diff options
Diffstat (limited to 'src/spdk/dpdk/app/test/test_red.c')
-rw-r--r-- | src/spdk/dpdk/app/test/test_red.c | 1856 |
1 files changed, 1856 insertions, 0 deletions
diff --git a/src/spdk/dpdk/app/test/test_red.c b/src/spdk/dpdk/app/test/test_red.c new file mode 100644 index 000000000..e973f3131 --- /dev/null +++ b/src/spdk/dpdk/app/test/test_red.c @@ -0,0 +1,1856 @@ +/* SPDX-License-Identifier: BSD-3-Clause + * Copyright(c) 2010-2014 Intel Corporation + */ + +#include <stdlib.h> +#include <stdio.h> +#include <string.h> +#include <stdint.h> +#include <unistd.h> +#include <inttypes.h> +#include <sys/time.h> +#include <time.h> +#include <math.h> + +#include "test.h" + +#include <rte_red.h> + +#ifdef __INTEL_COMPILER +#pragma warning(disable:2259) /* conversion may lose significant bits */ +#pragma warning(disable:181) /* Arg incompatible with format string */ +#endif + +#define TEST_HZ_PER_KHZ 1000 +#define TEST_NSEC_MARGIN 500 /**< nanosecond margin when calculating clk freq */ + +#define MAX_QEMPTY_TIME_MSEC 50000 +#define MSEC_PER_SEC 1000 /**< Milli-seconds per second */ +#define USEC_PER_MSEC 1000 /**< Micro-seconds per milli-second */ +#define USEC_PER_SEC 1000000 /**< Micro-seconds per second */ +#define NSEC_PER_SEC (USEC_PER_SEC * 1000) /**< Nano-seconds per second */ + +/**< structures for testing rte_red performance and function */ +struct test_rte_red_config { /**< Test structure for RTE_RED config */ + struct rte_red_config *rconfig; /**< RTE_RED configuration parameters */ + uint8_t num_cfg; /**< Number of RTE_RED configs to test */ + uint8_t *wq_log2; /**< Test wq_log2 value to use */ + uint32_t min_th; /**< Queue minimum threshold */ + uint32_t max_th; /**< Queue maximum threshold */ + uint8_t *maxp_inv; /**< Inverse mark probability */ +}; + +struct test_queue { /**< Test structure for RTE_RED Queues */ + struct rte_red *rdata; /**< RTE_RED runtime data */ + uint32_t num_queues; /**< Number of RTE_RED queues to test */ + uint32_t *qconfig; /**< Configuration of RTE_RED queues for test */ + uint32_t *q; /**< Queue size */ + uint32_t q_ramp_up; /**< Num of enqueues to ramp up the queue */ + uint32_t avg_ramp_up; /**< Average num of enqueues to ramp up the queue */ + uint32_t avg_tolerance; /**< Tolerance in queue average */ + double drop_tolerance; /**< Drop tolerance of packets not enqueued */ +}; + +struct test_var { /**< Test variables used for testing RTE_RED */ + uint32_t wait_usec; /**< Micro second wait interval */ + uint32_t num_iterations; /**< Number of test iterations */ + uint32_t num_ops; /**< Number of test operations */ + uint64_t clk_freq; /**< CPU clock frequency */ + uint32_t sleep_sec; /**< Seconds to sleep */ + uint32_t *dropped; /**< Test operations dropped */ + uint32_t *enqueued; /**< Test operations enqueued */ +}; + +struct test_config { /**< Master test structure for RTE_RED */ + const char *ifname; /**< Interface name */ + const char *msg; /**< Test message for display */ + const char *htxt; /**< Header txt display for result output */ + struct test_rte_red_config *tconfig; /**< Test structure for RTE_RED config */ + struct test_queue *tqueue; /**< Test structure for RTE_RED Queues */ + struct test_var *tvar; /**< Test variables used for testing RTE_RED */ + uint32_t *tlevel; /**< Queue levels */ +}; + +enum test_result { + FAIL = 0, + PASS +}; + +/**< Test structure to define tests to run */ +struct tests { + struct test_config *testcfg; + enum test_result (*testfn)(struct test_config *); +}; + +struct rdtsc_prof { + uint64_t clk_start; + uint64_t clk_min; /**< min clocks */ + uint64_t clk_max; /**< max clocks */ + uint64_t clk_avgc; /**< count to calc average */ + double clk_avg; /**< cumulative sum to calc average */ + const char *name; +}; + +static const uint64_t port_speed_bytes = (10ULL*1000ULL*1000ULL*1000ULL)/8ULL; +static double inv_cycles_per_byte = 0; +static double pkt_time_usec = 0; + +static void init_port_ts(uint64_t cpu_clock) +{ + double cycles_per_byte = (double)(cpu_clock) / (double)(port_speed_bytes); + inv_cycles_per_byte = 1.0 / cycles_per_byte; + pkt_time_usec = 1000000.0 / ((double)port_speed_bytes / (double)RTE_RED_S); +} + +static uint64_t get_port_ts(void) +{ + return (uint64_t)((double)rte_rdtsc() * inv_cycles_per_byte); +} + +static void rdtsc_prof_init(struct rdtsc_prof *p, const char *name) +{ + p->clk_min = (uint64_t)(-1LL); + p->clk_max = 0; + p->clk_avg = 0; + p->clk_avgc = 0; + p->name = name; +} + +static inline void rdtsc_prof_start(struct rdtsc_prof *p) +{ + p->clk_start = rte_rdtsc_precise(); +} + +static inline void rdtsc_prof_end(struct rdtsc_prof *p) +{ + uint64_t clk_start = rte_rdtsc() - p->clk_start; + + p->clk_avgc++; + p->clk_avg += (double) clk_start; + + if (clk_start > p->clk_max) + p->clk_max = clk_start; + if (clk_start < p->clk_min) + p->clk_min = clk_start; +} + +static void rdtsc_prof_print(struct rdtsc_prof *p) +{ + if (p->clk_avgc>0) { + printf("RDTSC stats for %s: n=%" PRIu64 ", min=%" PRIu64 ", max=%" PRIu64 ", avg=%.1f\n", + p->name, + p->clk_avgc, + p->clk_min, + p->clk_max, + (p->clk_avg / ((double) p->clk_avgc))); + } +} + +static uint32_t rte_red_get_avg_int(const struct rte_red_config *red_cfg, + struct rte_red *red) +{ + /** + * scale by 1/n and convert from fixed-point to integer + */ + return red->avg >> (RTE_RED_SCALING + red_cfg->wq_log2); +} + +static double rte_red_get_avg_float(const struct rte_red_config *red_cfg, + struct rte_red *red) +{ + /** + * scale by 1/n and convert from fixed-point to floating-point + */ + return ldexp((double)red->avg, -(RTE_RED_SCALING + red_cfg->wq_log2)); +} + +static void rte_red_set_avg_int(const struct rte_red_config *red_cfg, + struct rte_red *red, + uint32_t avg) +{ + /** + * scale by n and convert from integer to fixed-point + */ + red->avg = avg << (RTE_RED_SCALING + red_cfg->wq_log2); +} + +static double calc_exp_avg_on_empty(double avg, uint32_t n, uint32_t time_diff) +{ + return avg * pow((1.0 - 1.0 / (double)n), (double)time_diff / pkt_time_usec); +} + +static double calc_drop_rate(uint32_t enqueued, uint32_t dropped) +{ + return (double)dropped / ((double)enqueued + (double)dropped); +} + +/** + * calculate the drop probability + */ +static double calc_drop_prob(uint32_t min_th, uint32_t max_th, + uint32_t maxp_inv, uint32_t avg) +{ + double drop_prob = 0.0; + + if (avg < min_th) { + drop_prob = 0.0; + } else if (avg < max_th) { + drop_prob = (1.0 / (double)maxp_inv) + * ((double)(avg - min_th) + / (double)(max_th - min_th)); + } else { + drop_prob = 1.0; + } + return drop_prob; +} + +/** + * check if drop rate matches drop probability within tolerance + */ +static int check_drop_rate(double *diff, double drop_rate, double drop_prob, double tolerance) +{ + double abs_diff = 0.0; + int ret = 1; + + abs_diff = fabs(drop_rate - drop_prob); + if ((int)abs_diff == 0) { + *diff = 0.0; + } else { + *diff = (abs_diff / drop_prob) * 100.0; + if (*diff > tolerance) { + ret = 0; + } + } + return ret; +} + +/** + * check if average queue size is within tolerance + */ +static int check_avg(double *diff, double avg, double exp_avg, double tolerance) +{ + double abs_diff = 0.0; + int ret = 1; + + abs_diff = fabs(avg - exp_avg); + if ((int)abs_diff == 0) { + *diff = 0.0; + } else { + *diff = (abs_diff / exp_avg) * 100.0; + if (*diff > tolerance) { + ret = 0; + } + } + return ret; +} + +/** + * initialize the test rte_red config + */ +static enum test_result +test_rte_red_init(struct test_config *tcfg) +{ + unsigned i = 0; + + tcfg->tvar->clk_freq = rte_get_timer_hz(); + init_port_ts( tcfg->tvar->clk_freq ); + + for (i = 0; i < tcfg->tconfig->num_cfg; i++) { + if (rte_red_config_init(&tcfg->tconfig->rconfig[i], + (uint16_t)tcfg->tconfig->wq_log2[i], + (uint16_t)tcfg->tconfig->min_th, + (uint16_t)tcfg->tconfig->max_th, + (uint16_t)tcfg->tconfig->maxp_inv[i]) != 0) { + return FAIL; + } + } + + *tcfg->tqueue->q = 0; + *tcfg->tvar->dropped = 0; + *tcfg->tvar->enqueued = 0; + return PASS; +} + +/** + * enqueue until actual queue size reaches target level + */ +static int +increase_actual_qsize(struct rte_red_config *red_cfg, + struct rte_red *red, + uint32_t *q, + uint32_t level, + uint32_t attempts) +{ + uint32_t i = 0; + + for (i = 0; i < attempts; i++) { + int ret = 0; + + /** + * enqueue + */ + ret = rte_red_enqueue(red_cfg, red, *q, get_port_ts() ); + if (ret == 0) { + if (++(*q) >= level) + break; + } + } + /** + * check if target actual queue size has been reached + */ + if (*q != level) + return -1; + /** + * success + */ + return 0; +} + +/** + * enqueue until average queue size reaches target level + */ +static int +increase_average_qsize(struct rte_red_config *red_cfg, + struct rte_red *red, + uint32_t *q, + uint32_t level, + uint32_t num_ops) +{ + uint32_t avg = 0; + uint32_t i = 0; + + for (i = 0; i < num_ops; i++) { + /** + * enqueue + */ + rte_red_enqueue(red_cfg, red, *q, get_port_ts()); + } + /** + * check if target average queue size has been reached + */ + avg = rte_red_get_avg_int(red_cfg, red); + if (avg != level) + return -1; + /** + * success + */ + return 0; +} + +/** + * setup default values for the functional test structures + */ +static struct rte_red_config ft_wrconfig[1]; +static struct rte_red ft_rtdata[1]; +static uint8_t ft_wq_log2[] = {9}; +static uint8_t ft_maxp_inv[] = {10}; +static uint32_t ft_qconfig[] = {0, 0, 1, 1}; +static uint32_t ft_q[] ={0}; +static uint32_t ft_dropped[] ={0}; +static uint32_t ft_enqueued[] ={0}; + +static struct test_rte_red_config ft_tconfig = { + .rconfig = ft_wrconfig, + .num_cfg = RTE_DIM(ft_wrconfig), + .wq_log2 = ft_wq_log2, + .min_th = 32, + .max_th = 128, + .maxp_inv = ft_maxp_inv, +}; + +static struct test_queue ft_tqueue = { + .rdata = ft_rtdata, + .num_queues = RTE_DIM(ft_rtdata), + .qconfig = ft_qconfig, + .q = ft_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 5, /* 5 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +static struct test_var ft_tvar = { + .wait_usec = 10000, + .num_iterations = 5, + .num_ops = 10000, + .clk_freq = 0, + .dropped = ft_dropped, + .enqueued = ft_enqueued, + .sleep_sec = (MAX_QEMPTY_TIME_MSEC / MSEC_PER_SEC) + 2, +}; + +/** + * functional test enqueue/dequeue packets + */ +static void enqueue_dequeue_func(struct rte_red_config *red_cfg, + struct rte_red *red, + uint32_t *q, + uint32_t num_ops, + uint32_t *enqueued, + uint32_t *dropped) +{ + uint32_t i = 0; + + for (i = 0; i < num_ops; i++) { + int ret = 0; + + /** + * enqueue + */ + ret = rte_red_enqueue(red_cfg, red, *q, get_port_ts()); + if (ret == 0) + (*enqueued)++; + else + (*dropped)++; + } +} + +/** + * Test F1: functional test 1 + */ +static uint32_t ft1_tlevels[] = {6, 12, 18, 24, 30, 36, 42, 48, 54, 60, 66, 72, 78, 84, 90, 96, 102, 108, 114, 120, 126, 132, 138, 144}; + +static struct test_config func_test1_config = { + .ifname = "functional test 1 interface", + .msg = "functional test 1 : use one rte_red configuration,\n" + " increase average queue size to various levels,\n" + " compare drop rate to drop probability\n\n", + .htxt = " " + "avg queue size " + "enqueued " + "dropped " + "drop prob % " + "drop rate % " + "diff % " + "tolerance % " + "\n", + .tconfig = &ft_tconfig, + .tqueue = &ft_tqueue, + .tvar = &ft_tvar, + .tlevel = ft1_tlevels, +}; + +static enum test_result func_test1(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint32_t i = 0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + printf("%s", tcfg->htxt); + + for (i = 0; i < RTE_DIM(ft1_tlevels); i++) { + const char *label = NULL; + uint32_t avg = 0; + double drop_rate = 0.0; + double drop_prob = 0.0; + double diff = 0.0; + + /** + * reset rte_red run-time data + */ + rte_red_rt_data_init(tcfg->tqueue->rdata); + *tcfg->tvar->enqueued = 0; + *tcfg->tvar->dropped = 0; + + if (increase_actual_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + tcfg->tlevel[i], + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + + if (increase_average_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + tcfg->tlevel[i], + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + + enqueue_dequeue_func(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + tcfg->tvar->num_ops, + tcfg->tvar->enqueued, + tcfg->tvar->dropped); + + avg = rte_red_get_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + if (avg != tcfg->tlevel[i]) { + fprintf(stderr, "Fail: avg != level\n"); + result = FAIL; + } + + drop_rate = calc_drop_rate(*tcfg->tvar->enqueued, *tcfg->tvar->dropped); + drop_prob = calc_drop_prob(tcfg->tconfig->min_th, tcfg->tconfig->max_th, + *tcfg->tconfig->maxp_inv, tcfg->tlevel[i]); + if (!check_drop_rate(&diff, drop_rate, drop_prob, (double)tcfg->tqueue->drop_tolerance)) + result = FAIL; + + if (tcfg->tlevel[i] == tcfg->tconfig->min_th) + label = "min thresh: "; + else if (tcfg->tlevel[i] == tcfg->tconfig->max_th) + label = "max thresh: "; + else + label = " "; + printf("%s%-15u%-15u%-15u%-15.4lf%-15.4lf%-15.4lf%-15.4lf\n", + label, avg, *tcfg->tvar->enqueued, *tcfg->tvar->dropped, + drop_prob * 100.0, drop_rate * 100.0, diff, + (double)tcfg->tqueue->drop_tolerance); + } +out: + return result; +} + +/** + * Test F2: functional test 2 + */ +static uint32_t ft2_tlevel[] = {127}; +static uint8_t ft2_wq_log2[] = {9, 9, 9, 9, 9, 9, 9, 9, 9, 9}; +static uint8_t ft2_maxp_inv[] = {10, 20, 30, 40, 50, 60, 70, 80, 90, 100}; +static struct rte_red_config ft2_rconfig[10]; + +static struct test_rte_red_config ft2_tconfig = { + .rconfig = ft2_rconfig, + .num_cfg = RTE_DIM(ft2_rconfig), + .wq_log2 = ft2_wq_log2, + .min_th = 32, + .max_th = 128, + .maxp_inv = ft2_maxp_inv, +}; + +static struct test_config func_test2_config = { + .ifname = "functional test 2 interface", + .msg = "functional test 2 : use several RED configurations,\n" + " increase average queue size to just below maximum threshold,\n" + " compare drop rate to drop probability\n\n", + .htxt = "RED config " + "avg queue size " + "min threshold " + "max threshold " + "drop prob % " + "drop rate % " + "diff % " + "tolerance % " + "\n", + .tconfig = &ft2_tconfig, + .tqueue = &ft_tqueue, + .tvar = &ft_tvar, + .tlevel = ft2_tlevel, +}; + +static enum test_result func_test2(struct test_config *tcfg) +{ + enum test_result result = PASS; + double prev_drop_rate = 1.0; + uint32_t i = 0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + rte_red_rt_data_init(tcfg->tqueue->rdata); + + if (increase_actual_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + + if (increase_average_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + printf("%s", tcfg->htxt); + + for (i = 0; i < tcfg->tconfig->num_cfg; i++) { + uint32_t avg = 0; + double drop_rate = 0.0; + double drop_prob = 0.0; + double diff = 0.0; + + *tcfg->tvar->dropped = 0; + *tcfg->tvar->enqueued = 0; + + enqueue_dequeue_func(&tcfg->tconfig->rconfig[i], + tcfg->tqueue->rdata, + tcfg->tqueue->q, + tcfg->tvar->num_ops, + tcfg->tvar->enqueued, + tcfg->tvar->dropped); + + avg = rte_red_get_avg_int(&tcfg->tconfig->rconfig[i], tcfg->tqueue->rdata); + if (avg != *tcfg->tlevel) + result = FAIL; + + drop_rate = calc_drop_rate(*tcfg->tvar->enqueued, *tcfg->tvar->dropped); + drop_prob = calc_drop_prob(tcfg->tconfig->min_th, tcfg->tconfig->max_th, + tcfg->tconfig->maxp_inv[i], *tcfg->tlevel); + if (!check_drop_rate(&diff, drop_rate, drop_prob, (double)tcfg->tqueue->drop_tolerance)) + result = FAIL; + /** + * drop rate should decrease as maxp_inv increases + */ + if (drop_rate > prev_drop_rate) + result = FAIL; + prev_drop_rate = drop_rate; + + printf("%-15u%-15u%-15u%-15u%-15.4lf%-15.4lf%-15.4lf%-15.4lf\n", + i, avg, tcfg->tconfig->min_th, tcfg->tconfig->max_th, + drop_prob * 100.0, drop_rate * 100.0, diff, + (double)tcfg->tqueue->drop_tolerance); + } +out: + return result; +} + +/** + * Test F3: functional test 3 + */ +static uint32_t ft3_tlevel[] = {1022}; + +static struct test_rte_red_config ft3_tconfig = { + .rconfig = ft_wrconfig, + .num_cfg = RTE_DIM(ft_wrconfig), + .wq_log2 = ft_wq_log2, + .min_th = 32, + .max_th = 1023, + .maxp_inv = ft_maxp_inv, +}; + +static struct test_config func_test3_config = { + .ifname = "functional test 3 interface", + .msg = "functional test 3 : use one RED configuration,\n" + " increase average queue size to target level,\n" + " dequeue all packets until queue is empty,\n" + " confirm that average queue size is computed correctly while queue is empty\n\n", + .htxt = "q avg before " + "q avg after " + "expected " + "difference % " + "tolerance % " + "result " + "\n", + .tconfig = &ft3_tconfig, + .tqueue = &ft_tqueue, + .tvar = &ft_tvar, + .tlevel = ft3_tlevel, +}; + +static enum test_result func_test3(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint32_t i = 0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + rte_red_rt_data_init(tcfg->tqueue->rdata); + + if (increase_actual_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + + if (increase_average_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + + printf("%s", tcfg->htxt); + + for (i = 0; i < tcfg->tvar->num_iterations; i++) { + double avg_before = 0; + double avg_after = 0; + double exp_avg = 0; + double diff = 0.0; + + avg_before = rte_red_get_avg_float(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + + /** + * empty the queue + */ + *tcfg->tqueue->q = 0; + rte_red_mark_queue_empty(tcfg->tqueue->rdata, get_port_ts()); + + rte_delay_us(tcfg->tvar->wait_usec); + + /** + * enqueue one packet to recalculate average queue size + */ + if (rte_red_enqueue(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + *tcfg->tqueue->q, + get_port_ts()) == 0) { + (*tcfg->tqueue->q)++; + } else { + printf("%s:%d: packet enqueued on empty queue was dropped\n", __func__, __LINE__); + result = FAIL; + } + + exp_avg = calc_exp_avg_on_empty(avg_before, + (1 << *tcfg->tconfig->wq_log2), + tcfg->tvar->wait_usec); + avg_after = rte_red_get_avg_float(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata); + if (!check_avg(&diff, avg_after, exp_avg, (double)tcfg->tqueue->avg_tolerance)) + result = FAIL; + + printf("%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15s\n", + avg_before, avg_after, exp_avg, diff, + (double)tcfg->tqueue->avg_tolerance, + diff <= (double)tcfg->tqueue->avg_tolerance ? "pass" : "fail"); + } +out: + return result; +} + +/** + * Test F4: functional test 4 + */ +static uint32_t ft4_tlevel[] = {1022}; +static uint8_t ft4_wq_log2[] = {11}; + +static struct test_rte_red_config ft4_tconfig = { + .rconfig = ft_wrconfig, + .num_cfg = RTE_DIM(ft_wrconfig), + .min_th = 32, + .max_th = 1023, + .wq_log2 = ft4_wq_log2, + .maxp_inv = ft_maxp_inv, +}; + +static struct test_queue ft4_tqueue = { + .rdata = ft_rtdata, + .num_queues = RTE_DIM(ft_rtdata), + .qconfig = ft_qconfig, + .q = ft_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 0, /* 0 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +static struct test_config func_test4_config = { + .ifname = "functional test 4 interface", + .msg = "functional test 4 : use one RED configuration,\n" + " increase average queue size to target level,\n" + " dequeue all packets until queue is empty,\n" + " confirm that average queue size is computed correctly while\n" + " queue is empty for more than 50 sec,\n" + " (this test takes 52 sec to run)\n\n", + .htxt = "q avg before " + "q avg after " + "expected " + "difference % " + "tolerance % " + "result " + "\n", + .tconfig = &ft4_tconfig, + .tqueue = &ft4_tqueue, + .tvar = &ft_tvar, + .tlevel = ft4_tlevel, +}; + +static enum test_result func_test4(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint64_t time_diff = 0; + uint64_t start = 0; + double avg_before = 0.0; + double avg_after = 0.0; + double exp_avg = 0.0; + double diff = 0.0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + rte_red_rt_data_init(tcfg->tqueue->rdata); + + if (increase_actual_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + + if (increase_average_qsize(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + *tcfg->tlevel, + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + + printf("%s", tcfg->htxt); + + avg_before = rte_red_get_avg_float(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + + /** + * empty the queue + */ + *tcfg->tqueue->q = 0; + rte_red_mark_queue_empty(tcfg->tqueue->rdata, get_port_ts()); + + /** + * record empty time locally + */ + start = rte_rdtsc(); + + sleep(tcfg->tvar->sleep_sec); + + /** + * enqueue one packet to recalculate average queue size + */ + if (rte_red_enqueue(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + *tcfg->tqueue->q, + get_port_ts()) != 0) { + result = FAIL; + goto out; + } + (*tcfg->tqueue->q)++; + + /** + * calculate how long queue has been empty + */ + time_diff = ((rte_rdtsc() - start) / tcfg->tvar->clk_freq) + * MSEC_PER_SEC; + if (time_diff < MAX_QEMPTY_TIME_MSEC) { + /** + * this could happen if sleep was interrupted for some reason + */ + result = FAIL; + goto out; + } + + /** + * confirm that average queue size is now at expected level + */ + exp_avg = 0.0; + avg_after = rte_red_get_avg_float(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + if (!check_avg(&diff, avg_after, exp_avg, (double)tcfg->tqueue->avg_tolerance)) + result = FAIL; + + printf("%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15s\n", + avg_before, avg_after, exp_avg, + diff, (double)tcfg->tqueue->avg_tolerance, + diff <= (double)tcfg->tqueue->avg_tolerance ? "pass" : "fail"); +out: + return result; +} + +/** + * Test F5: functional test 5 + */ +static uint32_t ft5_tlevel[] = {127}; +static uint8_t ft5_wq_log2[] = {9, 8}; +static uint8_t ft5_maxp_inv[] = {10, 20}; +static struct rte_red_config ft5_config[2]; +static struct rte_red ft5_data[4]; +static uint32_t ft5_q[4]; +static uint32_t ft5_dropped[] = {0, 0, 0, 0}; +static uint32_t ft5_enqueued[] = {0, 0, 0, 0}; + +static struct test_rte_red_config ft5_tconfig = { + .rconfig = ft5_config, + .num_cfg = RTE_DIM(ft5_config), + .min_th = 32, + .max_th = 128, + .wq_log2 = ft5_wq_log2, + .maxp_inv = ft5_maxp_inv, +}; + +static struct test_queue ft5_tqueue = { + .rdata = ft5_data, + .num_queues = RTE_DIM(ft5_data), + .qconfig = ft_qconfig, + .q = ft5_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 5, /* 10 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +struct test_var ft5_tvar = { + .wait_usec = 0, + .num_iterations = 15, + .num_ops = 10000, + .clk_freq = 0, + .dropped = ft5_dropped, + .enqueued = ft5_enqueued, + .sleep_sec = 0, +}; + +static struct test_config func_test5_config = { + .ifname = "functional test 5 interface", + .msg = "functional test 5 : use several queues (each with its own run-time data),\n" + " use several RED configurations (such that each configuration is shared by multiple queues),\n" + " increase average queue size to just below maximum threshold,\n" + " compare drop rate to drop probability,\n" + " (this is a larger scale version of functional test 2)\n\n", + .htxt = "queue " + "config " + "avg queue size " + "min threshold " + "max threshold " + "drop prob % " + "drop rate % " + "diff % " + "tolerance % " + "\n", + .tconfig = &ft5_tconfig, + .tqueue = &ft5_tqueue, + .tvar = &ft5_tvar, + .tlevel = ft5_tlevel, +}; + +static enum test_result func_test5(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint32_t j = 0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + printf("%s", tcfg->htxt); + + for (j = 0; j < tcfg->tqueue->num_queues; j++) { + rte_red_rt_data_init(&tcfg->tqueue->rdata[j]); + tcfg->tqueue->q[j] = 0; + + if (increase_actual_qsize(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + &tcfg->tqueue->q[j], + *tcfg->tlevel, + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + + if (increase_average_qsize(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + &tcfg->tqueue->q[j], + *tcfg->tlevel, + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + } + + for (j = 0; j < tcfg->tqueue->num_queues; j++) { + uint32_t avg = 0; + double drop_rate = 0.0; + double drop_prob = 0.0; + double diff = 0.0; + + tcfg->tvar->dropped[j] = 0; + tcfg->tvar->enqueued[j] = 0; + + enqueue_dequeue_func(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + &tcfg->tqueue->q[j], + tcfg->tvar->num_ops, + &tcfg->tvar->enqueued[j], + &tcfg->tvar->dropped[j]); + + avg = rte_red_get_avg_int(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j]); + if (avg != *tcfg->tlevel) + result = FAIL; + + drop_rate = calc_drop_rate(tcfg->tvar->enqueued[j],tcfg->tvar->dropped[j]); + drop_prob = calc_drop_prob(tcfg->tconfig->min_th, tcfg->tconfig->max_th, + tcfg->tconfig->maxp_inv[tcfg->tqueue->qconfig[j]], + *tcfg->tlevel); + if (!check_drop_rate(&diff, drop_rate, drop_prob, (double)tcfg->tqueue->drop_tolerance)) + result = FAIL; + + printf("%-15u%-15u%-15u%-15u%-15u%-15.4lf%-15.4lf%-15.4lf%-15.4lf\n", + j, tcfg->tqueue->qconfig[j], avg, + tcfg->tconfig->min_th, tcfg->tconfig->max_th, + drop_prob * 100.0, drop_rate * 100.0, + diff, (double)tcfg->tqueue->drop_tolerance); + } +out: + return result; +} + +/** + * Test F6: functional test 6 + */ +static uint32_t ft6_tlevel[] = {1022}; +static uint8_t ft6_wq_log2[] = {9, 8}; +static uint8_t ft6_maxp_inv[] = {10, 20}; +static struct rte_red_config ft6_config[2]; +static struct rte_red ft6_data[4]; +static uint32_t ft6_q[4]; + +static struct test_rte_red_config ft6_tconfig = { + .rconfig = ft6_config, + .num_cfg = RTE_DIM(ft6_config), + .min_th = 32, + .max_th = 1023, + .wq_log2 = ft6_wq_log2, + .maxp_inv = ft6_maxp_inv, +}; + +static struct test_queue ft6_tqueue = { + .rdata = ft6_data, + .num_queues = RTE_DIM(ft6_data), + .qconfig = ft_qconfig, + .q = ft6_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 5, /* 10 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +static struct test_config func_test6_config = { + .ifname = "functional test 6 interface", + .msg = "functional test 6 : use several queues (each with its own run-time data),\n" + " use several RED configurations (such that each configuration is sharte_red by multiple queues),\n" + " increase average queue size to target level,\n" + " dequeue all packets until queue is empty,\n" + " confirm that average queue size is computed correctly while queue is empty\n" + " (this is a larger scale version of functional test 3)\n\n", + .htxt = "queue " + "config " + "q avg before " + "q avg after " + "expected " + "difference % " + "tolerance % " + "result ""\n", + .tconfig = &ft6_tconfig, + .tqueue = &ft6_tqueue, + .tvar = &ft_tvar, + .tlevel = ft6_tlevel, +}; + +static enum test_result func_test6(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint32_t j = 0; + + printf("%s", tcfg->msg); + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + printf("%s", tcfg->htxt); + + for (j = 0; j < tcfg->tqueue->num_queues; j++) { + rte_red_rt_data_init(&tcfg->tqueue->rdata[j]); + tcfg->tqueue->q[j] = 0; + + if (increase_actual_qsize(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + &tcfg->tqueue->q[j], + *tcfg->tlevel, + tcfg->tqueue->q_ramp_up) != 0) { + result = FAIL; + goto out; + } + if (increase_average_qsize(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + &tcfg->tqueue->q[j], + *tcfg->tlevel, + tcfg->tqueue->avg_ramp_up) != 0) { + result = FAIL; + goto out; + } + } + for (j = 0; j < tcfg->tqueue->num_queues; j++) { + double avg_before = 0; + double avg_after = 0; + double exp_avg = 0; + double diff = 0.0; + + avg_before = rte_red_get_avg_float(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j]); + + /** + * empty the queue + */ + tcfg->tqueue->q[j] = 0; + rte_red_mark_queue_empty(&tcfg->tqueue->rdata[j], get_port_ts()); + rte_delay_us(tcfg->tvar->wait_usec); + + /** + * enqueue one packet to recalculate average queue size + */ + if (rte_red_enqueue(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j], + tcfg->tqueue->q[j], + get_port_ts()) == 0) { + tcfg->tqueue->q[j]++; + } else { + printf("%s:%d: packet enqueued on empty queue was dropped\n", __func__, __LINE__); + result = FAIL; + } + + exp_avg = calc_exp_avg_on_empty(avg_before, + (1 << tcfg->tconfig->wq_log2[tcfg->tqueue->qconfig[j]]), + tcfg->tvar->wait_usec); + avg_after = rte_red_get_avg_float(&tcfg->tconfig->rconfig[tcfg->tqueue->qconfig[j]], + &tcfg->tqueue->rdata[j]); + if (!check_avg(&diff, avg_after, exp_avg, (double)tcfg->tqueue->avg_tolerance)) + result = FAIL; + + printf("%-15u%-15u%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15s\n", + j, tcfg->tqueue->qconfig[j], avg_before, avg_after, + exp_avg, diff, (double)tcfg->tqueue->avg_tolerance, + diff <= tcfg->tqueue->avg_tolerance ? "pass" : "fail"); + } +out: + return result; +} + +/** + * setup default values for the performance test structures + */ +static struct rte_red_config pt_wrconfig[1]; +static struct rte_red pt_rtdata[1]; +static uint8_t pt_wq_log2[] = {9}; +static uint8_t pt_maxp_inv[] = {10}; +static uint32_t pt_qconfig[] = {0}; +static uint32_t pt_q[] = {0}; +static uint32_t pt_dropped[] = {0}; +static uint32_t pt_enqueued[] = {0}; + +static struct test_rte_red_config pt_tconfig = { + .rconfig = pt_wrconfig, + .num_cfg = RTE_DIM(pt_wrconfig), + .wq_log2 = pt_wq_log2, + .min_th = 32, + .max_th = 128, + .maxp_inv = pt_maxp_inv, +}; + +static struct test_queue pt_tqueue = { + .rdata = pt_rtdata, + .num_queues = RTE_DIM(pt_rtdata), + .qconfig = pt_qconfig, + .q = pt_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 5, /* 10 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +/** + * enqueue/dequeue packets + */ +static void enqueue_dequeue_perf(struct rte_red_config *red_cfg, + struct rte_red *red, + uint32_t *q, + uint32_t num_ops, + uint32_t *enqueued, + uint32_t *dropped, + struct rdtsc_prof *prof) +{ + uint32_t i = 0; + + for (i = 0; i < num_ops; i++) { + uint64_t ts = 0; + int ret = 0; + /** + * enqueue + */ + ts = get_port_ts(); + rdtsc_prof_start(prof); + ret = rte_red_enqueue(red_cfg, red, *q, ts ); + rdtsc_prof_end(prof); + if (ret == 0) + (*enqueued)++; + else + (*dropped)++; + } +} + +/** + * Setup test structures for tests P1, P2, P3 + * performance tests 1, 2 and 3 + */ +static uint32_t pt1_tlevel[] = {16}; +static uint32_t pt2_tlevel[] = {80}; +static uint32_t pt3_tlevel[] = {144}; + +static struct test_var perf1_tvar = { + .wait_usec = 0, + .num_iterations = 15, + .num_ops = 50000000, + .clk_freq = 0, + .dropped = pt_dropped, + .enqueued = pt_enqueued, + .sleep_sec = 0 +}; + +static struct test_config perf1_test1_config = { + .ifname = "performance test 1 interface", + .msg = "performance test 1 : use one RED configuration,\n" + " set actual and average queue sizes to level below min threshold,\n" + " measure enqueue performance\n\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf1_tvar, + .tlevel = pt1_tlevel, +}; + +static struct test_config perf1_test2_config = { + .ifname = "performance test 2 interface", + .msg = "performance test 2 : use one RED configuration,\n" + " set actual and average queue sizes to level in between min and max thresholds,\n" + " measure enqueue performance\n\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf1_tvar, + .tlevel = pt2_tlevel, +}; + +static struct test_config perf1_test3_config = { + .ifname = "performance test 3 interface", + .msg = "performance test 3 : use one RED configuration,\n" + " set actual and average queue sizes to level above max threshold,\n" + " measure enqueue performance\n\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf1_tvar, + .tlevel = pt3_tlevel, +}; + +/** + * Performance test function to measure enqueue performance. + * This runs performance tests 1, 2 and 3 + */ +static enum test_result perf1_test(struct test_config *tcfg) +{ + enum test_result result = PASS; + struct rdtsc_prof prof = {0, 0, 0, 0, 0.0, NULL}; + uint32_t total = 0; + + printf("%s", tcfg->msg); + + rdtsc_prof_init(&prof, "enqueue"); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + /** + * set average queue size to target level + */ + *tcfg->tqueue->q = *tcfg->tlevel; + + /** + * initialize the rte_red run time data structure + */ + rte_red_rt_data_init(tcfg->tqueue->rdata); + + /** + * set the queue average + */ + rte_red_set_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata, *tcfg->tlevel); + if (rte_red_get_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata) + != *tcfg->tlevel) { + result = FAIL; + goto out; + } + + enqueue_dequeue_perf(tcfg->tconfig->rconfig, + tcfg->tqueue->rdata, + tcfg->tqueue->q, + tcfg->tvar->num_ops, + tcfg->tvar->enqueued, + tcfg->tvar->dropped, + &prof); + + total = *tcfg->tvar->enqueued + *tcfg->tvar->dropped; + + printf("\ntotal: %u, enqueued: %u (%.2lf%%), dropped: %u (%.2lf%%)\n", total, + *tcfg->tvar->enqueued, ((double)(*tcfg->tvar->enqueued) / (double)total) * 100.0, + *tcfg->tvar->dropped, ((double)(*tcfg->tvar->dropped) / (double)total) * 100.0); + + rdtsc_prof_print(&prof); +out: + return result; +} + +/** + * Setup test structures for tests P4, P5, P6 + * performance tests 4, 5 and 6 + */ +static uint32_t pt4_tlevel[] = {16}; +static uint32_t pt5_tlevel[] = {80}; +static uint32_t pt6_tlevel[] = {144}; + +static struct test_var perf2_tvar = { + .wait_usec = 500, + .num_iterations = 10000, + .num_ops = 10000, + .dropped = pt_dropped, + .enqueued = pt_enqueued, + .sleep_sec = 0 +}; + +static struct test_config perf2_test4_config = { + .ifname = "performance test 4 interface", + .msg = "performance test 4 : use one RED configuration,\n" + " set actual and average queue sizes to level below min threshold,\n" + " dequeue all packets until queue is empty,\n" + " measure enqueue performance when queue is empty\n\n", + .htxt = "iteration " + "q avg before " + "q avg after " + "expected " + "difference % " + "tolerance % " + "result ""\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf2_tvar, + .tlevel = pt4_tlevel, +}; + +static struct test_config perf2_test5_config = { + .ifname = "performance test 5 interface", + .msg = "performance test 5 : use one RED configuration,\n" + " set actual and average queue sizes to level in between min and max thresholds,\n" + " dequeue all packets until queue is empty,\n" + " measure enqueue performance when queue is empty\n\n", + .htxt = "iteration " + "q avg before " + "q avg after " + "expected " + "difference " + "tolerance " + "result ""\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf2_tvar, + .tlevel = pt5_tlevel, +}; + +static struct test_config perf2_test6_config = { + .ifname = "performance test 6 interface", + .msg = "performance test 6 : use one RED configuration,\n" + " set actual and average queue sizes to level above max threshold,\n" + " dequeue all packets until queue is empty,\n" + " measure enqueue performance when queue is empty\n\n", + .htxt = "iteration " + "q avg before " + "q avg after " + "expected " + "difference % " + "tolerance % " + "result ""\n", + .tconfig = &pt_tconfig, + .tqueue = &pt_tqueue, + .tvar = &perf2_tvar, + .tlevel = pt6_tlevel, +}; + +/** + * Performance test function to measure enqueue performance when the + * queue is empty. This runs performance tests 4, 5 and 6 + */ +static enum test_result perf2_test(struct test_config *tcfg) +{ + enum test_result result = PASS; + struct rdtsc_prof prof = {0, 0, 0, 0, 0.0, NULL}; + uint32_t total = 0; + uint32_t i = 0; + + printf("%s", tcfg->msg); + + rdtsc_prof_init(&prof, "enqueue"); + + if (test_rte_red_init(tcfg) != PASS) { + result = FAIL; + goto out; + } + + printf("%s", tcfg->htxt); + + for (i = 0; i < tcfg->tvar->num_iterations; i++) { + uint32_t count = 0; + uint64_t ts = 0; + double avg_before = 0; + int ret = 0; + + /** + * set average queue size to target level + */ + *tcfg->tqueue->q = *tcfg->tlevel; + count = (*tcfg->tqueue->rdata).count; + + /** + * initialize the rte_red run time data structure + */ + rte_red_rt_data_init(tcfg->tqueue->rdata); + (*tcfg->tqueue->rdata).count = count; + + /** + * set the queue average + */ + rte_red_set_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata, *tcfg->tlevel); + avg_before = rte_red_get_avg_float(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + if ((avg_before < *tcfg->tlevel) || (avg_before > *tcfg->tlevel)) { + result = FAIL; + goto out; + } + + /** + * empty the queue + */ + *tcfg->tqueue->q = 0; + rte_red_mark_queue_empty(tcfg->tqueue->rdata, get_port_ts()); + + /** + * wait for specified period of time + */ + rte_delay_us(tcfg->tvar->wait_usec); + + /** + * measure performance of enqueue operation while queue is empty + */ + ts = get_port_ts(); + rdtsc_prof_start(&prof); + ret = rte_red_enqueue(tcfg->tconfig->rconfig, tcfg->tqueue->rdata, + *tcfg->tqueue->q, ts ); + rdtsc_prof_end(&prof); + + /** + * gather enqueued/dropped statistics + */ + if (ret == 0) + (*tcfg->tvar->enqueued)++; + else + (*tcfg->tvar->dropped)++; + + /** + * on first and last iteration, confirm that + * average queue size was computed correctly + */ + if ((i == 0) || (i == tcfg->tvar->num_iterations - 1)) { + double avg_after = 0; + double exp_avg = 0; + double diff = 0.0; + int ok = 0; + + avg_after = rte_red_get_avg_float(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + exp_avg = calc_exp_avg_on_empty(avg_before, + (1 << *tcfg->tconfig->wq_log2), + tcfg->tvar->wait_usec); + if (check_avg(&diff, avg_after, exp_avg, (double)tcfg->tqueue->avg_tolerance)) + ok = 1; + printf("%-15u%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15.4lf%-15s\n", + i, avg_before, avg_after, exp_avg, diff, + (double)tcfg->tqueue->avg_tolerance, ok ? "pass" : "fail"); + if (!ok) { + result = FAIL; + goto out; + } + } + } + total = *tcfg->tvar->enqueued + *tcfg->tvar->dropped; + printf("\ntotal: %u, enqueued: %u (%.2lf%%), dropped: %u (%.2lf%%)\n", total, + *tcfg->tvar->enqueued, ((double)(*tcfg->tvar->enqueued) / (double)total) * 100.0, + *tcfg->tvar->dropped, ((double)(*tcfg->tvar->dropped) / (double)total) * 100.0); + + rdtsc_prof_print(&prof); +out: + return result; +} + +/** + * setup default values for overflow test structures + */ +static uint32_t avg_max = 0; +static uint32_t avg_max_bits = 0; + +static struct rte_red_config ovfl_wrconfig[1]; +static struct rte_red ovfl_rtdata[1]; +static uint8_t ovfl_maxp_inv[] = {10}; +static uint32_t ovfl_qconfig[] = {0, 0, 1, 1}; +static uint32_t ovfl_q[] ={0}; +static uint32_t ovfl_dropped[] ={0}; +static uint32_t ovfl_enqueued[] ={0}; +static uint32_t ovfl_tlevel[] = {1023}; +static uint8_t ovfl_wq_log2[] = {12}; + +static struct test_rte_red_config ovfl_tconfig = { + .rconfig = ovfl_wrconfig, + .num_cfg = RTE_DIM(ovfl_wrconfig), + .wq_log2 = ovfl_wq_log2, + .min_th = 32, + .max_th = 1023, + .maxp_inv = ovfl_maxp_inv, +}; + +static struct test_queue ovfl_tqueue = { + .rdata = ovfl_rtdata, + .num_queues = RTE_DIM(ovfl_rtdata), + .qconfig = ovfl_qconfig, + .q = ovfl_q, + .q_ramp_up = 1000000, + .avg_ramp_up = 1000000, + .avg_tolerance = 5, /* 10 percent */ + .drop_tolerance = 50, /* 50 percent */ +}; + +static struct test_var ovfl_tvar = { + .wait_usec = 10000, + .num_iterations = 1, + .num_ops = 10000, + .clk_freq = 0, + .dropped = ovfl_dropped, + .enqueued = ovfl_enqueued, + .sleep_sec = 0 +}; + +static void ovfl_check_avg(uint32_t avg) +{ + if (avg > avg_max) { + double avg_log = 0; + uint32_t bits = 0; + avg_max = avg; + avg_log = log(((double)avg_max)); + avg_log = avg_log / log(2.0); + bits = (uint32_t)ceil(avg_log); + if (bits > avg_max_bits) + avg_max_bits = bits; + } +} + +static struct test_config ovfl_test1_config = { + .ifname = "queue avergage overflow test interface", + .msg = "overflow test 1 : use one RED configuration,\n" + " increase average queue size to target level,\n" + " check maximum number of bits requirte_red to represent avg_s\n\n", + .htxt = "avg queue size " + "wq_log2 " + "fraction bits " + "max queue avg " + "num bits " + "enqueued " + "dropped " + "drop prob % " + "drop rate % " + "\n", + .tconfig = &ovfl_tconfig, + .tqueue = &ovfl_tqueue, + .tvar = &ovfl_tvar, + .tlevel = ovfl_tlevel, +}; + +static enum test_result ovfl_test1(struct test_config *tcfg) +{ + enum test_result result = PASS; + uint32_t avg = 0; + uint32_t i = 0; + double drop_rate = 0.0; + double drop_prob = 0.0; + double diff = 0.0; + int ret = 0; + + printf("%s", tcfg->msg); + + if (test_rte_red_init(tcfg) != PASS) { + + result = FAIL; + goto out; + } + + /** + * reset rte_red run-time data + */ + rte_red_rt_data_init(tcfg->tqueue->rdata); + + /** + * increase actual queue size + */ + for (i = 0; i < tcfg->tqueue->q_ramp_up; i++) { + ret = rte_red_enqueue(tcfg->tconfig->rconfig, tcfg->tqueue->rdata, + *tcfg->tqueue->q, get_port_ts()); + + if (ret == 0) { + if (++(*tcfg->tqueue->q) >= *tcfg->tlevel) + break; + } + } + + /** + * enqueue + */ + for (i = 0; i < tcfg->tqueue->avg_ramp_up; i++) { + ret = rte_red_enqueue(tcfg->tconfig->rconfig, tcfg->tqueue->rdata, + *tcfg->tqueue->q, get_port_ts()); + ovfl_check_avg((*tcfg->tqueue->rdata).avg); + avg = rte_red_get_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + if (avg == *tcfg->tlevel) { + if (ret == 0) + (*tcfg->tvar->enqueued)++; + else + (*tcfg->tvar->dropped)++; + } + } + + /** + * check if target average queue size has been reached + */ + avg = rte_red_get_avg_int(tcfg->tconfig->rconfig, tcfg->tqueue->rdata); + if (avg != *tcfg->tlevel) { + result = FAIL; + goto out; + } + + /** + * check drop rate against drop probability + */ + drop_rate = calc_drop_rate(*tcfg->tvar->enqueued, *tcfg->tvar->dropped); + drop_prob = calc_drop_prob(tcfg->tconfig->min_th, + tcfg->tconfig->max_th, + *tcfg->tconfig->maxp_inv, + *tcfg->tlevel); + if (!check_drop_rate(&diff, drop_rate, drop_prob, (double)tcfg->tqueue->drop_tolerance)) + result = FAIL; + + printf("%s", tcfg->htxt); + + printf("%-16u%-9u%-15u0x%08x %-10u%-10u%-10u%-13.2lf%-13.2lf\n", + avg, *tcfg->tconfig->wq_log2, RTE_RED_SCALING, + avg_max, avg_max_bits, + *tcfg->tvar->enqueued, *tcfg->tvar->dropped, + drop_prob * 100.0, drop_rate * 100.0); +out: + return result; +} + +/** + * define the functional and performance tests to be executed + */ +struct tests func_tests[] = { + { &func_test1_config, func_test1 }, + { &func_test2_config, func_test2 }, + { &func_test3_config, func_test3 }, + { &func_test4_config, func_test4 }, + { &func_test5_config, func_test5 }, + { &func_test6_config, func_test6 }, + { &ovfl_test1_config, ovfl_test1 }, +}; + +struct tests func_tests_quick[] = { + { &func_test1_config, func_test1 }, + { &func_test2_config, func_test2 }, + { &func_test3_config, func_test3 }, + /* no test 4 as it takes a lot of time */ + { &func_test5_config, func_test5 }, + { &func_test6_config, func_test6 }, + { &ovfl_test1_config, ovfl_test1 }, +}; + +struct tests perf_tests[] = { + { &perf1_test1_config, perf1_test }, + { &perf1_test2_config, perf1_test }, + { &perf1_test3_config, perf1_test }, + { &perf2_test4_config, perf2_test }, + { &perf2_test5_config, perf2_test }, + { &perf2_test6_config, perf2_test }, +}; + +/** + * function to execute the required_red tests + */ +static void run_tests(struct tests *test_type, uint32_t test_count, uint32_t *num_tests, uint32_t *num_pass) +{ + enum test_result result = PASS; + uint32_t i = 0; + + for (i = 0; i < test_count; i++) { + printf("\n--------------------------------------------------------------------------------\n"); + result = test_type[i].testfn(test_type[i].testcfg); + (*num_tests)++; + if (result == PASS) { + (*num_pass)++; + printf("-------------------------------------<pass>-------------------------------------\n"); + } else { + printf("-------------------------------------<fail>-------------------------------------\n"); + } + } + return; +} + +/** + * check if functions accept invalid parameters + * + * First, all functions will be called without initialized RED + * Then, all of them will be called with NULL/invalid parameters + * + * Some functions are not tested as they are performance-critical and thus + * don't do any parameter checking. + */ +static int +test_invalid_parameters(void) +{ + struct rte_red_config config; + + if (rte_red_rt_data_init(NULL) == 0) { + printf("rte_red_rt_data_init should have failed!\n"); + return -1; + } + + if (rte_red_config_init(NULL, 0, 0, 0, 0) == 0) { + printf("rte_red_config_init should have failed!\n"); + return -1; + } + + if (rte_red_rt_data_init(NULL) == 0) { + printf("rte_red_rt_data_init should have failed!\n"); + return -1; + } + + /* NULL config */ + if (rte_red_config_init(NULL, 0, 0, 0, 0) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* min_treshold == max_treshold */ + if (rte_red_config_init(&config, 0, 1, 1, 0) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* min_treshold > max_treshold */ + if (rte_red_config_init(&config, 0, 2, 1, 0) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* wq_log2 > RTE_RED_WQ_LOG2_MAX */ + if (rte_red_config_init(&config, + RTE_RED_WQ_LOG2_MAX + 1, 1, 2, 0) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* wq_log2 < RTE_RED_WQ_LOG2_MIN */ + if (rte_red_config_init(&config, + RTE_RED_WQ_LOG2_MIN - 1, 1, 2, 0) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* maxp_inv > RTE_RED_MAXP_INV_MAX */ + if (rte_red_config_init(&config, + RTE_RED_WQ_LOG2_MIN, 1, 2, RTE_RED_MAXP_INV_MAX + 1) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + /* maxp_inv < RTE_RED_MAXP_INV_MIN */ + if (rte_red_config_init(&config, + RTE_RED_WQ_LOG2_MIN, 1, 2, RTE_RED_MAXP_INV_MIN - 1) == 0) { + printf("%i: rte_red_config_init should have failed!\n", __LINE__); + return -1; + } + + return 0; +} + +static void +show_stats(const uint32_t num_tests, const uint32_t num_pass) +{ + if (num_pass == num_tests) + printf("[total: %u, pass: %u]\n", num_tests, num_pass); + else + printf("[total: %u, pass: %u, fail: %u]\n", num_tests, num_pass, + num_tests - num_pass); +} + +static int +tell_the_result(const uint32_t num_tests, const uint32_t num_pass) +{ + return (num_pass == num_tests) ? 0 : 1; +} + +static int +test_red(void) +{ + uint32_t num_tests = 0; + uint32_t num_pass = 0; + + if (test_invalid_parameters() < 0) + return -1; + run_tests(func_tests_quick, RTE_DIM(func_tests_quick), + &num_tests, &num_pass); + show_stats(num_tests, num_pass); + return tell_the_result(num_tests, num_pass); +} + +static int +test_red_perf(void) +{ + uint32_t num_tests = 0; + uint32_t num_pass = 0; + + run_tests(perf_tests, RTE_DIM(perf_tests), &num_tests, &num_pass); + show_stats(num_tests, num_pass); + return tell_the_result(num_tests, num_pass); +} + +static int +test_red_all(void) +{ + uint32_t num_tests = 0; + uint32_t num_pass = 0; + + if (test_invalid_parameters() < 0) + return -1; + + run_tests(func_tests, RTE_DIM(func_tests), &num_tests, &num_pass); + run_tests(perf_tests, RTE_DIM(perf_tests), &num_tests, &num_pass); + show_stats(num_tests, num_pass); + return tell_the_result(num_tests, num_pass); +} + +REGISTER_TEST_COMMAND(red_autotest, test_red); +REGISTER_TEST_COMMAND(red_perf, test_red_perf); +REGISTER_TEST_COMMAND(red_all, test_red_all); |