erkin yucel
mbed os with nrf51 internal bandgap enabled to read battery level
Dependents: BLE_file_test BLE_Blink ExternalEncoder
tools/toolchains/__init__.py
- Committer:
- elessair
- Date:
- 2016-10-23
- Revision:
- 0:f269e3021894
File content as of revision 0:f269e3021894:
"""
mbed SDK
Copyright (c) 2011-2013 ARM Limited
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
"""
import re
import sys
from os import stat, walk, getcwd, sep, remove
from copy import copy
from time import time, sleep
from types import ListType
from shutil import copyfile
from os.path import join, splitext, exists, relpath, dirname, basename, split, abspath, isfile, isdir
from inspect import getmro
from copy import deepcopy
from tools.config import Config
from abc import ABCMeta, abstractmethod
from distutils.spawn import find_executable
from multiprocessing import Pool, cpu_count
from tools.utils import run_cmd, mkdir, rel_path, ToolException, NotSupportedException, split_path, compile_worker
from tools.settings import MBED_ORG_USER
import tools.hooks as hooks
from tools.memap import MemapParser
from hashlib import md5
import fnmatch
#Disables multiprocessing if set to higher number than the host machine CPUs
CPU_COUNT_MIN = 1
CPU_COEF = 1
class Resources:
def __init__(self, base_path=None):
self.base_path = base_path
self.file_basepath = {}
self.inc_dirs = []
self.headers = []
self.s_sources = []
self.c_sources = []
self.cpp_sources = []
self.lib_dirs = set([])
self.objects = []
self.libraries = []
# mbed special files
self.lib_builds = []
self.lib_refs = []
self.repo_dirs = []
self.repo_files = []
self.linker_script = None
# Other files
self.hex_files = []
self.bin_files = []
self.json_files = []
# Features
self.features = {}
def __add__(self, resources):
if resources is None:
return self
else:
return self.add(resources)
def __radd__(self, resources):
if resources is None:
return self
else:
return self.add(resources)
def add(self, resources):
for f,p in resources.file_basepath.items():
self.file_basepath[f] = p
self.inc_dirs += resources.inc_dirs
self.headers += resources.headers
self.s_sources += resources.s_sources
self.c_sources += resources.c_sources
self.cpp_sources += resources.cpp_sources
self.lib_dirs |= resources.lib_dirs
self.objects += resources.objects
self.libraries += resources.libraries
self.lib_builds += resources.lib_builds
self.lib_refs += resources.lib_refs
self.repo_dirs += resources.repo_dirs
self.repo_files += resources.repo_files
if resources.linker_script is not None:
self.linker_script = resources.linker_script
self.hex_files += resources.hex_files
self.bin_files += resources.bin_files
self.json_files += resources.json_files
self.features.update(resources.features)
return self
def _collect_duplicates(self, dupe_dict, dupe_headers):
for filename in self.s_sources + self.c_sources + self.cpp_sources:
objname, _ = splitext(basename(filename))
dupe_dict.setdefault(objname, set())
dupe_dict[objname] |= set([filename])
for filename in self.headers:
headername = basename(filename)
dupe_headers.setdefault(headername, set())
dupe_headers[headername] |= set([headername])
for res in self.features.values():
res._collect_duplicates(dupe_dict, dupe_headers)
return dupe_dict, dupe_headers
def detect_duplicates(self, toolchain):
"""Detect all potential ambiguities in filenames and report them with
a toolchain notification
Positional Arguments:
toolchain - used for notifications
"""
count = 0
dupe_dict, dupe_headers = self._collect_duplicates(dict(), dict())
for objname, filenames in dupe_dict.iteritems():
if len(filenames) > 1:
count+=1
toolchain.tool_error(
"Object file %s.o is not unique! It could be made from: %s"\
% (objname, " ".join(filenames)))
for headername, locations in dupe_headers.iteritems():
if len(locations) > 1:
count+=1
toolchain.tool_error(
"Header file %s is not unique! It could be: %s" %\
(headername, " ".join(locations)))
return count
def relative_to(self, base, dot=False):
for field in ['inc_dirs', 'headers', 's_sources', 'c_sources',
'cpp_sources', 'lib_dirs', 'objects', 'libraries',
'lib_builds', 'lib_refs', 'repo_dirs', 'repo_files',
'hex_files', 'bin_files', 'json_files']:
v = [rel_path(f, base, dot) for f in getattr(self, field)]
setattr(self, field, v)
self.features = {k: f.relative_to(base, dot) for k, f in self.features.iteritems() if f}
if self.linker_script is not None:
self.linker_script = rel_path(self.linker_script, base, dot)
def win_to_unix(self):
for field in ['inc_dirs', 'headers', 's_sources', 'c_sources',
'cpp_sources', 'lib_dirs', 'objects', 'libraries',
'lib_builds', 'lib_refs', 'repo_dirs', 'repo_files',
'hex_files', 'bin_files', 'json_files']:
v = [f.replace('\\', '/') for f in getattr(self, field)]
setattr(self, field, v)
self.features = {k: f.win_to_unix() for k, f in self.features.iteritems() if f}
if self.linker_script is not None:
self.linker_script = self.linker_script.replace('\\', '/')
def __str__(self):
s = []
for (label, resources) in (
('Include Directories', self.inc_dirs),
('Headers', self.headers),
('Assembly sources', self.s_sources),
('C sources', self.c_sources),
('C++ sources', self.cpp_sources),
('Library directories', self.lib_dirs),
('Objects', self.objects),
('Libraries', self.libraries),
('Hex files', self.hex_files),
('Bin files', self.bin_files),
('Features', self.features),
):
if resources:
s.append('%s:\n ' % label + '\n '.join(resources))
if self.linker_script:
s.append('Linker Script: ' + self.linker_script)
return '\n'.join(s)
# Support legacy build conventions: the original mbed build system did not have
# standard labels for the "TARGET_" and "TOOLCHAIN_" specific directories, but
# had the knowledge of a list of these directories to be ignored.
LEGACY_IGNORE_DIRS = set([
'LPC11U24', 'LPC1768', 'LPC2368', 'LPC4088', 'LPC812', 'KL25Z',
'ARM', 'uARM', 'IAR',
'GCC_ARM', 'GCC_CS', 'GCC_CR', 'GCC_CW', 'GCC_CW_EWL', 'GCC_CW_NEWLIB',
])
LEGACY_TOOLCHAIN_NAMES = {
'ARM_STD':'ARM', 'ARM_MICRO': 'uARM',
'GCC_ARM': 'GCC_ARM', 'GCC_CR': 'GCC_CR',
'IAR': 'IAR',
}
class mbedToolchain:
# Verbose logging
VERBOSE = True
# Compile C files as CPP
COMPILE_C_AS_CPP = False
# Response files for compiling, includes, linking and archiving.
# Not needed on posix systems where the typical arg limit is 2 megabytes
RESPONSE_FILES = True
CORTEX_SYMBOLS = {
"Cortex-M0" : ["__CORTEX_M0", "ARM_MATH_CM0", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M0+": ["__CORTEX_M0PLUS", "ARM_MATH_CM0PLUS", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M1" : ["__CORTEX_M3", "ARM_MATH_CM1", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M3" : ["__CORTEX_M3", "ARM_MATH_CM3", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M4" : ["__CORTEX_M4", "ARM_MATH_CM4", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M4F" : ["__CORTEX_M4", "ARM_MATH_CM4", "__FPU_PRESENT=1", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M7" : ["__CORTEX_M7", "ARM_MATH_CM7", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M7F" : ["__CORTEX_M7", "ARM_MATH_CM7", "__FPU_PRESENT=1", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-M7FD" : ["__CORTEX_M7", "ARM_MATH_CM7", "__FPU_PRESENT=1", "__CMSIS_RTOS", "__MBED_CMSIS_RTOS_CM"],
"Cortex-A9" : ["__CORTEX_A9", "ARM_MATH_CA9", "__FPU_PRESENT", "__CMSIS_RTOS", "__EVAL", "__MBED_CMSIS_RTOS_CA9"],
}
MBED_CONFIG_FILE_NAME="mbed_config.h"
__metaclass__ = ABCMeta
profile_template = {'common':[], 'c':[], 'cxx':[], 'asm':[], 'ld':[]}
def __init__(self, target, notify=None, macros=None, silent=False, extra_verbose=False, build_profile=None):
self.target = target
self.name = self.__class__.__name__
# compile/assemble/link/binary hooks
self.hook = hooks.Hook(target, self)
# Toolchain flags
self.flags = deepcopy(build_profile or self.profile_template)
# User-defined macros
self.macros = macros or []
# Macros generated from toolchain and target rules/features
self.asm_symbols = None
self.cxx_symbols = None
# Labels generated from toolchain and target rules/features (used for selective build)
self.labels = None
# This will hold the initialized config object
self.config = None
# This will hold the configuration data (as returned by Config.get_config_data())
self.config_data = None
# This will hold the location of the configuration file or None if there's no configuration available
self.config_file = None
# Call guard for "get_config_data" (see the comments of get_config_data for details)
self.config_processed = False
# Non-incremental compile
self.build_all = False
# Build output dir
self.build_dir = None
self.timestamp = time()
# Output build naming based on target+toolchain combo (mbed 2.0 builds)
self.obj_path = join("TARGET_"+target.name, "TOOLCHAIN_"+self.name)
# Number of concurrent build jobs. 0 means auto (based on host system cores)
self.jobs = 0
# Ignore patterns from .mbedignore files
self.ignore_patterns = []
# Pre-mbed 2.0 ignore dirs
self.legacy_ignore_dirs = (LEGACY_IGNORE_DIRS | TOOLCHAINS) - set([target.name, LEGACY_TOOLCHAIN_NAMES[self.name]])
# Output notify function
# This function is passed all events, and expected to handle notification of the
# user, emit the events to a log, etc.
# The API for all notify methods passed into the notify parameter is as follows:
# def notify(Event, Silent)
# Where *Event* is a dict representing the toolchain event that was generated
# e.g.: a compile succeeded, or a warning was emitted by the compiler
# or an application was linked
# *Silent* is a boolean
if notify:
self.notify_fun = notify
elif extra_verbose:
self.notify_fun = self.print_notify_verbose
else:
self.notify_fun = self.print_notify
# Silent builds (no output)
self.silent = silent
# Print output buffer
self.output = str()
self.map_outputs = list() # Place to store memmap scan results in JSON like data structures
# uVisor spepcific rules
if 'UVISOR' in self.target.features and 'UVISOR_SUPPORTED' in self.target.extra_labels:
self.target.core = re.sub(r"F$", '', self.target.core)
# Stats cache is used to reduce the amount of IO requests to stat
# header files during dependency change. See need_update()
self.stat_cache = {}
# Used by the mbed Online Build System to build in chrooted environment
self.CHROOT = None
# Call post __init__() hooks before the ARM/GCC_ARM/IAR toolchain __init__() takes over
self.init()
# Used for post __init__() hooks
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def init(self):
return True
def get_output(self):
return self.output
def print_notify(self, event, silent=False):
""" Default command line notification
"""
msg = None
if not self.VERBOSE and event['type'] == 'tool_error':
msg = event['message']
elif event['type'] in ['info', 'debug']:
msg = event['message']
elif event['type'] == 'cc':
event['severity'] = event['severity'].title()
event['file'] = basename(event['file'])
msg = '[%(severity)s] %(file)s@%(line)s,%(col)s: %(message)s' % event
elif event['type'] == 'progress':
if 'percent' in event:
msg = '{} [{:>5.1f}%]: {}'.format(event['action'].title(),
event['percent'],
basename(event['file']))
else:
msg = '{}: {}'.format(event['action'].title(),
basename(event['file']))
if msg:
if not silent:
print msg
self.output += msg + "\n"
def print_notify_verbose(self, event, silent=False):
""" Default command line notification with more verbose mode
"""
if event['type'] in ['info', 'debug']:
self.print_notify(event, silent=silent) # standard handle
elif event['type'] == 'cc':
event['severity'] = event['severity'].title()
event['file'] = basename(event['file'])
event['mcu_name'] = "None"
event['target_name'] = event['target_name'].upper() if event['target_name'] else "Unknown"
event['toolchain_name'] = event['toolchain_name'].upper() if event['toolchain_name'] else "Unknown"
msg = '[%(severity)s] %(target_name)s::%(toolchain_name)s::%(file)s@%(line)s: %(message)s' % event
if not silent:
print msg
self.output += msg + "\n"
elif event['type'] == 'progress':
self.print_notify(event) # standard handle
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def notify(self, event):
""" Little closure for notify functions
"""
event['toolchain'] = self
return self.notify_fun(event, self.silent)
def get_symbols(self, for_asm=False):
if for_asm:
if self.asm_symbols is None:
self.asm_symbols = []
# Cortex CPU symbols
if self.target.core in mbedToolchain.CORTEX_SYMBOLS:
self.asm_symbols.extend(mbedToolchain.CORTEX_SYMBOLS[self.target.core])
# Add target's symbols
self.asm_symbols += self.target.macros
# Add extra symbols passed via 'macros' parameter
self.asm_symbols += self.macros
return list(set(self.asm_symbols)) # Return only unique symbols
else:
if self.cxx_symbols is None:
# Target and Toolchain symbols
labels = self.get_labels()
self.cxx_symbols = ["TARGET_%s" % t for t in labels['TARGET']]
self.cxx_symbols.extend(["TOOLCHAIN_%s" % t for t in labels['TOOLCHAIN']])
# Cortex CPU symbols
if self.target.core in mbedToolchain.CORTEX_SYMBOLS:
self.cxx_symbols.extend(mbedToolchain.CORTEX_SYMBOLS[self.target.core])
# Symbols defined by the on-line build.system
self.cxx_symbols.extend(['MBED_BUILD_TIMESTAMP=%s' % self.timestamp, 'TARGET_LIKE_MBED', '__MBED__=1'])
if MBED_ORG_USER:
self.cxx_symbols.append('MBED_USERNAME=' + MBED_ORG_USER)
# Add target's symbols
self.cxx_symbols += self.target.macros
# Add target's hardware
self.cxx_symbols += ["DEVICE_" + data + "=1" for data in self.target.device_has]
# Add target's features
self.cxx_symbols += ["FEATURE_" + data + "=1" for data in self.target.features]
# Add extra symbols passed via 'macros' parameter
self.cxx_symbols += self.macros
# Form factor variables
if hasattr(self.target, 'supported_form_factors'):
self.cxx_symbols.extend(["TARGET_FF_%s" % t for t in self.target.supported_form_factors])
return list(set(self.cxx_symbols)) # Return only unique symbols
# Extend the internal list of macros
def add_macros(self, new_macros):
self.macros.extend(new_macros)
def get_labels(self):
if self.labels is None:
toolchain_labels = [c.__name__ for c in getmro(self.__class__)]
toolchain_labels.remove('mbedToolchain')
self.labels = {
'TARGET': self.target.labels,
'FEATURE': self.target.features,
'TOOLCHAIN': toolchain_labels
}
# This is a policy decision and it should /really/ be in the config system
# ATM it's here for backward compatibility
if (("-g" in self.flags['common'] and
"-O0") in self.flags['common'] or
("-r" in self.flags['common'] and
"-On" in self.flags['common'])):
self.labels['TARGET'].append("DEBUG")
else:
self.labels['TARGET'].append("RELEASE")
return self.labels
# Determine whether a source file needs updating/compiling
def need_update(self, target, dependencies):
if self.build_all:
return True
if not exists(target):
return True
target_mod_time = stat(target).st_mtime
for d in dependencies:
# Some objects are not provided with full path and here we do not have
# information about the library paths. Safe option: assume an update
if not d or not exists(d):
return True
if not self.stat_cache.has_key(d):
self.stat_cache[d] = stat(d).st_mtime
if self.stat_cache[d] >= target_mod_time:
return True
return False
def is_ignored(self, file_path):
for pattern in self.ignore_patterns:
if fnmatch.fnmatch(file_path, pattern):
return True
return False
# Create a Resources object from the path pointed to by *path* by either traversing a
# a directory structure, when *path* is a directory, or adding *path* to the resources,
# when *path* is a file.
# The parameter *base_path* is used to set the base_path attribute of the Resources
# object and the parameter *exclude_paths* is used by the directory traversal to
# exclude certain paths from the traversal.
def scan_resources(self, path, exclude_paths=None, base_path=None):
self.progress("scan", path)
resources = Resources(path)
if not base_path:
if isfile(path):
base_path = dirname(path)
else:
base_path = path
resources.base_path = base_path
if isfile(path):
self._add_file(path, resources, base_path, exclude_paths=exclude_paths)
else:
self._add_dir(path, resources, base_path, exclude_paths=exclude_paths)
return resources
# A helper function for scan_resources. _add_dir traverses *path* (assumed to be a
# directory) and heeds the ".mbedignore" files along the way. _add_dir calls _add_file
# on every file it considers adding to the resources object.
def _add_dir(self, path, resources, base_path, exclude_paths=None):
""" os.walk(top[, topdown=True[, onerror=None[, followlinks=False]]])
When topdown is True, the caller can modify the dirnames list in-place
(perhaps using del or slice assignment), and walk() will only recurse into
the subdirectories whose names remain in dirnames; this can be used to prune
the search, impose a specific order of visiting, or even to inform walk()
about directories the caller creates or renames before it resumes walk()
again. Modifying dirnames when topdown is False is ineffective, because in
bottom-up mode the directories in dirnames are generated before dirpath
itself is generated.
"""
labels = self.get_labels()
for root, dirs, files in walk(path, followlinks=True):
# Check if folder contains .mbedignore
if ".mbedignore" in files:
with open (join(root,".mbedignore"), "r") as f:
lines=f.readlines()
lines = [l.strip() for l in lines] # Strip whitespaces
lines = [l for l in lines if l != ""] # Strip empty lines
lines = [l for l in lines if not re.match("^#",l)] # Strip comment lines
# Append root path to glob patterns and append patterns to ignore_patterns
self.ignore_patterns.extend([join(root,line.strip()) for line in lines])
# Skip the whole folder if ignored, e.g. .mbedignore containing '*'
if self.is_ignored(join(root,"")):
continue
for d in copy(dirs):
dir_path = join(root, d)
# Add internal repo folders/files. This is needed for exporters
if d == '.hg' or d == '.git':
resources.repo_dirs.append(dir_path)
if ((d.startswith('.') or d in self.legacy_ignore_dirs) or
# Ignore targets that do not match the TARGET in extra_labels list
(d.startswith('TARGET_') and d[7:] not in labels['TARGET']) or
# Ignore toolchain that do not match the current TOOLCHAIN
(d.startswith('TOOLCHAIN_') and d[10:] not in labels['TOOLCHAIN']) or
# Ignore .mbedignore files
self.is_ignored(join(dir_path,"")) or
# Ignore TESTS dir
(d == 'TESTS')):
dirs.remove(d)
elif d.startswith('FEATURE_'):
# Recursively scan features but ignore them in the current scan.
# These are dynamically added by the config system if the conditions are matched
resources.features[d[8:]] = self.scan_resources(dir_path, base_path=base_path)
dirs.remove(d)
elif exclude_paths:
for exclude_path in exclude_paths:
rel_path = relpath(dir_path, exclude_path)
if not (rel_path.startswith('..')):
dirs.remove(d)
break
# Add root to include paths
resources.inc_dirs.append(root)
resources.file_basepath[root] = base_path
for file in files:
file_path = join(root, file)
self._add_file(file_path, resources, base_path)
# A helper function for both scan_resources and _add_dir. _add_file adds one file
# (*file_path*) to the resources object based on the file type.
def _add_file(self, file_path, resources, base_path, exclude_paths=None):
resources.file_basepath[file_path] = base_path
if self.is_ignored(file_path):
return
_, ext = splitext(file_path)
ext = ext.lower()
if ext == '.s':
resources.s_sources.append(file_path)
elif ext == '.c':
resources.c_sources.append(file_path)
elif ext == '.cpp':
resources.cpp_sources.append(file_path)
elif ext == '.h' or ext == '.hpp':
resources.headers.append(file_path)
elif ext == '.o':
resources.objects.append(file_path)
elif ext == self.LIBRARY_EXT:
resources.libraries.append(file_path)
resources.lib_dirs.add(dirname(file_path))
elif ext == self.LINKER_EXT:
if resources.linker_script is not None:
self.info("Warning: Multiple linker scripts detected: %s -> %s" % (resources.linker_script, file_path))
resources.linker_script = file_path
elif ext == '.lib':
resources.lib_refs.append(file_path)
elif ext == '.bld':
resources.lib_builds.append(file_path)
elif basename(file_path) == '.hgignore':
resources.repo_files.append(file_path)
elif basename(file_path) == '.gitignore':
resources.repo_files.append(file_path)
elif ext == '.hex':
resources.hex_files.append(file_path)
elif ext == '.bin':
resources.bin_files.append(file_path)
elif ext == '.json':
resources.json_files.append(file_path)
def scan_repository(self, path):
resources = []
for root, dirs, files in walk(path):
# Remove ignored directories
for d in copy(dirs):
if d == '.' or d == '..':
dirs.remove(d)
for file in files:
file_path = join(root, file)
resources.append(file_path)
return resources
def copy_files(self, files_paths, trg_path, resources=None, rel_path=None):
# Handle a single file
if type(files_paths) != ListType: files_paths = [files_paths]
for source in files_paths:
if source is None:
files_paths.remove(source)
for source in files_paths:
if resources is not None and resources.file_basepath.has_key(source):
relative_path = relpath(source, resources.file_basepath[source])
elif rel_path is not None:
relative_path = relpath(source, rel_path)
else:
_, relative_path = split(source)
target = join(trg_path, relative_path)
if (target != source) and (self.need_update(target, [source])):
self.progress("copy", relative_path)
mkdir(dirname(target))
copyfile(source, target)
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def relative_object_path(self, build_path, base_dir, source):
source_dir, name, _ = split_path(source)
obj_dir = join(build_path, relpath(source_dir, base_dir))
if obj_dir is not self.prev_dir:
self.prev_dir = obj_dir
mkdir(obj_dir)
return join(obj_dir, name + '.o')
# Generate response file for all includes.
# ARM, GCC, IAR cross compatible
def get_inc_file(self, includes):
include_file = join(self.build_dir, ".includes_%s.txt" % self.inc_md5)
if not exists(include_file):
with open(include_file, "wb") as f:
cmd_list = []
for c in includes:
if c:
c = c.replace("\\", "/")
if self.CHROOT:
c = c.replace(self.CHROOT, '')
cmd_list.append('-I%s' % c)
string = " ".join(cmd_list)
f.write(string)
return include_file
# Generate response file for all objects when linking.
# ARM, GCC, IAR cross compatible
def get_link_file(self, cmd):
link_file = join(self.build_dir, ".link_files.txt")
with open(link_file, "wb") as f:
cmd_list = []
for c in cmd:
if c:
c = c.replace("\\", "/")
if self.CHROOT:
c = c.replace(self.CHROOT, '')
cmd_list.append(('"%s"' % c) if not c.startswith('-') else c)
string = " ".join(cmd_list)
f.write(string)
return link_file
# Generate response file for all objects when archiving.
# ARM, GCC, IAR cross compatible
def get_arch_file(self, objects):
archive_file = join(self.build_dir, ".archive_files.txt")
with open(archive_file, "wb") as f:
o_list = []
for o in objects:
o_list.append('"%s"' % o)
string = " ".join(o_list).replace("\\", "/")
f.write(string)
return archive_file
# THIS METHOD IS BEING CALLED BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def compile_sources(self, resources, build_path, inc_dirs=None):
# Web IDE progress bar for project build
files_to_compile = resources.s_sources + resources.c_sources + resources.cpp_sources
self.to_be_compiled = len(files_to_compile)
self.compiled = 0
self.cc_verbose("Macros: "+' '.join(['-D%s' % s for s in self.get_symbols()]))
inc_paths = resources.inc_dirs
if inc_dirs is not None:
inc_paths.extend(inc_dirs)
# De-duplicate include paths
inc_paths = set(inc_paths)
# Sort include paths for consistency
inc_paths = sorted(set(inc_paths))
# Unique id of all include paths
self.inc_md5 = md5(' '.join(inc_paths)).hexdigest()
# Where to store response files
self.build_dir = build_path
objects = []
queue = []
work_dir = getcwd()
self.prev_dir = None
# Generate configuration header (this will update self.build_all if needed)
self.get_config_header()
# Sort compile queue for consistency
files_to_compile.sort()
for source in files_to_compile:
object = self.relative_object_path(build_path, resources.file_basepath[source], source)
# Queue mode (multiprocessing)
commands = self.compile_command(source, object, inc_paths)
if commands is not None:
queue.append({
'source': source,
'object': object,
'commands': commands,
'work_dir': work_dir,
'chroot': self.CHROOT
})
else:
self.compiled += 1
objects.append(object)
# Use queues/multiprocessing if cpu count is higher than setting
jobs = self.jobs if self.jobs else cpu_count()
if jobs > CPU_COUNT_MIN and len(queue) > jobs:
return self.compile_queue(queue, objects)
else:
return self.compile_seq(queue, objects)
# Compile source files queue in sequential order
def compile_seq(self, queue, objects):
for item in queue:
result = compile_worker(item)
self.compiled += 1
self.progress("compile", item['source'], build_update=True)
for res in result['results']:
self.cc_verbose("Compile: %s" % ' '.join(res['command']), result['source'])
self.compile_output([
res['code'],
res['output'],
res['command']
])
objects.append(result['object'])
return objects
# Compile source files queue in parallel by creating pool of worker threads
def compile_queue(self, queue, objects):
jobs_count = int(self.jobs if self.jobs else cpu_count() * CPU_COEF)
p = Pool(processes=jobs_count)
results = []
for i in range(len(queue)):
results.append(p.apply_async(compile_worker, [queue[i]]))
p.close()
itr = 0
while len(results):
itr += 1
if itr > 180000:
p.terminate()
p.join()
raise ToolException("Compile did not finish in 5 minutes")
sleep(0.01)
pending = 0
for r in results:
if r._ready is True:
try:
result = r.get()
results.remove(r)
self.compiled += 1
self.progress("compile", result['source'], build_update=True)
for res in result['results']:
self.cc_verbose("Compile: %s" % ' '.join(res['command']), result['source'])
self.compile_output([
res['code'],
res['output'],
res['command']
])
objects.append(result['object'])
except ToolException, err:
if p._taskqueue.queue:
p._taskqueue.queue.clear()
sleep(0.5)
p.terminate()
p.join()
raise ToolException(err)
else:
pending += 1
if pending >= jobs_count:
break
results = None
p.join()
return objects
# Determine the compile command based on type of source file
def compile_command(self, source, object, includes):
# Check dependencies
_, ext = splitext(source)
ext = ext.lower()
if ext == '.c' or ext == '.cpp':
base, _ = splitext(object)
dep_path = base + '.d'
deps = self.parse_dependencies(dep_path) if (exists(dep_path)) else []
if len(deps) == 0 or self.need_update(object, deps):
if ext == '.cpp' or self.COMPILE_C_AS_CPP:
return self.compile_cpp(source, object, includes)
else:
return self.compile_c(source, object, includes)
elif ext == '.s':
deps = [source]
if self.need_update(object, deps):
return self.assemble(source, object, includes)
else:
return False
return None
@abstractmethod
def parse_dependencies(self, dep_path):
"""Parse the dependency information generated by the compiler.
Positional arguments:
dep_path -- the path to a file generated by a previous run of the compiler
Return value:
A list of all source files that the dependency file indicated were dependencies
Side effects:
None
"""
raise NotImplemented
def is_not_supported_error(self, output):
return "#error directive: [NOT_SUPPORTED]" in output
@abstractmethod
def parse_output(self, output):
"""Take in compiler output and extract sinlge line warnings and errors from it.
Positional arguments:
output -- a string of all the messages emitted by a run of the compiler
Return value:
None
Side effects:
call self.cc_info or self.notify with a description of the event generated by the compiler
"""
raise NotImplemented
def compile_output(self, output=[]):
_rc = output[0]
_stderr = output[1]
command = output[2]
# Parse output for Warnings and Errors
self.parse_output(_stderr)
self.debug("Return: %s"% _rc)
for error_line in _stderr.splitlines():
self.debug("Output: %s"% error_line)
# Check return code
if _rc != 0:
if self.is_not_supported_error(_stderr):
raise NotSupportedException(_stderr)
else:
raise ToolException(_stderr)
def build_library(self, objects, dir, name):
needed_update = False
lib = self.STD_LIB_NAME % name
fout = join(dir, lib)
if self.need_update(fout, objects):
self.info("Library: %s" % lib)
self.archive(objects, fout)
needed_update = True
return needed_update
def link_program(self, r, tmp_path, name):
needed_update = False
ext = 'bin'
if hasattr(self.target, 'OUTPUT_EXT'):
ext = self.target.OUTPUT_EXT
if hasattr(self.target, 'OUTPUT_NAMING'):
self.var("binary_naming", self.target.OUTPUT_NAMING)
if self.target.OUTPUT_NAMING == "8.3":
name = name[0:8]
ext = ext[0:3]
# Create destination directory
head, tail = split(name)
new_path = join(tmp_path, head)
mkdir(new_path)
filename = name+'.'+ext
elf = join(tmp_path, name + '.elf')
bin = join(tmp_path, filename)
map = join(tmp_path, name + '.map')
r.objects = sorted(set(r.objects))
if self.need_update(elf, r.objects + r.libraries + [r.linker_script]):
needed_update = True
self.progress("link", name)
self.link(elf, r.objects, r.libraries, r.lib_dirs, r.linker_script)
if self.need_update(bin, [elf]):
needed_update = True
self.progress("elf2bin", name)
self.binary(r, elf, bin)
self.map_outputs = self.mem_stats(map)
self.var("compile_succeded", True)
self.var("binary", filename)
return bin, needed_update
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def default_cmd(self, command):
_stdout, _stderr, _rc = run_cmd(command, work_dir=getcwd(), chroot=self.CHROOT)
self.debug("Return: %s"% _rc)
for output_line in _stdout.splitlines():
self.debug("Output: %s"% output_line)
for error_line in _stderr.splitlines():
self.debug("Errors: %s"% error_line)
if _rc != 0:
for line in _stderr.splitlines():
self.tool_error(line)
raise ToolException(_stderr)
### NOTIFICATIONS ###
def info(self, message):
self.notify({'type': 'info', 'message': message})
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def debug(self, message):
if self.VERBOSE:
if type(message) is ListType:
message = ' '.join(message)
message = "[DEBUG] " + message
self.notify({'type': 'debug', 'message': message})
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def cc_info(self, info=None):
if info is not None:
info['type'] = 'cc'
self.notify(info)
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def cc_verbose(self, message, file=""):
self.debug(message)
def progress(self, action, file, build_update=False):
msg = {'type': 'progress', 'action': action, 'file': file}
if build_update:
msg['percent'] = 100. * float(self.compiled) / float(self.to_be_compiled)
self.notify(msg)
def tool_error(self, message):
self.notify({'type': 'tool_error', 'message': message})
def var(self, key, value):
self.notify({'type': 'var', 'key': key, 'val': value})
# THIS METHOD IS BEING OVERRIDDEN BY THE MBED ONLINE BUILD SYSTEM
# ANY CHANGE OF PARAMETERS OR RETURN VALUES WILL BREAK COMPATIBILITY
def mem_stats(self, map):
"""! Creates parser object
@param map Path to linker map file to parse and decode
@return Memory summary structure with memory usage statistics
None if map file can't be opened and processed
"""
toolchain = self.__class__.__name__
# Create memap object
memap = MemapParser()
# Parse and decode a map file
if memap.parse(abspath(map), toolchain) is False:
self.info("Unknown toolchain for memory statistics %s" % toolchain)
return None
# Store the memap instance for later use
self.memap_instance = memap
# Here we return memory statistics structure (constructed after
# call to generate_output) which contains raw data in bytes
# about sections + summary
return memap.mem_report
# Set the configuration data
def set_config_data(self, config_data):
self.config_data = config_data
# Creates the configuration header if needed:
# - if there is no configuration data, "mbed_config.h" is not create (or deleted if it exists).
# - if there is configuration data and "mbed_config.h" does not exist, it is created.
# - if there is configuration data similar to the previous configuration data,
# "mbed_config.h" is left untouched.
# - if there is new configuration data, "mbed_config.h" is overriden.
# The function needs to be called exactly once for the lifetime of this toolchain instance.
# The "config_processed" variable (below) ensures this behaviour.
# The function returns the location of the configuration file, or None if there is no
# configuration data available (and thus no configuration file)
def get_config_header(self):
if self.config_processed: # this function was already called, return its result
return self.config_file
# The config file is located in the build directory
self.config_file = join(self.build_dir, self.MBED_CONFIG_FILE_NAME)
# If the file exists, read its current content in prev_data
if exists(self.config_file):
with open(self.config_file, "rt") as f:
prev_data = f.read()
else:
prev_data = None
# Get the current configuration data
crt_data = Config.config_to_header(self.config_data) if self.config_data else None
# "changed" indicates if a configuration change was detected
changed = False
if prev_data is not None: # a previous mbed_config.h exists
if crt_data is None: # no configuration data, so "mbed_config.h" needs to be removed
remove(self.config_file)
self.config_file = None # this means "config file not present"
changed = True
elif crt_data != prev_data: # different content of config file
with open(self.config_file, "wt") as f:
f.write(crt_data)
changed = True
else: # a previous mbed_config.h does not exist
if crt_data is not None: # there's configuration data available
with open(self.config_file, "wt") as f:
f.write(crt_data)
changed = True
else:
self.config_file = None # this means "config file not present"
# If there was a change in configuration, rebuild everything
self.build_all = changed
# Make sure that this function will only return the location of the configuration
# file for subsequent calls, without trying to manipulate its content in any way.
self.config_processed = True
return self.config_file
@staticmethod
def generic_check_executable(tool_key, executable_name, levels_up,
nested_dir=None):
"""
Positional args:
tool_key: the key to index TOOLCHAIN_PATHS
executable_name: the toolchain's named executable (ex. armcc)
levels_up: each toolchain joins the toolchain_path, some
variable directories (bin, include), and the executable name,
so the TOOLCHAIN_PATH value must be appropriately distanced
Keyword args:
nested_dir: the directory within TOOLCHAIN_PATHS where the executable
is found (ex: 'bin' for ARM\bin\armcc (necessary to check for path
that will be used by toolchain's compile)
Returns True if the executable location specified by the user
exists and is valid OR the executable can be found on the PATH.
Returns False otherwise.
"""
# Search PATH if user did not specify a path or specified path doesn't
# exist.
if not TOOLCHAIN_PATHS[tool_key] or not exists(TOOLCHAIN_PATHS[tool_key]):
exe = find_executable(executable_name)
if not exe:
return False
for level in range(levels_up):
# move up the specified number of directories
exe = dirname(exe)
TOOLCHAIN_PATHS[tool_key] = exe
if nested_dir:
subdir = join(TOOLCHAIN_PATHS[tool_key], nested_dir,
executable_name)
else:
subdir = join(TOOLCHAIN_PATHS[tool_key],executable_name)
# User could have specified a path that exists but does not contain exe
return exists(subdir) or exists(subdir +'.exe')
@abstractmethod
def check_executable(self):
"""Returns True if the executable (armcc) location specified by the
user exists OR the executable can be found on the PATH.
Returns False otherwise."""
raise NotImplemented
@abstractmethod
def get_config_option(self, config_header):
"""Generate the compiler option that forces the inclusion of the configuration
header file.
Positional arguments:
config_header -- The configuration header that will be included within all source files
Return value:
A list of the command line arguments that will force the inclusion the specified header
Side effects:
None
"""
raise NotImplemented
@abstractmethod
def assemble(self, source, object, includes):
"""Generate the command line that assembles.
Positional arguments:
source -- a file path that is the file to assemble
object -- a file path that is the destination object
includes -- a list of all directories where header files may be found
Return value:
The complete command line, as a list, that would invoke the assembler
on the source file, include all the include paths, and generate
the specified object file.
Side effects:
None
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
@abstractmethod
def compile_c(self, source, object, includes):
"""Generate the command line that compiles a C source file.
Positional arguments:
source -- the C source file to compile
object -- the destination object file
includes -- a list of all the directories where header files may be found
Return value:
The complete command line, as a list, that would invoke the C compiler
on the source file, include all the include paths, and generate the
specified object file.
Side effects:
None
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
@abstractmethod
def compile_cpp(self, source, object, includes):
"""Generate the command line that compiles a C++ source file.
Positional arguments:
source -- the C++ source file to compile
object -- the destination object file
includes -- a list of all the directories where header files may be found
Return value:
The complete command line, as a list, that would invoke the C++ compiler
on the source file, include all the include paths, and generate the
specified object file.
Side effects:
None
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
@abstractmethod
def link(self, output, objects, libraries, lib_dirs, mem_map):
"""Run the linker to create an executable and memory map.
Positional arguments:
output -- the file name to place the executable in
objects -- all of the object files to link
libraries -- all of the required libraries
lib_dirs -- where the required libraries are located
mem_map -- the location where the memory map file should be stored
Return value:
None
Side effect:
Runs the linker to produce the executable.
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
@abstractmethod
def archive(self, objects, lib_path):
"""Run the command line that creates an archive.
Positional arguhments:
objects -- a list of all the object files that should be archived
lib_path -- the file name of the resulting library file
Return value:
None
Side effect:
Runs the archiving tool to produce the library file.
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
@abstractmethod
def binary(self, resources, elf, bin):
"""Run the command line that will Extract a simplified binary file.
Positional arguments:
resources -- A resources object (Is not used in any of the toolchains)
elf -- the executable file that is to be converted
bin -- the file name of the to be created simplified binary file
Return value:
None
Side effect:
Runs the elf2bin tool to produce the simplified binary file.
Note:
This method should be decorated with @hook_tool.
"""
raise NotImplemented
# Return the list of macros geenrated by the build system
def get_config_macros(self):
return Config.config_to_macros(self.config_data) if self.config_data else []
from tools.settings import ARM_PATH
from tools.settings import GCC_ARM_PATH, GCC_CR_PATH
from tools.settings import IAR_PATH
TOOLCHAIN_PATHS = {
'ARM': ARM_PATH,
'uARM': ARM_PATH,
'GCC_ARM': GCC_ARM_PATH,
'GCC_CR': GCC_CR_PATH,
'IAR': IAR_PATH
}
from tools.toolchains.arm import ARM_STD, ARM_MICRO
from tools.toolchains.gcc import GCC_ARM, GCC_CR
from tools.toolchains.iar import IAR
TOOLCHAIN_CLASSES = {
'ARM': ARM_STD,
'uARM': ARM_MICRO,
'GCC_ARM': GCC_ARM,
'GCC_CR': GCC_CR,
'IAR': IAR
}
TOOLCHAINS = set(TOOLCHAIN_CLASSES.keys())