blob: e1d47f013facfa6f770eb0b4d29a0f6415246ee1 [file] [log] [blame]
#!/usr/bin/env python3
# vim: set syntax=python ts=4 :
# SPDX-License-Identifier: Apache-2.0
"""Zephyr Sanity Tests
Also check the "User and Developer Guides" at https://docs.zephyrproject.org/
This script scans for the set of unit test applications in the git
repository and attempts to execute them. By default, it tries to
build each test case on one platform per architecture, using a precedence
list defined in an architecture configuration file, and if possible
run the tests in any available emulators or simulators on the system.
Test cases are detected by the presence of a 'testcase.yaml' or a sample.yaml
files in the application's project directory. This file may contain one or more
blocks, each identifying a test scenario. The title of the block is a name for
the test case, which only needs to be unique for the test cases specified in
that testcase meta-data. The full canonical name for each test case is <path to
test case>/<block>.
Each test block in the testcase meta data can define the following key/value
pairs:
tags: <list of tags> (required)
A set of string tags for the testcase. Usually pertains to
functional domains but can be anything. Command line invocations
of this script can filter the set of tests to run based on tag.
skip: <True|False> (default False)
skip testcase unconditionally. This can be used for broken tests.
slow: <True|False> (default False)
Don't build or run this test case unless --enable-slow was passed
in on the command line. Intended for time-consuming test cases
that are only run under certain circumstances, like daily
builds.
extra_args: <list of extra arguments>
Extra cache entries to pass to CMake when building or running the
test case.
extra_configs: <list of extra configurations>
Extra configuration options to be merged with a master prj.conf
when building or running the test case.
build_only: <True|False> (default False)
If true, don't try to run the test even if the selected platform
supports it.
build_on_all: <True|False> (default False)
If true, attempt to build test on all available platforms.
depends_on: <list of features>
A board or platform can announce what features it supports, this option
will enable the test only those platforms that provide this feature.
min_ram: <integer>
minimum amount of RAM needed for this test to build and run. This is
compared with information provided by the board metadata.
min_flash: <integer>
minimum amount of ROM needed for this test to build and run. This is
compared with information provided by the board metadata.
timeout: <number of seconds>
Length of time to run test in emulator before automatically killing it.
Default to 60 seconds.
arch_whitelist: <list of arches, such as x86, arm, arc>
Set of architectures that this test case should only be run for.
arch_exclude: <list of arches, such as x86, arm, arc>
Set of architectures that this test case should not run on.
platform_whitelist: <list of platforms>
Set of platforms that this test case should only be run for.
platform_exclude: <list of platforms>
Set of platforms that this test case should not run on.
extra_sections: <list of extra binary sections>
When computing sizes, sanitycheck will report errors if it finds
extra, unexpected sections in the Zephyr binary unless they are named
here. They will not be included in the size calculation.
filter: <expression>
Filter whether the testcase should be run by evaluating an expression
against an environment containing the following values:
{ ARCH : <architecture>,
PLATFORM : <platform>,
<all CONFIG_* key/value pairs in the test's generated defconfig>,
<all DT_* key/value pairs in the test's generated device tree file>,
<all CMake key/value pairs in the test's generated CMakeCache.txt file>,
*<env>: any environment variable available
}
The grammar for the expression language is as follows:
expression ::= expression "and" expression
| expression "or" expression
| "not" expression
| "(" expression ")"
| symbol "==" constant
| symbol "!=" constant
| symbol "<" number
| symbol ">" number
| symbol ">=" number
| symbol "<=" number
| symbol "in" list
| symbol ":" string
| symbol
list ::= "[" list_contents "]"
list_contents ::= constant
| list_contents "," constant
constant ::= number
| string
For the case where expression ::= symbol, it evaluates to true
if the symbol is defined to a non-empty string.
Operator precedence, starting from lowest to highest:
or (left associative)
and (left associative)
not (right associative)
all comparison operators (non-associative)
arch_whitelist, arch_exclude, platform_whitelist, platform_exclude
are all syntactic sugar for these expressions. For instance
arch_exclude = x86 arc
Is the same as:
filter = not ARCH in ["x86", "arc"]
The ':' operator compiles the string argument as a regular expression,
and then returns a true value only if the symbol's value in the environment
matches. For example, if CONFIG_SOC="stm32f107xc" then
filter = CONFIG_SOC : "stm.*"
Would match it.
The set of test cases that actually run depends on directives in the testcase
filed and options passed in on the command line. If there is any confusion,
running with -v or examining the discard report (sanitycheck_discard.csv)
can help show why particular test cases were skipped.
Metrics (such as pass/fail state and binary size) for the last code
release are stored in scripts/sanity_chk/sanity_last_release.csv.
To update this, pass the --all --release options.
To load arguments from a file, write '+' before the file name, e.g.,
+file_name. File content must be one or more valid arguments separated by
line break instead of white spaces.
Most everyday users will run with no arguments.
"""
import os
import contextlib
import string
import mmap
import argparse
import sys
import re
import subprocess
import multiprocessing
import select
import shutil
import shlex
import signal
import threading
import concurrent.futures
from threading import BoundedSemaphore
import queue
import time
import datetime
import csv
import yaml
import glob
import serial
import concurrent
import xml.etree.ElementTree as ET
from collections import OrderedDict
from itertools import islice
from pathlib import Path
from distutils.spawn import find_executable
ZEPHYR_BASE = os.getenv("ZEPHYR_BASE")
if not ZEPHYR_BASE:
sys.exit("$ZEPHYR_BASE environment variable undefined")
sys.path.insert(0, os.path.join(ZEPHYR_BASE, "scripts", "dts"))
import edtlib
import logging
hw_map_local = threading.Lock()
report_lock = threading.Lock()
log_format = "%(levelname)s %(name)s::%(module)s.%(funcName)s():%(lineno)d: %(message)s"
logging.basicConfig(format=log_format, level=30)
# Use this for internal comparisons; that's what canonicalization is
# for. Don't use it when invoking other components of the build system
# to avoid confusing and hard to trace inconsistencies in error messages
# and logs, generated Makefiles, etc. compared to when users invoke these
# components directly.
# Note "normalization" is different from canonicalization, see os.path.
canonical_zephyr_base = os.path.realpath(ZEPHYR_BASE)
sys.path.insert(0, os.path.join(ZEPHYR_BASE, "scripts/"))
from sanity_chk import scl
from sanity_chk import expr_parser
VERBOSE = 0
RELEASE_DATA = os.path.join(ZEPHYR_BASE, "scripts", "sanity_chk",
"sanity_last_release.csv")
if os.isatty(sys.stdout.fileno()):
TERMINAL = True
COLOR_NORMAL = '\033[0m'
COLOR_RED = '\033[91m'
COLOR_GREEN = '\033[92m'
COLOR_YELLOW = '\033[93m'
else:
TERMINAL = False
COLOR_NORMAL = ""
COLOR_RED = ""
COLOR_GREEN = ""
COLOR_YELLOW = ""
class CMakeCacheEntry:
'''Represents a CMake cache entry.
This class understands the type system in a CMakeCache.txt, and
converts the following cache types to Python types:
Cache Type Python type
---------- -------------------------------------------
FILEPATH str
PATH str
STRING str OR list of str (if ';' is in the value)
BOOL bool
INTERNAL str OR list of str (if ';' is in the value)
---------- -------------------------------------------
'''
# Regular expression for a cache entry.
#
# CMake variable names can include escape characters, allowing a
# wider set of names than is easy to match with a regular
# expression. To be permissive here, use a non-greedy match up to
# the first colon (':'). This breaks if the variable name has a
# colon inside, but it's good enough.
CACHE_ENTRY = re.compile(
r'''(?P<name>.*?) # name
:(?P<type>FILEPATH|PATH|STRING|BOOL|INTERNAL) # type
=(?P<value>.*) # value
''', re.X)
@classmethod
def _to_bool(cls, val):
# Convert a CMake BOOL string into a Python bool.
#
# "True if the constant is 1, ON, YES, TRUE, Y, or a
# non-zero number. False if the constant is 0, OFF, NO,
# FALSE, N, IGNORE, NOTFOUND, the empty string, or ends in
# the suffix -NOTFOUND. Named boolean constants are
# case-insensitive. If the argument is not one of these
# constants, it is treated as a variable."
#
# https://cmake.org/cmake/help/v3.0/command/if.html
val = val.upper()
if val in ('ON', 'YES', 'TRUE', 'Y'):
return 1
elif val in ('OFF', 'NO', 'FALSE', 'N', 'IGNORE', 'NOTFOUND', ''):
return 0
elif val.endswith('-NOTFOUND'):
return 0
else:
try:
v = int(val)
return v != 0
except ValueError as exc:
raise ValueError('invalid bool {}'.format(val)) from exc
@classmethod
def from_line(cls, line, line_no):
# Comments can only occur at the beginning of a line.
# (The value of an entry could contain a comment character).
if line.startswith('//') or line.startswith('#'):
return None
# Whitespace-only lines do not contain cache entries.
if not line.strip():
return None
m = cls.CACHE_ENTRY.match(line)
if not m:
return None
name, type_, value = (m.group(g) for g in ('name', 'type', 'value'))
if type_ == 'BOOL':
try:
value = cls._to_bool(value)
except ValueError as exc:
args = exc.args + ('on line {}: {}'.format(line_no, line),)
raise ValueError(args) from exc
elif type_ in ['STRING','INTERNAL']:
# If the value is a CMake list (i.e. is a string which
# contains a ';'), convert to a Python list.
if ';' in value:
value = value.split(';')
return CMakeCacheEntry(name, value)
def __init__(self, name, value):
self.name = name
self.value = value
def __str__(self):
fmt = 'CMakeCacheEntry(name={}, value={})'
return fmt.format(self.name, self.value)
class CMakeCache:
'''Parses and represents a CMake cache file.'''
@staticmethod
def from_file(cache_file):
return CMakeCache(cache_file)
def __init__(self, cache_file):
self.cache_file = cache_file
self.load(cache_file)
def load(self, cache_file):
entries = []
with open(cache_file, 'r') as cache:
for line_no, line in enumerate(cache):
entry = CMakeCacheEntry.from_line(line, line_no)
if entry:
entries.append(entry)
self._entries = OrderedDict((e.name, e) for e in entries)
def get(self, name, default=None):
entry = self._entries.get(name)
if entry is not None:
return entry.value
else:
return default
def get_list(self, name, default=None):
if default is None:
default = []
entry = self._entries.get(name)
if entry is not None:
value = entry.value
if isinstance(value, list):
return value
elif isinstance(value, str):
return [value] if value else []
else:
msg = 'invalid value {} type {}'
raise RuntimeError(msg.format(value, type(value)))
else:
return default
def __contains__(self, name):
return name in self._entries
def __getitem__(self, name):
return self._entries[name].value
def __setitem__(self, name, entry):
if not isinstance(entry, CMakeCacheEntry):
msg = 'improper type {} for value {}, expecting CMakeCacheEntry'
raise TypeError(msg.format(type(entry), entry))
self._entries[name] = entry
def __delitem__(self, name):
del self._entries[name]
def __iter__(self):
return iter(self._entries.values())
class SanityCheckException(Exception):
pass
class SanityRuntimeError(SanityCheckException):
pass
class ConfigurationError(SanityCheckException):
def __init__(self, cfile, message):
SanityCheckException.__init__(self, cfile + ": " + message)
class BuildError(SanityCheckException):
pass
class ExecutionError(SanityCheckException):
pass
log_file = None
# Debug Functions
def info(what, show_time=True):
if options.timestamps and show_time:
date = datetime.datetime.now().strftime("%Y-%m-%d %H:%M:%S")
what = "{}: {}".format(date, what)
sys.stdout.write(what + "\n")
sys.stdout.flush()
if log_file:
log_file.write(what + "\n")
log_file.flush()
def error(what):
if options.timestamps:
date = datetime.datetime.now().strftime("%Y-%m-%dT%H:%M:%S")
what = "{}: {}".format(date, what)
sys.stderr.write(COLOR_RED + what + COLOR_NORMAL + "\n")
if log_file:
log_file(what + "\n")
log_file.flush()
def debug(what):
if VERBOSE >= 1:
info(what)
def verbose(what):
if VERBOSE >= 2:
info(what)
class HarnessImporter:
def __init__(self, name):
sys.path.insert(0, os.path.join(ZEPHYR_BASE, "scripts/sanity_chk"))
module = __import__("harness")
if name:
my_class = getattr(module, name)
else:
my_class = getattr(module, "Test")
self.instance = my_class()
class Handler:
def __init__(self, instance, type_str="build"):
"""Constructor
"""
self.lock = threading.Lock()
self.state = "waiting"
self.run = False
self.duration = 0
self.type_str = type_str
self.binary = None
self.pid_fn = None
self.call_make_run = False
self.name = instance.name
self.instance = instance
self.timeout = instance.testcase.timeout
self.sourcedir = instance.testcase.source_dir
self.build_dir = instance.build_dir
self.log = os.path.join(self.build_dir, "handler.log")
self.returncode = 0
self.set_state("running", self.duration)
self.args = []
def set_state(self, state, duration):
self.lock.acquire()
self.state = state
self.duration = duration
self.lock.release()
def get_state(self):
self.lock.acquire()
ret = (self.state, self.duration)
self.lock.release()
return ret
def record(self, harness):
if harness.recording:
filename = os.path.join(options.outdir,
self.instance.platform.name,
self.instance.testcase.name, "recording.csv")
with open(filename, "at") as csvfile:
cw = csv.writer(csvfile, harness.fieldnames, lineterminator=os.linesep)
cw.writerow(harness.fieldnames)
for instance in harness.recording:
cw.writerow(instance)
class BinaryHandler(Handler):
def __init__(self, instance, type_str):
"""Constructor
@param instance Test Instance
"""
super().__init__(instance, type_str)
self.terminated = False
def try_kill_process_by_pid(self):
if self.pid_fn:
pid = int(open(self.pid_fn).read())
os.unlink(self.pid_fn)
self.pid_fn = None # clear so we don't try to kill the binary twice
try:
os.kill(pid, signal.SIGTERM)
except ProcessLookupError:
pass
def _output_reader(self, proc, harness):
log_out_fp = open(self.log, "wt")
for line in iter(proc.stdout.readline, b''):
verbose("OUTPUT: {0}".format(line.decode('utf-8').rstrip()))
log_out_fp.write(line.decode('utf-8'))
log_out_fp.flush()
harness.handle(line.decode('utf-8').rstrip())
if harness.state:
try:
#POSIX arch based ztests end on their own,
#so let's give it up to 100ms to do so
proc.wait(0.1)
except subprocess.TimeoutExpired:
proc.terminate()
self.terminated = True
break
log_out_fp.close()
def handle(self):
harness_name = self.instance.testcase.harness.capitalize()
harness_import = HarnessImporter(harness_name)
harness = harness_import.instance
harness.configure(self.instance)
if self.call_make_run:
command = [get_generator()[0], "run"]
else:
command = [self.binary]
run_valgrind = False
if options.enable_valgrind and shutil.which("valgrind"):
command = ["valgrind", "--error-exitcode=2",
"--leak-check=full",
"--suppressions="+ZEPHYR_BASE+"/scripts/valgrind.supp",
"--log-file="+self.build_dir+"/valgrind.log"
] + command
run_valgrind = True
verbose("Spawning process: " +
" ".join(shlex.quote(word) for word in command) + os.linesep +
"Spawning process in directory: " + self.build_dir)
start_time = time.time()
env = os.environ.copy()
if options.enable_asan:
env["ASAN_OPTIONS"] = "log_path=stdout:" + \
env.get("ASAN_OPTIONS", "")
if not options.enable_lsan:
env["ASAN_OPTIONS"] += "detect_leaks=0"
with subprocess.Popen(command, stdout=subprocess.PIPE,
stderr=subprocess.PIPE, cwd=self.build_dir, env=env) as proc:
verbose("Spawning BinaryHandler Thread for %s" % self.name)
t = threading.Thread(target=self._output_reader, args=(proc, harness, ), daemon=True)
t.start()
t.join(self.timeout)
if t.is_alive():
self.try_kill_process_by_pid()
proc.terminate()
self.terminated = True
t.join()
proc.wait()
self.returncode = proc.returncode
handler_time = time.time() - start_time
if options.enable_coverage:
subprocess.call(["GCOV_PREFIX=" + self.build_dir,
"gcov", self.sourcedir, "-b", "-s", self.build_dir], shell=True)
self.try_kill_process_by_pid()
# FIXME: This is needed when killing the simulator, the console is
# garbled and needs to be reset. Did not find a better way to do that.
subprocess.call(["stty", "sane"])
self.instance.results = harness.tests
if not self.terminated and self.returncode != 0:
#When a process is killed, the default handler returns 128 + SIGTERM
#so in that case the return code itself is not meaningful
self.set_state("failed", handler_time)
self.instance.reason = "Handler Error"
elif run_valgrind and self.returncode == 2:
self.set_state("failed", handler_time)
self.instance.reason = "Valgrind error"
elif harness.state:
self.set_state(harness.state, handler_time)
else:
self.set_state("timeout", handler_time)
self.instance.reason = "Handler timeout"
self.record(harness)
class DeviceHandler(Handler):
def __init__(self, instance, type_str):
"""Constructor
@param instance Test Instance
"""
super().__init__(instance, type_str)
self.suite = None
def monitor_serial(self, ser, halt_fileno, harness):
log_out_fp = open(self.log, "wt")
ser_fileno = ser.fileno()
readlist = [halt_fileno, ser_fileno]
while ser.isOpen():
readable, _, _ = select.select(readlist, [], [], self.timeout)
if halt_fileno in readable:
verbose('halted')
ser.close()
break
if ser_fileno not in readable:
continue # Timeout.
serial_line = None
try:
serial_line = ser.readline()
except TypeError:
pass
except serial.SerialException:
ser.close()
break
# Just because ser_fileno has data doesn't mean an entire line
# is available yet.
if serial_line:
sl = serial_line.decode('utf-8', 'ignore')
verbose("DEVICE: {0}".format(sl.rstrip()))
log_out_fp.write(sl)
log_out_fp.flush()
harness.handle(sl.rstrip())
if harness.state:
ser.close()
break
log_out_fp.close()
def device_is_available(self, device):
for i in self.suite.connected_hardware:
if i['platform'] == device and i['available'] and i['connected']:
return True
return False
def get_available_device(self, device):
for i in self.suite.connected_hardware:
if i['platform'] == device and i['available']:
i['available'] = False
i['counter'] += 1
return i
return None
def make_device_available(self, serial):
with hw_map_local:
for i in self.suite.connected_hardware:
if i['serial'] == serial:
i['available'] = True
def handle(self):
out_state = "failed"
if options.west_flash:
command = ["west", "flash", "--skip-rebuild", "-d", self.build_dir]
if options.west_runner:
command.append("--runner")
command.append(options.west_runner)
# There are three ways this option is used.
# 1) bare: --west-flash
# This results in options.west_flash == []
# 2) with a value: --west-flash="--board-id=42"
# This results in options.west_flash == "--board-id=42"
# 3) Multiple values: --west-flash="--board-id=42,--erase"
# This results in options.west_flash == "--board-id=42 --erase"
if options.west_flash != []:
command.append('--')
command.extend(options.west_flash.split(','))
else:
command = [get_generator()[0], "-C", self.build_dir, "flash"]
while not self.device_is_available(self.instance.platform.name):
time.sleep(1)
hardware = self.get_available_device(self.instance.platform.name)
runner = hardware.get('runner', None)
if runner:
board_id = hardware.get("probe_id", hardware.get("id", None))
product = hardware.get("product", None)
command = ["west", "flash", "--skip-rebuild", "-d", self.build_dir]
command.append("--runner")
command.append(hardware.get('runner', None))
if runner == "pyocd":
command.append("--board-id")
command.append(board_id)
elif runner == "nrfjprog":
command.append('--')
command.append("--snr")
command.append(board_id)
elif runner == "openocd" and product == "STM32 STLink":
command.append('--')
command.append("--cmd-pre-init")
command.append("hla_serial %s" %(board_id))
elif runner == "openocd" and product == "EDBG CMSIS-DAP":
command.append('--')
command.append("--cmd-pre-init")
command.append("cmsis_dap_serial %s" %(board_id))
elif runner == "jlink":
command.append("--tool-opt=-SelectEmuBySN %s" %(board_id))
serial_device = hardware['serial']
try:
ser = serial.Serial(
serial_device,
baudrate=115200,
parity=serial.PARITY_NONE,
stopbits=serial.STOPBITS_ONE,
bytesize=serial.EIGHTBITS,
timeout=self.timeout
)
except serial.SerialException as e:
self.set_state("failed", 0)
error("Serial device err: %s" %(str(e)))
self.make_device_available(serial_device)
return
ser.flush()
harness_name = self.instance.testcase.harness.capitalize()
harness_import = HarnessImporter(harness_name)
harness = harness_import.instance
harness.configure(self.instance)
read_pipe, write_pipe = os.pipe()
start_time = time.time()
t = threading.Thread(target=self.monitor_serial, daemon=True,
args=(ser, read_pipe, harness))
t.start()
logging.debug('Flash command: %s', command)
try:
if VERBOSE and not runner:
subprocess.check_call(command)
else:
subprocess.check_output(command, stderr=subprocess.PIPE)
except subprocess.CalledProcessError:
os.write(write_pipe, b'x') # halt the thread
t.join(self.timeout)
if t.is_alive():
out_state = "timeout"
if ser.isOpen():
ser.close()
if out_state == "timeout":
for c in self.instance.testcase.cases:
if c not in harness.tests:
harness.tests[c] = "BLOCK"
handler_time = time.time() - start_time
self.instance.results = harness.tests
if harness.state:
self.set_state(harness.state, handler_time)
else:
self.set_state(out_state, handler_time)
self.make_device_available(serial_device)
self.record(harness)
class QEMUHandler(Handler):
"""Spawns a thread to monitor QEMU output from pipes
We pass QEMU_PIPE to 'make run' and monitor the pipes for output.
We need to do this as once qemu starts, it runs forever until killed.
Test cases emit special messages to the console as they run, we check
for these to collect whether the test passed or failed.
"""
def __init__(self, instance, type_str):
"""Constructor
@param instance Test instance
"""
super().__init__(instance, type_str)
self.fifo_fn = os.path.join(instance.build_dir, "qemu-fifo")
self.pid_fn = os.path.join(instance.build_dir, "qemu.pid")
@staticmethod
def _thread(handler, timeout, outdir, logfile, fifo_fn, pid_fn, results, harness):
fifo_in = fifo_fn + ".in"
fifo_out = fifo_fn + ".out"
# These in/out nodes are named from QEMU's perspective, not ours
if os.path.exists(fifo_in):
os.unlink(fifo_in)
os.mkfifo(fifo_in)
if os.path.exists(fifo_out):
os.unlink(fifo_out)
os.mkfifo(fifo_out)
# We don't do anything with out_fp but we need to open it for
# writing so that QEMU doesn't block, due to the way pipes work
out_fp = open(fifo_in, "wb")
# Disable internal buffering, we don't
# want read() or poll() to ever block if there is data in there
in_fp = open(fifo_out, "rb", buffering=0)
log_out_fp = open(logfile, "wt")
start_time = time.time()
timeout_time = start_time + timeout
p = select.poll()
p.register(in_fp, select.POLLIN)
out_state = None
line = ""
timeout_extended = False
while True:
this_timeout = int((timeout_time - time.time()) * 1000)
if this_timeout < 0 or not p.poll(this_timeout):
if not out_state:
out_state = "timeout"
break
try:
c = in_fp.read(1).decode("utf-8")
except UnicodeDecodeError:
# Test is writing something weird, fail
out_state = "unexpected byte"
break
if c == "":
# EOF, this shouldn't happen unless QEMU crashes
out_state = "unexpected eof"
break
line = line + c
if c != "\n":
continue
# line contains a full line of data output from QEMU
log_out_fp.write(line)
log_out_fp.flush()
line = line.strip()
verbose("QEMU: %s" % line)
harness.handle(line)
if harness.state:
# if we have registered a fail make sure the state is not
# overridden by a false success message coming from the
# testsuite
if out_state != 'failed':
out_state = harness.state
# if we get some state, that means test is doing well, we reset
# the timeout and wait for 2 more seconds to catch anything
# printed late. We wait much longer if code
# coverage is enabled since dumping this information can
# take some time.
if not timeout_extended or harness.capture_coverage:
timeout_extended= True
if harness.capture_coverage:
timeout_time = time.time() + 30
else:
timeout_time = time.time() + 2
line = ""
handler.record(harness)
handler_time = time.time() - start_time
verbose("QEMU complete (%s) after %f seconds" %
(out_state, handler_time))
handler.set_state(out_state, handler_time)
log_out_fp.close()
out_fp.close()
in_fp.close()
if os.path.exists(pid_fn):
pid = int(open(pid_fn).read())
os.unlink(pid_fn)
try:
if pid:
os.kill(pid, signal.SIGTERM)
except ProcessLookupError:
# Oh well, as long as it's dead! User probably sent Ctrl-C
pass
os.unlink(fifo_in)
os.unlink(fifo_out)
def handle(self):
self.results = {}
self.run = True
# We pass this to QEMU which looks for fifos with .in and .out
# suffixes.
self.fifo_fn = os.path.join(self.instance.build_dir, "qemu-fifo")
self.pid_fn = os.path.join(self.instance.build_dir, "qemu.pid")
if os.path.exists(self.pid_fn):
os.unlink(self.pid_fn)
self.log_fn = self.log
harness_import = HarnessImporter(self.instance.testcase.harness.capitalize())
harness = harness_import.instance
harness.configure(self.instance)
self.thread = threading.Thread(name=self.name, target=QEMUHandler._thread,
args=(self, self.timeout, self.build_dir,
self.log_fn, self.fifo_fn,
self.pid_fn, self.results, harness))
self.instance.results = harness.tests
self.thread.daemon = True
verbose("Spawning QEMUHandler Thread for %s" % self.name)
self.thread.start()
subprocess.call(["stty", "sane"])
verbose("Running %s (%s)" %(self.name, self.type_str))
command = [get_generator()[0]]
command += ["-C", self.build_dir, "run"]
with subprocess.Popen(command, stdout=subprocess.PIPE, stderr=subprocess.PIPE, cwd=self.build_dir) as proc:
verbose("Spawning QEMUHandler Thread for %s" % self.name)
proc.wait()
self.returncode = proc.returncode
if self.returncode != 0:
self.set_state("failed", 0)
self.instance.reason = "Exited with {}".format(self.returncode)
def get_fifo(self):
return self.fifo_fn
class SizeCalculator:
alloc_sections = [
"bss",
"noinit",
"app_bss",
"app_noinit",
"ccm_bss",
"ccm_noinit"
]
rw_sections = [
"datas",
"initlevel",
"exceptions",
"initshell",
"_static_thread_area",
"_k_timer_area",
"_k_mem_slab_area",
"_k_mem_pool_area",
"sw_isr_table",
"_k_sem_area",
"_k_mutex_area",
"app_shmem_regions",
"_k_fifo_area",
"_k_lifo_area",
"_k_stack_area",
"_k_msgq_area",
"_k_mbox_area",
"_k_pipe_area",
"net_if",
"net_if_dev",
"net_stack",
"net_l2_data",
"_k_queue_area",
"_net_buf_pool_area",
"app_datas",
"kobject_data",
"mmu_tables",
"app_pad",
"priv_stacks",
"ccm_data",
"usb_descriptor",
"usb_data", "usb_bos_desc",
'log_backends_sections',
'log_dynamic_sections',
'log_const_sections',
"app_smem",
'shell_root_cmds_sections',
'log_const_sections',
"font_entry_sections",
"priv_stacks_noinit",
"_TEXT_SECTION_NAME_2",
"_GCOV_BSS_SECTION_NAME",
"gcov",
"nocache"
]
# These get copied into RAM only on non-XIP
ro_sections = [
"text",
"ctors",
"init_array",
"reset",
"object_access",
"rodata",
"devconfig",
"net_l2",
"vector",
"sw_isr_table",
"_settings_handlers_area",
"_bt_channels_area",
"_bt_br_channels_area",
"_bt_services_area",
"vectors",
"net_socket_register",
"net_ppp_proto"
]
def __init__(self, filename, extra_sections):
"""Constructor
@param filename Path to the output binary
The <filename> is parsed by objdump to determine section sizes
"""
# Make sure this is an ELF binary
with open(filename, "rb") as f:
magic = f.read(4)
try:
if magic != b'\x7fELF':
raise SanityRuntimeError("%s is not an ELF binary" % filename)
except Exception as e:
print(str(e))
sys.exit(2)
# Search for CONFIG_XIP in the ELF's list of symbols using NM and AWK.
# GREP can not be used as it returns an error if the symbol is not
# found.
is_xip_command = "nm " + filename + \
" | awk '/CONFIG_XIP/ { print $3 }'"
is_xip_output = subprocess.check_output(
is_xip_command, shell=True, stderr=subprocess.STDOUT).decode(
"utf-8").strip()
try:
if is_xip_output.endswith("no symbols"):
raise SanityRuntimeError("%s has no symbol information" % filename)
except Exception as e:
print(str(e))
sys.exit(2)
self.is_xip = (len(is_xip_output) != 0)
self.filename = filename
self.sections = []
self.rom_size = 0
self.ram_size = 0
self.extra_sections = extra_sections
self._calculate_sizes()
def get_ram_size(self):
"""Get the amount of RAM the application will use up on the device
@return amount of RAM, in bytes
"""
return self.ram_size
def get_rom_size(self):
"""Get the size of the data that this application uses on device's flash
@return amount of ROM, in bytes
"""
return self.rom_size
def unrecognized_sections(self):
"""Get a list of sections inside the binary that weren't recognized
@return list of unrecognized section names
"""
slist = []
for v in self.sections:
if not v["recognized"]:
slist.append(v["name"])
return slist
def _calculate_sizes(self):
""" Calculate RAM and ROM usage by section """
objdump_command = "objdump -h " + self.filename
objdump_output = subprocess.check_output(
objdump_command, shell=True).decode("utf-8").splitlines()
for line in objdump_output:
words = line.split()
if not words: # Skip lines that are too short
continue
index = words[0]
if not index[0].isdigit(): # Skip lines that do not start
continue # with a digit
name = words[1] # Skip lines with section names
if name[0] == '.': # starting with '.'
continue
# TODO this doesn't actually reflect the size in flash or RAM as
# it doesn't include linker-imposed padding between sections.
# It is close though.
size = int(words[2], 16)
if size == 0:
continue
load_addr = int(words[4], 16)
virt_addr = int(words[3], 16)
# Add section to memory use totals (for both non-XIP and XIP scenarios)
# Unrecognized section names are not included in the calculations.
recognized = True
if name in SizeCalculator.alloc_sections:
self.ram_size += size
stype = "alloc"
elif name in SizeCalculator.rw_sections:
self.ram_size += size
self.rom_size += size
stype = "rw"
elif name in SizeCalculator.ro_sections:
self.rom_size += size
if not self.is_xip:
self.ram_size += size
stype = "ro"
else:
stype = "unknown"
if name not in self.extra_sections:
recognized = False
self.sections.append({"name": name, "load_addr": load_addr,
"size": size, "virt_addr": virt_addr,
"type": stype, "recognized": recognized})
# "list" - List of strings
# "list:<type>" - List of <type>
# "set" - Set of unordered, unique strings
# "set:<type>" - Set of <type>
# "float" - Floating point
# "int" - Integer
# "bool" - Boolean
# "str" - String
# XXX Be sure to update __doc__ if you change any of this!!
platform_valid_keys = {
"supported_toolchains": {"type": "list", "default": []},
"env": {"type": "list", "default": []}
}
testcase_valid_keys = {"tags": {"type": "set", "required": False},
"type": {"type": "str", "default": "integration"},
"extra_args": {"type": "list"},
"extra_configs": {"type": "list"},
"build_only": {"type": "bool", "default": False},
"build_on_all": {"type": "bool", "default": False},
"skip": {"type": "bool", "default": False},
"slow": {"type": "bool", "default": False},
"timeout": {"type": "int", "default": 60},
"min_ram": {"type": "int", "default": 8},
"depends_on": {"type": "set"},
"min_flash": {"type": "int", "default": 32},
"arch_whitelist": {"type": "set"},
"arch_exclude": {"type": "set"},
"extra_sections": {"type": "list", "default": []},
"platform_exclude": {"type": "set"},
"platform_whitelist": {"type": "set"},
"toolchain_exclude": {"type": "set"},
"toolchain_whitelist": {"type": "set"},
"filter": {"type": "str"},
"harness": {"type": "str"},
"harness_config": {"type": "map", "default": {}}
}
class SanityConfigParser:
"""Class to read test case files with semantic checking
"""
def __init__(self, filename, schema):
"""Instantiate a new SanityConfigParser object
@param filename Source .yaml file to read
"""
self.data = {}
self.schema = schema
self.filename = filename
self.tests = {}
self.common = {}
def load(self):
self.data = scl.yaml_load_verify(self.filename, self.schema)
if 'tests' in self.data:
self.tests = self.data['tests']
if 'common' in self.data:
self.common = self.data['common']
def _cast_value(self, value, typestr):
if isinstance(value, str):
v = value.strip()
if typestr == "str":
return v
elif typestr == "float":
return float(value)
elif typestr == "int":
return int(value)
elif typestr == "bool":
return value
elif typestr.startswith("list") and isinstance(value, list):
return value
elif typestr.startswith("list") and isinstance(value, str):
vs = v.split()
if len(typestr) > 4 and typestr[4] == ":":
return [self._cast_value(vsi, typestr[5:]) for vsi in vs]
else:
return vs
elif typestr.startswith("set"):
vs = v.split()
if len(typestr) > 3 and typestr[3] == ":":
return {self._cast_value(vsi, typestr[4:]) for vsi in vs}
else:
return set(vs)
elif typestr.startswith("map"):
return value
else:
raise ConfigurationError(
self.filename, "unknown type '%s'" % value)
def get_test(self, name, valid_keys):
"""Get a dictionary representing the keys/values within a test
@param name The test in the .yaml file to retrieve data from
@param valid_keys A dictionary representing the intended semantics
for this test. Each key in this dictionary is a key that could
be specified, if a key is given in the .yaml file which isn't in
here, it will generate an error. Each value in this dictionary
is another dictionary containing metadata:
"default" - Default value if not given
"type" - Data type to convert the text value to. Simple types
supported are "str", "float", "int", "bool" which will get
converted to respective Python data types. "set" and "list"
may also be specified which will split the value by
whitespace (but keep the elements as strings). finally,
"list:<type>" and "set:<type>" may be given which will
perform a type conversion after splitting the value up.
"required" - If true, raise an error if not defined. If false
and "default" isn't specified, a type conversion will be
done on an empty string
@return A dictionary containing the test key-value pairs with
type conversion and default values filled in per valid_keys
"""
d = {}
for k, v in self.common.items():
d[k] = v
for k, v in self.tests[name].items():
if k not in valid_keys:
raise ConfigurationError(
self.filename,
"Unknown config key '%s' in definition for '%s'" %
(k, name))
if k in d:
if isinstance(d[k], str):
# By default, we just concatenate string values of keys
# which appear both in "common" and per-test sections,
# but some keys are handled in adhoc way based on their
# semantics.
if k == "filter":
d[k] = "(%s) and (%s)" % (d[k], v)
else:
d[k] += " " + v
else:
d[k] = v
for k, kinfo in valid_keys.items():
if k not in d:
if "required" in kinfo:
required = kinfo["required"]
else:
required = False
if required:
raise ConfigurationError(
self.filename,
"missing required value for '%s' in test '%s'" %
(k, name))
else:
if "default" in kinfo:
default = kinfo["default"]
else:
default = self._cast_value("", kinfo["type"])
d[k] = default
else:
try:
d[k] = self._cast_value(d[k], kinfo["type"])
except ValueError:
raise ConfigurationError(
self.filename, "bad %s value '%s' for key '%s' in name '%s'" %
(kinfo["type"], d[k], k, name))
return d
class Platform:
"""Class representing metadata for a particular platform
Maps directly to BOARD when building"""
platform_schema = scl.yaml_load(os.path.join(ZEPHYR_BASE,
"scripts","sanity_chk","platform-schema.yaml"))
def __init__(self):
"""Constructor.
"""
self.name = ""
self.sanitycheck = True
# if no RAM size is specified by the board, take a default of 128K
self.ram = 128
self.ignore_tags = []
self.default = False
# if no flash size is specified by the board, take a default of 512K
self.flash = 512
self.supported = set()
self.arch = ""
self.type = "na"
self.simulation = "na"
self.supported_toolchains = []
self.env = []
self.env_satisfied = True
self.filter_data = dict()
def load(self, platform_file):
scp = SanityConfigParser(platform_file, self.platform_schema)
scp.load()
data = scp.data
self.name = data['identifier']
self.sanitycheck = data.get("sanitycheck", True)
# if no RAM size is specified by the board, take a default of 128K
self.ram = data.get("ram", 128)
testing = data.get("testing", {})
self.ignore_tags = testing.get("ignore_tags", [])
self.default = testing.get("default", False)
# if no flash size is specified by the board, take a default of 512K
self.flash = data.get("flash", 512)
self.supported = set()
for supp_feature in data.get("supported", []):
for item in supp_feature.split(":"):
self.supported.add(item)
self.arch = data['arch']
self.type = data.get('type', "na")
self.simulation = data.get('simulation', "na")
self.supported_toolchains = data.get("toolchain", [])
self.env = data.get("env", [])
self.env_satisfied = True
for env in self.env:
if not os.environ.get(env, None):
self.env_satisfied = False
def __repr__(self):
return "<%s on %s>" % (self.name, self.arch)
class TestCase(object):
"""Class representing a test application
"""
def __init__(self):
"""TestCase constructor.
This gets called by TestSuite as it finds and reads test yaml files.
Multiple TestCase instances may be generated from a single testcase.yaml,
each one corresponds to an entry within that file.
We need to have a unique name for every single test case. Since
a testcase.yaml can define multiple tests, the canonical name for
the test case is <workdir>/<name>.
@param testcase_root os.path.abspath() of one of the --testcase-root
@param workdir Sub-directory of testcase_root where the
.yaml test configuration file was found
@param name Name of this test case, corresponding to the entry name
in the test case configuration file. For many test cases that just
define one test, can be anything and is usually "test". This is
really only used to distinguish between different cases when
the testcase.yaml defines multiple tests
@param tc_dict Dictionary with test values for this test case
from the testcase.yaml file
"""
self.id = ""
self.source_dir = ""
self.yamlfile = ""
self.cases = []
self.name = ""
self.type = None
self.tags = None
self.extra_args = None
self.extra_configs = None
self.arch_whitelist = None
self.arch_exclude = None
self.skip = None
self.platform_exclude = None
self.platform_whitelist = None
self.toolchain_exclude = None
self.toolchain_whitelist = None
self.tc_filter = None
self.timeout = 60
self.harness = ""
self.harness_config = {}
self.build_only = True
self.build_on_all = False
self.slow = False
self.min_ram = None
self.depends_on = None
self.min_flash = None
self.extra_sections = None
@staticmethod
def get_unique(testcase_root, workdir, name):
canonical_testcase_root = os.path.realpath(testcase_root)
if Path(canonical_zephyr_base) in Path(canonical_testcase_root).parents:
# This is in ZEPHYR_BASE, so include path in name for uniqueness
# FIXME: We should not depend on path of test for unique names.
relative_tc_root = os.path.relpath(canonical_testcase_root,
start=canonical_zephyr_base)
else:
relative_tc_root = ""
# workdir can be "."
unique = os.path.normpath(os.path.join(relative_tc_root, workdir, name))
return unique
@staticmethod
def scan_file(inf_name):
suite_regex = re.compile(
# do not match until end-of-line, otherwise we won't allow
# stc_regex below to catch the ones that are declared in the same
# line--as we only search starting the end of this match
br"^\s*ztest_test_suite\(\s*(?P<suite_name>[a-zA-Z0-9_]+)\s*,",
re.MULTILINE)
stc_regex = re.compile(
br"^\s*" # empy space at the beginning is ok
# catch the case where it is declared in the same sentence, e.g:
#
# ztest_test_suite(mutex_complex, ztest_user_unit_test(TESTNAME));
br"(?:ztest_test_suite\([a-zA-Z0-9_]+,\s*)?"
# Catch ztest[_user]_unit_test-[_setup_teardown](TESTNAME)
br"ztest_(?:1cpu_)?(?:user_)?unit_test(?:_setup_teardown)?"
# Consume the argument that becomes the extra testcse
br"\(\s*"
br"(?P<stc_name>[a-zA-Z0-9_]+)"
# _setup_teardown() variant has two extra arguments that we ignore
br"(?:\s*,\s*[a-zA-Z0-9_]+\s*,\s*[a-zA-Z0-9_]+)?"
br"\s*\)",
# We don't check how it finishes; we don't care
re.MULTILINE)
suite_run_regex = re.compile(
br"^\s*ztest_run_test_suite\((?P<suite_name>[a-zA-Z0-9_]+)\)",
re.MULTILINE)
achtung_regex = re.compile(
br"(#ifdef|#endif)",
re.MULTILINE)
warnings = None
with open(inf_name) as inf:
if os.name == 'nt':
mmap_args = {'fileno':inf.fileno(), 'length':0, 'access':mmap.ACCESS_READ}
else:
mmap_args = {'fileno':inf.fileno(), 'length':0, 'flags':mmap.MAP_PRIVATE, 'prot':mmap.PROT_READ, 'offset':0}
with contextlib.closing(mmap.mmap(**mmap_args)) as main_c:
# contextlib makes pylint think main_c isn't subscriptable
# pylint: disable=unsubscriptable-object
suite_regex_match = suite_regex.search(main_c)
if not suite_regex_match:
# can't find ztest_test_suite, maybe a client, because
# it includes ztest.h
return None, None
suite_run_match = suite_run_regex.search(main_c)
if not suite_run_match:
raise ValueError("can't find ztest_run_test_suite")
achtung_matches = re.findall(
achtung_regex,
main_c[suite_regex_match.end():suite_run_match.start()])
if achtung_matches:
warnings = "found invalid %s in ztest_test_suite()" \
% ", ".join({match.decode() for match in achtung_matches})
_matches = re.findall(
stc_regex,
main_c[suite_regex_match.end():suite_run_match.start()])
matches = [ match.decode().replace("test_", "") for match in _matches ]
return matches, warnings
def scan_path(self, path):
subcases = []
for filename in glob.glob(os.path.join(path, "src", "*.c")):
try:
_subcases, warnings = self.scan_file(filename)
if warnings:
error("%s: %s" % (filename, warnings))
if _subcases:
subcases += _subcases
except ValueError as e:
error("%s: can't find: %s" % (filename, e))
return subcases
def parse_subcases(self, test_path):
results = self.scan_path(test_path)
for sub in results:
name = "{}.{}".format(self.id, sub)
self.cases.append(name)
if not results:
self.cases.append(self.id)
def __str__(self):
return self.name
class TestInstance:
"""Class representing the execution of a particular TestCase on a platform
@param test The TestCase object we want to build/execute
@param platform Platform object that we want to build and run against
@param base_outdir Base directory for all test results. The actual
out directory used is <outdir>/<platform>/<test case name>
"""
def __init__(self, testcase, platform, base_outdir):
self.testcase = testcase
self.platform = platform
self.status = None
self.reason = "N/A"
self.metrics = dict()
self.handler = None
self.name = os.path.join(platform.name, testcase.name)
self.build_dir = os.path.join(base_outdir, platform.name, testcase.name)
self.build_only = self.check_build_or_run()
self.run = not self.build_only
self.results = {}
def __lt__(self, other):
return self.name < other.name
def check_build_or_run(self):
# right now we only support building on windows. running is still work
# in progress.
if os.name == 'nt':
return True
build_only = True
# we asked for build-only on the command line
if options.build_only:
return True
# The testcase is designed to be build only.
if self.testcase.build_only:
return True
# Do not run slow tests:
skip_slow = self.testcase.slow and not options.enable_slow
if skip_slow:
return True
runnable =bool(self.testcase.type == "unit" or \
self.platform.type == "native" or \
self.platform.simulation in ["nsim", "renode", "qemu"] or \
options.device_testing)
if self.platform.simulation == "nsim":
if not find_executable("nsimdrv"):
runnable = False
if self.platform.simulation == "renode":
if not find_executable("renode"):
runnable = False
# console harness allows us to run the test and capture data.
if self.testcase.harness == 'console':
# if we have a fixture that is also being supplied on the
# command-line, then we need to run the test, not just build it.
if "fixture" in self.testcase.harness_config:
fixture = self.testcase.harness_config['fixture']
if fixture in options.fixture:
build_only = False
else:
build_only = True
else:
build_only = False
elif self.testcase.harness:
build_only = True
else:
build_only = False
return not (not build_only and runnable)
def create_overlay(self, platform):
# Create this in a "sanitycheck/" subdirectory otherwise this
# will pass this overlay to kconfig.py *twice* and kconfig.cmake
# will silently give that second time precedence over any
# --extra-args=CONFIG_*
subdir = os.path.join(self.build_dir, "sanitycheck")
os.makedirs(subdir, exist_ok=True)
file = os.path.join(subdir, "testcase_extra.conf")
with open(file, "w") as f:
content = ""
if self.testcase.extra_configs:
content = "\n".join(self.testcase.extra_configs)
if options.enable_coverage:
if platform.name in options.coverage_platform:
content = content + "\nCONFIG_COVERAGE=y"
if options.enable_asan:
if platform.type == "native":
content = content + "\nCONFIG_ASAN=y"
f.write(content)
def calculate_sizes(self):
"""Get the RAM/ROM sizes of a test case.
This can only be run after the instance has been executed by
MakeGenerator, otherwise there won't be any binaries to measure.
@return A SizeCalculator object
"""
fns = glob.glob(os.path.join(self.build_dir, "zephyr", "*.elf"))
fns.extend(glob.glob(os.path.join(self.build_dir, "zephyr", "*.exe")))
fns = [x for x in fns if not x.endswith('_prebuilt.elf')]
if len(fns) != 1:
raise BuildError("Missing/multiple output ELF binary")
return SizeCalculator(fns[0], self.testcase.extra_sections)
def __repr__(self):
return "<TestCase %s on %s>" % (self.testcase.name, self.platform.name)
class CMake():
config_re = re.compile('(CONFIG_[A-Za-z0-9_]+)[=]\"?([^\"]*)\"?$')
dt_re = re.compile('([A-Za-z0-9_]+)[=]\"?([^\"]*)\"?$')
def __init__(self, testcase, platform, source_dir, build_dir):
self.cwd = None
self.capture_output = True
self.defconfig = {}
self.cmake_cache = {}
self.instance = None
self.testcase = testcase
self.platform = platform
self.source_dir = source_dir
self.build_dir = build_dir
self.log = "build.log"
def parse_generated(self):
self.defconfig = {}
return {}
def run_build(self, args=[]):
verbose("Building %s for %s" % (self.source_dir, self.platform.name))
cmake_args = []
cmake_args.extend(args)
cmake = shutil.which('cmake')
cmd = [cmake] + cmake_args
kwargs = dict()
if self.capture_output:
kwargs['stdout'] = subprocess.PIPE
# CMake sends the output of message() to stderr unless it's STATUS
kwargs['stderr'] = subprocess.STDOUT
if self.cwd:
kwargs['cwd'] = self.cwd
p = subprocess.Popen(cmd, **kwargs)
out, _ = p.communicate()
results = {}
if p.returncode == 0:
msg = "Finished building %s for %s" %(self.source_dir, self.platform.name)
self.instance.status = "passed"
results = {'msg': msg, "returncode": p.returncode, "instance": self.instance}
if out:
log_msg = out.decode(sys.getdefaultencoding())
with open(os.path.join(self.build_dir, self.log), "a") as log:
log.write(log_msg)
else:
return None
else:
# A real error occurred, raise an exception
if out:
log_msg = out.decode(sys.getdefaultencoding())
with open(os.path.join(self.build_dir, self.log), "a") as log:
log.write(log_msg)
overflow_flash = "region `FLASH' overflowed by"
overflow_ram = "region `RAM' overflowed by"
if log_msg:
if log_msg.find(overflow_flash) > 0 or log_msg.find(overflow_ram) > 0:
verbose("RAM/ROM Overflow")
self.instance.status = "skipped"
self.instance.reason = "overflow"
else:
self.instance.status = "failed"
self.instance.reason = "Build failure"
results = {
"returncode": p.returncode,
"instance": self.instance,
}
return results
def run_cmake(self, args=[]):
verbose("Running cmake on %s for %s" %(self.source_dir, self.platform.name))
ldflags="-Wl,--fatal-warnings"
#fixme: add additional cflags based on options
cmake_args = [
'-B{}'.format(self.build_dir),
'-S{}'.format(self.source_dir),
'-DEXTRA_CFLAGS="-Werror ',
'-DEXTRA_AFLAGS=-Wa,--fatal-warnings',
'-DEXTRA_LDFLAGS="{}'.format(ldflags),
'-G{}'.format(get_generator()[1])
]
args = ["-D{}".format(a.replace('"', '')) for a in args]
cmake_args.extend(args)
cmake_opts = ['-DBOARD={}'.format(self.platform.name)]
cmake_args.extend(cmake_opts)
cmake = shutil.which('cmake')
cmd = [cmake] + cmake_args
kwargs = dict()
if self.capture_output:
kwargs['stdout'] = subprocess.PIPE
# CMake sends the output of message() to stderr unless it's STATUS
kwargs['stderr'] = subprocess.STDOUT
if self.cwd:
kwargs['cwd'] = self.cwd
p = subprocess.Popen(cmd, **kwargs)
out, _ = p.communicate()
if p.returncode == 0:
filter_results = self.parse_generated()
msg = "Finished building %s for %s" %(self.source_dir, self.platform.name)
results = {'msg': msg, 'filter': filter_results}
else:
self.instance.status = "failed"
self.instance.reason = "Cmake build failure"
results = {"returncode": p.returncode}
if out:
with open(os.path.join(self.build_dir, self.log), "a") as log:
log_msg = out.decode(sys.getdefaultencoding())
log.write(log_msg)
return results
class FilterBuilder(CMake):
def __init__(self, testcase, platform, source_dir, build_dir):
super().__init__(testcase, platform, source_dir, build_dir)
self.log = "config-sanitycheck.log"
def parse_generated(self):
if self.platform.name == "unit_testing":
return {}
cmake_cache_path = os.path.join(self.build_dir, "CMakeCache.txt")
defconfig_path = os.path.join(self.build_dir, "zephyr", ".config")
with open(defconfig_path, "r") as fp:
defconfig = {}
for line in fp.readlines():
m = self.config_re.match(line)
if not m:
if line.strip() and not line.startswith("#"):
sys.stderr.write("Unrecognized line %s\n" % line)
continue
defconfig[m.group(1)] = m.group(2).strip()
self.defconfig = defconfig
cmake_conf = {}
try:
cache = CMakeCache.from_file(cmake_cache_path)
except FileNotFoundError:
cache = {}
for k in iter(cache):
cmake_conf[k.name] = k.value
self.cmake_cache = cmake_conf
filter_data = {
"ARCH": self.platform.arch,
"PLATFORM": self.platform.name
}
filter_data.update(os.environ)
filter_data.update(self.defconfig)
filter_data.update(self.cmake_cache)
dts_path = os.path.join(self.build_dir, "zephyr", self.platform.name + ".dts.pre.tmp")
if self.testcase and self.testcase.tc_filter:
try:
if os.path.exists(dts_path):
edt = edtlib.EDT(dts_path, [os.path.join(ZEPHYR_BASE, "dts", "bindings")])
else:
edt = None
res = expr_parser.parse(self.testcase.tc_filter, filter_data, edt)
except (ValueError, SyntaxError) as se:
sys.stderr.write(
"Failed processing %s\n" % self.testcase.yamlfile)
raise se
if not res:
return {os.path.join(self.platform.name, self.testcase.name): True}
else:
return {os.path.join(self.platform.name, self.testcase.name): False}
else:
self.platform.filter_data = filter_data
return filter_data
class ProjectBuilder(FilterBuilder):
def __init__(self, suite, instance):
super().__init__(instance.testcase, instance.platform, instance.testcase.source_dir, instance.build_dir)
self.log = "build.log"
self.instance = instance
self.suite = suite
def setup_handler(self):
instance = self.instance
args = []
# FIXME: Needs simplification
if instance.platform.simulation == "qemu":
instance.handler = QEMUHandler(instance, "qemu")
args.append("QEMU_PIPE=%s" % instance.handler.get_fifo())
instance.handler.call_make_run = True
elif instance.testcase.type == "unit":
instance.handler = BinaryHandler(instance, "unit")
instance.handler.binary = os.path.join(instance.build_dir, "testbinary")
elif instance.platform.type == "native":
instance.handler = BinaryHandler(instance, "native")
instance.handler.binary = os.path.join(instance.build_dir, "zephyr", "zephyr.exe")
elif instance.platform.simulation == "nsim":
if find_executable("nsimdrv"):
instance.handler = BinaryHandler(instance, "nsim")
instance.handler.call_make_run = True
elif instance.platform.simulation == "renode":
if find_executable("renode"):
instance.handler = BinaryHandler(instance, "renode")
instance.handler.pid_fn = os.path.join(instance.build_dir, "renode.pid")
instance.handler.call_make_run = True
elif options.device_testing:
instance.handler = DeviceHandler(instance, "device")
if instance.handler:
instance.handler.args = args
def process(self, message):
op = message.get('op')
if not self.instance.handler:
self.setup_handler()
# The build process, call cmake and build with configured generator
if op == "cmake":
results = self.cmake()
if self.instance.status == "failed":
pipeline.put({"op": "report", "test": self.instance})
elif options.cmake_only:
pipeline.put({"op": "report", "test": self.instance})
else:
if self.instance.name in results['filter'] and results['filter'][self.instance.name]:
verbose("filtering %s" % self.instance.name)
self.instance.status = "skipped"
self.instance.reason = "filter"
pipeline.put({"op": "report", "test": self.instance})
else:
pipeline.put({"op": "build", "test": self.instance})
elif op == "build":
verbose("build test: %s" %self.instance.name)
results = self.build()
if results.get('returncode', 1) > 0:
pipeline.put({"op": "report", "test": self.instance})
else:
if self.instance.run:
pipeline.put({"op": "run", "test": self.instance})
else:
pipeline.put({"op": "report", "test": self.instance})
# Run the generated binary using one of the supported handlers
elif op == "run":
verbose("run test: %s" %self.instance.name)
self.run()
self.instance.status, _ = self.instance.handler.get_state()
pipeline.put({
"op": "report",
"test": self.instance,
"state": "executed",
"status": self.instance.status,
"reason": self.instance.reason}
)
# Report results and output progress to screen
elif op == "report":
with report_lock:
self.report_out()
def report_out(self):
total_tests_width = len(str(self.suite.total_tests))
self.suite.total_done += 1
instance = self.instance
if instance.status in ["failed", "timeout"]:
self.suite.total_failed += 1
if VERBOSE or not TERMINAL:
status = COLOR_RED + "FAILED " + COLOR_NORMAL + instance.reason
else:
info(
"\n{:<25} {:<50} {}FAILED{}: {}".format(
instance.platform.name,
instance.testcase.name,
COLOR_RED,
COLOR_NORMAL,
instance.reason), False)
if not VERBOSE:
log_info_file(instance)
elif instance.status == "skipped":
self.suite.total_skipped += 1
status = COLOR_YELLOW + "SKIPPED" + COLOR_NORMAL
else:
status = COLOR_GREEN + "PASSED" + COLOR_NORMAL
if VERBOSE or not TERMINAL:
if options.cmake_only:
more_info = "cmake"
elif instance.status == "skipped":
more_info = instance.reason
else:
if instance.handler and instance.run:
more_info = instance.handler.type_str
htime = instance.handler.duration
if htime:
more_info += " {:.3f}s".format(htime)
else:
more_info = "build"
info("{:>{}}/{} {:<25} {:<50} {} ({})".format(
self.suite.total_done, total_tests_width, self.suite.total_tests, instance.platform.name,
instance.testcase.name, status, more_info))
if instance.status in ["failed", "timeout"]:
log_info_file(instance)
else:
sys.stdout.write("\rtotal complete: %s%4d/%4d%s %2d%% skipped: %s%4d%s, failed: %s%4d%s" % (
COLOR_GREEN,
self.suite.total_done,
self.suite.total_tests,
COLOR_NORMAL,
int((float(self.suite.total_done) / self.suite.total_tests) * 100),
COLOR_YELLOW if self.suite.total_skipped > 0 else COLOR_NORMAL,
self.suite.total_skipped,
COLOR_NORMAL,
COLOR_RED if self.suite.total_failed > 0 else COLOR_NORMAL,
self.suite.total_failed,
COLOR_NORMAL
)
)
sys.stdout.flush()
def cmake(self):
instance = self.instance
args = self.testcase.extra_args[:]
if options.extra_args:
args += options.extra_args
if instance.handler:
args += instance.handler.args
# merge overlay files into one variable
overlays = ""
idx = 0
for arg in args:
match = re.search('OVERLAY_CONFIG="(.*)"', arg)
if match:
overlays += match.group(1)
del args[idx]
idx += 1
if (self.testcase.extra_configs or options.coverage or
options.enable_asan):
args.append("OVERLAY_CONFIG=\"%s %s\"" %(overlays,
os.path.join(instance.build_dir,
"sanitycheck", "testcase_extra.conf")))
results = self.run_cmake(args)
return results
def build(self):
results = self.run_build(['--build', self.build_dir])
return results
def run(self):
instance = self.instance
if instance.handler.type_str == "device":
instance.handler.suite = self.suite
instance.handler.handle()
sys.stdout.flush()
pipeline = queue.LifoQueue()
class BoundedExecutor(concurrent.futures.ThreadPoolExecutor):
"""BoundedExecutor behaves as a ThreadPoolExecutor which will block on
calls to submit() once the limit given as "bound" work items are queued for
execution.
:param bound: Integer - the maximum number of items in the work queue
:param max_workers: Integer - the size of the thread pool
"""
def __init__(self, bound, max_workers, **kwargs):
super().__init__(max_workers)
#self.executor = ThreadPoolExecutor(max_workers=max_workers)
self.semaphore = BoundedSemaphore(bound + max_workers)
def submit(self, fn, *args, **kwargs):
self.semaphore.acquire()
try:
future = super().submit(fn, *args, **kwargs)
except:
self.semaphore.release()
raise
else:
future.add_done_callback(lambda x: self.semaphore.release())
return future
class TestSuite:
config_re = re.compile('(CONFIG_[A-Za-z0-9_]+)[=]\"?([^\"]*)\"?$')
dt_re = re.compile('([A-Za-z0-9_]+)[=]\"?([^\"]*)\"?$')
tc_schema = scl.yaml_load(
os.path.join(ZEPHYR_BASE,
"scripts", "sanity_chk", "testcase-schema.yaml"))
def __init__(self, board_root_list, testcase_roots, outdir):
self.roots = testcase_roots
if not isinstance(board_root_list, list):
self.board_roots= [board_root_list]
else:
self.board_roots = board_root_list
# Keep track of which test cases we've filtered out and why
self.testcases = {}
self.platforms = []
self.default_platforms = []
self.outdir = os.path.abspath(outdir)
self.discards = None
self.load_errors = 0
self.instances = dict()
self.total_tests = 0 # number of test instances
self.total_cases = 0 # number of test cases
self.total_done = 0 # tests completed
self.total_failed = 0
self.total_skipped = 0
self.total_platforms = 0
self.start_time = 0
self.duration = 0
self.warnings = 0
self.cv = threading.Condition()
# hardcoded for now
self.connected_hardware = []
if options.jobs:
self.jobs = options.jobs
elif options.build_only:
self.jobs = multiprocessing.cpu_count() * 2
else:
self.jobs = multiprocessing.cpu_count()
info("JOBS: %d" % self.jobs)
def update(self):
self.total_tests = len(self.instances)
self.total_cases = len(self.testcases)
def compare_metrics(self, filename):
# name, datatype, lower results better
interesting_metrics = [("ram_size", int, True),
("rom_size", int, True)]
if not os.path.exists(filename):
info("Cannot compare metrics, %s not found" % filename)
return []
results = []
saved_metrics = {}
with open(filename) as fp:
cr = csv.DictReader(fp)
for row in cr:
d = {}
for m, _, _ in interesting_metrics:
d[m] = row[m]
saved_metrics[(row["test"], row["platform"])] = d
for instance in self.instances.values():
mkey = (instance.testcase.name, instance.platform.name)
if mkey not in saved_metrics:
continue
sm = saved_metrics[mkey]
for metric, mtype, lower_better in interesting_metrics:
if metric not in instance.metrics:
continue
if sm[metric] == "":
continue
delta = instance.metrics.get(metric, 0) - mtype(sm[metric])
if delta == 0:
continue
results.append((instance, metric, instance.metrics.get(metric, 0 ), delta,
lower_better))
return results
def misc_reports(self, report, show_footprint, all_deltas,
footprint_threshold, last_metrics):
if not report:
return
deltas = self.compare_metrics(report)
warnings = 0
if deltas and show_footprint:
for i, metric, value, delta, lower_better in deltas:
if not all_deltas and ((delta < 0 and lower_better) or
(delta > 0 and not lower_better)):
continue
percentage = (float(delta) / float(value - delta))
if not all_deltas and (percentage <
(footprint_threshold / 100.0)):
continue
info("{:<25} {:<60} {}{}{}: {} {:<+4}, is now {:6} {:+.2%}".format(
i.platform.name, i.testcase.name, COLOR_YELLOW,
"INFO" if all_deltas else "WARNING", COLOR_NORMAL,
metric, delta, value, percentage))
warnings += 1
if warnings:
info("Deltas based on metrics from last %s" %
("release" if not last_metrics else "run"))
def summary(self, unrecognized_sections):
failed = 0
for instance in self.instances.values():
if instance.status == "failed":
failed += 1
elif instance.metrics.get("unrecognized") and not unrecognized_sections:
info("%sFAILED%s: %s has unrecognized binary sections: %s" %
(COLOR_RED, COLOR_NORMAL, instance.name,
str(instance.metrics.get("unrecognized", []))))
failed += 1
if self.total_tests and self.total_tests != self.total_skipped:
pass_rate = (float(self.total_tests - self.total_failed - self.total_skipped)/ float(self.total_tests - self.total_skipped))
else:
pass_rate = 0
info("{}{} of {}{} tests passed ({:.2%}), {}{}{} failed, {} skipped with {}{}{} warnings in {:.2f} seconds".format(
COLOR_RED if failed else COLOR_GREEN,
self.total_tests - self.total_failed - self.total_skipped,
self.total_tests,
COLOR_NORMAL,
pass_rate,
COLOR_RED if self.total_failed else COLOR_NORMAL,
self.total_failed,
COLOR_NORMAL,
self.total_skipped,
COLOR_YELLOW if self.warnings else COLOR_NORMAL,
self.warnings,
COLOR_NORMAL,
self.duration))
platforms = set(p.platform for p in self.instances.values())
self.total_platforms = len(self.platforms)
if self.platforms:
info("In total {} test cases were executed on {} out of total {} platforms ({:02.2f}%)".format(
self.total_cases,
len(platforms),
self.total_platforms,
(100 * len(platforms) / len(self.platforms))
))
def save_reports(self):
if not self.instances:
return
report_name = "sanitycheck"
if options.report_name:
report_name = options.report_name
if options.report_dir:
os.makedirs(options.report_dir, exist_ok=True)
filename = os.path.join(options.report_dir, report_name)
outdir = options.report_dir
else:
filename = os.path.join(options.outdir, report_name)
outdir = options.outdir
if not options.no_update:
self.xunit_report(filename + ".xml")
self.csv_report(filename + ".csv")
self.target_report(outdir)
if self.discards:
self.discard_report(filename + "_discard.csv")
if options.release:
self.csv_report(RELEASE_DATA)
if log_file:
log_file.close()
def load_hardware_map_from_cmdline(self, serial, platform):
device = {
"serial": serial,
"platform": platform,
"counter": 0,
"available": True,
"connected": True
}
self.connected_hardware = [device]
def load_hardware_map(self, map_file):
with open(map_file, 'r') as stream:
try:
self.connected_hardware = yaml.safe_load(stream)
except yaml.YAMLError as exc:
print(exc)
for i in self.connected_hardware:
i['counter'] = 0
def add_configurations(self):
for board_root in self.board_roots:
board_root = os.path.abspath(board_root)
debug("Reading platform configuration files under %s..." %
board_root)
for file in glob.glob(os.path.join(board_root, "*", "*", "*.yaml")):
verbose("Found plaform configuration " + file)
try:
platform = Platform()
platform.load(file)
if platform.sanitycheck:
self.platforms.append(platform)
if platform.default:
self.default_platforms.append(platform.name)
except RuntimeError as e:
error("E: %s: can't load: %s" % (file, e))
self.load_errors += 1
def get_all_tests(self):
tests = []
for _, tc in self.testcases.items():
for case in tc.cases:
tests.append(case)
return tests
@staticmethod
def get_toolchain():
toolchain = os.environ.get("ZEPHYR_TOOLCHAIN_VARIANT", None) or \
os.environ.get("ZEPHYR_GCC_VARIANT", None)
if toolchain == "gccarmemb":
# Remove this translation when gccarmemb is no longer supported.
toolchain = "gnuarmemb"
try:
if not toolchain:
raise SanityRuntimeError("E: Variable ZEPHYR_TOOLCHAIN_VARIANT is not defined")
except Exception as e:
print(str(e))
sys.exit(2)
return toolchain
def add_testcases(self):
for root in self.roots:
root = os.path.abspath(root)
debug("Reading test case configuration files under %s..." %root)
for dirpath, dirnames, filenames in os.walk(root, topdown=True):
verbose("scanning %s" % dirpath)
if 'sample.yaml' in filenames:
filename = 'sample.yaml'
elif 'testcase.yaml' in filenames:
filename = 'testcase.yaml'
else:
continue
verbose("Found possible test case in " + dirpath)
dirnames[:] = []
tc_path = os.path.join(dirpath, filename)
self.add_testcase(tc_path, root)
def add_testcase(self, tc_data_file, root):
try:
parsed_data = SanityConfigParser(tc_data_file, self.tc_schema)
parsed_data.load()
tc_path = os.path.dirname(tc_data_file)
workdir = os.path.relpath(tc_path, root)
for name in parsed_data.tests.keys():
tc = TestCase()
tc.name = tc.get_unique(root, workdir, name)
tc_dict = parsed_data.get_test(name, testcase_valid_keys)
tc.source_dir = tc_path
tc.yamlfile = tc_data_file
tc.id = name
tc.type = tc_dict["type"]
tc.tags = tc_dict["tags"]
tc.extra_args = tc_dict["extra_args"]
tc.extra_configs = tc_dict["extra_configs"]
tc.arch_whitelist = tc_dict["arch_whitelist"]
tc.arch_exclude = tc_dict["arch_exclude"]
tc.skip = tc_dict["skip"]
tc.platform_exclude = tc_dict["platform_exclude"]
tc.platform_whitelist = tc_dict["platform_whitelist"]
tc.toolchain_exclude = tc_dict["toolchain_exclude"]
tc.toolchain_whitelist = tc_dict["toolchain_whitelist"]
tc.tc_filter = tc_dict["filter"]
tc.timeout = tc_dict["timeout"]
tc.harness = tc_dict["harness"]
tc.harness_config = tc_dict["harness_config"]
tc.build_only = tc_dict["build_only"]
tc.build_on_all = tc_dict["build_on_all"]
tc.slow = tc_dict["slow"]
tc.min_ram = tc_dict["min_ram"]
tc.depends_on = tc_dict["depends_on"]
tc.min_flash = tc_dict["min_flash"]
tc.extra_sections = tc_dict["extra_sections"]
tc.parse_subcases(tc_path)
if tc.name:
self.testcases[tc.name] = tc
except Exception as e:
error("E: %s: can't load (skipping): %s" % (tc_data_file, e))
self.load_errors += 1
return False
return True
def get_platform(self, name):
selected_platform = None
for platform in self.platforms:
if platform.name == name:
selected_platform = platform
break
return selected_platform
def get_last_failed(self):
last_run = os.path.join(options.outdir, "sanitycheck.csv")
try:
if not os.path.exists(last_run):
raise SanityRuntimeError("Couldn't find last sanitycheck run.: %s" %last_run)
except Exception as e:
print(str(e))
sys.exit(2)
total_tests = 0
with open(last_run, "r") as fp:
cr = csv.DictReader(fp)
instance_list = []
for row in cr:
total_tests += 1
if row["passed"] == "True":
continue
test = row["test"]
platform = self.get_platform(row["platform"])
instance = TestInstance(self.testcases[test], platform, self.outdir)
instance.create_overlay(platform)
instance_list.append(instance)
self.add_instances(instance_list)
tests_to_run = len(self.instances)
info("%d tests passed already, retyring %d tests" %(total_tests - tests_to_run, tests_to_run))
def load_from_file(self, file):
try:
if not os.path.exists(file):
raise SanityRuntimeError(
"Couldn't find input file with list of tests.")
except Exception as e:
print(str(e))
sys.exit(2)
with open(file, "r") as fp:
cr = csv.DictReader(fp)
instance_list = []
for row in cr:
if row["arch"] == "arch":
continue
test = row["test"]
platform = self.get_platform(row["platform"])
instance = TestInstance(self.testcases[test], platform, self.outdir)
instance.create_overlay(platform)
instance_list.append(instance)
self.add_instances(instance_list)
def apply_filters(self):
toolchain = self.get_toolchain()
discards = {}
platform_filter = options.platform
testcase_filter = run_individual_tests
arch_filter = options.arch
tag_filter = options.tag
exclude_tag = options.exclude_tag
verbose("platform filter: " + str(platform_filter))
verbose(" arch_filter: " + str(arch_filter))
verbose(" tag_filter: " + str(tag_filter))
verbose(" exclude_tag: " + str(exclude_tag))
default_platforms = False
if platform_filter:
platforms = list(filter(lambda p: p.name in platform_filter, self.platforms))
else:
platforms = self.platforms
if options.all:
info("Selecting all possible platforms per test case")
# When --all used, any --platform arguments ignored
platform_filter = []
elif not platform_filter:
info("Selecting default platforms per test case")
default_platforms = True
info("Building initial testcase list...")
for tc_name, tc in self.testcases.items():
# list of instances per testcase, aka configurations.
instance_list = []
for plat in platforms:
instance = TestInstance(tc, plat, self.outdir)
if (plat.arch == "unit") != (tc.type == "unit"):
# Discard silently
continue
if options.device_testing and instance.build_only:
discards[instance] = "Not runnable on device"
continue
if tc.skip:
discards[instance] = "Skip filter"
continue
if tc.build_on_all and not platform_filter:
platform_filter = []
if tag_filter and not tc.tags.intersection(tag_filter):
discards[instance] = "Command line testcase tag filter"
continue
if exclude_tag and tc.tags.intersection(exclude_tag):
discards[instance] = "Command line testcase exclude filter"
continue
if testcase_filter and tc_name not in testcase_filter:
discards[instance] = "Testcase name filter"
continue
if arch_filter and plat.arch not in arch_filter:
discards[instance] = "Command line testcase arch filter"
continue
if tc.arch_whitelist and plat.arch not in tc.arch_whitelist:
discards[instance] = "Not in test case arch whitelist"
continue
if tc.arch_exclude and plat.arch in tc.arch_exclude:
discards[instance] = "In test case arch exclude"
continue
if tc.platform_exclude and plat.name in tc.platform_exclude:
discards[instance] = "In test case platform exclude"
continue
if tc.toolchain_exclude and toolchain in tc.toolchain_exclude:
discards[instance] = "In test case toolchain exclude"
continue
if platform_filter and plat.name not in platform_filter:
discards[instance] = "Command line platform filter"
continue
if tc.platform_whitelist and plat.name not in tc.platform_whitelist:
discards[instance] = "Not in testcase platform whitelist"
continue
if tc.toolchain_whitelist and toolchain not in tc.toolchain_whitelist:
discards[instance] = "Not in testcase toolchain whitelist"
continue
if not plat.env_satisfied:
discards[instance] = "Environment ({}) not satisfied".format(", ".join(plat.env))
continue
if not options.force_toolchain \
and toolchain and (toolchain not in plat.supported_toolchains) \
and tc.type != 'unit':
discards[instance] = "Not supported by the toolchain"
continue
if plat.ram < tc.min_ram:
discards[instance] = "Not enough RAM"
continue
if tc.depends_on:
dep_intersection = tc.depends_on.intersection(set(plat.supported))
if dep_intersection != set(tc.depends_on):
discards[instance] = "No hardware support"
continue
if plat.flash < tc.min_flash:
discards[instance] = "Not enough FLASH"
continue
if set(plat.ignore_tags) & tc.tags:
discards[instance] = "Excluded tags per platform"
continue
# if nothing stopped us until now, it means this configuration
# needs to be added.
instance_list.append(instance)
# no configurations, so jump to next testcase
if not instance_list:
continue
# if sanitycheck was launched with no platform options at all, we
# take all default platforms
if default_platforms and not tc.build_on_all:
if tc.platform_whitelist:
a = set(self.default_platforms)
b = set(tc.platform_whitelist)
c = a.intersection(b)
if c:
aa = list( filter( lambda tc: tc.platform.name in c, instance_list))
self.add_instances(aa)
else:
self.add_instances(instance_list[:1])
else:
instances = list( filter( lambda tc: tc.platform.default, instance_list))
self.add_instances(instances)
for instance in list(filter(lambda tc: not tc.platform.default, instance_list)):
discards[instance] = "Not a default test platform"
else:
self.add_instances(instance_list)
for _, case in self.instances.items():
case.create_overlay(case.platform)
self.discards = discards
return discards
def add_instances(self, instance_list):
for instance in instance_list:
self.instances[instance.name] = instance
def add_tasks_to_queue(self):
for instance in self.instances.values():
if options.test_only:
if instance.run:
pipeline.put({"op": "run", "test": instance, "status": "built"})
else:
if instance.status not in ['passed', 'skipped']:
instance.status = None
pipeline.put({"op": "cmake", "test": instance})
return "DONE FEEDING"
def execute(self):
def calc_one_elf_size(instance):
if instance.status not in ["failed", "skipped"]:
if instance.platform.type != "native":
size_calc = instance.calculate_sizes()
instance.metrics["ram_size"] = size_calc.get_ram_size()
instance.metrics["rom_size"] = size_calc.get_rom_size()
instance.metrics["unrecognized"] = size_calc.unrecognized_sections()
else:
instance.metrics["ram_size"] = 0
instance.metrics["rom_size"] = 0
instance.metrics["unrecognized"] = []
instance.metrics["handler_time"] = instance.handler.duration if instance.handler else 0
info("Adding tasks to the queue...")
# We can use a with statement to ensure threads are cleaned up promptly
with BoundedExecutor(bound=self.jobs, max_workers=self.jobs) as executor:
# start a future for a thread which sends work in through the queue
future_to_test = {
executor.submit(self.add_tasks_to_queue): 'FEEDER DONE'}
while future_to_test:
# check for status of the futures which are currently working
done, _ = concurrent.futures.wait(
future_to_test, timeout=0.25,
return_when=concurrent.futures.FIRST_COMPLETED)
# if there is incoming work, start a new future
while not pipeline.empty():
# fetch a url from the queue
message = pipeline.get()
test = message['test']
# Start the load operation and mark the future with its URL
pb = ProjectBuilder(self, test)
future_to_test[executor.submit(pb.process, message)] = test.name
# process any completed futures
for future in done:
test = future_to_test[future]
try:
data = future.result()
except Exception as exc:
sys.exit('%r generated an exception: %s' % (test, exc))
else:
if data:
verbose(data)
# remove the now completed future
del future_to_test[future]
if options.enable_size_report and not options.cmake_only:
# Parallelize size calculation
executor = concurrent.futures.ThreadPoolExecutor(self.jobs)
futures = [executor.submit(calc_one_elf_size, instance)
for instance in self.instances.values()]
concurrent.futures.wait(futures)
else:
for instance in self.instances.values():
instance.metrics["ram_size"] = 0
instance.metrics["rom_size"] = 0
instance.metrics["handler_time"] = instance.handler.duration if instance.handler else 0
instance.metrics["unrecognized"] = []
def discard_report(self, filename):
try:
if self.discards is None:
raise SanityRuntimeError("apply_filters() hasn't been run!")
except Exception as e:
error(str(e))
sys.exit(2)
with open(filename, "wt") as csvfile:
fieldnames = ["test", "arch", "platform", "reason"]
cw = csv.DictWriter(csvfile, fieldnames, lineterminator=os.linesep)
cw.writeheader()
for instance, reason in sorted(self.discards.items()):
rowdict = {"test": instance.testcase.name,
"arch": instance.platform.arch,
"platform": instance.platform.name,
"reason": reason}
cw.writerow(rowdict)
def target_report(self, outdir):
run = "Sanitycheck"
eleTestsuite = None
platforms = {inst.platform.name for _,inst in self.instances.items()}
for platform in platforms:
errors = 0
passes = 0
fails = 0
duration = 0
skips = 0
for _, instance in self.instances.items():
if instance.platform.name != platform:
continue
handler_time = instance.metrics.get('handler_time', 0)
duration += handler_time
for k in instance.results.keys():
if instance.results[k] == 'PASS':
passes += 1
elif instance.results[k] == 'BLOCK':
errors += 1
elif instance.results[k] == 'SKIP':
skips += 1
else:
fails += 1
eleTestsuites = ET.Element('testsuites')
eleTestsuite = ET.SubElement(eleTestsuites, 'testsuite',
name=run, time="%f" % duration,
tests="%d" % (errors + passes + fails),
failures="%d" % fails,
errors="%d" % errors, skipped="%d" %skips)
handler_time = 0
# print out test results
for _, instance in self.instances.items():
if instance.platform.name != platform:
continue
handler_time = instance.metrics.get('handler_time', 0)
for k in instance.results.keys():
eleTestcase = ET.SubElement(
eleTestsuite, 'testcase', classname="%s:%s" %(instance.platform.name, os.path.basename(instance.testcase.name)),
name="%s" % (k), time="%f" %handler_time)
if instance.results[k] in ['FAIL', 'BLOCK']:
el = None
if instance.results[k] == 'FAIL':
el = ET.SubElement(
eleTestcase,
'failure',
type="failure",
message="failed")
elif instance.results[k] == 'BLOCK':
el = ET.SubElement(
eleTestcase,
'error',
type="failure",
message="failed")
p = os.path.join(options.outdir, instance.platform.name, instance.testcase.name)
log_file = os.path.join(p, "handler.log")
if os.path.exists(log_file):
with open(log_file, "rb") as f:
log = f.read().decode("utf-8")
filtered_string = ''.join(filter(lambda x: x in string.printable, log))
el.text = filtered_string
elif instance.results[k] == 'SKIP':
el = ET.SubElement(
eleTestcase,
'skipped',
type="skipped",
message="Skipped")
result = ET.tostring(eleTestsuites)
with open(os.path.join(outdir, platform + ".xml"), 'wb') as f:
f.write(result)
def xunit_report(self, filename):
fails = 0
passes = 0
errors = 0
skips = 0
duration = 0
for instance in self.instances.values():
handler_time = instance.metrics.get('handler_time', 0)
duration += handler_time
if instance.status == "failed":
if instance.reason in ['build_error', 'handler_crash']:
errors += 1
else:
fails += 1
elif instance.status == 'skipped':
skips += 1
else:
passes += 1
run = "Sanitycheck"
eleTestsuite = None
append = options.only_failed
# When we re-run the tests, we re-use the results and update only with
# the newly run tests.
if os.path.exists(filename) and append:
tree = ET.parse(filename)
eleTestsuites = tree.getroot()
eleTestsuite = tree.findall('testsuite')[0]
else:
eleTestsuites = ET.Element('testsuites')
eleTestsuite = ET.SubElement(eleTestsuites, 'testsuite',
name=run, time="%f" % duration,
tests="%d" % (errors + passes + fails + skips),
failures="%d" % fails,
errors="%d" %(errors), skip="%s" %(skips))
for instance in self.instances.values():
# remove testcases that are a re-run
if append:
for tc in eleTestsuite.findall('testcase'):
if tc.get('classname') == "%s:%s" % (
instance.platform.name, instance.testcase.name):
eleTestsuite.remove(tc)
handler_time = 0
if instance.status != "failed" and instance.handler:
handler_time = instance.metrics.get("handler_time", 0)
eleTestcase = ET.SubElement(
eleTestsuite, 'testcase', classname="%s:%s" %
(instance.platform.name, instance.testcase.name), name="%s" %
(instance.testcase.name), time="%f" %handler_time)
if instance.status == "failed":
failure = ET.SubElement(
eleTestcase,
'failure',
type="failure",
message=instance.reason)
p = ("%s/%s/%s" % (options.outdir, instance.platform.name, instance.testcase.name))
bl = os.path.join(p, "build.log")
hl = os.path.join(p, "handler.log")
log_file = bl
if instance.reason != 'Build error':
if os.path.exists(hl):
log_file = hl
else:
log_file = bl
if os.path.exists(log_file):
with open(log_file, "rb") as f:
log = f.read().decode("utf-8")
filtered_string = ''.join(filter(lambda x: x in string.printable, log))
failure.text = filtered_string
f.close()
elif instance.status == "skipped":
ET.SubElement( eleTestcase, 'skipped', type="skipped", message="Skipped")
result = ET.tostring(eleTestsuites)
with open(filename, 'wb') as report:
report.write(result)
def csv_report(self, filename):
with open(filename, "wt") as csvfile:
fieldnames = ["test", "arch", "platform", "passed", "status",
"extra_args", "handler", "handler_time", "ram_size",
"rom_size"]
cw = csv.DictWriter(csvfile, fieldnames, lineterminator=os.linesep)
cw.writeheader()
for instance in sorted(self.instances.values()):
rowdict = {"test": instance.testcase.name,
"arch": instance.platform.arch,
"platform": instance.platform.name,
"extra_args": " ".join(instance.testcase.extra_args),
"handler": instance.platform.simulation}
if instance.status in ["failed", "timeout"]:
rowdict["passed"] = False
rowdict["status"] = instance.reason
else:
rowdict["passed"] = True
if instance.handler:
rowdict["handler_time"] = instance.metrics.get("handler_time", 0)
ram_size = instance.metrics.get("ram_size", 0)
rom_size = instance.metrics.get("rom_size", 0)
rowdict["ram_size"] = ram_size
rowdict["rom_size"] = rom_size
cw.writerow(rowdict)
def get_testcase(self, identifier):
results = []
for _, tc in self.testcases.items():
for case in tc.cases:
if case == identifier:
results.append(tc)
return results
def parse_arguments():
parser = argparse.ArgumentParser(
description=__doc__,
formatter_class=argparse.RawDescriptionHelpFormatter)
parser.fromfile_prefix_chars = "+"
case_select = parser.add_argument_group("Test case selection",
"""
Artificially long but functional example:
$ ./scripts/sanitycheck -v \\
--testcase-root tests/ztest/base \\
--testcase-root tests/kernel \\
--test tests/ztest/base/testing.ztest.verbose_0 \\
--test tests/kernel/fifo/fifo_api/kernel.fifo.poll
"kernel.fifo.poll" is one of the test section names in
__/fifo_api/testcase.yaml
""")
parser.add_argument("--force-toolchain", action="store_true",
help="Do not filter based on toolchain, use the set "
" toolchain unconditionally")
parser.add_argument(
"-p", "--platform", action="append",
help="Platform filter for testing. This option may be used multiple "
"times. Testcases will only be built/run on the platforms "
"specified. If this option is not used, then platforms marked "
"as default in the platform metadata file will be chosen "
"to build and test. ")
parser.add_argument(
"-a", "--arch", action="append",
help="Arch filter for testing. Takes precedence over --platform. "
"If unspecified, test all arches. Multiple invocations "
"are treated as a logical 'or' relationship")
parser.add_argument(
"-t", "--tag", action="append",
help="Specify tags to restrict which tests to run by tag value. "
"Default is to not do any tag filtering. Multiple invocations "
"are treated as a logical 'or' relationship")
parser.add_argument("-e", "--exclude-tag", action="append",
help="Specify tags of tests that should not run. "
"Default is to run all tests with all tags.")
case_select.add_argument(
"-f",
"--only-failed",
action="store_true",
help="Run only those tests that failed the previous sanity check "
"invocation.")
parser.add_argument(
"--retry-failed", type=int, default=0,
help="Retry failing tests again, up to the number of times specified.")
test_xor_subtest = case_select.add_mutually_exclusive_group()
test_xor_subtest.add_argument(
"-s", "--test", action="append",
help="Run only the specified test cases. These are named by "
"<path/relative/to/Zephyr/base/section.name.in.testcase.yaml>")
test_xor_subtest.add_argument(
"--sub-test", action="append",
help="""Recursively find sub-test functions and run the entire
test section where they were found, including all sibling test
functions. Sub-tests are named by:
section.name.in.testcase.yaml.function_name_without_test_prefix
Example: kernel.fifo.poll.fifo_loop
""")
parser.add_argument(
"-l", "--all", action="store_true",
help="Build/test on all platforms. Any --platform arguments "
"ignored.")
parser.add_argument(
"-o", "--report-dir",
help="""Output reports containing results of the test run into the
specified directory.
The output will be both in CSV and JUNIT format
(sanitycheck.csv and sanitycheck.xml).
""")
parser.add_argument(
"--report-name",
help="""Create a report with a custom name.
""")
parser.add_argument("--detailed-report",
action="store",
metavar="FILENAME",
help="""Generate a junit report with detailed testcase results.
Unlike the CSV file produced by --testcase-report, this XML
report includes only tests which have run and none which were
merely built. If an image with multiple tests crashes early then
later tests are not accounted for either.""")
parser.add_argument("--report-excluded",
action="store_true",
help="""List all tests that are never run based on current scope and
coverage. If you are looking for accurate results, run this with
--all, but this will take a while...""")
parser.add_argument("--compare-report",
help="Use this report file for size comparison")
parser.add_argument(
"-B", "--subset",
help="Only run a subset of the tests, 1/4 for running the first 25%%, "
"3/5 means run the 3rd fifth of the total. "
"This option is useful when running a large number of tests on "
"different hosts to speed up execution time.")
parser.add_argument(
"-N", "--ninja", action="store_true",
help="Use the Ninja generator with CMake")
parser.add_argument(
"-y", "--dry-run", action="store_true",
help="""Create the filtered list of test cases, but don't actually
run them. Useful if you're just interested in the discard report
generated for every run and saved in the specified output
directory (sanitycheck_discard.csv).
""")
parser.add_argument("--list-tags", action="store_true",
help="list all tags in selected tests")
case_select.add_argument("--list-tests", action="store_true",
help="""List of all sub-test functions recursively found in
all --testcase-root arguments. Note different sub-tests can share
the same section name and come from different directories.
The output is flattened and reports --sub-test names only,
not their directories. For instance net.socket.getaddrinfo_ok
and net.socket.fd_set belong to different directories.
""")
case_select.add_argument("--list-test-duplicates", action="store_true",
help="""List tests with duplicate identifiers.
""")
parser.add_argument("--export-tests", action="store",
metavar="FILENAME",
help="Export tests case meta-data to a file in CSV format.")
parser.add_argument("--timestamps",
action="store_true",
help="Print all messages with time stamps")
parser.add_argument(
"-r", "--release", action="store_true",
help="Update the benchmark database with the results of this test "
"run. Intended to be run by CI when tagging an official "
"release. This database is used as a basis for comparison "
"when looking for deltas in metrics such as footprint")
parser.add_argument("-w", "--warnings-as-errors", action="store_true",
help="Treat warning conditions as errors")
parser.add_argument(
"-v",
"--verbose",
action="count",
default=0,
help="Emit debugging information, call multiple times to increase "
"verbosity")
parser.add_argument(
"-i", "--inline-logs", action="store_true",
help="Upon test failure, print relevant log data to stdout "
"instead of just a path to it")
parser.add_argument("--log-file", metavar="FILENAME", action="store",
help="log also to file")
parser.add_argument(
"-m", "--last-metrics", action="store_true",
help="Instead of comparing metrics from the last --release, "
"compare with the results of the previous sanity check "
"invocation")
parser.add_argument(
"-u",
"--no-update",
action="store_true",
help="do not update the results of the last run of the sanity "
"checks")
case_select.add_argument(
"-F",
"--load-tests",
metavar="FILENAME",
action="store",
help="Load list of tests and platforms to be run from file.")
case_select.add_argument(
"-E",
"--save-tests",
metavar="FILENAME",
action="store",
help="Append list of tests and platforms to be run to file.")
test_or_build = parser.add_mutually_exclusive_group()
test_or_build.add_argument(
"-b", "--build-only", action="store_true",
help="Only build the code, do not execute any of it in QEMU")
test_or_build.add_argument(
"--test-only", action="store_true",
help="""Only run device tests with current artifacts, do not build
the code""")
parser.add_argument(
"--cmake-only", action="store_true",
help="Only run cmake, do not build or run.")
parser.add_argument(
"-j", "--jobs", type=int,
help="Number of jobs for building, defaults to number of CPU threads, "
"overcommited by factor 2 when --build-only")
parser.add_argument(
"--show-footprint", action="store_true",
help="Show footprint statistics and deltas since last release."
)
parser.add_argument(
"-H", "--footprint-threshold", type=float, default=5,
help="When checking test case footprint sizes, warn the user if "
"the new app size is greater then the specified percentage "
"from the last release. Default is 5. 0 to warn on any "
"increase on app size")
parser.add_argument(
"-D", "--all-deltas", action="store_true",
help="Show all footprint deltas, positive or negative. Implies "
"--footprint-threshold=0")
parser.add_argument(
"-O", "--outdir",
default=os.path.join(os.getcwd(),"sanity-out"),
help="Output directory for logs and binaries. "
"Default is 'sanity-out' in the current directory. "
"This directory will be deleted unless '--no-clean' is set.")
parser.add_argument(
"-n", "--no-clean", action="store_true",
help="Do not delete the outdir before building. Will result in "
"faster compilation since builds will be incremental")
case_select.add_argument(
"-T", "--testcase-root", action="append", default=[],
help="Base directory to recursively search for test cases. All "
"testcase.yaml files under here will be processed. May be "
"called multiple times. Defaults to the 'samples/' and "
"'tests/' directories at the base of the Zephyr tree.")
board_root_list = ["%s/boards" % ZEPHYR_BASE,
"%s/scripts/sanity_chk/boards" % ZEPHYR_BASE]
parser.add_argument(
"-A", "--board-root", action="append", default=board_root_list,
help="""Directory to search for board configuration files. All .yaml
files in the directory will be processed. The directory should have the same
structure in the main Zephyr tree: boards/<arch>/<board_name>/""")
parser.add_argument(
"-z", "--size", action="append",
help="Don't run sanity checks. Instead, produce a report to "
"stdout detailing RAM/ROM sizes on the specified filenames. "
"All other command line arguments ignored.")
parser.add_argument(
"-S", "--enable-slow", action="store_true",
help="Execute time-consuming test cases that have been marked "
"as 'slow' in testcase.yaml. Normally these are only built.")
parser.add_argument(
"--disable-unrecognized-section-test", action="store_true",
default=False,
help="Skip the 'unrecognized section' test.")
parser.add_argument("-R", "--enable-asserts", action="store_true",
default=True,
help="deprecated, left for compatibility")
parser.add_argument("--disable-asserts", action="store_false",
dest="enable_asserts",
help="deprecated, left for compatibility")
parser.add_argument("-Q", "--error-on-deprecations", action="store_false",
help="Error on deprecation warnings.")
parser.add_argument("--enable-size-report", action="store_true",
help="Enable expensive computation of RAM/ROM segment sizes.")
parser.add_argument(
"-x", "--extra-args", action="append", default=[],
help="""Extra CMake cache entries to define when building test cases.
May be called multiple times. The key-value entries will be
prefixed with -D before being passed to CMake.
E.g
"sanitycheck -x=USE_CCACHE=0"
will translate to
"cmake -DUSE_CCACHE=0"
which will ultimately disable ccache.
"""
)
parser.add_argument(
"--device-testing", action="store_true",
help="Test on device directly. Specify the serial device to "
"use with the --device-serial option.")
parser.add_argument(
"-X", "--fixture", action="append", default=[],
help="Specify a fixture that a board might support")
parser.add_argument(
"--device-serial",
help="Serial device for accessing the board (e.g., /dev/ttyACM0)")
parser.add_argument("--generate-hardware-map",
help="""Probe serial devices connected to this platform
and create a hardware map file to be used with
--device-testing
""")
parser.add_argument("--hardware-map",
help="""Load hardware map from a file. This will be used
for testing on hardware that is listed in the file.
""")
parser.add_argument(
"--west-flash", nargs='?', const=[],
help="""Uses west instead of ninja or make to flash when running with
--device-testing. Supports comma-separated argument list.
E.g "sanitycheck --device-testing --device-serial /dev/ttyACM0
--west-flash="--board-id=foobar,--erase"
will translate to "west flash -- --board-id=foobar --erase"
NOTE: device-testing must be enabled to use this option.
"""
)
parser.add_argument(
"--west-runner",
help="""Uses the specified west runner instead of default when running
with --west-flash.
E.g "sanitycheck --device-testing --device-serial /dev/ttyACM0
--west-flash --west-runner=pyocd"
will translate to "west flash --runner pyocd"
NOTE: west-flash must be enabled to use this option.
"""
)
valgrind_asan_group = parser.add_mutually_exclusive_group()
valgrind_asan_group.add_argument(
"--enable-valgrind", action="store_true",
help="""Run binary through valgrind and check for several memory access
errors. Valgrind needs to be installed on the host. This option only
works with host binaries such as those generated for the native_posix
configuration and is mutual exclusive with --enable-asan.
""")
valgrind_asan_group.add_argument(
"--enable-asan", action="store_true",
help="""Enable address sanitizer to check for several memory access
errors. Libasan needs to be installed on the host. This option only
works with host binaries such as those generated for the native_posix
configuration and is mutual exclusive with --enable-valgrind.
""")
parser.add_argument(
"--enable-lsan", action="store_true",
help="""Enable leak sanitizer to check for heap memory leaks.
Libasan needs to be installed on the host. This option only
works with host binaries such as those generated for the native_posix
configuration and when --enable-asan is given.
""")
parser.add_argument("--enable-coverage", action="store_true",
help="Enable code coverage using gcov.")
parser.add_argument("-C", "--coverage", action="store_true",
help="Generate coverage reports. Implies "
"--enable_coverage.")
parser.add_argument("--coverage-platform", action="append", default=[],
help="Plarforms to run coverage reports on. "
"This option may be used multiple times. "
"Default to what was selected with --platform.")
parser.add_argument("--gcov-tool", default=None,
help="Path to the gcov tool to use for code coverage "
"reports")
return parser.parse_args()
def log_info(filename):
filename = os.path.relpath(os.path.realpath(filename))
if options.inline_logs:
info("{:-^100}".format(filename))
try:
with open(filename) as fp:
data = fp.read()
except Exception as e:
data = "Unable to read log data (%s)\n" % (str(e))
sys.stdout.write(data)
if log_file:
log_file.write(data)
info("{:-^100}".format(filename))
else:
info("\n\tsee: " + COLOR_YELLOW + filename + COLOR_NORMAL)
def log_info_file(instance):
build_dir = instance.build_dir
h_log = "{}/handler.log".format(build_dir)
b_log = "{}/build.log".format(build_dir)
v_log = "{}/valgrind.log".format(build_dir)
if os.path.exists(v_log) and "Valgrind" in instance.reason:
log_info("{}".format(v_log))
elif os.path.exists(h_log):
log_info("{}".format(h_log))
else:
log_info("{}".format(b_log))
def size_report(sc):
info(sc.filename)
info("SECTION NAME VMA LMA SIZE HEX SZ TYPE")
for i in range(len(sc.sections)):
v = sc.sections[i]
info("%-17s 0x%08x 0x%08x %8d 0x%05x %-7s" %
(v["name"], v["virt_addr"], v["load_addr"], v["size"], v["size"],
v["type"]))
info("Totals: %d bytes (ROM), %d bytes (RAM)" %
(sc.rom_size, sc.ram_size))
info("")
def retrieve_gcov_data(intput_file):
if VERBOSE:
print("Working on %s" %intput_file)
extracted_coverage_info = {}
capture_data = False
capture_complete = False
with open(intput_file, 'r') as fp:
for line in fp.readlines():
if re.search("GCOV_COVERAGE_DUMP_START", line):
capture_data = True
continue
if re.search("GCOV_COVERAGE_DUMP_END", line):
capture_complete = True
break
# Loop until the coverage data is found.
if not capture_data:
continue
if line.startswith("*"):
sp = line.split("<")
if len(sp) > 1:
# Remove the leading delimiter "*"
file_name = sp[0][1:]
# Remove the trailing new line char
hex_dump = sp[1][:-1]
else:
continue
else:
continue
extracted_coverage_info.update({file_name:hex_dump})
if not capture_data:
capture_complete = True
return {'complete': capture_complete, 'data': extracted_coverage_info}
def create_gcda_files(extracted_coverage_info):
if VERBOSE:
print("Generating gcda files")
for filename, hexdump_val in extracted_coverage_info.items():
# if kobject_hash is given for coverage gcovr fails
# hence skipping it problem only in gcovr v4.1
if "kobject_hash" in filename:
filename = (filename[:-4]) +"gcno"
try:
os.remove(filename)
except Exception:
pass
continue
with open(filename, 'wb') as fp:
fp.write(bytes.fromhex(hexdump_val))
def generate_coverage(outdir, ignores):
for filename in glob.glob("%s/**/handler.log" %outdir, recursive=True):
gcov_data = retrieve_gcov_data(filename)
capture_complete = gcov_data['complete']
extracted_coverage_info = gcov_data['data']
if capture_complete:
create_gcda_files(extracted_coverage_info)
verbose("Gcov data captured: {}".format(filename))
else:
error("Gcov data capture incomplete: {}".format(filename))
gcov_tool = options.gcov_tool
with open(os.path.join(outdir, "coverage.log"), "a") as coveragelog:
coveragefile = os.path.join(outdir, "coverage.info")
ztestfile = os.path.join(outdir, "ztest.info")
subprocess.call(["lcov", "--gcov-tool", gcov_tool,
"--capture", "--directory", outdir,
"--rc", "lcov_branch_coverage=1",
"--output-file", coveragefile], stdout=coveragelog)
# We want to remove tests/* and tests/ztest/test/* but save tests/ztest
subprocess.call(["lcov", "--gcov-tool", gcov_tool, "--extract", coveragefile,
os.path.join(ZEPHYR_BASE, "tests", "ztest", "*"),
"--output-file", ztestfile,
"--rc", "lcov_branch_coverage=1"], stdout=coveragelog)
if os.path.exists(ztestfile) and os.path.getsize(ztestfile) > 0:
subprocess.call(["lcov", "--gcov-tool", gcov_tool, "--remove", ztestfile,
os.path.join(ZEPHYR_BASE, "tests/ztest/test/*"),
"--output-file", ztestfile,
"--rc", "lcov_branch_coverage=1"],
stdout=coveragelog)
files = [coveragefile, ztestfile]
else:
files = [coveragefile]
for i in ignores:
subprocess.call(
["lcov", "--gcov-tool", gcov_tool, "--remove",
coveragefile, i, "--output-file",
coveragefile, "--rc", "lcov_branch_coverage=1"],
stdout=coveragelog)
#The --ignore-errors source option is added to avoid it exiting due to
#samples/application_development/external_lib/
ret = subprocess.call(["genhtml", "--legend", "--branch-coverage",
"--ignore-errors", "source",
"-output-directory",
os.path.join(outdir, "coverage")] + files,
stdout=coveragelog)
if ret==0:
info("HTML report generated: %s"%
os.path.join(outdir, "coverage","index.html"))
def get_generator():
if options.ninja:
generator_cmd = "ninja"
generator = "Ninja"
else:
generator_cmd = "make"
generator = "Unix Makefiles"
return generator_cmd, generator
def export_tests(filename, tests):
with open(filename, "wt") as csvfile:
fieldnames = ['section', 'subsection', 'title', 'reference']
cw = csv.DictWriter(csvfile, fieldnames, lineterminator=os.linesep)
for test in tests:
data = test.split(".")
if len(data) > 1:
subsec = " ".join(data[1].split("_")).title()
rowdict = {
"section": data[0].capitalize(),
"subsection": subsec,
"title": test,
"reference": test
}
cw.writerow(rowdict)
else:
info("{} can't be exported".format(test))
def native_and_unit_first(a, b):
if a[0].startswith('unit_testing'):
return -1
if b[0].startswith('unit_testing'):
return 1
if a[0].startswith('native_posix'):
return -1
if b[0].startswith('native_posix'):
return 1
if a[0].split("/",1)[0].endswith("_bsim"):
return -1
if b[0].split("/",1)[0].endswith("_bsim"):
return 1
return (a > b) - (a < b)
run_individual_tests = None
options = None
def main():
start_time = time.time()
global VERBOSE, log_file
global options
global run_individual_tests
options = parse_arguments()
if options.generate_hardware_map:
from serial.tools import list_ports
serial_devices = list_ports.comports()
filtered = []
for d in serial_devices:
if d.manufacturer in ['ARM', 'SEGGER', 'MBED', 'STMicroelectronics',
'Atmel Corp.', 'Texas Instruments',
'Silicon Labs', 'NXP Semiconductors']:
# TI XDS110 can have multiple serial devices for a single board
# assume endpoint 0 is the serial, skip all others
if d.manufacturer == 'Texas Instruments' and not d.location.endswith('0'):
continue
s_dev = {}
s_dev['platform'] = "unknown"
s_dev['id'] = d.serial_number
s_dev['serial'] = d.device
s_dev['product'] = d.product
if s_dev['product'] in ['DAPLink CMSIS-DAP', 'MBED CMSIS-DAP']:
s_dev['runner'] = "pyocd"
elif s_dev['product'] in ['J-Link', 'J-Link OB']:
s_dev['runner'] = "jlink"
elif s_dev['product'] in ['STM32 STLink']:
s_dev['runner'] = "openocd"
elif s_dev['product'].startswith('XDS110'):
s_dev['runner'] = "openocd"
else:
s_dev['runner'] = "unknown"
s_dev['available'] = True
s_dev['connected'] = True
filtered.append(s_dev)
else:
print("Unsupported device (%s): %s" %(d.manufacturer, d))
if os.path.exists(options.generate_hardware_map):
# use existing map
with open(options.generate_hardware_map, 'r') as yaml_file:
hwm = yaml.load(yaml_file, Loader=yaml.FullLoader)
# disconnect everything
for h in hwm:
h['connected'] = False
h['serial'] = None
for d in filtered:
for h in hwm:
if d['id'] == h['id'] and d['product'] == h['product']:
print("Already in map: %s (%s)" %(d['product'], d['id']))
h['connected'] = True
h['serial'] = d['serial']
d['match'] = True
new = list(filter(lambda n: not n.get('match', False), filtered))
hwm = hwm + new
#import pprint
#pprint.pprint(hwm)
with open(options.generate_hardware_map, 'w') as yaml_file:
yaml.dump(hwm, yaml_file, default_flow_style=False)
else:
# create new file
with open(options.generate_hardware_map, 'w') as yaml_file:
yaml.dump(filtered, yaml_file, default_flow_style=False)
return
if options.west_runner and not options.west_flash:
error("west-runner requires west-flash to be enabled")
sys.exit(1)
if options.west_flash and not options.device_testing:
error("west-flash requires device-testing to be enabled")
sys.exit(1)
if options.coverage:
options.enable_coverage = True
if not options.coverage_platform:
options.coverage_platform = options.platform
if options.size:
for fn in options.size:
size_report(SizeCalculator(fn, []))
sys.exit(0)
VERBOSE += options.verbose
if options.log_file:
log_file = open(options.log_file, "w")
if options.subset:
subset, sets = options.subset.split("/")
if int(subset) > 0 and int(sets) >= int(subset):
info("Running only a subset: %s/%s" % (subset, sets))
else:
error("You have provided a wrong subset value: %s." % options.subset)
return
# Cleanup
if options.no_clean or options.only_failed or options.test_only:
if os.path.exists(options.outdir):
info("Keeping artifacts untouched")
elif os.path.exists(options.outdir):
for i in range(1,100):
new_out = options.outdir + ".{}".format(i)
if not os.path.exists(new_out):
info("Renaming output directory to {}".format(new_out))
shutil.move(options.outdir, new_out)
break
#shutil.rmtree("%s.old" %options.outdir)
if not options.testcase_root:
options.testcase_root = [os.path.join(ZEPHYR_BASE, "tests"),
os.path.join(ZEPHYR_BASE, "samples")]
suite = TestSuite(options.board_root, options.testcase_root, options.outdir)
suite.add_testcases()
suite.add_configurations()
if options.device_testing:
if options.hardware_map:
suite.load_hardware_map(options.hardware_map)
if not options.platform:
options.platform = []
for platform in suite.connected_hardware:
if platform['connected']:
options.platform.append(platform['platform'])
elif options.device_serial: #back-ward compatibility
if options.platform and len(options.platform) == 1:
suite.load_hardware_map_from_cmdline(options.device_serial,
options.platform[0])
else:
error("""When --device-testing is used with --device-serial, only one
platform is allowed""")
if suite.load_errors:
sys.exit(1)
if options.list_tags:
tags = set()
for _, tc in suite.testcases.items():
tags = tags.union(tc.tags)
for t in tags:
print("- {}".format(t))
return
if options.export_tests:
cnt = 0
tests = suite.get_all_tests()
export_tests(options.export_tests, tests)
return
run_individual_tests = []
if options.test:
run_individual_tests = options.test
if options.list_tests or options.list_test_duplicates or options.sub_test:
cnt = 0
all_tests = suite.get_all_tests()
if options.list_test_duplicates:
import collections
dupes = [item for item, count in collections.Counter(all_tests).items() if count > 1]
if dupes:
print("Tests with duplicate identifiers:")
for dupe in dupes:
print("- {}".format(dupe))
for dc in suite.get_testcase(dupe):
print(" - {}".format(dc))
else:
print("No duplicates found.")
return
if options.sub_test:
for st in options.sub_test:
subtests = suite.get_testcase(st)
for sti in subtests:
run_individual_tests.append(sti.name)
if run_individual_tests:
info("Running the following tests:")
for test in run_individual_tests:
print(" - {}".format(test))
else:
info("Tests not found")
return
elif options.list_tests:
for test in all_tests:
cnt = cnt + 1
print(" - {}".format(test))
print("{} total.".format(cnt))
return
discards = []
if options.only_failed:
suite.get_last_failed()
elif options.load_tests:
suite.load_from_file(options.load_tests)
elif options.test_only:
last_run = os.path.join(options.outdir, "sanitycheck.csv")
suite.load_from_file(last_run)
else:
discards = suite.apply_filters()
if VERBOSE > 1 and discards:
# if we are using command line platform filter, no need to list every
# other platform as excluded, we know that already.
# Show only the discards that apply to the selected platforms on the
# command line
for i, reason in discards.items():
if options.platform and i.platform.name not in options.platform:
continue
debug(
"{:<25} {:<50} {}SKIPPED{}: {}".format(
i.platform.name,
i.testcase.name,
COLOR_YELLOW,
COLOR_NORMAL,
reason))
if options.report_excluded:
all_tests = suite.get_all_tests()
to_be_run = set()
for i,p in suite.instances.items():
to_be_run.update(p.testcase.cases)
if all_tests - to_be_run:
print("Tests that never build or run:")
for not_run in all_tests - to_be_run:
print("- {}".format(not_run))
return
if options.subset:
#suite.instances = OrderedDict(sorted(suite.instances.items(),
# key=cmp_to_key(native_and_unit_first)))
subset, sets = options.subset.split("/")
total = len(suite.instances)
per_set = round(total / int(sets))
start = (int(subset) - 1) * per_set
if subset == sets:
end = total
else:
end = start + per_set
sliced_instances = islice(suite.instances.items(), start, end)
suite.instances = OrderedDict(sliced_instances)
if options.save_tests:
suite.csv_report(options.save_tests)
return
info("%d test configurations selected, %d configurations discarded due to filters." %
(len(suite.instances), len(discards)))
if options.device_testing:
print("\nDevice testing on:")
for p in suite.connected_hardware:
if p['connected']:
print("%s (%s) on %s" %(p['platform'], p.get('id', None), p['serial']))
if options.dry_run:
duration = time.time() - start_time
info("Completed in %d seconds" % (duration))
return
retries = options.retry_failed + 1
completed = 0
suite.update()
suite.start_time = start_time
while True:
completed += 1
if completed > 1:
info("%d Iteration:" %(completed ))
time.sleep(60) # waiting for the system to settle down
suite.total_done = suite.total_tests - suite.total_failed
suite.total_failed = 0
suite.execute()
info("", False)
retries = retries - 1
if retries == 0 or suite.total_failed == 0:
break
suite.misc_reports(options.compare_report, options.show_footprint,
options.all_deltas, options.footprint_threshold, options.last_metrics)
suite.duration = time.time() - start_time
suite.summary(options.disable_unrecognized_section_test)
if options.coverage:
if options.gcov_tool is None:
use_system_gcov = False
for plat in options.coverage_platform:
ts_plat = suite.get_platform(plat)
if ts_plat and (ts_plat.type in {"native", "unit"}):
use_system_gcov = True
if use_system_gcov or "ZEPHYR_SDK_INSTALL_DIR" not in os.environ:
options.gcov_tool = "gcov"
else:
options.gcov_tool = os.path.join(os.environ["ZEPHYR_SDK_INSTALL_DIR"],
"i586-zephyr-elf/bin/i586-zephyr-elf-gcov")
info("Generating coverage files...")
generate_coverage(options.outdir, ["*generated*", "tests/*", "samples/*"])
if options.device_testing:
print("\nHardware distribution summary:\n")
for p in suite.connected_hardware:
if p['connected']:
print("%s (%s): %d" %(p['platform'], p.get('id', None), p['counter']))
suite.save_reports()
if suite.total_failed or (suite.warnings and options.warnings_as_errors):
sys.exit(1)
if __name__ == "__main__":
main()