def run(self, project, name, prop_set, sources):
if not name:
return None
# If name is empty, it means we're called not from top-level.
# In this case, we just fail immediately, because SearchedLibGenerator
# cannot be used to produce intermediate targets.
properties = prop_set.raw ()
shared = '<link>shared' in properties
a = virtual_target.NullAction (project.manager(), prop_set)
real_name = feature.get_values ('<name>', properties)
if real_name:
real_name = real_name[0]
else:
real_name = name
search = feature.get_values('<search>', properties)
usage_requirements = property_set.create(['<xdll-path>' + p for p in search])
t = SearchedLibTarget(real_name, project, shared, search, a)
# We return sources for a simple reason. If there's
# lib png : z : <name>png ;
# the 'z' target should be returned, so that apps linking to
# 'png' will link to 'z', too.
return(usage_requirements, [b2.manager.get_manager().virtual_targets().register(t)] + sources)
def run(self, project, name, prop_set, sources):
if not name:
return None
# If name is empty, it means we're called not from top-level.
# In this case, we just fail immediately, because SearchedLibGenerator
# cannot be used to produce intermediate targets.
properties = prop_set.raw()
shared = '<link>shared' in properties
a = virtual_target.NullAction(project.manager(), prop_set)
real_name = feature.get_values('<name>', properties)
if real_name:
real_name = real_name[0]
else:
real_nake = name
search = feature.get_values('<search>', properties)
usage_requirements = property_set.create(
['<xdll-path>' + p for p in search])
t = SearchedLibTarget(name, project, shared, real_name, search, a)
# We return sources for a simple reason. If there's
# lib png : z : <name>png ;
# the 'z' target should be returned, so that apps linking to
# 'png' will link to 'z', too.
return (usage_requirements,
[b2.manager.get_manager().virtual_targets().register(t)] +
sources)
def handle_options(tool, condition, command, options):
""" Handle common options for toolset, specifically sets the following
flag variables:
- CONFIG_COMMAND to 'command'
- OPTIOns for compile to the value of <compileflags> in options
- OPTIONS for compile.c to the value of <cflags> in options
- OPTIONS for compile.c++ to the value of <cxxflags> in options
- OPTIONS for compile.fortran to the value of <fflags> in options
- OPTIONs for link to the value of <linkflags> in options
"""
from b2.build import toolset
assert (isinstance(tool, str))
assert (isinstance(condition, list))
assert (isinstance(command, str))
assert (isinstance(options, list))
assert (command)
toolset.flags(tool, 'CONFIG_COMMAND', condition, [command])
toolset.flags(tool + '.compile', 'OPTIONS', condition,
feature.get_values('<compileflags>', options))
toolset.flags(tool + '.compile.c', 'OPTIONS', condition,
feature.get_values('<cflags>', options))
toolset.flags(tool + '.compile.c++', 'OPTIONS', condition,
feature.get_values('<cxxflags>', options))
toolset.flags(tool + '.compile.fortran', 'OPTIONS', condition,
feature.get_values('<fflags>', options))
toolset.flags(tool + '.link', 'OPTIONS', condition,
feature.get_values('<linkflags>', options))
def configure (command = None, condition = None, options = None):
"""
Configures a new resource compilation command specific to a condition,
usually a toolset selection condition. The possible options are:
* <rc-type>(rc|windres) - Indicates the type of options the command
accepts.
Even though the arguments are all optional, only when a command, condition,
and at minimum the rc-type option are given will the command be configured.
This is so that callers don't have to check auto-configuration values
before calling this. And still get the functionality of build failures when
the resource compiler can't be found.
"""
rc_type = feature.get_values('<rc-type>', options)
if rc_type:
assert(len(rc_type) == 1)
rc_type = rc_type[0]
if command and condition and rc_type:
flags('rc.compile.resource', '.RC', condition, command)
flags('rc.compile.resource', '.RC_TYPE', condition, rc_type.lower())
flags('rc.compile.resource', 'DEFINES', [], ['<define>'])
flags('rc.compile.resource', 'INCLUDES', [], ['<include>'])
if debug():
print 'notice: using rc compiler ::', condition, '::', command
def configure (command = None, condition = None, options = None):
"""
Configures a new resource compilation command specific to a condition,
usually a toolset selection condition. The possible options are:
* <rc-type>(rc|windres) - Indicates the type of options the command
accepts.
Even though the arguments are all optional, only when a command, condition,
and at minimum the rc-type option are given will the command be configured.
This is so that callers don't have to check auto-configuration values
before calling this. And still get the functionality of build failures when
the resource compiler can't be found.
"""
rc_type = feature.get_values('<rc-type>', options)
if rc_type:
assert(len(rc_type) == 1)
rc_type = rc_type[0]
if command and condition and rc_type:
flags('rc.compile.resource', '.RC', condition, command)
flags('rc.compile.resource', '.RC_TYPE', condition, [rc_type.lower()])
flags('rc.compile.resource', 'DEFINES', [], ['<define>'])
flags('rc.compile.resource', 'INCLUDES', [], ['<include>'])
if debug():
print 'notice: using rc compiler ::', condition, '::', command
def handle_options(tool, condition, command, options):
""" Handle common options for toolset, specifically sets the following
flag variables:
- CONFIG_COMMAND to 'command'
- OPTIOns for compile to the value of <compileflags> in options
- OPTIONS for compile.c to the value of <cflags> in options
- OPTIONS for compile.c++ to the value of <cxxflags> in options
- OPTIONS for compile.fortran to the value of <fflags> in options
- OPTIONs for link to the value of <linkflags> in options
"""
from b2.build import toolset
assert isinstance(tool, basestring)
assert is_iterable_typed(condition, basestring)
assert command and isinstance(command, basestring)
assert is_iterable_typed(options, basestring)
toolset.flags(tool, 'CONFIG_COMMAND', condition, [command])
toolset.flags(tool + '.compile', 'OPTIONS', condition, feature.get_values('<compileflags>', options))
toolset.flags(tool + '.compile.c', 'OPTIONS', condition, feature.get_values('<cflags>', options))
toolset.flags(tool + '.compile.c++', 'OPTIONS', condition, feature.get_values('<cxxflags>', options))
toolset.flags(tool + '.compile.fortran', 'OPTIONS', condition, feature.get_values('<fflags>', options))
toolset.flags(tool + '.link', 'OPTIONS', condition, feature.get_values('<linkflags>', options))
def init(version = None, command = None, options = None):
"""
Initializes the gcc toolset for the given version. If necessary, command may
be used to specify where the compiler is located. The parameter 'options' is a
space-delimited list of options, each one specified as
<option-name>option-value. Valid option names are: cxxflags, linkflags and
linker-type. Accepted linker-type values are gnu, darwin, osf, hpux or sun
and the default value will be selected based on the current OS.
Example:
using gcc : 3.4 : : <cxxflags>foo <linkflags>bar <linker-type>sun ;
"""
options = to_seq(options)
command = to_seq(command)
# Information about the gcc command...
# The command.
command = to_seq(common.get_invocation_command('gcc', 'g++', command))
# The root directory of the tool install.
root = feature.get_values('<root>', options) ;
# The bin directory where to find the command to execute.
bin = None
# The flavor of compiler.
flavor = feature.get_values('<flavor>', options)
# Autodetect the root and bin dir if not given.
if command:
if not bin:
bin = common.get_absolute_tool_path(command[-1])
if not root:
root = os.path.dirname(bin)
# Autodetect the version and flavor if not given.
if command:
machine_info = subprocess.Popen(command + ['-dumpmachine'], stdout=subprocess.PIPE).communicate()[0]
machine = __machine_match.search(machine_info).group(1)
version_info = subprocess.Popen(command + ['-dumpversion'], stdout=subprocess.PIPE).communicate()[0]
version = __version_match.search(version_info).group(1)
if not flavor and machine.find('mingw') != -1:
flavor = 'mingw'
condition = None
if flavor:
condition = common.check_init_parameters('gcc', None,
('version', version),
('flavor', flavor))
else:
condition = common.check_init_parameters('gcc', None,
('version', version))
if command:
command = command[0]
common.handle_options('gcc', condition, command, options)
linker = feature.get_values('<linker-type>', options)
if not linker:
if os_name() == 'OSF':
linker = 'osf'
elif os_name() == 'HPUX':
linker = 'hpux' ;
else:
linker = 'gnu'
init_link_flags('gcc', linker, condition)
# If gcc is installed in non-standard location, we'd need to add
# LD_LIBRARY_PATH when running programs created with it (for unit-test/run
# rules).
if command:
# On multilib 64-bit boxes, there are both 32-bit and 64-bit libraries
# and all must be added to LD_LIBRARY_PATH. The linker will pick the
# right onces. Note that we don't provide a clean way to build 32-bit
# binary with 64-bit compiler, but user can always pass -m32 manually.
lib_path = [os.path.join(root, 'bin'),
os.path.join(root, 'lib'),
os.path.join(root, 'lib32'),
os.path.join(root, 'lib64')]
if debug():
print 'notice: using gcc libraries ::', condition, '::', lib_path
toolset.flags('gcc.link', 'RUN_PATH', condition, lib_path)
# If it's not a system gcc install we should adjust the various programs as
# needed to prefer using the install specific versions. This is essential
# for correct use of MinGW and for cross-compiling.
# - The archive builder.
archiver = common.get_invocation_command('gcc',
'ar', feature.get_values('<archiver>', options), [bin], path_last=True)
toolset.flags('gcc.archive', '.AR', condition, [archiver])
if debug():
print 'notice: using gcc archiver ::', condition, '::', archiver
# - The resource compiler.
rc_command = common.get_invocation_command_nodefault('gcc',
'windres', feature.get_values('<rc>', options), [bin], path_last=True)
rc_type = feature.get_values('<rc-type>', options)
if not rc_type:
rc_type = 'windres'
if not rc_command:
# If we can't find an RC compiler we fallback to a null RC compiler that
# creates empty object files. This allows the same Jamfiles to work
# across the board. The null RC uses the assembler to create the empty
# objects, so configure that.
rc_command = common.get_invocation_command('gcc', 'as', [], [bin], path_last=True)
rc_type = 'null'
rc.configure(rc_command, condition, '<rc-type>' + rc_type)
def init(version=None, command=None, options=None):
"""
Initializes the gcc toolset for the given version. If necessary, command may
be used to specify where the compiler is located. The parameter 'options' is a
space-delimited list of options, each one specified as
<option-name>option-value. Valid option names are: cxxflags, linkflags and
linker-type. Accepted linker-type values are gnu, darwin, osf, hpux or sun
and the default value will be selected based on the current OS.
Example:
using gcc : 3.4 : : <cxxflags>foo <linkflags>bar <linker-type>sun ;
"""
options = to_seq(options)
command = to_seq(command)
# Information about the gcc command...
# The command.
command = to_seq(common.get_invocation_command('gcc', 'g++', command))
# The root directory of the tool install.
root = feature.get_values('<root>', options)
# The bin directory where to find the command to execute.
bin = None
# The flavor of compiler.
flavor = feature.get_values('<flavor>', options)
# Autodetect the root and bin dir if not given.
if command:
if not bin:
bin = common.get_absolute_tool_path(command[-1])
if not root:
root = os.path.dirname(bin)
# Autodetect the version and flavor if not given.
if command:
machine_info = subprocess.Popen(
command + ['-dumpmachine'],
stdout=subprocess.PIPE).communicate()[0]
machine = __machine_match.search(machine_info).group(1)
version_info = subprocess.Popen(
command + ['-dumpversion'],
stdout=subprocess.PIPE).communicate()[0]
version = __version_match.search(version_info).group(1)
if not flavor and machine.find('mingw') != -1:
flavor = 'mingw'
condition = None
if flavor:
condition = common.check_init_parameters('gcc', None,
('version', version),
('flavor', flavor))
else:
condition = common.check_init_parameters('gcc', None,
('version', version))
if command:
command = command[0]
common.handle_options('gcc', condition, command, options)
linker = feature.get_values('<linker-type>', options)
if not linker:
if os_name() == 'OSF':
linker = 'osf'
elif os_name() == 'HPUX':
linker = 'hpux'
else:
linker = 'gnu'
init_link_flags('gcc', linker, condition)
# If gcc is installed in non-standard location, we'd need to add
# LD_LIBRARY_PATH when running programs created with it (for unit-test/run
# rules).
if command:
# On multilib 64-bit boxes, there are both 32-bit and 64-bit libraries
# and all must be added to LD_LIBRARY_PATH. The linker will pick the
# right onces. Note that we don't provide a clean way to build 32-bit
# binary with 64-bit compiler, but user can always pass -m32 manually.
lib_path = [
os.path.join(root, 'bin'),
os.path.join(root, 'lib'),
os.path.join(root, 'lib32'),
os.path.join(root, 'lib64')
]
if debug():
print 'notice: using gcc libraries ::', condition, '::', lib_path
toolset.flags('gcc.link', 'RUN_PATH', condition, lib_path)
# If it's not a system gcc install we should adjust the various programs as
# needed to prefer using the install specific versions. This is essential
# for correct use of MinGW and for cross-compiling.
# - The archive builder.
archiver = common.get_invocation_command('gcc',
'ar',
feature.get_values(
'<archiver>', options), [bin],
path_last=True)
toolset.flags('gcc.archive', '.AR', condition, [archiver])
if debug():
print 'notice: using gcc archiver ::', condition, '::', archiver
# - Ranlib
ranlib = common.get_invocation_command('gcc',
'ranlib',
feature.get_values(
'<ranlib>', options), [bin],
path_last=True)
toolset.flags('gcc.archive', '.RANLIB', condition, [ranlib])
if debug():
print 'notice: using gcc archiver ::', condition, '::', ranlib
# - The resource compiler.
rc_command = common.get_invocation_command_nodefault('gcc',
'windres',
feature.get_values(
'<rc>', options),
[bin],
path_last=True)
rc_type = feature.get_values('<rc-type>', options)
if not rc_type:
rc_type = 'windres'
if not rc_command:
# If we can't find an RC compiler we fallback to a null RC compiler that
# creates empty object files. This allows the same Jamfiles to work
# across the board. The null RC uses the assembler to create the empty
# objects, so configure that.
rc_command = common.get_invocation_command('gcc',
'as', [], [bin],
path_last=True)
rc_type = 'null'
rc.configure(rc_command, condition, '<rc-type>' + rc_type)