v7 = {0,0}; ++ ++ ++ /* Vector auxiliary variables. */ ++ __vector unsigned long long va0, va1, va2, va3, va4, va5, va6, va7; ++ ++ unsigned int result = 0; ++ unsigned int offset; /* Constant table offset. */ ++ ++ unsigned long i; /* Counter. */ ++ unsigned long chunks; ++ ++ unsigned long block_size; ++ int next_block = 0; ++ ++ /* Align by 128 bits. The last 128 bit block will be processed at end. */ ++ unsigned long length = len & 0xFFFFFFFFFFFFFF80UL; ++ ++#ifdef REFLECT ++ vcrc = (__vector unsigned long long)__builtin_pack_vector(0UL, crc); ++#else ++ vcrc = (__vector unsigned long long)__builtin_pack_vector(crc, 0UL); ++ ++ /* Shift into top 32 bits */ ++ vcrc = (__vector unsigned long long)vec_sld((__vector unsigned char)vcrc, ++ (__vector unsigned char)vzero, 4); ++#endif ++ ++ /* Short version. */ ++ if (len < 256) { ++ /* Calculate where in the constant table we need to start. */ ++ offset = 256 - len; ++ ++ vconst1 = vec_ld(offset, vcrc_short_const); ++ vdata0 = vec_ld(0, (__vector unsigned long long*) p); ++ VEC_PERM(vdata0, vdata0, vconst1, vperm_const); ++ ++ /* xor initial value*/ ++ vdata0 = vec_xor(vdata0, vcrc); ++ ++ vdata0 = (__vector unsigned long long) __builtin_crypto_vpmsumw ++ ((__vector unsigned int)vdata0, (__vector unsigned int)vconst1); ++ v0 = vec_xor(v0, vdata0); ++ ++ for (i = 16; i < len; i += 16) { ++ vconst1 = vec_ld(offset + i, vcrc_short_const); ++ vdata0 = vec_ld(i, (__vector unsigned long long*) p); ++ VEC_PERM(vdata0, vdata0, vconst1, vperm_const); ++ vdata0 = (__vector unsigned long long) __builtin_crypto_vpmsumw ++ ((__vector unsigned int)vdata0, (__vector unsigned int)vconst1); ++ v0 = vec_xor(v0, vdata0); ++ } ++ } else { ++ ++ /* Load initial values. */ ++ vdata0 = vec_ld(0, (__vector unsigned long long*) p); ++ vdata1 = vec_ld(16, (__vector unsigned long long*) p); ++ ++ VEC_PERM(vdata0, vdata0, vdata0, vperm_const); ++ VEC_PERM(vdata1, vdata1, vdata1, vperm_const); ++ ++ vdata2 = vec_ld(32, (__vector unsigned long long*) p); ++ vdata3 = vec_ld(48, (__vector unsigned long long*) p); ++ ++ VEC_PERM(vdata2, vdata2, vdata2, vperm_const); ++ VEC_PERM(vdata3, vdata3, vdata3, vperm_const); ++ ++ vdata4 = vec_ld(64, (__vector unsigned long long*) p); ++ vdata5 = vec_ld(80, (__vector unsigned long long*) p); ++ ++ VEC_PERM(vdata4, vdata4, vdata4, vperm_const); ++ VEC_PERM(vdata5, vdata5, vdata5, vperm_const); ++ ++ vdata6 = vec_ld(96, (__vector unsigned long long*) p); ++ vdata7 = vec_ld(112, (__vector unsigned long long*) p); ++ ++ VEC_PERM(vdata6, vdata6, vdata6, vperm_const); ++ VEC_PERM(vdata7, vdata7, vdata7, vperm_const); ++ ++ /* xor in initial value */ ++ vdata0 = vec_xor(vdata0, vcrc); ++ ++ p = (char *)p + 128; ++ ++ do { ++ /* Checksum in blocks of MAX_SIZE. */ ++ block_size = length; ++ if (block_size > MAX_SIZE) { ++ block_size = MAX_SIZE; ++ } ++ ++ length = length - block_size; ++ ++ /* ++ * Work out the offset into the constants table to start at. Each ++ * constant is 16 bytes, and it is used against 128 bytes of input ++ * data - 128 / 16 = 8 ++ */ ++ offset = (MAX_SIZE/8) - (block_size/8); ++ /* We reduce our final 128 bytes in a separate step */ ++ chunks = (block_size/128)-1; ++ ++ vconst1 = vec_ld(offset, vcrc_const); ++ ++ va0 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata0, ++ (__vector unsigned long long)vconst1); ++ va1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata1, ++ (__vector unsigned long long)vconst1); ++ va2 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata2, ++ (__vector unsigned long long)vconst1); ++ va3 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata3, ++ (__vector unsigned long long)vconst1); ++ va4 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata4, ++ (__vector unsigned long long)vconst1); ++ va5 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata5, ++ (__vector unsigned long long)vconst1); ++ va6 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata6, ++ (__vector unsigned long long)vconst1); ++ va7 = __builtin_crypto_vpmsumd ((__vector unsigned long long)vdata7, ++ (__vector unsigned long long)vconst1); ++ ++ if (chunks > 1) { ++ offset += 16; ++ vconst2 = vec_ld(offset, vcrc_const); ++ GROUP_ENDING_NOP; ++ ++ vdata0 = vec_ld(0, (__vector unsigned long long*) p); ++ VEC_PERM(vdata0, vdata0, vdata0, vperm_const); ++ ++ vdata1 = vec_ld(16, (__vector unsigned long long*) p); ++ VEC_PERM(vdata1, vdata1, vdata1, vperm_const); ++ ++ vdata2 = vec_ld(32, (__vector unsigned long long*) p); ++ VEC_PERM(vdata2, vdata2, vdata2, vperm_const); ++ ++ vdata3 = vec_ld(48, (__vector unsigned long long*) p); ++ VEC_PERM(vdata3, vdata3, vdata3, vperm_const); ++ ++ vdata4 = vec_ld(64, (__vector unsigned long long*) p); ++ VEC_PERM(vdata4, vdata4, vdata4, vperm_const); ++ ++ vdata5 = vec_ld(80, (__vector unsigned long long*) p); ++ VEC_PERM(vdata5, vdata5, vdata5, vperm_const); ++ ++ vdata6 = vec_ld(96, (__vector unsigned long long*) p); ++ VEC_PERM(vdata6, vdata6, vdata6, vperm_const); ++ ++ vdata7 = vec_ld(112, (__vector unsigned long long*) p); ++ VEC_PERM(vdata7, vdata7, vdata7, vperm_const); ++ ++ p = (char *)p + 128; ++ ++ /* ++ * main loop. We modulo schedule it such that it takes three ++ * iterations to complete - first iteration load, second ++ * iteration vpmsum, third iteration xor. ++ */ ++ for (i = 0; i < chunks-2; i++) { ++ vconst1 = vec_ld(offset, vcrc_const); ++ offset += 16; ++ GROUP_ENDING_NOP; ++ ++ v0 = vec_xor(v0, va0); ++ va0 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata0, (__vector unsigned long long)vconst2); ++ vdata0 = vec_ld(0, (__vector unsigned long long*) p); ++ VEC_PERM(vdata0, vdata0, vdata0, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v1 = vec_xor(v1, va1); ++ va1 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata1, (__vector unsigned long long)vconst2); ++ vdata1 = vec_ld(16, (__vector unsigned long long*) p); ++ VEC_PERM(vdata1, vdata1, vdata1, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v2 = vec_xor(v2, va2); ++ va2 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata2, (__vector unsigned long long)vconst2); ++ vdata2 = vec_ld(32, (__vector unsigned long long*) p); ++ VEC_PERM(vdata2, vdata2, vdata2, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v3 = vec_xor(v3, va3); ++ va3 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata3, (__vector unsigned long long)vconst2); ++ vdata3 = vec_ld(48, (__vector unsigned long long*) p); ++ VEC_PERM(vdata3, vdata3, vdata3, vperm_const); ++ ++ vconst2 = vec_ld(offset, vcrc_const); ++ GROUP_ENDING_NOP; ++ ++ v4 = vec_xor(v4, va4); ++ va4 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata4, (__vector unsigned long long)vconst1); ++ vdata4 = vec_ld(64, (__vector unsigned long long*) p); ++ VEC_PERM(vdata4, vdata4, vdata4, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v5 = vec_xor(v5, va5); ++ va5 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata5, (__vector unsigned long long)vconst1); ++ vdata5 = vec_ld(80, (__vector unsigned long long*) p); ++ VEC_PERM(vdata5, vdata5, vdata5, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v6 = vec_xor(v6, va6); ++ va6 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata6, (__vector unsigned long long)vconst1); ++ vdata6 = vec_ld(96, (__vector unsigned long long*) p); ++ VEC_PERM(vdata6, vdata6, vdata6, vperm_const); ++ GROUP_ENDING_NOP; ++ ++ v7 = vec_xor(v7, va7); ++ va7 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata7, (__vector unsigned long long)vconst1); ++ vdata7 = vec_ld(112, (__vector unsigned long long*) p); ++ VEC_PERM(vdata7, vdata7, vdata7, vperm_const); ++ ++ p = (char *)p + 128; ++ } ++ ++ /* First cool down*/ ++ vconst1 = vec_ld(offset, vcrc_const); ++ offset += 16; ++ ++ v0 = vec_xor(v0, va0); ++ va0 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata0, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v1 = vec_xor(v1, va1); ++ va1 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata1, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v2 = vec_xor(v2, va2); ++ va2 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata2, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v3 = vec_xor(v3, va3); ++ va3 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata3, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v4 = vec_xor(v4, va4); ++ va4 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata4, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v5 = vec_xor(v5, va5); ++ va5 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata5, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v6 = vec_xor(v6, va6); ++ va6 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata6, (__vector unsigned long long)vconst1); ++ GROUP_ENDING_NOP; ++ ++ v7 = vec_xor(v7, va7); ++ va7 = __builtin_crypto_vpmsumd ((__vector unsigned long ++ long)vdata7, (__vector unsigned long long)vconst1); ++ }/* else */ ++ ++ /* Second cool down. */ ++ v0 = vec_xor(v0, va0); ++ v1 = vec_xor(v1, va1); ++ v2 = vec_xor(v2, va2); ++ v3 = vec_xor(v3, va3); ++ v4 = vec_xor(v4, va4); ++ v5 = vec_xor(v5, va5); ++ v6 = vec_xor(v6, va6); ++ v7 = vec_xor(v7, va7); ++ ++#ifdef REFLECT ++ /* ++ * vpmsumd produces a 96 bit result in the least significant bits ++ * of the register. Since we are bit reflected we have to shift it ++ * left 32 bits so it occupies the least significant bits in the ++ * bit reflected domain. ++ */ ++ v0 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, ++ (__vector unsigned char)vzero, 4); ++ v1 = (__vector unsigned long long)vec_sld((__vector unsigned char)v1, ++ (__vector unsigned char)vzero, 4); ++ v2 = (__vector unsigned long long)vec_sld((__vector unsigned char)v2, ++ (__vector unsigned char)vzero, 4); ++ v3 = (__vector unsigned long long)vec_sld((__vector unsigned char)v3, ++ (__vector unsigned char)vzero, 4); ++ v4 = (__vector unsigned long long)vec_sld((__vector unsigned char)v4, ++ (__vector unsigned char)vzero, 4); ++ v5 = (__vector unsigned long long)vec_sld((__vector unsigned char)v5, ++ (__vector unsigned char)vzero, 4); ++ v6 = (__vector unsigned long long)vec_sld((__vector unsigned char)v6, ++ (__vector unsigned char)vzero, 4); ++ v7 = (__vector unsigned long long)vec_sld((__vector unsigned char)v7, ++ (__vector unsigned char)vzero, 4); ++#endif ++ ++ /* xor with the last 1024 bits. */ ++ va0 = vec_ld(0, (__vector unsigned long long*) p); ++ VEC_PERM(va0, va0, va0, vperm_const); ++ ++ va1 = vec_ld(16, (__vector unsigned long long*) p); ++ VEC_PERM(va1, va1, va1, vperm_const); ++ ++ va2 = vec_ld(32, (__vector unsigned long long*) p); ++ VEC_PERM(va2, va2, va2, vperm_const); ++ ++ va3 = vec_ld(48, (__vector unsigned long long*) p); ++ VEC_PERM(va3, va3, va3, vperm_const); ++ ++ va4 = vec_ld(64, (__vector unsigned long long*) p); ++ VEC_PERM(va4, va4, va4, vperm_const); ++ ++ va5 = vec_ld(80, (__vector unsigned long long*) p); ++ VEC_PERM(va5, va5, va5, vperm_const); ++ ++ va6 = vec_ld(96, (__vector unsigned long long*) p); ++ VEC_PERM(va6, va6, va6, vperm_const); ++ ++ va7 = vec_ld(112, (__vector unsigned long long*) p); ++ VEC_PERM(va7, va7, va7, vperm_const); ++ ++ p = (char *)p + 128; ++ ++ vdata0 = vec_xor(v0, va0); ++ vdata1 = vec_xor(v1, va1); ++ vdata2 = vec_xor(v2, va2); ++ vdata3 = vec_xor(v3, va3); ++ vdata4 = vec_xor(v4, va4); ++ vdata5 = vec_xor(v5, va5); ++ vdata6 = vec_xor(v6, va6); ++ vdata7 = vec_xor(v7, va7); ++ ++ /* Check if we have more blocks to process */ ++ next_block = 0; ++ if (length != 0) { ++ next_block = 1; ++ ++ /* zero v0-v7 */ ++ v0 = vec_xor(v0, v0); ++ v1 = vec_xor(v1, v1); ++ v2 = vec_xor(v2, v2); ++ v3 = vec_xor(v3, v3); ++ v4 = vec_xor(v4, v4); ++ v5 = vec_xor(v5, v5); ++ v6 = vec_xor(v6, v6); ++ v7 = vec_xor(v7, v7); ++ } ++ length = length + 128; ++ ++ } while (next_block); ++ ++ /* Calculate how many bytes we have left. */ ++ length = (len & 127); ++ ++ /* Calculate where in (short) constant table we need to start. */ ++ offset = 128 - length; ++ ++ v0 = vec_ld(offset, vcrc_short_const); ++ v1 = vec_ld(offset + 16, vcrc_short_const); ++ v2 = vec_ld(offset + 32, vcrc_short_const); ++ v3 = vec_ld(offset + 48, vcrc_short_const); ++ v4 = vec_ld(offset + 64, vcrc_short_const); ++ v5 = vec_ld(offset + 80, vcrc_short_const); ++ v6 = vec_ld(offset + 96, vcrc_short_const); ++ v7 = vec_ld(offset + 112, vcrc_short_const); ++ ++ offset += 128; ++ ++ v0 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata0,(__vector unsigned int)v0); ++ v1 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata1,(__vector unsigned int)v1); ++ v2 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata2,(__vector unsigned int)v2); ++ v3 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata3,(__vector unsigned int)v3); ++ v4 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata4,(__vector unsigned int)v4); ++ v5 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata5,(__vector unsigned int)v5); ++ v6 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata6,(__vector unsigned int)v6); ++ v7 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata7,(__vector unsigned int)v7); ++ ++ /* Now reduce the tail (0-112 bytes). */ ++ for (i = 0; i < length; i+=16) { ++ vdata0 = vec_ld(i,(__vector unsigned long long*)p); ++ VEC_PERM(vdata0, vdata0, vdata0, vperm_const); ++ va0 = vec_ld(offset + i,vcrc_short_const); ++ va0 = (__vector unsigned long long)__builtin_crypto_vpmsumw ( ++ (__vector unsigned int)vdata0,(__vector unsigned int)va0); ++ v0 = vec_xor(v0, va0); ++ } ++ ++ /* xor all parallel chunks together. */ ++ v0 = vec_xor(v0, v1); ++ v2 = vec_xor(v2, v3); ++ v4 = vec_xor(v4, v5); ++ v6 = vec_xor(v6, v7); ++ ++ v0 = vec_xor(v0, v2); ++ v4 = vec_xor(v4, v6); ++ ++ v0 = vec_xor(v0, v4); ++ } ++ ++ /* Barrett Reduction */ ++ vconst1 = vec_ld(0, v_Barrett_const); ++ vconst2 = vec_ld(16, v_Barrett_const); ++ ++ v1 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, ++ (__vector unsigned char)v0, 8); ++ v0 = vec_xor(v1,v0); ++ ++#ifdef REFLECT ++ /* shift left one bit */ ++ __vector unsigned char vsht_splat = vec_splat_u8 (1); ++ v0 = (__vector unsigned long long)vec_sll ((__vector unsigned char)v0, ++ vsht_splat); ++#endif ++ ++ v0 = vec_and(v0, vmask_64bit); ++ ++#ifndef REFLECT ++ ++ /* ++ * Now for the actual algorithm. The idea is to calculate q, ++ * the multiple of our polynomial that we need to subtract. By ++ * doing the computation 2x bits higher (ie 64 bits) and shifting the ++ * result back down 2x bits, we round down to the nearest multiple. ++ */ ++ ++ /* ma */ ++ v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v0, ++ (__vector unsigned long long)vconst1); ++ /* q = floor(ma/(2^64)) */ ++ v1 = (__vector unsigned long long)vec_sld ((__vector unsigned char)vzero, ++ (__vector unsigned char)v1, 8); ++ /* qn */ ++ v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, ++ (__vector unsigned long long)vconst2); ++ /* a - qn, subtraction is xor in GF(2) */ ++ v0 = vec_xor (v0, v1); ++ /* ++ * Get the result into r3. We need to shift it left 8 bytes: ++ * V0 [ 0 1 2 X ] ++ * V0 [ 0 X 2 3 ] ++ */ ++ result = __builtin_unpack_vector_1 (v0); ++#else ++ ++ /* ++ * The reflected version of Barrett reduction. Instead of bit ++ * reflecting our data (which is expensive to do), we bit reflect our ++ * constants and our algorithm, which means the intermediate data in ++ * our vector registers goes from 0-63 instead of 63-0. We can reflect ++ * the algorithm because we don't carry in mod 2 arithmetic. ++ */ ++ ++ /* bottom 32 bits of a */ ++ v1 = vec_and(v0, vmask_32bit); ++ ++ /* ma */ ++ v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, ++ (__vector unsigned long long)vconst1); ++ ++ /* bottom 32bits of ma */ ++ v1 = vec_and(v1, vmask_32bit); ++ /* qn */ ++ v1 = __builtin_crypto_vpmsumd ((__vector unsigned long long)v1, ++ (__vector unsigned long long)vconst2); ++ /* a - qn, subtraction is xor in GF(2) */ ++ v0 = vec_xor (v0, v1); ++ ++ /* ++ * Since we are bit reflected, the result (ie the low 32 bits) is in ++ * the high 32 bits. We just need to shift it left 4 bytes ++ * V0 [ 0 1 X 3 ] ++ * V0 [ 0 X 2 3 ] ++ */ ++ ++ /* shift result into top 64 bits of */ ++ v0 = (__vector unsigned long long)vec_sld((__vector unsigned char)v0, ++ (__vector unsigned char)vzero, 4); ++ ++ result = __builtin_unpack_vector_0 (v0); ++#endif ++ ++ return result; ++} +diff --git a/crc32.c b/crc32.c +index 9580440..406d350 100644 +--- a/crc32.c ++++ b/crc32.c +@@ -199,13 +199,78 @@ const z_crc_t FAR * ZEXPORT get_crc_table() + #define DO8 DO1; DO1; DO1; DO1; DO1; DO1; DO1; DO1 + + /* ========================================================================= */ +-unsigned long ZEXPORT crc32_z(crc, buf, len) ++local ++unsigned long ZEXPORT crc32_table_lookup(crc, buf, len) + unsigned long crc; + const unsigned char FAR *buf; + z_size_t len; + { + if (buf == Z_NULL) return 0UL; + ++ crc = crc ^ 0xffffffffUL; ++ while (len >= 8) { ++ DO8; ++ len -= 8; ++ } ++ if (len) do { ++ DO1; ++ } while (--len); ++ return crc ^ 0xffffffffUL; ++} ++ ++/* Small helper function to compare optfun against the reference table lookup ++ * return test_ref_comparision_##optfn in crc32_z_ifunc ++#include ++#define TEST_COMPARE(optfn) \ ++ static unsigned long test_ref_comparision_ ## optfn(unsigned long crc, const unsigned char FAR *p, z_size_t len) \ ++ { \ ++ unsigned long crc_tbl_lookup = crc32_table_lookup(crc, p, len); \ ++ unsigned long optcrc = optfn(crc, p, len); \ ++ assert( optcrc == crc_tbl_lookup ); \ ++ return optcrc; \ ++ } ++*/ ++ ++#ifdef Z_IFUNC_ASM ++unsigned long (*(crc32_z_ifunc(void)))(unsigned long, const unsigned char FAR *, z_size_t) ++ __asm__ ("crc32_z"); ++__asm__(".type crc32_z, %gnu_indirect_function"); ++#elif defined(Z_IFUNC_NATIVE) ++unsigned long ZEXPORT crc32_z( ++ unsigned long crc, ++ const unsigned char FAR *buf, ++ z_size_t len) ++ __attribute__ ((ifunc ("crc32_z_ifunc"))); ++#endif ++ ++#if _ARCH_PWR8==1 ++unsigned long crc32_vpmsum(unsigned long, const unsigned char FAR *, z_size_t); ++/* for testing TEST_COMPARE(crc32_vpmsum) */ ++#ifndef __BUILTIN_CPU_SUPPORTS__ ++#include ++#include ++#endif ++#endif ++ ++/* due to a quirk of gnu_indirect_function - "local" (aka static) is applied to ++ * crc32_z which is not desired. crc32_z_ifunc is implictly "local" */ ++#ifndef Z_IFUNC_ASM ++local ++#endif ++unsigned long (*(crc32_z_ifunc(void)))(unsigned long, const unsigned char FAR *, z_size_t) ++{ ++#if _ARCH_PWR8==1 ++#if defined(__BUILTIN_CPU_SUPPORTS__) ++ if (__builtin_cpu_supports("arch_2_07")) ++ return crc32_vpmsum; ++#else ++ if (getauxval(AT_HWCAP2) & PPC_FEATURE2_ARCH_2_07) ++ return crc32_vpmsum; ++#endif ++#endif /* _ARCH_PWR8 */ ++ ++/* return a function pointer for optimized arches here */ ++ + #ifdef DYNAMIC_CRC_TABLE + if (crc_table_empty) + make_crc_table(); +@@ -217,22 +282,31 @@ unsigned long ZEXPORT crc32_z(crc, buf, len) + + endian = 1; + if (*((unsigned char *)(&endian))) +- return crc32_little(crc, buf, len); ++ return crc32_little; + else +- return crc32_big(crc, buf, len); ++ return crc32_big; + } + #endif /* BYFOUR */ +- crc = crc ^ 0xffffffffUL; +- while (len >= 8) { +- DO8; +- len -= 8; +- } +- if (len) do { +- DO1; +- } while (--len); +- return crc ^ 0xffffffffUL; ++ ++ return crc32_table_lookup; + } + ++#if !defined(Z_IFUNC_ASM) && !defined(Z_IFUNC_NATIVE) ++ ++unsigned long ZEXPORT crc32_z(crc, buf, len) ++ unsigned long crc; ++ const unsigned char FAR *buf; ++ z_size_t len; ++{ ++ static unsigned long ZEXPORT (*crc32_func)(unsigned long, const unsigned char FAR *, z_size_t) = NULL; ++ ++ if (!crc32_func) ++ crc32_func = crc32_z_ifunc(); ++ return (*crc32_func)(crc, buf, len); ++} ++ ++#endif /* defined(Z_IFUNC_ASM) || defined(Z_IFUNC_NATIVE) */ ++ + /* ========================================================================= */ + unsigned long ZEXPORT crc32(crc, buf, len) + unsigned long crc; +@@ -271,6 +345,7 @@ local unsigned long crc32_little(crc, buf, len) + register z_crc_t c; + register const z_crc_t FAR *buf4; + ++ if (buf == Z_NULL) return 0UL; + c = (z_crc_t)crc; + c = ~c; + while (len && ((ptrdiff_t)buf & 3)) { +@@ -311,6 +386,7 @@ local unsigned long crc32_big(crc, buf, len) + register z_crc_t c; + register const z_crc_t FAR *buf4; + ++ if (buf == Z_NULL) return 0UL; + c = ZSWAP32((z_crc_t)crc); + c = ~c; + while (len && ((ptrdiff_t)buf & 3)) { +-- +2.19.1 + diff --git a/SPECS/zlib.spec b/SPECS/zlib.spec index e3fd67f..4884bd9 100644 --- a/SPECS/zlib.spec +++ b/SPECS/zlib.spec @@ -3,7 +3,7 @@ Name: zlib Version: 1.2.11 -Release: 10%{?dist} +Release: 13%{?dist} Summary: The compression and decompression library # /contrib/dotzlib/ have Boost license License: zlib and Boost @@ -14,6 +14,14 @@ Source: http://www.zlib.net/zlib-%{version}.tar.xz Patch0: zlib-1.2.5-minizip-fixuncrypt.patch # resolves: #805113 Patch1: zlib-1.2.11-optimized-s390.patch +# IBM Z optimalizations +Patch2: zlib-1.2.11-IBM-Z-hw-accelrated-deflate-s390x.patch +# IBM CRC32 optimalization for POWER archs +Patch3: zlib-1.2.11-optimized-CRC32-framework.patch +# fixed firefox crash + added test case +Patch4: zlib-1.2.11-firefox-crash-fix.patch +# fixed covscan issues +Patch5: zlib-1.2.11-covscan-issues.patch BuildRequires: automake, autoconf, libtool @@ -68,6 +76,10 @@ developing applications which use minizip. %ifarch s390 s390x %patch1 -p1 -b .optimized-deflate %endif +%patch2 -p1 +%patch3 -p1 +%patch4 -p1 +%patch5 -p1 iconv -f iso-8859-2 -t utf-8 < ChangeLog > ChangeLog.tmp mv ChangeLog.tmp ChangeLog @@ -78,10 +90,19 @@ export CFLAGS="$RPM_OPT_FLAGS" %ifarch ppc64 CFLAGS+=" -O3" %endif +%ifarch s390 s390x +CFLAGS+=" -DDFLTCC" +%endif + +export MKFLAGS="" +%ifarch s390 s390x +MKFLAGS+="OBJA=dfltcc.o PIC_OBJA=dfltcc.lo" +%endif + export LDFLAGS="$LDFLAGS -Wl,-z,relro -Wl,-z,now" # no-autotools, %%configure is not compatible ./configure --libdir=%{_libdir} --includedir=%{_includedir} --prefix=%{_prefix} -%make_build +%make_build $MKFLAGS %if %{with minizip} cd contrib/minizip @@ -142,6 +163,19 @@ find $RPM_BUILD_ROOT -name '*.la' -delete %changelog +* Tue Oct 29 2019 Ondrej Dubaj - 1.2.11-13 +- Added -DDFLTCC parameter to configure to enable +- Z hardware-accelerated deflate for s390x architectures + +* Tue Oct 15 2019 Ondrej Dubaj - 1.2.11-12 +- fixed covscan issues + +* Mon Oct 14 2019 Ondrej Dubaj - 1.2.11-11 +- IBM Z hardware-accelerated deflate for s390x architectures +- IBM CRC32 optimalization for POWER 8+ architectures +- fixed firefox crash due to zlib (#1741266) +- added test for crc32 + * Fri Aug 03 2018 Pavel Raiskup - 1.2.11-10 - sync with fedora rawhide