// SPDX-License-Identifier: BSD-3-Clause
/*
 * Loopback test application
 *
 * Copyright 2015 Google Inc.
 * Copyright 2015 Linaro Ltd.
 */
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdint.h>
#include <poll.h>
#include <sys/types.h>
#include <time.h>
#include <unistd.h>
#include <dirent.h>
#include <signal.h>

#define MAX_NUM_DEVICES 10
#define MAX_SYSFS_PREFIX 0x80
#define MAX_SYSFS_PATH  0x200
#define CSV_MAX_LINE    0x1000
#define SYSFS_MAX_INT   0x20
#define MAX_STR_LEN     255
#define DEFAULT_ASYNC_TIMEOUT 200000

struct dict {
        char *name;
        int type;
};

static struct dict dict[] = {
        {"ping", 2},
        {"transfer", 3},
        {"sink", 4},
        {NULL,}         /* list termination */
};

struct loopback_results {
        float latency_avg;
        uint32_t latency_max;
        uint32_t latency_min;
        uint32_t latency_jitter;

        float request_avg;
        uint32_t request_max;
        uint32_t request_min;
        uint32_t request_jitter;

        float throughput_avg;
        uint32_t throughput_max;
        uint32_t throughput_min;
        uint32_t throughput_jitter;

        float apbridge_unipro_latency_avg;
        uint32_t apbridge_unipro_latency_max;
        uint32_t apbridge_unipro_latency_min;
        uint32_t apbridge_unipro_latency_jitter;

        float gbphy_firmware_latency_avg;
        uint32_t gbphy_firmware_latency_max;
        uint32_t gbphy_firmware_latency_min;
        uint32_t gbphy_firmware_latency_jitter;

        uint32_t error;
};

struct loopback_device {
        char name[MAX_STR_LEN];
        char sysfs_entry[MAX_SYSFS_PATH];
        char debugfs_entry[MAX_SYSFS_PATH];
        struct loopback_results results;
};

struct loopback_test {
        int verbose;
        int debug;
        int raw_data_dump;
        int porcelain;
        int mask;
        int size;
        int iteration_max;
        int aggregate_output;
        int test_id;
        int device_count;
        int list_devices;
        int use_async;
        int async_timeout;
        int async_outstanding_operations;
        int us_wait;
        int file_output;
        int stop_all;
        int poll_count;
        char test_name[MAX_STR_LEN];
        char sysfs_prefix[MAX_SYSFS_PREFIX];
        char debugfs_prefix[MAX_SYSFS_PREFIX];
        struct timespec poll_timeout;
        struct loopback_device devices[MAX_NUM_DEVICES];
        struct loopback_results aggregate_results;
        struct pollfd fds[MAX_NUM_DEVICES];
};

struct loopback_test t;

/* Helper macros to calculate the aggregate results for all devices */
static inline int device_enabled(struct loopback_test *t, int dev_idx);

#define GET_MAX(field)                                                  \
static int get_##field##_aggregate(struct loopback_test *t)             \
{                                                                       \
        uint32_t max = 0;                                               \
        int i;                                                          \
        for (i = 0; i < t->device_count; i++) {                         \
                if (!device_enabled(t, i))                              \
                        continue;                                       \
                if (t->devices[i].results.field > max)                  \
                        max = t->devices[i].results.field;              \
        }                                                               \
        return max;                                                     \
}                                                                       \

#define GET_MIN(field)                                                  \
static int get_##field##_aggregate(struct loopback_test *t)             \
{                                                                       \
        uint32_t min = ~0;                                              \
        int i;                                                          \
        for (i = 0; i < t->device_count; i++) {                         \
                if (!device_enabled(t, i))                              \
                        continue;                                       \
                if (t->devices[i].results.field < min)                  \
                        min = t->devices[i].results.field;              \
        }                                                               \
        return min;                                                     \
}                                                                       \

#define GET_AVG(field)                                                  \
static int get_##field##_aggregate(struct loopback_test *t)             \
{                                                                       \
        uint32_t val = 0;                                               \
        uint32_t count = 0;                                             \
        int i;                                                          \
        for (i = 0; i < t->device_count; i++) {                         \
                if (!device_enabled(t, i))                              \
                        continue;                                       \
                count++;                                                \
                val += t->devices[i].results.field;                     \
        }                                                               \
        if (count)                                                      \
                val /= count;                                           \
        return val;                                                     \
}                                                                       \

GET_MAX(throughput_max);
GET_MAX(request_max);
GET_MAX(latency_max);
GET_MAX(apbridge_unipro_latency_max);
GET_MAX(gbphy_firmware_latency_max);
GET_MIN(throughput_min);
GET_MIN(request_min);
GET_MIN(latency_min);
GET_MIN(apbridge_unipro_latency_min);
GET_MIN(gbphy_firmware_latency_min);
GET_AVG(throughput_avg);
GET_AVG(request_avg);
GET_AVG(latency_avg);
GET_AVG(apbridge_unipro_latency_avg);
GET_AVG(gbphy_firmware_latency_avg);

void abort(void)
{
        _exit(1);
}

void usage(void)
{
        fprintf(stderr, "Usage: loopback_test TEST [SIZE] ITERATIONS [SYSPATH] [DBGPATH]\n\n"
        "  Run TEST for a number of ITERATIONS with operation data SIZE bytes\n"
        "  TEST may be \'ping\' \'transfer\' or \'sink\'\n"
        "  SIZE indicates the size of transfer <= greybus max payload bytes\n"
        "  ITERATIONS indicates the number of times to execute TEST at SIZE bytes\n"
        "             Note if ITERATIONS is set to zero then this utility will\n"
        "             initiate an infinite (non terminating) test and exit\n"
        "             without logging any metrics data\n"
        "  SYSPATH indicates the sysfs path for the loopback greybus entries e.g.\n"
        "          /sys/bus/greybus/devices\n"
        "  DBGPATH indicates the debugfs path for the loopback greybus entries e.g.\n"
        "          /sys/kernel/debug/gb_loopback/\n"
        " Mandatory arguments\n"
        "   -t     must be one of the test names - sink, transfer or ping\n"
        "   -i     iteration count - the number of iterations to run the test over\n"
        " Optional arguments\n"
        "   -S     sysfs location - location for greybus 'endo' entries default /sys/bus/greybus/devices/\n"
        "   -D     debugfs location - location for loopback debugfs entries default /sys/kernel/debug/gb_loopback/\n"
        "   -s     size of data packet to send during test - defaults to zero\n"
        "   -m     mask - a bit mask of connections to include example: -m 8 = 4th connection -m 9 = 1st and 4th connection etc\n"
        "                 default is zero which means broadcast to all connections\n"
        "   -v     verbose output\n"
        "   -d     debug output\n"
        "   -r     raw data output - when specified the full list of latency values are included in the output CSV\n"
        "   -p     porcelain - when specified printout is in a user-friendly non-CSV format. This option suppresses writing to CSV file\n"
        "   -a     aggregate - show aggregation of all enabled devices\n"
        "   -l     list found loopback devices and exit\n"
        "   -x     Async - Enable async transfers\n"
        "   -o     Async Timeout - Timeout in uSec for async operations\n"
        "   -O     Poll loop time out in seconds(max time a test is expected to last, default: 30sec)\n"
        "   -c     Max number of outstanding operations for async operations\n"
        "   -w     Wait in uSec between operations\n"
        "   -z     Enable output to a CSV file (incompatible with -p)\n"
        "   -f     When starting new loopback test, stop currently running tests on all devices\n"
        "Examples:\n"
        "  Send 10000 transfers with a packet size of 128 bytes to all active connections\n"
        "  loopback_test -t transfer -s 128 -i 10000 -S /sys/bus/greybus/devices/ -D /sys/kernel/debug/gb_loopback/\n"
        "  loopback_test -t transfer -s 128 -i 10000 -m 0\n"
        "  Send 10000 transfers with a packet size of 128 bytes to connection 1 and 4\n"
        "  loopback_test -t transfer -s 128 -i 10000 -m 9\n"
        "  loopback_test -t ping -s 0 128 -i -S /sys/bus/greybus/devices/ -D /sys/kernel/debug/gb_loopback/\n"
        "  loopback_test -t sink -s 2030 -i 32768 -S /sys/bus/greybus/devices/ -D /sys/kernel/debug/gb_loopback/\n");
        abort();
}

static inline int device_enabled(struct loopback_test *t, int dev_idx)
{
        if (!t->mask || (t->mask & (1 << dev_idx)))
                return 1;

        return 0;
}

static void show_loopback_devices(struct loopback_test *t)
{
        int i;

        if (t->device_count == 0) {
                printf("No loopback devices.\n");
                return;
        }

        for (i = 0; i < t->device_count; i++)
                printf("device[%d] = %s\n", i, t->devices[i].name);

}

int open_sysfs(const char *sys_pfx, const char *node, int flags)
{
        int fd;
        char path[MAX_SYSFS_PATH];

        snprintf(path, sizeof(path), "%s%s", sys_pfx, node);
        fd = open(path, flags);
        if (fd < 0) {
                fprintf(stderr, "unable to open %s\n", path);
                abort();
        }
        return fd;
}

int read_sysfs_int_fd(int fd, const char *sys_pfx, const char *node)
{
        char buf[SYSFS_MAX_INT];

        if (read(fd, buf, sizeof(buf)) < 0) {
                fprintf(stderr, "unable to read from %s%s %s\n", sys_pfx, node,
                        strerror(errno));
                close(fd);
                abort();
        }
        return atoi(buf);
}

float read_sysfs_float_fd(int fd, const char *sys_pfx, const char *node)
{
        char buf[SYSFS_MAX_INT];

        if (read(fd, buf, sizeof(buf)) < 0) {

                fprintf(stderr, "unable to read from %s%s %s\n", sys_pfx, node,
                        strerror(errno));
                close(fd);
                abort();
        }
        return atof(buf);
}

int read_sysfs_int(const char *sys_pfx, const char *node)
{
        int fd, val;

        fd = open_sysfs(sys_pfx, node, O_RDONLY);
        val = read_sysfs_int_fd(fd, sys_pfx, node);
        close(fd);
        return val;
}

float read_sysfs_float(const char *sys_pfx, const char *node)
{
        int fd;
        float val;

        fd = open_sysfs(sys_pfx, node, O_RDONLY);
        val = read_sysfs_float_fd(fd, sys_pfx, node);
        close(fd);
        return val;
}

void write_sysfs_val(const char *sys_pfx, const char *node, int val)
{
        int fd, len;
        char buf[SYSFS_MAX_INT];

        fd = open_sysfs(sys_pfx, node, O_RDWR);
        len = snprintf(buf, sizeof(buf), "%d", val);
        if (write(fd, buf, len) < 0) {
                fprintf(stderr, "unable to write to %s%s %s\n", sys_pfx, node,
                        strerror(errno));
                close(fd);
                abort();
        }
        close(fd);
}

static int get_results(struct loopback_test *t)
{
        struct loopback_device *d;
        struct loopback_results *r;
        int i;

        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;

                d = &t->devices[i];
                r = &d->results;

                r->error = read_sysfs_int(d->sysfs_entry, "error");
                r->request_min = read_sysfs_int(d->sysfs_entry, "requests_per_second_min");
                r->request_max = read_sysfs_int(d->sysfs_entry, "requests_per_second_max");
                r->request_avg = read_sysfs_float(d->sysfs_entry, "requests_per_second_avg");

                r->latency_min = read_sysfs_int(d->sysfs_entry, "latency_min");
                r->latency_max = read_sysfs_int(d->sysfs_entry, "latency_max");
                r->latency_avg = read_sysfs_float(d->sysfs_entry, "latency_avg");

                r->throughput_min = read_sysfs_int(d->sysfs_entry, "throughput_min");
                r->throughput_max = read_sysfs_int(d->sysfs_entry, "throughput_max");
                r->throughput_avg = read_sysfs_float(d->sysfs_entry, "throughput_avg");

                r->apbridge_unipro_latency_min =
                        read_sysfs_int(d->sysfs_entry, "apbridge_unipro_latency_min");
                r->apbridge_unipro_latency_max =
                        read_sysfs_int(d->sysfs_entry, "apbridge_unipro_latency_max");
                r->apbridge_unipro_latency_avg =
                        read_sysfs_float(d->sysfs_entry, "apbridge_unipro_latency_avg");

                r->gbphy_firmware_latency_min =
                        read_sysfs_int(d->sysfs_entry, "gbphy_firmware_latency_min");
                r->gbphy_firmware_latency_max =
                        read_sysfs_int(d->sysfs_entry, "gbphy_firmware_latency_max");
                r->gbphy_firmware_latency_avg =
                        read_sysfs_float(d->sysfs_entry, "gbphy_firmware_latency_avg");

                r->request_jitter = r->request_max - r->request_min;
                r->latency_jitter = r->latency_max - r->latency_min;
                r->throughput_jitter = r->throughput_max - r->throughput_min;
                r->apbridge_unipro_latency_jitter =
                        r->apbridge_unipro_latency_max - r->apbridge_unipro_latency_min;
                r->gbphy_firmware_latency_jitter =
                        r->gbphy_firmware_latency_max - r->gbphy_firmware_latency_min;

        }

        /*calculate the aggregate results of all enabled devices */
        if (t->aggregate_output) {
                r = &t->aggregate_results;

                r->request_min = get_request_min_aggregate(t);
                r->request_max = get_request_max_aggregate(t);
                r->request_avg = get_request_avg_aggregate(t);

                r->latency_min = get_latency_min_aggregate(t);
                r->latency_max = get_latency_max_aggregate(t);
                r->latency_avg = get_latency_avg_aggregate(t);

                r->throughput_min = get_throughput_min_aggregate(t);
                r->throughput_max = get_throughput_max_aggregate(t);
                r->throughput_avg = get_throughput_avg_aggregate(t);

                r->apbridge_unipro_latency_min =
                        get_apbridge_unipro_latency_min_aggregate(t);
                r->apbridge_unipro_latency_max =
                        get_apbridge_unipro_latency_max_aggregate(t);
                r->apbridge_unipro_latency_avg =
                        get_apbridge_unipro_latency_avg_aggregate(t);

                r->gbphy_firmware_latency_min =
                        get_gbphy_firmware_latency_min_aggregate(t);
                r->gbphy_firmware_latency_max =
                        get_gbphy_firmware_latency_max_aggregate(t);
                r->gbphy_firmware_latency_avg =
                        get_gbphy_firmware_latency_avg_aggregate(t);

                r->request_jitter = r->request_max - r->request_min;
                r->latency_jitter = r->latency_max - r->latency_min;
                r->throughput_jitter = r->throughput_max - r->throughput_min;
                r->apbridge_unipro_latency_jitter =
                        r->apbridge_unipro_latency_max - r->apbridge_unipro_latency_min;
                r->gbphy_firmware_latency_jitter =
                        r->gbphy_firmware_latency_max - r->gbphy_firmware_latency_min;

        }

        return 0;
}

int format_output(struct loopback_test *t,
                  struct loopback_results *r,
                  const char *dev_name,
                  char *buf, int buf_len,
                  struct tm *tm)
{
        int len = 0;

        memset(buf, 0x00, buf_len);
        len = snprintf(buf, buf_len, "%u-%u-%u %u:%u:%u",
                       tm->tm_year + 1900, tm->tm_mon + 1, tm->tm_mday,
                       tm->tm_hour, tm->tm_min, tm->tm_sec);

        if (t->porcelain) {
                len += snprintf(&buf[len], buf_len - len,
                        "\n test:\t\t\t%s\n path:\t\t\t%s\n size:\t\t\t%u\n iterations:\t\t%u\n errors:\t\t%u\n async:\t\t\t%s\n",
                        t->test_name,
                        dev_name,
                        t->size,
                        t->iteration_max,
                        r->error,
                        t->use_async ? "Enabled" : "Disabled");

                len += snprintf(&buf[len], buf_len - len,
                        " requests per-sec:\tmin=%u, max=%u, average=%f, jitter=%u\n",
                        r->request_min,
                        r->request_max,
                        r->request_avg,
                        r->request_jitter);

                len += snprintf(&buf[len], buf_len - len,
                        " ap-throughput B/s:\tmin=%u max=%u average=%f jitter=%u\n",
                        r->throughput_min,
                        r->throughput_max,
                        r->throughput_avg,
                        r->throughput_jitter);
                len += snprintf(&buf[len], buf_len - len,
                        " ap-latency usec:\tmin=%u max=%u average=%f jitter=%u\n",
                        r->latency_min,
                        r->latency_max,
                        r->latency_avg,
                        r->latency_jitter);
                len += snprintf(&buf[len], buf_len - len,
                        " apbridge-latency usec:\tmin=%u max=%u average=%f jitter=%u\n",
                        r->apbridge_unipro_latency_min,
                        r->apbridge_unipro_latency_max,
                        r->apbridge_unipro_latency_avg,
                        r->apbridge_unipro_latency_jitter);

                len += snprintf(&buf[len], buf_len - len,
                        " gbphy-latency usec:\tmin=%u max=%u average=%f jitter=%u\n",
                        r->gbphy_firmware_latency_min,
                        r->gbphy_firmware_latency_max,
                        r->gbphy_firmware_latency_avg,
                        r->gbphy_firmware_latency_jitter);

        } else {
                len += snprintf(&buf[len], buf_len - len, ",%s,%s,%u,%u,%u",
                        t->test_name, dev_name, t->size, t->iteration_max,
                        r->error);

                len += snprintf(&buf[len], buf_len - len, ",%u,%u,%f,%u",
                        r->request_min,
                        r->request_max,
                        r->request_avg,
                        r->request_jitter);

                len += snprintf(&buf[len], buf_len - len, ",%u,%u,%f,%u",
                        r->latency_min,
                        r->latency_max,
                        r->latency_avg,
                        r->latency_jitter);

                len += snprintf(&buf[len], buf_len - len, ",%u,%u,%f,%u",
                        r->throughput_min,
                        r->throughput_max,
                        r->throughput_avg,
                        r->throughput_jitter);

                len += snprintf(&buf[len], buf_len - len, ",%u,%u,%f,%u",
                        r->apbridge_unipro_latency_min,
                        r->apbridge_unipro_latency_max,
                        r->apbridge_unipro_latency_avg,
                        r->apbridge_unipro_latency_jitter);

                len += snprintf(&buf[len], buf_len - len, ",%u,%u,%f,%u",
                        r->gbphy_firmware_latency_min,
                        r->gbphy_firmware_latency_max,
                        r->gbphy_firmware_latency_avg,
                        r->gbphy_firmware_latency_jitter);
        }

        printf("\n%s\n", buf);

        return len;
}

static int log_results(struct loopback_test *t)
{
        int fd, i, len, ret;
        struct tm tm;
        time_t local_time;
        char file_name[MAX_SYSFS_PATH];
        char data[CSV_MAX_LINE];

        local_time = time(NULL);
        tm = *localtime(&local_time);

        /*
         * file name will test_name_size_iteration_max.csv
         * every time the same test with the same parameters is run we will then
         * append to the same CSV with datestamp - representing each test
         * dataset.
         */
        if (t->file_output && !t->porcelain) {
                snprintf(file_name, sizeof(file_name), "%s_%d_%d.csv",
                         t->test_name, t->size, t->iteration_max);

                fd = open(file_name, O_WRONLY | O_CREAT | O_APPEND, 0644);
                if (fd < 0) {
                        fprintf(stderr, "unable to open %s for appendation\n", file_name);
                        abort();
                }

        }
        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;

                len = format_output(t, &t->devices[i].results,
                                    t->devices[i].name,
                                    data, sizeof(data), &tm);
                if (t->file_output && !t->porcelain) {
                        ret = write(fd, data, len);
                        if (ret == -1)
                                fprintf(stderr, "unable to write %d bytes to csv.\n", len);
                }

        }


        if (t->aggregate_output) {
                len = format_output(t, &t->aggregate_results, "aggregate",
                                    data, sizeof(data), &tm);
                if (t->file_output && !t->porcelain) {
                        ret = write(fd, data, len);
                        if (ret == -1)
                                fprintf(stderr, "unable to write %d bytes to csv.\n", len);
                }
        }

        if (t->file_output && !t->porcelain)
                close(fd);

        return 0;
}

int is_loopback_device(const char *path, const char *node)
{
        char file[MAX_SYSFS_PATH];

        snprintf(file, MAX_SYSFS_PATH, "%s%s/iteration_count", path, node);
        if (access(file, F_OK) == 0)
                return 1;
        return 0;
}

int find_loopback_devices(struct loopback_test *t)
{
        struct dirent **namelist;
        int i, n, ret;
        unsigned int dev_id;
        struct loopback_device *d;

        n = scandir(t->sysfs_prefix, &namelist, NULL, alphasort);
        if (n < 0) {
                perror("scandir");
                ret = -ENODEV;
                goto baddir;
        }

        /* Don't include '.' and '..' */
        if (n <= 2) {
                ret = -ENOMEM;
                goto done;
        }

        for (i = 0; i < n; i++) {
                ret = sscanf(namelist[i]->d_name, "gb_loopback%u", &dev_id);
                if (ret != 1)
                        continue;

                if (!is_loopback_device(t->sysfs_prefix, namelist[i]->d_name))
                        continue;

                if (t->device_count == MAX_NUM_DEVICES) {
                        fprintf(stderr, "max number of devices reached!\n");
                        break;
                }

                d = &t->devices[t->device_count++];
                snprintf(d->name, MAX_STR_LEN, "gb_loopback%u", dev_id);

                snprintf(d->sysfs_entry, MAX_SYSFS_PATH, "%s%s/",
                         t->sysfs_prefix, d->name);

                snprintf(d->debugfs_entry, MAX_SYSFS_PATH, "%sraw_latency_%s",
                         t->debugfs_prefix, d->name);

                if (t->debug)
                        printf("add %s %s\n", d->sysfs_entry, d->debugfs_entry);
        }

        ret = 0;
done:
        for (i = 0; i < n; i++)
                free(namelist[i]);
        free(namelist);
baddir:
        return ret;
}

static int open_poll_files(struct loopback_test *t)
{
        struct loopback_device *dev;
        char buf[MAX_SYSFS_PATH + MAX_STR_LEN];
        char dummy;
        int fds_idx = 0;
        int i;

        for (i = 0; i < t->device_count; i++) {
                dev = &t->devices[i];

                if (!device_enabled(t, i))
                        continue;

                snprintf(buf, sizeof(buf), "%s%s", dev->sysfs_entry, "iteration_count");
                t->fds[fds_idx].fd = open(buf, O_RDONLY);
                if (t->fds[fds_idx].fd < 0) {
                        fprintf(stderr, "Error opening poll file!\n");
                        goto err;
                }
                read(t->fds[fds_idx].fd, &dummy, 1);
                t->fds[fds_idx].events = POLLERR | POLLPRI;
                t->fds[fds_idx].revents = 0;
                fds_idx++;
        }

        t->poll_count = fds_idx;

        return 0;

err:
        for (i = 0; i < fds_idx; i++)
                close(t->fds[i].fd);

        return -1;
}

static int close_poll_files(struct loopback_test *t)
{
        int i;
        for (i = 0; i < t->poll_count; i++)
                close(t->fds[i].fd);

        return 0;
}
static int is_complete(struct loopback_test *t)
{
        int iteration_count;
        int i;

        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;

                iteration_count = read_sysfs_int(t->devices[i].sysfs_entry,
                                                 "iteration_count");

                /* at least one device did not finish yet */
                if (iteration_count != t->iteration_max)
                        return 0;
        }

        return 1;
}

static void stop_tests(struct loopback_test *t)
{
        int i;

        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;
                write_sysfs_val(t->devices[i].sysfs_entry, "type", 0);
        }
}

static void handler(int sig) { /* do nothing */  }

static int wait_for_complete(struct loopback_test *t)
{
        int number_of_events = 0;
        char dummy;
        int ret;
        int i;
        struct timespec *ts = NULL;
        struct sigaction sa;
        sigset_t mask_old, mask;

        sigemptyset(&mask);
        sigemptyset(&mask_old);
        sigaddset(&mask, SIGINT);
        sigprocmask(SIG_BLOCK, &mask, &mask_old);

        sa.sa_handler = handler;
        sa.sa_flags = 0;
        sigemptyset(&sa.sa_mask);
        if (sigaction(SIGINT, &sa, NULL) == -1) {
                fprintf(stderr, "sigaction error\n");
                return -1;
        }

        if (t->poll_timeout.tv_sec != 0)
                ts = &t->poll_timeout;

        while (1) {

                ret = ppoll(t->fds, t->poll_count, ts, &mask_old);
                if (ret <= 0) {
                        stop_tests(t);
                        fprintf(stderr, "Poll exit with errno %d\n", errno);
                        return -1;
                }

                for (i = 0; i < t->poll_count; i++) {
                        if (t->fds[i].revents & POLLPRI) {
                                /* Dummy read to clear the event */
                                read(t->fds[i].fd, &dummy, 1);
                                number_of_events++;
                        }
                }

                if (number_of_events == t->poll_count)
                        break;
        }

        if (!is_complete(t)) {
                fprintf(stderr, "Iteration count did not finish!\n");
                return -1;
        }

        return 0;
}

static void prepare_devices(struct loopback_test *t)
{
        int i;

        /*
         * Cancel any running tests on enabled devices. If
         * stop_all option is given, stop test on all devices.
         */
        for (i = 0; i < t->device_count; i++)
                if (t->stop_all || device_enabled(t, i))
                        write_sysfs_val(t->devices[i].sysfs_entry, "type", 0);


        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;

                write_sysfs_val(t->devices[i].sysfs_entry, "us_wait",
                                t->us_wait);

                /* Set operation size */
                write_sysfs_val(t->devices[i].sysfs_entry, "size", t->size);

                /* Set iterations */
                write_sysfs_val(t->devices[i].sysfs_entry, "iteration_max",
                                t->iteration_max);

                if (t->use_async) {
                        write_sysfs_val(t->devices[i].sysfs_entry, "async", 1);
                        write_sysfs_val(t->devices[i].sysfs_entry,
                                        "timeout", t->async_timeout);
                        write_sysfs_val(t->devices[i].sysfs_entry,
                                        "outstanding_operations_max",
                                        t->async_outstanding_operations);
                } else {
                        write_sysfs_val(t->devices[i].sysfs_entry, "async", 0);
                }
        }
}

static int start(struct loopback_test *t)
{
        int i;

        /* the test starts by writing test_id to the type file. */
        for (i = 0; i < t->device_count; i++) {
                if (!device_enabled(t, i))
                        continue;

                write_sysfs_val(t->devices[i].sysfs_entry, "type", t->test_id);
        }

        return 0;
}


void loopback_run(struct loopback_test *t)
{
        int i;
        int ret;

        for (i = 0; dict[i].name != NULL; i++) {
                if (strstr(dict[i].name, t->test_name))
                        t->test_id = dict[i].type;
        }
        if (!t->test_id) {
                fprintf(stderr, "invalid test %s\n", t->test_name);
                usage();
                return;
        }

        prepare_devices(t);

        ret = open_poll_files(t);
        if (ret)
                goto err;

        start(t);

        ret = wait_for_complete(t);
        close_poll_files(t);
        if (ret)
                goto err;


        get_results(t);

        log_results(t);

        return;

err:
        printf("Error running test\n");
        return;
}

static int sanity_check(struct loopback_test *t)
{
        int i;

        if (t->device_count == 0) {
                fprintf(stderr, "No loopback devices found\n");
                return -1;
        }

        for (i = 0; i < MAX_NUM_DEVICES; i++) {
                if (!device_enabled(t, i))
                        continue;

                if (t->mask && !strcmp(t->devices[i].name, "")) {
                        fprintf(stderr, "Bad device mask %x\n", (1 << i));
                        return -1;
                }

        }


        return 0;
}

int main(int argc, char *argv[])
{
        int o, ret;
        char *sysfs_prefix = "/sys/class/gb_loopback/";
        char *debugfs_prefix = "/sys/kernel/debug/gb_loopback/";

        memset(&t, 0, sizeof(t));

        while ((o = getopt(argc, argv,
                           "t:s:i:S:D:m:v::d::r::p::a::l::x::o:O:c:w:z::f::")) != -1) {
                switch (o) {
                case 't':
                        snprintf(t.test_name, MAX_STR_LEN, "%s", optarg);
                        break;
                case 's':
                        t.size = atoi(optarg);
                        break;
                case 'i':
                        t.iteration_max = atoi(optarg);
                        break;
                case 'S':
                        snprintf(t.sysfs_prefix, MAX_SYSFS_PREFIX, "%s", optarg);
                        break;
                case 'D':
                        snprintf(t.debugfs_prefix, MAX_SYSFS_PREFIX, "%s", optarg);
                        break;
                case 'm':
                        t.mask = atol(optarg);
                        break;
                case 'v':
                        t.verbose = 1;
                        break;
                case 'd':
                        t.debug = 1;
                        break;
                case 'r':
                        t.raw_data_dump = 1;
                        break;
                case 'p':
                        t.porcelain = 1;
                        break;
                case 'a':
                        t.aggregate_output = 1;
                        break;
                case 'l':
                        t.list_devices = 1;
                        break;
                case 'x':
                        t.use_async = 1;
                        break;
                case 'o':
                        t.async_timeout = atoi(optarg);
                        break;
                case 'O':
                        t.poll_timeout.tv_sec = atoi(optarg);
                        break;
                case 'c':
                        t.async_outstanding_operations = atoi(optarg);
                        break;
                case 'w':
                        t.us_wait = atoi(optarg);
                        break;
                case 'z':
                        t.file_output = 1;
                        break;
                case 'f':
                        t.stop_all = 1;
                        break;
                default:
                        usage();
                        return -EINVAL;
                }
        }

        if (!strcmp(t.sysfs_prefix, ""))
                snprintf(t.sysfs_prefix, MAX_SYSFS_PREFIX, "%s", sysfs_prefix);

        if (!strcmp(t.debugfs_prefix, ""))
                snprintf(t.debugfs_prefix, MAX_SYSFS_PREFIX, "%s", debugfs_prefix);

        ret = find_loopback_devices(&t);
        if (ret)
                return ret;
        ret = sanity_check(&t);
        if (ret)
                return ret;

        if (t.list_devices) {
                show_loopback_devices(&t);
                return 0;
        }

        if (t.test_name[0] == '\0' || t.iteration_max == 0)
                usage();

        if (t.async_timeout == 0)
                t.async_timeout = DEFAULT_ASYNC_TIMEOUT;

        loopback_run(&t);

        return 0;
}