linuxdebug/tools/testing/selftests/powerpc/nx-gzip/gzfht_test.c

447 lines
12 KiB
C
Raw Permalink Normal View History

2024-07-16 15:50:57 +02:00
// SPDX-License-Identifier: GPL-2.0-or-later
/* P9 gzip sample code for demonstrating the P9 NX hardware interface.
* Not intended for productive uses or for performance or compression
* ratio measurements. For simplicity of demonstration, this sample
* code compresses in to fixed Huffman blocks only (Deflate btype=1)
* and has very simple memory management. Dynamic Huffman blocks
* (Deflate btype=2) are more involved as detailed in the user guide.
* Note also that /dev/crypto/gzip, VAS and skiboot support are
* required.
*
* Copyright 2020 IBM Corp.
*
* https://github.com/libnxz/power-gzip for zlib api and other utils
*
* Author: Bulent Abali <abali@us.ibm.com>
*
* Definitions of acronyms used here. See
* P9 NX Gzip Accelerator User's Manual for details:
* https://github.com/libnxz/power-gzip/blob/develop/doc/power_nx_gzip_um.pdf
*
* adler/crc: 32 bit checksums appended to stream tail
* ce: completion extension
* cpb: coprocessor parameter block (metadata)
* crb: coprocessor request block (command)
* csb: coprocessor status block (status)
* dht: dynamic huffman table
* dde: data descriptor element (address, length)
* ddl: list of ddes
* dh/fh: dynamic and fixed huffman types
* fc: coprocessor function code
* histlen: history/dictionary length
* history: sliding window of up to 32KB of data
* lzcount: Deflate LZ symbol counts
* rembytecnt: remaining byte count
* sfbt: source final block type; last block's type during decomp
* spbc: source processed byte count
* subc: source unprocessed bit count
* tebc: target ending bit count; valid bits in the last byte
* tpbc: target processed byte count
* vas: virtual accelerator switch; the user mode interface
*/
#define _ISOC11_SOURCE // For aligned_alloc()
#define _DEFAULT_SOURCE // For endian.h
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <stdint.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <sys/fcntl.h>
#include <sys/mman.h>
#include <endian.h>
#include <bits/endian.h>
#include <sys/ioctl.h>
#include <assert.h>
#include <errno.h>
#include <signal.h>
#include "utils.h"
#include "nxu.h"
#include "nx.h"
int nx_dbg;
FILE *nx_gzip_log;
#define NX_MIN(X, Y) (((X) < (Y)) ? (X) : (Y))
#define FNAME_MAX 1024
#define FEXT ".nx.gz"
#define SYSFS_MAX_REQ_BUF_PATH "devices/vio/ibm,compression-v1/nx_gzip_caps/req_max_processed_len"
/*
* LZ counts returned in the user supplied nx_gzip_crb_cpb_t structure.
*/
static int compress_fht_sample(char *src, uint32_t srclen, char *dst,
uint32_t dstlen, int with_count,
struct nx_gzip_crb_cpb_t *cmdp, void *handle)
{
uint32_t fc;
assert(!!cmdp);
put32(cmdp->crb, gzip_fc, 0); /* clear */
fc = (with_count) ? GZIP_FC_COMPRESS_RESUME_FHT_COUNT :
GZIP_FC_COMPRESS_RESUME_FHT;
putnn(cmdp->crb, gzip_fc, fc);
putnn(cmdp->cpb, in_histlen, 0); /* resuming with no history */
memset((void *) &cmdp->crb.csb, 0, sizeof(cmdp->crb.csb));
/* Section 6.6 programming notes; spbc may be in two different
* places depending on FC.
*/
if (!with_count)
put32(cmdp->cpb, out_spbc_comp, 0);
else
put32(cmdp->cpb, out_spbc_comp_with_count, 0);
/* Figure 6-3 6-4; CSB location */
put64(cmdp->crb, csb_address, 0);
put64(cmdp->crb, csb_address,
(uint64_t) &cmdp->crb.csb & csb_address_mask);
/* Source direct dde (scatter-gather list) */
clear_dde(cmdp->crb.source_dde);
putnn(cmdp->crb.source_dde, dde_count, 0);
put32(cmdp->crb.source_dde, ddebc, srclen);
put64(cmdp->crb.source_dde, ddead, (uint64_t) src);
/* Target direct dde (scatter-gather list) */
clear_dde(cmdp->crb.target_dde);
putnn(cmdp->crb.target_dde, dde_count, 0);
put32(cmdp->crb.target_dde, ddebc, dstlen);
put64(cmdp->crb.target_dde, ddead, (uint64_t) dst);
/* Submit the crb, the job descriptor, to the accelerator */
return nxu_submit_job(cmdp, handle);
}
/*
* Prepares a blank no filename no timestamp gzip header and returns
* the number of bytes written to buf.
* Gzip specification at https://tools.ietf.org/html/rfc1952
*/
int gzip_header_blank(char *buf)
{
int i = 0;
buf[i++] = 0x1f; /* ID1 */
buf[i++] = 0x8b; /* ID2 */
buf[i++] = 0x08; /* CM */
buf[i++] = 0x00; /* FLG */
buf[i++] = 0x00; /* MTIME */
buf[i++] = 0x00; /* MTIME */
buf[i++] = 0x00; /* MTIME */
buf[i++] = 0x00; /* MTIME */
buf[i++] = 0x04; /* XFL 4=fastest */
buf[i++] = 0x03; /* OS UNIX */
return i;
}
/* Caller must free the allocated buffer return nonzero on error. */
int read_alloc_input_file(char *fname, char **buf, size_t *bufsize)
{
struct stat statbuf;
FILE *fp;
char *p;
size_t num_bytes;
if (stat(fname, &statbuf)) {
perror(fname);
return(-1);
}
fp = fopen(fname, "r");
if (fp == NULL) {
perror(fname);
return(-1);
}
assert(NULL != (p = (char *) malloc(statbuf.st_size)));
num_bytes = fread(p, 1, statbuf.st_size, fp);
if (ferror(fp) || (num_bytes != statbuf.st_size)) {
perror(fname);
return(-1);
}
*buf = p;
*bufsize = num_bytes;
return 0;
}
/* Returns nonzero on error */
int write_output_file(char *fname, char *buf, size_t bufsize)
{
FILE *fp;
size_t num_bytes;
fp = fopen(fname, "w");
if (fp == NULL) {
perror(fname);
return(-1);
}
num_bytes = fwrite(buf, 1, bufsize, fp);
if (ferror(fp) || (num_bytes != bufsize)) {
perror(fname);
return(-1);
}
fclose(fp);
return 0;
}
/*
* Z_SYNC_FLUSH as described in zlib.h.
* Returns number of appended bytes
*/
int append_sync_flush(char *buf, int tebc, int final)
{
uint64_t flush;
int shift = (tebc & 0x7);
if (tebc > 0) {
/* Last byte is partially full */
buf = buf - 1;
*buf = *buf & (unsigned char) ((1<<tebc)-1);
} else
*buf = 0;
flush = ((0x1ULL & final) << shift) | *buf;
shift = shift + 3; /* BFINAL and BTYPE written */
shift = (shift <= 8) ? 8 : 16;
flush |= (0xFFFF0000ULL) << shift; /* Zero length block */
shift = shift + 32;
while (shift > 0) {
*buf++ = (unsigned char) (flush & 0xffULL);
flush = flush >> 8;
shift = shift - 8;
}
return(((tebc > 5) || (tebc == 0)) ? 5 : 4);
}
/*
* Final deflate block bit. This call assumes the block
* beginning is byte aligned.
*/
static void set_bfinal(void *buf, int bfinal)
{
char *b = buf;
if (bfinal)
*b = *b | (unsigned char) 0x01;
else
*b = *b & (unsigned char) 0xfe;
}
int compress_file(int argc, char **argv, void *handle)
{
char *inbuf, *outbuf, *srcbuf, *dstbuf;
char outname[FNAME_MAX];
uint32_t srclen, dstlen;
uint32_t flushlen, chunk;
size_t inlen, outlen, dsttotlen, srctotlen;
uint32_t crc, spbc, tpbc, tebc;
int lzcounts = 0;
int cc;
int num_hdr_bytes;
struct nx_gzip_crb_cpb_t *cmdp;
uint32_t pagelen = 65536;
int fault_tries = NX_MAX_FAULTS;
char buf[32];
cmdp = (void *)(uintptr_t)
aligned_alloc(sizeof(struct nx_gzip_crb_cpb_t),
sizeof(struct nx_gzip_crb_cpb_t));
if (argc != 2) {
fprintf(stderr, "usage: %s <fname>\n", argv[0]);
exit(-1);
}
if (read_alloc_input_file(argv[1], &inbuf, &inlen))
exit(-1);
fprintf(stderr, "file %s read, %ld bytes\n", argv[1], inlen);
/* Generous output buffer for header/trailer */
outlen = 2 * inlen + 1024;
assert(NULL != (outbuf = (char *)malloc(outlen)));
nxu_touch_pages(outbuf, outlen, pagelen, 1);
/*
* On PowerVM, the hypervisor defines the maximum request buffer
* size is defined and this value is available via sysfs.
*/
if (!read_sysfs_file(SYSFS_MAX_REQ_BUF_PATH, buf, sizeof(buf))) {
chunk = atoi(buf);
} else {
/* sysfs entry is not available on PowerNV */
/* Compress piecemeal in smallish chunks */
chunk = 1<<22;
}
/* Write the gzip header to the stream */
num_hdr_bytes = gzip_header_blank(outbuf);
dstbuf = outbuf + num_hdr_bytes;
outlen = outlen - num_hdr_bytes;
dsttotlen = num_hdr_bytes;
srcbuf = inbuf;
srctotlen = 0;
/* Init the CRB, the coprocessor request block */
memset(&cmdp->crb, 0, sizeof(cmdp->crb));
/* Initial gzip crc32 */
put32(cmdp->cpb, in_crc, 0);
while (inlen > 0) {
/* Submit chunk size source data per job */
srclen = NX_MIN(chunk, inlen);
/* Supply large target in case data expands */
dstlen = NX_MIN(2*srclen, outlen);
/* Page faults are handled by the user code */
/* Fault-in pages; an improved code wouldn't touch so
* many pages but would try to estimate the
* compression ratio and adjust both the src and dst
* touch amounts.
*/
nxu_touch_pages(cmdp, sizeof(struct nx_gzip_crb_cpb_t), pagelen,
1);
nxu_touch_pages(srcbuf, srclen, pagelen, 0);
nxu_touch_pages(dstbuf, dstlen, pagelen, 1);
cc = compress_fht_sample(
srcbuf, srclen,
dstbuf, dstlen,
lzcounts, cmdp, handle);
if (cc != ERR_NX_OK && cc != ERR_NX_TPBC_GT_SPBC &&
cc != ERR_NX_AT_FAULT) {
fprintf(stderr, "nx error: cc= %d\n", cc);
exit(-1);
}
/* Page faults are handled by the user code */
if (cc == ERR_NX_AT_FAULT) {
NXPRT(fprintf(stderr, "page fault: cc= %d, ", cc));
NXPRT(fprintf(stderr, "try= %d, fsa= %08llx\n",
fault_tries,
(unsigned long long) cmdp->crb.csb.fsaddr));
fault_tries--;
if (fault_tries > 0) {
continue;
} else {
fprintf(stderr, "error: cannot progress; ");
fprintf(stderr, "too many faults\n");
exit(-1);
}
}
fault_tries = NX_MAX_FAULTS; /* Reset for the next chunk */
inlen = inlen - srclen;
srcbuf = srcbuf + srclen;
srctotlen = srctotlen + srclen;
/* Two possible locations for spbc depending on the function
* code.
*/
spbc = (!lzcounts) ? get32(cmdp->cpb, out_spbc_comp) :
get32(cmdp->cpb, out_spbc_comp_with_count);
assert(spbc == srclen);
/* Target byte count */
tpbc = get32(cmdp->crb.csb, tpbc);
/* Target ending bit count */
tebc = getnn(cmdp->cpb, out_tebc);
NXPRT(fprintf(stderr, "compressed chunk %d ", spbc));
NXPRT(fprintf(stderr, "to %d bytes, tebc= %d\n", tpbc, tebc));
if (inlen > 0) { /* More chunks to go */
set_bfinal(dstbuf, 0);
dstbuf = dstbuf + tpbc;
dsttotlen = dsttotlen + tpbc;
outlen = outlen - tpbc;
/* Round up to the next byte with a flush
* block; do not set the BFINAqL bit.
*/
flushlen = append_sync_flush(dstbuf, tebc, 0);
dsttotlen = dsttotlen + flushlen;
outlen = outlen - flushlen;
dstbuf = dstbuf + flushlen;
NXPRT(fprintf(stderr, "added sync_flush %d bytes\n",
flushlen));
} else { /* Done */
/* Set the BFINAL bit of the last block per Deflate
* specification.
*/
set_bfinal(dstbuf, 1);
dstbuf = dstbuf + tpbc;
dsttotlen = dsttotlen + tpbc;
outlen = outlen - tpbc;
}
/* Resuming crc32 for the next chunk */
crc = get32(cmdp->cpb, out_crc);
put32(cmdp->cpb, in_crc, crc);
crc = be32toh(crc);
}
/* Append crc32 and ISIZE to the end */
memcpy(dstbuf, &crc, 4);
memcpy(dstbuf+4, &srctotlen, 4);
dsttotlen = dsttotlen + 8;
outlen = outlen - 8;
assert(FNAME_MAX > (strlen(argv[1]) + strlen(FEXT)));
strcpy(outname, argv[1]);
strcat(outname, FEXT);
if (write_output_file(outname, outbuf, dsttotlen)) {
fprintf(stderr, "write error: %s\n", outname);
exit(-1);
}
fprintf(stderr, "compressed %ld to %ld bytes total, ", srctotlen,
dsttotlen);
fprintf(stderr, "crc32 checksum = %08x\n", crc);
if (inbuf != NULL)
free(inbuf);
if (outbuf != NULL)
free(outbuf);
return 0;
}
int main(int argc, char **argv)
{
int rc;
struct sigaction act;
void *handle;
nx_dbg = 0;
nx_gzip_log = NULL;
act.sa_handler = 0;
act.sa_sigaction = nxu_sigsegv_handler;
act.sa_flags = SA_SIGINFO;
act.sa_restorer = 0;
sigemptyset(&act.sa_mask);
sigaction(SIGSEGV, &act, NULL);
handle = nx_function_begin(NX_FUNC_COMP_GZIP, 0);
if (!handle) {
fprintf(stderr, "Unable to init NX, errno %d\n", errno);
exit(-1);
}
rc = compress_file(argc, argv, handle);
nx_function_end(handle);
return rc;
}