[dpdk-dev] [PATCH 2/3] app/compress-perf: add performance measurement
Verma, Shally
Shally.Verma at cavium.com
Fri Oct 12 12:15:58 CEST 2018
HI TomaszX
Sorry for delay in response. Comments inline.
>-----Original Message-----
>From: dev <dev-bounces at dpdk.org> On Behalf Of Tomasz Jozwiak
>Sent: 01 October 2018 18:57
>To: dev at dpdk.org; fiona.trahe at intel.com; tomaszx.jozwiak at intel.com; akhil.goyal at nxp.com; pablo.de.lara.guarch at intel.com
>Cc: De at dpdk.org; Lara at dpdk.org; Guarch at dpdk.org
>Subject: [dpdk-dev] [PATCH 2/3] app/compress-perf: add performance measurement
>
>External Email
>
>Added performance measurement part into compression perf. test.
>
>Signed-off-by: De Lara Guarch, Pablo <pablo.de.lara.guarch at intel.com>
>Signed-off-by: Tomasz Jozwiak <tomaszx.jozwiak at intel.com>
>---
> app/test-compress-perf/main.c | 844 ++++++++++++++++++++++++++++++++++++++++++
> 1 file changed, 844 insertions(+)
>
>diff --git a/app/test-compress-perf/main.c b/app/test-compress-perf/main.c
>index f52b98d..093dfaf 100644
>--- a/app/test-compress-perf/main.c
>+++ b/app/test-compress-perf/main.c
>@@ -5,13 +5,721 @@
> #include <rte_malloc.h>
> #include <rte_eal.h>
> #include <rte_log.h>
>+#include <rte_cycles.h>
> #include <rte_compressdev.h>
>
> #include "comp_perf_options.h"
>
>+#define NUM_MAX_XFORMS 16
>+#define NUM_MAX_INFLIGHT_OPS 512
>+#define EXPANSE_RATIO 1.05
>+#define MIN_ISAL_SIZE 8
>+
>+#define DIV_CEIL(a, b) ((a) / (b) + ((a) % (b) != 0))
>+
>+static int
>+param_range_check(uint16_t size, const struct rte_param_log2_range *range)
>+{
>+ unsigned int next_size;
>+
>+ /* Check lower/upper bounds */
>+ if (size < range->min)
>+ return -1;
>+
>+ if (size > range->max)
>+ return -1;
>+
>+ /* If range is actually only one value, size is correct */
>+ if (range->increment == 0)
>+ return 0;
>+
>+ /* Check if value is one of the supported sizes */
>+ for (next_size = range->min; next_size <= range->max;
>+ next_size += range->increment)
>+ if (size == next_size)
>+ return 0;
>+
>+ return -1;
>+}
>+
>+static int
>+comp_perf_check_capabilities(struct comp_test_data *test_data)
>+{
>+ const struct rte_compressdev_capabilities *cap;
>+
>+ cap = rte_compressdev_capability_get(test_data->cdev_id,
>+ RTE_COMP_ALGO_DEFLATE);
>+
>+ if (cap == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Compress device does not support DEFLATE\n");
>+ return -1;
>+ }
>+
>+ uint64_t comp_flags = cap->comp_feature_flags;
>+
>+ /* Huffman enconding */
>+ if (test_data->huffman_enc == RTE_COMP_HUFFMAN_FIXED &&
>+ (comp_flags & RTE_COMP_FF_HUFFMAN_FIXED) == 0) {
>+ RTE_LOG(ERR, USER1,
>+ "Compress device does not supported Fixed Huffman\n");
>+ return -1;
>+ }
>+
>+ if (test_data->huffman_enc == RTE_COMP_HUFFMAN_DYNAMIC &&
>+ (comp_flags & RTE_COMP_FF_HUFFMAN_DYNAMIC) == 0) {
>+ RTE_LOG(ERR, USER1,
>+ "Compress device does not supported Dynamic Huffman\n");
>+ return -1;
>+ }
>+
>+ /* Window size */
>+ if (test_data->window_sz != -1) {
>+ if (param_range_check(test_data->window_sz, &cap->window_size)
What if cap->window_size is 0 i.e. implementation default?
>+ < 0) {
>+ RTE_LOG(ERR, USER1,
>+ "Compress device does not support "
>+ "this window size\n");
>+ return -1;
>+ }
>+ } else
>+ /* Set window size to PMD maximum if none was specified */
>+ test_data->window_sz = cap->window_size.max;
>+
>+ /* Check if chained mbufs is supported */
>+ if (test_data->max_sgl_segs > 1 &&
>+ (comp_flags & RTE_COMP_FF_OOP_SGL_IN_SGL_OUT) == 0) {
>+ RTE_LOG(INFO, USER1, "Compress device does not support "
>+ "chained mbufs. Max SGL segments set to 1\n");
>+ test_data->max_sgl_segs = 1;
>+ }
>+
>+ /* Level 0 support */
>+ if (test_data->level.min == 0 &&
>+ (comp_flags & RTE_COMP_FF_NONCOMPRESSED_BLOCKS) == 0) {
>+ RTE_LOG(ERR, USER1, "Compress device does not support "
>+ "level 0 (no compression)\n");
>+ return -1;
>+ }
>+
>+ return 0;
>+}
>+
>+static int
>+comp_perf_allocate_memory(struct comp_test_data *test_data)
>+{
>+ /* Number of segments for input and output
>+ * (compression and decompression)
>+ */
>+ uint32_t total_segs = DIV_CEIL(test_data->input_data_sz,
>+ test_data->seg_sz);
>+ test_data->comp_buf_pool = rte_pktmbuf_pool_create("comp_buf_pool",
>+ total_segs,
>+ 0, 0, test_data->seg_sz + RTE_PKTMBUF_HEADROOM,
>+ rte_socket_id());
>+ if (test_data->comp_buf_pool == NULL) {
>+ RTE_LOG(ERR, USER1, "Mbuf mempool could not be created\n");
>+ return -1;
>+ }
>+
>+ test_data->decomp_buf_pool = rte_pktmbuf_pool_create("decomp_buf_pool",
>+ total_segs,
>+ 0, 0, test_data->seg_sz + RTE_PKTMBUF_HEADROOM,
>+ rte_socket_id());
>+ if (test_data->decomp_buf_pool == NULL) {
>+ RTE_LOG(ERR, USER1, "Mbuf mempool could not be created\n");
>+ return -1;
>+ }
>+
>+ test_data->total_bufs = DIV_CEIL(total_segs, test_data->max_sgl_segs);
>+
>+ test_data->op_pool = rte_comp_op_pool_create("op_pool",
>+ test_data->total_bufs,
>+ 0, 0, rte_socket_id());
>+ if (test_data->op_pool == NULL) {
>+ RTE_LOG(ERR, USER1, "Comp op mempool could not be created\n");
>+ return -1;
>+ }
>+
>+ /*
>+ * Compressed data might be a bit larger than input data,
>+ * if data cannot be compressed
Possible only if it's zlib format right? Or deflate as well?
>+ */
>+ test_data->compressed_data = rte_zmalloc_socket(NULL,
>+ test_data->input_data_sz * EXPANSE_RATIO
>+ + MIN_ISAL_SIZE, 0,
>+ rte_socket_id());
>+ if (test_data->compressed_data == NULL) {
>+ RTE_LOG(ERR, USER1, "Memory to hold the data from the input "
>+ "file could not be allocated\n");
>+ return -1;
>+ }
>+
>+ test_data->decompressed_data = rte_zmalloc_socket(NULL,
>+ test_data->input_data_sz, 0,
>+ rte_socket_id());
>+ if (test_data->decompressed_data == NULL) {
>+ RTE_LOG(ERR, USER1, "Memory to hold the data from the input "
>+ "file could not be allocated\n");
>+ return -1;
>+ }
>+
>+ test_data->comp_bufs = rte_zmalloc_socket(NULL,
>+ test_data->total_bufs * sizeof(struct rte_mbuf *),
>+ 0, rte_socket_id());
>+ if (test_data->comp_bufs == NULL) {
>+ RTE_LOG(ERR, USER1, "Memory to hold the compression mbufs"
>+ " could not be allocated\n");
>+ return -1;
>+ }
>+
>+ test_data->decomp_bufs = rte_zmalloc_socket(NULL,
>+ test_data->total_bufs * sizeof(struct rte_mbuf *),
>+ 0, rte_socket_id());
>+ if (test_data->decomp_bufs == NULL) {
>+ RTE_LOG(ERR, USER1, "Memory to hold the decompression mbufs"
>+ " could not be allocated\n");
>+ return -1;
>+ }
>+ return 0;
>+}
>+
>+static int
>+comp_perf_dump_input_data(struct comp_test_data *test_data)
>+{
>+ FILE *f = fopen(test_data->input_file, "r");
>+
>+ if (f == NULL) {
>+ RTE_LOG(ERR, USER1, "Input file could not be opened\n");
>+ return -1;
>+ }
>+
>+ if (fseek(f, 0, SEEK_END) != 0) {
>+ RTE_LOG(ERR, USER1, "Size of input could not be calculated\n");
>+ goto err;
>+ }
>+ size_t actual_file_sz = ftell(f);
>+ /* If extended input data size has not been set,
>+ * input data size = file size
>+ */
>+
>+ if (test_data->input_data_sz == 0)
>+ test_data->input_data_sz = actual_file_sz;
>+
>+ if (fseek(f, 0, SEEK_SET) != 0) {
>+ RTE_LOG(ERR, USER1, "Size of input could not be calculated\n");
>+ goto err;
>+ }
>+
>+ test_data->input_data = rte_zmalloc_socket(NULL,
>+ test_data->input_data_sz, 0, rte_socket_id());
>+
>+ if (test_data->input_data == NULL) {
>+ RTE_LOG(ERR, USER1, "Memory to hold the data from the input "
>+ "file could not be allocated\n");
>+ goto err;
>+ }
>+
>+ size_t remaining_data = test_data->input_data_sz;
>+ uint8_t *data = test_data->input_data;
>+
>+ while (remaining_data > 0) {
>+ size_t data_to_read = RTE_MIN(remaining_data, actual_file_sz);
>+
>+ if (fread(data, data_to_read, 1, f) != 1) {
>+ RTE_LOG(ERR, USER1, "Input file could not be read\n");
>+ goto err;
>+ }
>+ if (fseek(f, 0, SEEK_SET) != 0) {
>+ RTE_LOG(ERR, USER1,
>+ "Size of input could not be calculated\n");
>+ goto err;
>+ }
>+ remaining_data -= data_to_read;
>+ data += data_to_read;
It looks like it will run 2nd time only if input file size < input data size in which case it will just keep filling input buffer with repeated data.
Is that the intention here?
>+ }
>+
>+ if (test_data->input_data_sz > actual_file_sz)
>+ RTE_LOG(INFO, USER1,
>+ "%zu bytes read from file %s, extending the file %.2f times\n",
>+ test_data->input_data_sz, test_data->input_file,
>+ (double)test_data->input_data_sz/actual_file_sz);
>+ else
>+ RTE_LOG(INFO, USER1,
>+ "%zu bytes read from file %s\n",
>+ test_data->input_data_sz, test_data->input_file);
>+
>+ fclose(f);
>+
>+ return 0;
>+
>+err:
>+ fclose(f);
>+ rte_free(test_data->input_data);
>+ test_data->input_data = NULL;
>+
>+ return -1;
>+}
>+
>+static int
>+comp_perf_initialize_compressdev(struct comp_test_data *test_data)
>+{
>+ uint8_t enabled_cdev_count;
>+ uint8_t enabled_cdevs[RTE_COMPRESS_MAX_DEVS];
>+
>+ enabled_cdev_count = rte_compressdev_devices_get(test_data->driver_name,
>+ enabled_cdevs, RTE_COMPRESS_MAX_DEVS);
>+ if (enabled_cdev_count == 0) {
>+ RTE_LOG(ERR, USER1, "No compress devices type %s available\n",
>+ test_data->driver_name);
>+ return -EINVAL;
>+ }
>+
>+ if (enabled_cdev_count > 1)
>+ RTE_LOG(INFO, USER1,
>+ "Only the first compress device will be used\n");
>+
>+ test_data->cdev_id = enabled_cdevs[0];
>+
>+ if (comp_perf_check_capabilities(test_data) < 0)
>+ return -1;
>+
>+ /* Configure compressdev (one device, one queue pair) */
>+ struct rte_compressdev_config config = {
>+ .socket_id = rte_socket_id(),
>+ .nb_queue_pairs = 1,
>+ .max_nb_priv_xforms = NUM_MAX_XFORMS,
>+ .max_nb_streams = 0
>+ };
>+
>+ if (rte_compressdev_configure(test_data->cdev_id, &config) < 0) {
>+ RTE_LOG(ERR, USER1, "Device configuration failed\n");
>+ return -1;
>+ }
>+
>+ if (rte_compressdev_queue_pair_setup(test_data->cdev_id, 0,
>+ NUM_MAX_INFLIGHT_OPS, rte_socket_id()) < 0) {
>+ RTE_LOG(ERR, USER1, "Queue pair setup failed\n");
>+ return -1;
>+ }
>+
>+ if (rte_compressdev_start(test_data->cdev_id) < 0) {
>+ RTE_LOG(ERR, USER1, "Device could not be started\n");
>+ return -1;
>+ }
>+
>+ return 0;
>+}
>+
>+static int
>+prepare_bufs(struct comp_test_data *test_data)
>+{
>+ uint32_t remaining_data = test_data->input_data_sz;
>+ uint8_t *input_data_ptr = test_data->input_data;
>+ size_t data_sz;
>+ uint8_t *data_addr;
>+ uint32_t i, j;
>+
>+ for (i = 0; i < test_data->total_bufs; i++) {
>+ /* Allocate data in input mbuf and copy data from input file */
>+ test_data->decomp_bufs[i] =
>+ rte_pktmbuf_alloc(test_data->decomp_buf_pool);
>+ if (test_data->decomp_bufs[i] == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not allocate mbuf\n");
>+ return -1;
>+ }
>+
>+ data_sz = RTE_MIN(remaining_data, test_data->seg_sz);
>+ data_addr = (uint8_t *) rte_pktmbuf_append(
>+ test_data->decomp_bufs[i], data_sz);
>+ if (data_addr == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not append data\n");
>+ return -1;
>+ }
>+ rte_memcpy(data_addr, input_data_ptr, data_sz);
>+
>+ input_data_ptr += data_sz;
>+ remaining_data -= data_sz;
>+
>+ /* Already one segment in the mbuf */
>+ uint16_t segs_per_mbuf = 1;
>+
>+ /* Chain mbufs if needed for input mbufs */
>+ while (segs_per_mbuf < test_data->max_sgl_segs
>+ && remaining_data > 0) {
>+ struct rte_mbuf *next_seg =
>+ rte_pktmbuf_alloc(test_data->decomp_buf_pool);
>+
>+ if (next_seg == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Could not allocate mbuf\n");
>+ return -1;
>+ }
>+
>+ data_sz = RTE_MIN(remaining_data, test_data->seg_sz);
>+ data_addr = (uint8_t *)rte_pktmbuf_append(next_seg,
>+ data_sz);
>+
>+ if (data_addr == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not append data\n");
Since a new buffer per segment is allocated, so is it possible for append to fail? think, this check is redundant here.
>+ return -1;
>+ }
>+
>+ rte_memcpy(data_addr, input_data_ptr, data_sz);
>+ input_data_ptr += data_sz;
>+ remaining_data -= data_sz;
>+
>+ if (rte_pktmbuf_chain(test_data->decomp_bufs[i],
>+ next_seg) < 0) {
>+ RTE_LOG(ERR, USER1, "Could not chain mbufs\n");
>+ return -1;
>+ }
>+ segs_per_mbuf++;
>+ }
>+
>+ /* Allocate data in output mbuf */
>+ test_data->comp_bufs[i] =
>+ rte_pktmbuf_alloc(test_data->comp_buf_pool);
>+ if (test_data->comp_bufs[i] == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not allocate mbuf\n");
>+ return -1;
>+ }
>+ data_addr = (uint8_t *) rte_pktmbuf_append(
>+ test_data->comp_bufs[i],
>+ test_data->seg_sz);
>+ if (data_addr == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not append data\n");
>+ return -1;
>+ }
>+
>+ /* Chain mbufs if needed for output mbufs */
>+ for (j = 1; j < segs_per_mbuf; j++) {
>+ struct rte_mbuf *next_seg =
>+ rte_pktmbuf_alloc(test_data->comp_buf_pool);
>+
>+ if (next_seg == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Could not allocate mbuf\n");
>+ return -1;
>+ }
>+
>+ data_addr = (uint8_t *)rte_pktmbuf_append(next_seg,
>+ test_data->seg_sz);
>+
>+ if (data_addr == NULL) {
>+ RTE_LOG(ERR, USER1, "Could not append data\n");
>+ return -1;
>+ }
>+
>+ if (rte_pktmbuf_chain(test_data->comp_bufs[i],
>+ next_seg) < 0) {
>+ RTE_LOG(ERR, USER1, "Could not chain mbufs\n");
>+ return -1;
>+ }
>+ }
>+ }
>+
>+ return 0;
>+}
>+
>+static void
>+free_bufs(struct comp_test_data *test_data)
>+{
>+ uint32_t i;
>+
>+ for (i = 0; i < test_data->total_bufs; i++) {
>+ rte_pktmbuf_free(test_data->comp_bufs[i]);
>+ rte_pktmbuf_free(test_data->decomp_bufs[i]);
>+ }
>+ rte_free(test_data->comp_bufs);
>+ rte_free(test_data->decomp_bufs);
>+}
>+
>+static int
>+main_loop(struct comp_test_data *test_data, uint8_t level,
>+ enum rte_comp_xform_type type,
>+ uint8_t *output_data_ptr,
>+ size_t *output_data_sz,
>+ unsigned int benchmarking)
>+{
>+ uint8_t dev_id = test_data->cdev_id;
>+ uint32_t i, iter, num_iter;
>+ struct rte_comp_op **ops, **deq_ops;
>+ void *priv_xform = NULL;
>+ struct rte_comp_xform xform;
>+ size_t output_size = 0;
>+ struct rte_mbuf **input_bufs, **output_bufs;
>+ int res = 0;
>+ int allocated = 0;
>+
>+ if (test_data == NULL || !test_data->burst_sz) {
>+ RTE_LOG(ERR, USER1,
>+ "Unknow burst size\n");
>+ return -1;
>+ }
>+
>+ ops = rte_zmalloc_socket(NULL,
>+ 2 * test_data->total_bufs * sizeof(struct rte_comp_op *),
>+ 0, rte_socket_id());
>+
>+ if (ops == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Can't allocate memory for ops strucures\n");
>+ return -1;
>+ }
>+
>+ deq_ops = &ops[test_data->total_bufs];
>+
>+ if (type == RTE_COMP_COMPRESS) {
>+ xform = (struct rte_comp_xform) {
>+ .type = RTE_COMP_COMPRESS,
>+ .compress = {
>+ .algo = RTE_COMP_ALGO_DEFLATE,
>+ .deflate.huffman = test_data->huffman_enc,
>+ .level = level,
>+ .window_size = test_data->window_sz,
>+ .chksum = RTE_COMP_CHECKSUM_NONE,
>+ .hash_algo = RTE_COMP_HASH_ALGO_NONE
>+ }
>+ };
>+ input_bufs = test_data->decomp_bufs;
>+ output_bufs = test_data->comp_bufs;
>+ } else {
>+ xform = (struct rte_comp_xform) {
>+ .type = RTE_COMP_DECOMPRESS,
>+ .decompress = {
>+ .algo = RTE_COMP_ALGO_DEFLATE,
>+ .chksum = RTE_COMP_CHECKSUM_NONE,
>+ .window_size = test_data->window_sz,
>+ .hash_algo = RTE_COMP_HASH_ALGO_NONE
>+ }
>+ };
>+ input_bufs = test_data->comp_bufs;
>+ output_bufs = test_data->decomp_bufs;
>+ }
>+
>+ /* Create private xform */
>+ if (rte_compressdev_private_xform_create(dev_id, &xform,
>+ &priv_xform) < 0) {
>+ RTE_LOG(ERR, USER1, "Private xform could not be created\n");
>+ res = -1;
>+ goto end;
>+ }
>+
>+ uint64_t tsc_start, tsc_end, tsc_duration;
>+
>+ tsc_start = tsc_end = tsc_duration = 0;
>+ if (benchmarking) {
>+ tsc_start = rte_rdtsc();
>+ num_iter = test_data->num_iter;
>+ } else
>+ num_iter = 1;
Looks like in same code we're doing benchmarking and functional validation. It can be reorganised to keep validation test separately like done in crypto_perf.
>+
>+ for (iter = 0; iter < num_iter; iter++) {
>+ uint32_t total_ops = test_data->total_bufs;
>+ uint32_t remaining_ops = test_data->total_bufs;
>+ uint32_t total_deq_ops = 0;
>+ uint32_t total_enq_ops = 0;
>+ uint16_t ops_unused = 0;
>+ uint16_t num_enq = 0;
>+ uint16_t num_deq = 0;
>+
>+ output_size = 0;
>+
>+ while (remaining_ops > 0) {
>+ uint16_t num_ops = RTE_MIN(remaining_ops,
>+ test_data->burst_sz);
>+ uint16_t ops_needed = num_ops - ops_unused;
>+
>+ /*
>+ * Move the unused operations from the previous
>+ * enqueue_burst call to the front, to maintain order
>+ */
>+ if ((ops_unused > 0) && (num_enq > 0)) {
>+ size_t nb_b_to_mov =
>+ ops_unused * sizeof(struct rte_comp_op *);
>+
>+ memmove(ops, &ops[num_enq], nb_b_to_mov);
>+ }
>+
>+ /* Allocate compression operations */
>+ if (ops_needed && !rte_comp_op_bulk_alloc(
>+ test_data->op_pool,
>+ &ops[ops_unused],
>+ ops_needed)) {
>+ RTE_LOG(ERR, USER1,
>+ "Could not allocate enough operations\n");
>+ res = -1;
>+ goto end;
>+ }
>+ allocated += ops_needed;
>+
>+ for (i = 0; i < ops_needed; i++) {
>+ /*
>+ * Calculate next buffer to attach to operation
>+ */
>+ uint32_t buf_id = total_enq_ops + i +
>+ ops_unused;
>+ uint16_t op_id = ops_unused + i;
>+ /* Reset all data in output buffers */
>+ struct rte_mbuf *m = output_bufs[buf_id];
>+
>+ m->pkt_len = test_data->seg_sz * m->nb_segs;
Isn't pkt_len set already when we call rte_pktmbuf_append() and chain()?
>+ while (m) {
>+ m->data_len = m->buf_len - m->data_off;
Same question, shouldn't rte_pktmbuf_append() adjust data_len as well per each mbuf?
>+ m = m->next;
>+ }
>+ ops[op_id]->m_src = input_bufs[buf_id];
>+ ops[op_id]->m_dst = output_bufs[buf_id];
>+ ops[op_id]->src.offset = 0;
>+ ops[op_id]->src.length =
>+ rte_pktmbuf_pkt_len(input_bufs[buf_id]);
>+ ops[op_id]->dst.offset = 0;
>+ ops[op_id]->flush_flag = RTE_COMP_FLUSH_FINAL;
>+ ops[op_id]->input_chksum = buf_id;
>+ ops[op_id]->private_xform = priv_xform;
>+ }
>+
>+ num_enq = rte_compressdev_enqueue_burst(dev_id, 0, ops,
>+ num_ops);
>+ ops_unused = num_ops - num_enq;
>+ remaining_ops -= num_enq;
>+ total_enq_ops += num_enq;
>+
>+ num_deq = rte_compressdev_dequeue_burst(dev_id, 0,
>+ deq_ops,
>+ test_data->burst_sz);
>+ total_deq_ops += num_deq;
>+ if (benchmarking == 0) {
>+ for (i = 0; i < num_deq; i++) {
>+ struct rte_comp_op *op = deq_ops[i];
>+ const void *read_data_addr =
>+ rte_pktmbuf_read(op->m_dst, 0,
>+ op->produced, output_data_ptr);
>+ if (read_data_addr == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Could not copy buffer in destination\n");
>+ res = -1;
>+ goto end;
>+ }
>+
>+ if (read_data_addr != output_data_ptr)
>+ rte_memcpy(output_data_ptr,
>+ rte_pktmbuf_mtod(
>+ op->m_dst, uint8_t *),
>+ op->produced);
>+ output_data_ptr += op->produced;
>+ output_size += op->produced;
>+
>+ }
>+ }
>+
>+ if (iter == num_iter - 1) {
>+ for (i = 0; i < num_deq; i++) {
Why is it only for last iteration, we are adjusting dst mbuf data_len.?
Shouldn't it be done for each dequeued op?
And, for benchmarking, do we even need to set data and pkt len on dst mbuf?
>+ struct rte_comp_op *op = deq_ops[i];
>+ struct rte_mbuf *m = op->m_dst;
>+
>+ m->pkt_len = op->produced;
>+ uint32_t remaining_data = op->produced;
>+ uint16_t data_to_append;
>+
>+ while (remaining_data > 0) {
>+ data_to_append =
>+ RTE_MIN(remaining_data,
>+ test_data->seg_sz);
>+ m->data_len = data_to_append;
>+ remaining_data -=
>+ data_to_append;
>+ m = m->next;
Should break if m->next == NULL
>+ }
>+ }
>+ }
>+ rte_mempool_put_bulk(test_data->op_pool,
>+ (void **)deq_ops, num_deq);
>+ allocated -= num_deq;
>+ }
>+
>+ /* Dequeue the last operations */
>+ while (total_deq_ops < total_ops) {
>+ num_deq = rte_compressdev_dequeue_burst(dev_id, 0,
>+ deq_ops, test_data->burst_sz);
>+ total_deq_ops += num_deq;
>+ if (benchmarking == 0) {
>+ for (i = 0; i < num_deq; i++) {
>+ struct rte_comp_op *op = deq_ops[i];
>+ const void *read_data_addr =
>+ rte_pktmbuf_read(op->m_dst, 0,
>+ op->produced, output_data_ptr);
>+ if (read_data_addr == NULL) {
>+ RTE_LOG(ERR, USER1,
>+ "Could not copy buffer in destination\n");
>+ res = -1;
>+ goto end;
>+ }
>+
>+ if (read_data_addr != output_data_ptr)
>+ rte_memcpy(output_data_ptr,
>+ rte_pktmbuf_mtod(
>+ op->m_dst, uint8_t *),
>+ op->produced);
>+ output_data_ptr += op->produced;
>+ output_size += op->produced;
>+
>+ }
>+ }
>+
>+ if (iter == num_iter - 1) {
>+ for (i = 0; i < num_deq; i++) {
>+ struct rte_comp_op *op = deq_ops[i];
>+ struct rte_mbuf *m = op->m_dst;
>+
>+ m->pkt_len = op->produced;
>+ uint32_t remaining_data = op->produced;
>+ uint16_t data_to_append;
>+
>+ while (remaining_data > 0) {
>+ data_to_append =
>+ RTE_MIN(remaining_data,
>+ test_data->seg_sz);
>+ m->data_len = data_to_append;
>+ remaining_data -=
>+ data_to_append;
>+ m = m->next;
>+ }
>+ }
>+ }
>+ rte_mempool_put_bulk(test_data->op_pool,
>+ (void **)deq_ops, num_deq);
>+ allocated -= num_deq;
>+ }
>+ }
>+
>+ if (benchmarking) {
>+ tsc_end = rte_rdtsc();
>+ tsc_duration = tsc_end - tsc_start;
>+
>+ if (type == RTE_COMP_COMPRESS)
test looks for stateless operations only, so can we add perf test type like: test type perf, op type:STATELESS/STATEFUL
Also, why do we need --max-num-sgl-segs as an input option from user? Shouldn't input_sz and seg_sz internally decide on num-segs?
Or is it added to serve some other different purpose?
Thanks
Shally
>+ test_data->comp_tsc_duration[level] =
>+ tsc_duration / num_iter;
>+ else
>+ test_data->decomp_tsc_duration[level] =
>+ tsc_duration / num_iter;
>+ }
>+
>+ if (benchmarking == 0 && output_data_sz)
>+ *output_data_sz = output_size;
>+end:
>+ rte_mempool_put_bulk(test_data->op_pool, (void **)ops, allocated);
>+ rte_compressdev_private_xform_free(dev_id, priv_xform);
>+ rte_free(ops);
>+ return res;
>+}
>+
> int
> main(int argc, char **argv)
> {
>+ uint8_t level, level_idx = 0;
>+ uint8_t i;
> int ret;
> struct comp_test_data *test_data;
>
>@@ -43,9 +751,145 @@ main(int argc, char **argv)
> goto err;
> }
>
>+ if (comp_perf_initialize_compressdev(test_data) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (comp_perf_dump_input_data(test_data) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (comp_perf_allocate_memory(test_data) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (prepare_bufs(test_data) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (test_data->level.inc != 0)
>+ level = test_data->level.min;
>+ else
>+ level = test_data->level.list[0];
>+
>+ size_t comp_data_sz;
>+ size_t decomp_data_sz;
>+
>+ printf("Burst size = %u\n", test_data->burst_sz);
>+ printf("File size = %zu\n", test_data->input_data_sz);
>+
>+ printf("%6s%12s%17s%19s%21s%15s%21s%23s%16s\n",
>+ "Level", "Comp size", "Comp ratio [%]",
>+ "Comp [Cycles/it]", "Comp [Cycles/Byte]", "Comp [Gbps]",
>+ "Decomp [Cycles/it]", "Decomp [Cycles/Byte]", "Decomp [Gbps]");
>+
>+ while (level <= test_data->level.max) {
>+ /*
>+ * Run a first iteration, to verify compression and
>+ * get the compression ratio for the level
>+ */
>+ if (main_loop(test_data, level, RTE_COMP_COMPRESS,
>+ test_data->compressed_data,
>+ &comp_data_sz, 0) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (main_loop(test_data, level, RTE_COMP_DECOMPRESS,
>+ test_data->decompressed_data,
>+ &decomp_data_sz, 0) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+
>+ if (decomp_data_sz != test_data->input_data_sz) {
>+ RTE_LOG(ERR, USER1,
>+ "Decompressed data length not equal to input data length\n");
>+ RTE_LOG(ERR, USER1,
>+ "Decompressed size = %zu, expected = %zu\n",
>+ decomp_data_sz, test_data->input_data_sz);
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ } else {
>+ if (memcmp(test_data->decompressed_data,
>+ test_data->input_data,
>+ test_data->input_data_sz) != 0) {
>+ RTE_LOG(ERR, USER1,
>+ "Decompressed data is not the same as file data\n");
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+ }
>+
>+ double ratio = (double) comp_data_sz /
>+ test_data->input_data_sz * 100;
>+
>+ /*
>+ * Run the tests twice, discarding the first performance
>+ * results, before the cache is warmed up
>+ */
>+ for (i = 0; i < 2; i++) {
>+ if (main_loop(test_data, level, RTE_COMP_COMPRESS,
>+ NULL, NULL, 1) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+ }
>+
>+ for (i = 0; i < 2; i++) {
>+ if (main_loop(test_data, level, RTE_COMP_DECOMPRESS,
>+ NULL, NULL, 1) < 0) {
>+ ret = EXIT_FAILURE;
>+ goto err;
>+ }
>+ }
>+
>+ uint64_t comp_tsc_duration =
>+ test_data->comp_tsc_duration[level];
>+ double comp_tsc_byte = (double)comp_tsc_duration /
>+ test_data->input_data_sz;
>+ double comp_gbps = rte_get_tsc_hz() / comp_tsc_byte * 8 /
>+ 1000000000;
>+ uint64_t decomp_tsc_duration =
>+ test_data->decomp_tsc_duration[level];
>+ double decomp_tsc_byte = (double)decomp_tsc_duration /
>+ test_data->input_data_sz;
>+ double decomp_gbps = rte_get_tsc_hz() / decomp_tsc_byte * 8 /
>+ 1000000000;
>+
>+ printf("%6u%12zu%17.2f%19"PRIu64"%21.2f"
>+ "%15.2f%21"PRIu64"%23.2f%16.2f\n",
>+ level, comp_data_sz, ratio, comp_tsc_duration,
>+ comp_tsc_byte, comp_gbps, decomp_tsc_duration,
>+ decomp_tsc_byte, decomp_gbps);
>+
>+ if (test_data->level.inc != 0)
>+ level += test_data->level.inc;
>+ else {
>+ if (++level_idx == test_data->level.count)
>+ break;
>+ level = test_data->level.list[level_idx];
>+ }
>+ }
>+
> ret = EXIT_SUCCESS;
>
> err:
>+ if (test_data->cdev_id != -1)
>+ rte_compressdev_stop(test_data->cdev_id);
>+
>+ free_bufs(test_data);
>+ rte_free(test_data->compressed_data);
>+ rte_free(test_data->decompressed_data);
>+ rte_free(test_data->input_data);
>+ rte_mempool_free(test_data->comp_buf_pool);
>+ rte_mempool_free(test_data->decomp_buf_pool);
>+ rte_mempool_free(test_data->op_pool);
>+
> rte_free(test_data);
>
> return ret;
>--
>2.7.4
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