greybus: tools: Add tools directory to greybus repo and add loopback

Move the loopback test to the greybus main repo, as we will be adding
more tests over time and it doesn't need to be burried in the gbsim
repo.

This moves the latest version from gbsim to this repo and fixes up the
Makefile to be a bit more "smart" when building the code.

Signed-off-by: Greg Kroah-Hartman <gregkh@google.com>
This commit is contained in:
Greg Kroah-Hartman 2015-12-15 12:46:22 -08:00
parent 8e77c83e2a
commit 6b0658f687
7 changed files with 1371 additions and 1 deletions

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@ -12,3 +12,4 @@ tags
cscope.*
ncscope.*
*.patch
tools/loopback_test

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@ -85,7 +85,10 @@ ccflags-y := -Wall
# needed for trace events
ccflags-y += -I$(src)
all: module
all: module tools
tools::
$(MAKE) -C tools KERNELDIR=$(realpath $(KERNELDIR))
module:
$(MAKE) -C $(KERNELDIR) M=$(PWD)
@ -97,6 +100,7 @@ clean:
rm -f *.o *~ core .depend .*.cmd *.ko *.mod.c
rm -f Module.markers Module.symvers modules.order
rm -rf .tmp_versions Modules.symvers
$(MAKE) -C tools clean
coccicheck:
$(MAKE) -C $(KERNELDIR) M=$(PWD) coccicheck

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@ -0,0 +1,10 @@
LOCAL_PATH:= $(call my-dir)
include $(CLEAR_VARS)
LOCAL_SRC_FILES:= loopback_test.c
LOCAL_MODULE_TAGS := optional
LOCAL_MODULE := gb_loopback_test
include $(BUILD_EXECUTABLE)

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@ -0,0 +1,31 @@
ifeq ($(strip $(V)), 1)
Q =
else
Q = @
endif
CFLAGS += -std=gnu99 -Wall -Wextra -g \
-D_GNU_SOURCE \
-Wno-unused-parameter \
-Wmaybe-uninitialized \
-Wredundant-decls \
-Wcast-align \
-Wsign-compare \
-Wno-missing-field-initializers
CC := $(CROSS_COMPILE)gcc
TOOLS = loopback_test
all: $(TOOLS)
%.o: %.c ../greybus_protocols.h
@echo ' TARGET_CC $@'
$(Q)$(CC) $(CFLAGS) -c $< -o $@
loopback_%: loopback_%.o
@echo ' TARGET_LD $@'
$(Q)$(CC) $(CFLAGS) $(LDFLAGS) $^ -o $@
clean::
rm -f *.o $(TOOLS)

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@ -0,0 +1,198 @@
1 - LOOPBACK DRIVER
The driver implements the main logic of the loopback test and provides
sysfs files to configure the test and retrieve the results.
A user could run a test without the need of the test application given
that he understands the sysfs interface of the loopback driver.
The loopback kernel driver needs to be loaded and at least one module
with the loopback feature enabled must be present for the sysfs files to be
created and for the loopback test application to be able to run.
To load the module:
# modprobe gb-loopback
When the module is probed, New files are available on the sysfs
directory of the detected loopback device.
(typically under "/sys/bus/graybus/devices").
Here is a short summary of the sysfs interface files that should be visible:
* Loopback Configuration Files:
async - Use asynchronous operations.
iteration_max - Number of tests iterations to perform.
size - payload size of the transfer.
timeout - The number of microseconds to give an individual
asynchronous request before timing out.
us_wait - Time to wait between 2 messages
type - By writing the test type to this file, the test starts.
Valid tests are:
0 stop the test
2 - ping
3 - transfer
4 - sink
* Loopback feedback files:
error - number of errors that have occurred.
iteration_count - Number of iterations performed.
requests_completed - Number of requests successfully completed.
requests_timedout - Number of requests that have timed out.
timeout_max - Max allowed timeout
timeout_min - Min allowed timeout.
* Loopback result files:
apbridge_unipro_latency_avg
apbridge_unipro_latency_max
apbridge_unipro_latency_min
gpbridge_firmware_latency_avg
gpbridge_firmware_latency_max
gpbridge_firmware_latency_min
requests_per_second_avg
requests_per_second_max
requests_per_second_min
latency_avg
latency_max
latency_min
throughput_avg
throughput_max
throughput_min
2 - LOOPBACK TEST APPLICATION
The loopback test application manages and formats the results provided by
the loopback kernel module. The purpose of this application
is to:
- Start and manage multiple loopback device tests concurrently.
- Calculate the aggregate results for multiple devices.
- Gather and format test results (csv or human readable).
The best way to get up to date usage information for the application is
usually to pass the "-h" parameter.
Here is the summary of the available options:
Mandatory arguments
-t must be one of the test names - sink, transfer or ping
-i iteration count - the number of iterations to run the test over
Optional arguments
-S sysfs location - location for greybus 'endo' entires default /sys/bus/greybus/devices/
-D debugfs location - location for loopback debugfs entries default /sys/kernel/debug/gb_loopback/
-s size of data packet to send during test - defaults to zero
-m mask - a bit mask of connections to include example: -m 8 = 4th connection -m 9 = 1st and 4th connection etc
default is zero which means broadcast to all connections
-v verbose output
-d debug output
-r raw data output - when specified the full list of latency values are included in the output CSV
-p porcelain - when specified printout is in a user-friendly non-CSV format. This option suppresses writing to CSV file
-a aggregate - show aggregation of all enabled devies
-l list found loopback devices and exit.
-x Async - Enable async transfers.
-o Timeout - Timeout in microseconds for async operations.
3 - REAL WORLD EXAMPLE USAGES
3.1 - Using the driver sysfs files to run a test on a single device:
* Run a 1000 transfers of a 100 byte packet. Each transfer is started only
after the previous one finished successfully:
echo 0 > /sys/bus/greybus/devices/1-2.17/type
echo 0 > /sys/bus/greybus/devices/1-2.17/async
echo 2000 > /sys/bus/greybus/devices/1-2.17/us_wait
echo 100 > /sys/bus/greybus/devices/1-2.17/size
echo 1000 > /sys/bus/greybus/devices/1-2.17/iteration_max
echo 0 > /sys/bus/greybus/devices/1-2.17/mask
echo 200000 > /sys/bus/greybus/devices/1-2.17/timeout
echo 3 > /sys/bus/greybus/devices/1-2.17/type
* Run a 1000 transfers of a 100 byte packet. Transfers are started without
waiting for the previous one to finish:
echo 0 > /sys/bus/greybus/devices/1-2.17/type
echo 3 > /sys/bus/greybus/devices/1-2.17/async
echo 0 > /sys/bus/greybus/devices/1-2.17/us_wait
echo 100 > /sys/bus/greybus/devices/1-2.17/size
echo 1000 > /sys/bus/greybus/devices/1-2.17/iteration_max
echo 0 > /sys/bus/greybus/devices/1-2.17/mask
echo 200000 > /sys/bus/greybus/devices/1-2.17/timeout
echo 3 > /sys/bus/greybus/devices/1-2.17/type
* Read the results from sysfs:
cat /sys/bus/greybus/devices/1-2.17/requests_per_second_min
cat /sys/bus/greybus/devices/1-2.17/requests_per_second_max
cat /sys/bus/greybus/devices/1-2.17/requests_per_second_avg
cat /sys/bus/greybus/devices/1-2.17/latency_min
cat /sys/bus/greybus/devices/1-2.17/latency_max
cat /sys/bus/greybus/devices/1-2.17/latency_avg
cat /sys/bus/greybus/devices/1-2.17/apbridge_unipro_latency_min
cat /sys/bus/greybus/devices/1-2.17/apbridge_unipro_latency_max
cat /sys/bus/greybus/devices/1-2.17/apbridge_unipro_latency_avg
cat /sys/bus/greybus/devices/1-2.17/gpbridge_firmware_latency_min
cat /sys/bus/greybus/devices/1-2.17/gpbridge_firmware_latency_max
cat /sys/bus/greybus/devices/1-2.17/gpbridge_firmware_latency_avg
cat /sys/bus/greybus/devices/1-2.17/error
cat /sys/bus/greybus/devices/1-2.17/requests_completed
cat /sys/bus/greybus/devices/1-2.17/requests_timedout
3.2 - using the test application:
* Run a transfer test 10 iterations of size 100 bytes on all available devices
#/loopback_test -t transfer -i 10 -s 100
1970-1-1 0:10:7,transfer,1-4.17,100,10,0,443,509,471.700012,66,1963,2256,2124.600098,293,102776,118088,109318.898438,15312,1620,1998,1894.099976,378,56,57,56.799999,1
1970-1-1 0:10:7,transfer,1-5.17,100,10,0,399,542,463.399994,143,1845,2505,2175.800049,660,92568,125744,107393.296875,33176,1469,2305,1806.500000,836,56,57,56.799999,1
* Show the aggregate results of both devices. ("-a")
#/loopback_test -t transfer -i 10 -s 100 -a
1970-1-1 0:10:35,transfer,1-4.17,100,10,0,448,580,494.100006,132,1722,2230,2039.400024,508,103936,134560,114515.703125,30624,1513,1980,1806.900024,467,56,57,57.299999,1
1970-1-1 0:10:35,transfer,1-5.17,100,10,0,383,558,478.600006,175,1791,2606,2115.199951,815,88856,129456,110919.703125,40600,1457,2246,1773.599976,789,56,57,57.099998,1
1970-1-1 0:10:35,transfer,aggregate,100,10,0,383,580,486.000000,197,1722,2606,2077.000000,884,88856,134560,112717.000000,45704,1457,2246,1789.000000,789,56,57,57.000000,1
* Example usage of the mask option to select which devices will
run the test (1st, 2nd, or both devices):
# /loopback_test -t transfer -i 10 -s 100 -m 1
1970-1-1 0:11:56,transfer,1-4.17,100,10,0,514,558,544.900024,44,1791,1943,1836.599976,152,119248,129456,126301.296875,10208,1600,1001609,101613.601562,1000009,56,57,56.900002,1
# /loopback_test -t transfer -i 10 -s 100 -m 2
1970-1-1 0:12:0,transfer,1-5.17,100,10,0,468,554,539.000000,86,1804,2134,1859.500000,330,108576,128528,124932.500000,19952,1606,1626,1619.300049,20,56,57,57.400002,1
# /loopback_test -t transfer -i 10 -s 100 -m 3
1970-1-1 0:12:3,transfer,1-4.17,100,10,0,432,510,469.399994,78,1959,2313,2135.800049,354,100224,118320,108785.296875,18096,1610,2024,1893.500000,414,56,57,57.200001,1
1970-1-1 0:12:3,transfer,1-5.17,100,10,0,404,542,468.799988,138,1843,2472,2152.500000,629,93728,125744,108646.101562,32016,1504,2247,1853.099976,743,56,57,57.099998,1
* Show output in human readable format ("-p")
# /loopback_test -t transfer -i 10 -s 100 -m 3 -p
1970-1-1 0:12:37
test: transfer
path: 1-4.17
size: 100
iterations: 10
errors: 0
async: Disabled
requests per-sec: min=390, max=547, average=469.299988, jitter=157
ap-throughput B/s: min=90480 max=126904 average=108762.101562 jitter=36424
ap-latency usec: min=1826 max=2560 average=2146.000000 jitter=734
apbridge-latency usec: min=1620 max=1982 average=1882.099976 jitter=362
gpbridge-latency usec: min=56 max=57 average=57.099998 jitter=1
1970-1-1 0:12:37
test: transfer
path: 1-5.17
size: 100
iterations: 10
errors: 0
async: Disabled
requests per-sec: min=397, max=538, average=461.700012, jitter=141
ap-throughput B/s: min=92104 max=124816 average=106998.898438 jitter=32712
ap-latency usec: min=1856 max=2514 average=2185.699951 jitter=658
apbridge-latency usec: min=1460 max=2296 average=1828.599976 jitter=836
gpbridge-latency usec: min=56 max=57 average=57.099998 jitter=1

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#!/usr/bin/env python
# Copyright (c) 2015 Google, Inc.
# Copyright (c) 2015 Linaro, Ltd.
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are met:
# 1. Redistributions of source code must retain the above copyright notice,
# this list of conditions and the following disclaimer.
# 2. Redistributions in binary form must reproduce the above copyright notice,
# this list of conditions and the following disclaimer in the documentation
# and/or other materials provided with the distribution.
# 3. Neither the name of the copyright holder nor the names of its
# contributors may be used to endorse or promote products derived from this
# software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
# AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
# THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
# PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
# CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
# EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
# PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
# OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
# WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
# OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
# ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
from __future__ import print_function
import csv
import datetime
import sys
import time
dict = {'ping': '2', 'transfer': '3', 'sink': '4'}
verbose = 1
def abort():
sys.exit(1)
def usage():
print('Usage: looptest TEST SIZE ITERATIONS PATH\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'
' PATH indicates the sysfs path for the loopback greybus entries e.g.\n'
' /sys/bus/greybus/devices/endo0:1:1:1:1/\n'
'Examples:\n'
' looptest transfer 128 10000\n'
' looptest ping 0 128\n'
' looptest sink 2030 32768\n'
.format(sys.argv[0]), file=sys.stderr)
abort()
def read_sysfs_int(path):
try:
f = open(path, "r");
val = f.read();
f.close()
return int(val)
except IOError as e:
print("I/O error({0}): {1}".format(e.errno, e.strerror))
print("Invalid path %s" % path)
def write_sysfs_val(path, val):
try:
f = open(path, "r+")
f.write(val)
f.close()
except IOError as e:
print("I/O error({0}): {1}".format(e.errno, e.strerror))
print("Invalid path %s" % path)
def log_csv(test_name, size, iteration_max, sys_pfx):
# 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
fname = test_name + '_' + size + '_' + str(iteration_max) + '.csv'
try:
# gather data set
date = str(datetime.datetime.now())
error = read_sysfs_int(sys_pfx + 'error')
request_min = read_sysfs_int(sys_pfx + 'requests_per_second_min')
request_max = read_sysfs_int(sys_pfx + 'requests_per_second_max')
request_avg = read_sysfs_int(sys_pfx + 'requests_per_second_avg')
latency_min = read_sysfs_int(sys_pfx + 'latency_min')
latency_max = read_sysfs_int(sys_pfx + 'latency_max')
latency_avg = read_sysfs_int(sys_pfx + 'latency_avg')
throughput_min = read_sysfs_int(sys_pfx + 'throughput_min')
throughput_max = read_sysfs_int(sys_pfx + 'throughput_max')
throughput_avg = read_sysfs_int(sys_pfx + 'throughput_avg')
# derive jitter
request_jitter = request_max - request_min
latency_jitter = latency_max - latency_min
throughput_jitter = throughput_max - throughput_min
# append data set to file
with open(fname, 'a') as csvf:
row = csv.writer(csvf, delimiter=",", quotechar="'",
quoting=csv.QUOTE_MINIMAL)
row.writerow([date, test_name, size, iteration_max, error,
request_min, request_max, request_avg, request_jitter,
latency_min, latency_max, latency_avg, latency_jitter,
throughput_min, throughput_max, throughput_avg, throughput_jitter])
except IOError as e:
print("I/O error({0}): {1}".format(e.errno, e.strerror))
def loopback_run(test_name, size, iteration_max, sys_pfx):
test_id = dict[test_name]
try:
# Terminate any currently running test
write_sysfs_val(sys_pfx + 'type', '0')
# Set parameter for no wait between messages
write_sysfs_val(sys_pfx + 'ms_wait', '0')
# Set operation size
write_sysfs_val(sys_pfx + 'size', size)
# Set iterations
write_sysfs_val(sys_pfx + 'iteration_max', str(iteration_max))
# Initiate by setting loopback operation type
write_sysfs_val(sys_pfx + 'type', test_id)
time.sleep(1)
if iteration_max == 0:
print ("Infinite test initiated CSV won't be logged\n")
return
previous = 0
err = 0
while True:
# get current count bail out if it hasn't changed
iteration_count = read_sysfs_int(sys_pfx + 'iteration_count')
if previous == iteration_count:
err = 1
break
elif iteration_count == iteration_max:
break
previous = iteration_count
if verbose:
print('%02d%% complete %d of %d ' %
(100 * iteration_count / iteration_max,
iteration_count, iteration_max))
time.sleep(1)
if err:
print ('\nError executing test\n')
else:
log_csv(test_name, size, iteration_max, sys_pfx)
except ValueError as ve:
print("Error: %s " % format(e.strerror), file=sys.stderr)
abort()
def main():
if len(sys.argv) < 5:
usage()
if sys.argv[1] in dict.keys():
loopback_run(sys.argv[1], sys.argv[2], int(sys.argv[3]), sys.argv[4])
else:
usage()
if __name__ == '__main__':
main()

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/*
* Loopback test application
*
* Copyright 2015 Google Inc.
* Copyright 2015 Linaro Ltd.
*
* Provided under the three clause BSD license found in the LICENSE file.
*/
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <sys/inotify.h>
#include <sys/types.h>
#include <time.h>
#include <unistd.h>
#include <dirent.h>
#define MAX_NUM_DEVICES 50
#define MAX_SYSFS_PATH 0x200
#define CSV_MAX_LINE 0x1000
#define SYSFS_MAX_INT 0x20
#define MAX_STR_LEN 255
#define MAX_TIMEOUT_COUNT 5
#define TIMEOUT_SEC 1
#define DEFAULT_ASYNC_TIMEOUT 200000
struct dict {
char *name;
int type;
};
static struct dict dict[] = {
{"ping", 2},
{"transfer", 3},
{"sink", 4}
};
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 gpbridge_firmware_latency_avg;
uint32_t gpbridge_firmware_latency_max;
uint32_t gpbridge_firmware_latency_min;
uint32_t gpbridge_firmware_latency_jitter;
uint32_t error;
};
struct loopback_device {
char name[MAX_SYSFS_PATH];
char sysfs_entry[MAX_SYSFS_PATH];
char debugfs_entry[MAX_SYSFS_PATH];
int inotify_wd;
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 inotify_fd;
int list_devices;
int use_async;
int async_timeout;
int async_outstanding_operations;
int us_wait;
char test_name[MAX_STR_LEN];
char sysfs_prefix[MAX_SYSFS_PATH];
char debugfs_prefix[MAX_SYSFS_PATH];
struct loopback_device devices[MAX_NUM_DEVICES];
struct loopback_results aggregate_results;
};
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(gpbridge_firmware_latency_max);
GET_MIN(throughput_min);
GET_MIN(request_min);
GET_MIN(latency_min);
GET_MIN(apbridge_unipro_latency_min);
GET_MIN(gpbridge_firmware_latency_min);
GET_AVG(throughput_avg);
GET_AVG(request_avg);
GET_AVG(latency_avg);
GET_AVG(apbridge_unipro_latency_avg);
GET_AVG(gpbridge_firmware_latency_avg);
void abort()
{
_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' entires 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"
" -c Max number of outstanding operations for async operations\n"
" -w Wait in uSec between operations\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->gpbridge_firmware_latency_min =
read_sysfs_int(d->sysfs_entry, "gpbridge_firmware_latency_min");
r->gpbridge_firmware_latency_max =
read_sysfs_int(d->sysfs_entry, "gpbridge_firmware_latency_max");
r->gpbridge_firmware_latency_avg =
read_sysfs_float(d->sysfs_entry, "gpbridge_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->gpbridge_firmware_latency_jitter =
r->gpbridge_firmware_latency_max - r->gpbridge_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->gpbridge_firmware_latency_min =
get_gpbridge_firmware_latency_min_aggregate(t);
r->gpbridge_firmware_latency_max =
get_gpbridge_firmware_latency_max_aggregate(t);
r->gpbridge_firmware_latency_avg =
get_gpbridge_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->gpbridge_firmware_latency_jitter =
r->gpbridge_firmware_latency_max - r->gpbridge_firmware_latency_min;
}
return 0;
}
void log_csv_error(int len, int err)
{
fprintf(stderr, "unable to write %d bytes to csv %s\n", len,
strerror(err));
}
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,
" gpbridge-latency usec:\tmin=%u max=%u average=%f jitter=%u\n",
r->gpbridge_firmware_latency_min,
r->gpbridge_firmware_latency_max,
r->gpbridge_firmware_latency_avg,
r->gpbridge_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->gpbridge_firmware_latency_min,
r->gpbridge_firmware_latency_max,
r->gpbridge_firmware_latency_avg,
r->gpbridge_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;
mode_t mode = S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH;
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->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, mode);
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->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->porcelain) {
ret = write(fd, data, len);
if (ret == -1)
fprintf(stderr, "unable to write %d bytes to csv.\n", len);
}
}
if (!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[n]);
free(namelist);
baddir:
return ret;
}
static int register_for_notification(struct loopback_test *t)
{
char buf[MAX_SYSFS_PATH];
int i;
t->inotify_fd = inotify_init();
if (t->inotify_fd < 0) {
fprintf(stderr, "inotify_init fail %s\n", strerror(errno));
abort();
}
for (i = 0; i < t->device_count; i++) {
if (!device_enabled(t, i))
continue;
snprintf(buf, sizeof(buf), "%s%s", t->devices[i].sysfs_entry,
"iteration_count");
t->devices[i].inotify_wd = inotify_add_watch(t->inotify_fd,
buf, IN_MODIFY);
if (t->devices[i].inotify_wd < 0) {
fprintf(stderr, "inotify_add_watch %s fail %s\n",
buf, strerror(errno));
close(t->inotify_fd);
abort();
}
}
return 0;
}
static int unregister_for_notification(struct loopback_test *t)
{
int i;
int ret = 0;
for (i = 0; i < t->device_count; i++) {
if (!device_enabled(t, i))
continue;
ret = inotify_rm_watch(t->inotify_fd, t->devices[i].inotify_wd);
if (ret) {
fprintf(stderr, "inotify_rm_watch error.\n");
return ret;
}
}
close(t->inotify_fd);
return 0;
}
static int is_complete(struct loopback_test *t)
{
uint32_t iteration_count = 0;
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 int wait_for_complete(struct loopback_test *t)
{
int remaining_timeouts = MAX_TIMEOUT_COUNT;
char buf[MAX_SYSFS_PATH];
struct timeval timeout;
fd_set read_fds;
int ret;
while (1) {
/* Wait for change */
timeout.tv_sec = TIMEOUT_SEC;
timeout.tv_usec = 0;
FD_ZERO(&read_fds);
FD_SET(t->inotify_fd, &read_fds);
ret = select(FD_SETSIZE, &read_fds, NULL, NULL, &timeout);
if (ret < 0) {
fprintf(stderr, "Select error.\n");
return -1;
}
/* timeout - test may be finished.*/
if (!FD_ISSET(t->inotify_fd, &read_fds)) {
remaining_timeouts--;
if (is_complete(t))
return 0;
if (!remaining_timeouts) {
fprintf(stderr, "Too many timeouts\n");
return -1;
}
} else {
/* read to clear the event */
ret = read(t->inotify_fd, buf, sizeof(buf));
}
}
return 0;
}
static void prepare_devices(struct loopback_test *t)
{
int i;
/* Cancel any running tests */
for (i = 0; i < t->device_count; 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; i < sizeof(dict) / sizeof(struct dict); 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 = register_for_notification(t);
if (ret)
goto err;
start(t);
sleep(1);
wait_for_complete(t);
unregister_for_notification(t);
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:c:w:")) != -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_PATH, "%s", optarg);
break;
case 'D':
snprintf(t.debugfs_prefix, MAX_SYSFS_PATH, "%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 'c':
t.async_outstanding_operations = atoi(optarg);
break;
case 'w':
t.us_wait = atoi(optarg);
break;
default:
usage();
return -EINVAL;
}
}
if (!strcmp(t.sysfs_prefix, ""))
snprintf(t.sysfs_prefix, MAX_SYSFS_PATH, "%s", sysfs_prefix);
if (!strcmp(t.debugfs_prefix, ""))
snprintf(t.debugfs_prefix, MAX_SYSFS_PATH, "%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;
}