llvm-project/llvm/utils/llvm-build/llvmbuild/main.py

903 lines
36 KiB
Python

from __future__ import absolute_import
import filecmp
import os
import sys
import llvmbuild.componentinfo as componentinfo
import llvmbuild.configutil as configutil
from llvmbuild.util import fatal, note
###
def cmake_quote_string(value):
"""
cmake_quote_string(value) -> str
Return a quoted form of the given value that is suitable for use in CMake
language files.
"""
# Currently, we only handle escaping backslashes.
value = value.replace("\\", "\\\\")
return value
def cmake_quote_path(value):
"""
cmake_quote_path(value) -> str
Return a quoted form of the given value that is suitable for use in CMake
language files.
"""
# CMake has a bug in it's Makefile generator that doesn't properly quote
# strings it generates. So instead of using proper quoting, we just use "/"
# style paths. Currently, we only handle escaping backslashes.
value = value.replace("\\", "/")
return value
def make_install_dir(path):
"""
make_install_dir(path) -> None
Create the given directory path for installation, including any parents.
"""
# os.makedirs considers it an error to be called with an existent path.
if not os.path.exists(path):
os.makedirs(path)
###
class LLVMProjectInfo(object):
@staticmethod
def load_infos_from_path(llvmbuild_source_root):
def recurse(subpath):
# Load the LLVMBuild file.
llvmbuild_path = os.path.join(llvmbuild_source_root + subpath,
'LLVMBuild.txt')
if not os.path.exists(llvmbuild_path):
fatal("missing LLVMBuild.txt file at: %r" % (llvmbuild_path,))
# Parse the components from it.
common,info_iter = componentinfo.load_from_path(llvmbuild_path,
subpath)
for info in info_iter:
yield info
# Recurse into the specified subdirectories.
for subdir in common.get_list("subdirectories"):
for item in recurse(os.path.join(subpath, subdir)):
yield item
return recurse("/")
@staticmethod
def load_from_path(source_root, llvmbuild_source_root):
infos = list(
LLVMProjectInfo.load_infos_from_path(llvmbuild_source_root))
return LLVMProjectInfo(source_root, infos)
def __init__(self, source_root, component_infos):
# Store our simple ivars.
self.source_root = source_root
self.component_infos = list(component_infos)
self.component_info_map = None
self.ordered_component_infos = None
def validate_components(self):
"""validate_components() -> None
Validate that the project components are well-defined. Among other
things, this checks that:
- Components have valid references.
- Components references do not form cycles.
We also construct the map from component names to info, and the
topological ordering of components.
"""
# Create the component info map and validate that component names are
# unique.
self.component_info_map = {}
for ci in self.component_infos:
existing = self.component_info_map.get(ci.name)
if existing is not None:
# We found a duplicate component name, report it and error out.
fatal("found duplicate component %r (at %r and %r)" % (
ci.name, ci.subpath, existing.subpath))
self.component_info_map[ci.name] = ci
# Disallow 'all' as a component name, which is a special case.
if 'all' in self.component_info_map:
fatal("project is not allowed to define 'all' component")
# Add the root component.
if '$ROOT' in self.component_info_map:
fatal("project is not allowed to define $ROOT component")
self.component_info_map['$ROOT'] = componentinfo.GroupComponentInfo(
'/', '$ROOT', None)
self.component_infos.append(self.component_info_map['$ROOT'])
# Topologically order the component information according to their
# component references.
def visit_component_info(ci, current_stack, current_set):
# Check for a cycles.
if ci in current_set:
# We found a cycle, report it and error out.
cycle_description = ' -> '.join(
'%r (%s)' % (ci.name, relation)
for relation,ci in current_stack)
fatal("found cycle to %r after following: %s -> %s" % (
ci.name, cycle_description, ci.name))
# If we have already visited this item, we are done.
if ci not in components_to_visit:
return
# Otherwise, mark the component info as visited and traverse.
components_to_visit.remove(ci)
# Validate the parent reference, which we treat specially.
if ci.parent is not None:
parent = self.component_info_map.get(ci.parent)
if parent is None:
fatal("component %r has invalid reference %r (via %r)" % (
ci.name, ci.parent, 'parent'))
ci.set_parent_instance(parent)
for relation,referent_name in ci.get_component_references():
# Validate that the reference is ok.
referent = self.component_info_map.get(referent_name)
if referent is None:
fatal("component %r has invalid reference %r (via %r)" % (
ci.name, referent_name, relation))
# Visit the reference.
current_stack.append((relation,ci))
current_set.add(ci)
visit_component_info(referent, current_stack, current_set)
current_set.remove(ci)
current_stack.pop()
# Finally, add the component info to the ordered list.
self.ordered_component_infos.append(ci)
# FIXME: We aren't actually correctly checking for cycles along the
# parent edges. Haven't decided how I want to handle this -- I thought
# about only checking cycles by relation type. If we do that, it falls
# out easily. If we don't, we should special case the check.
self.ordered_component_infos = []
components_to_visit = sorted(
set(self.component_infos),
key = lambda c: c.name)
while components_to_visit:
visit_component_info(components_to_visit[0], [], set())
# Canonicalize children lists.
for c in self.ordered_component_infos:
c.children.sort(key = lambda c: c.name)
def print_tree(self):
def visit(node, depth = 0):
print('%s%-40s (%s)' % (' '*depth, node.name, node.type_name))
for c in node.children:
visit(c, depth + 1)
visit(self.component_info_map['$ROOT'])
def write_components(self, output_path):
# Organize all the components by the directory their LLVMBuild file
# should go in.
info_basedir = {}
for ci in self.component_infos:
# Ignore the $ROOT component.
if ci.parent is None:
continue
info_basedir[ci.subpath] = info_basedir.get(ci.subpath, []) + [ci]
# Compute the list of subdirectories to scan.
subpath_subdirs = {}
for ci in self.component_infos:
# Ignore root components.
if ci.subpath == '/':
continue
# Otherwise, append this subpath to the parent list.
parent_path = os.path.dirname(ci.subpath)
subpath_subdirs[parent_path] = parent_list = subpath_subdirs.get(
parent_path, set())
parent_list.add(os.path.basename(ci.subpath))
# Generate the build files.
for subpath, infos in info_basedir.items():
# Order the components by name to have a canonical ordering.
infos.sort(key = lambda ci: ci.name)
# Format the components into llvmbuild fragments.
fragments = []
# Add the common fragments.
subdirectories = subpath_subdirs.get(subpath)
if subdirectories:
fragment = """\
subdirectories = %s
""" % (" ".join(sorted(subdirectories)),)
fragments.append(("common", fragment))
# Add the component fragments.
num_common_fragments = len(fragments)
for ci in infos:
fragment = ci.get_llvmbuild_fragment()
if fragment is None:
continue
name = "component_%d" % (len(fragments) - num_common_fragments)
fragments.append((name, fragment))
if not fragments:
continue
assert subpath.startswith('/')
directory_path = os.path.join(output_path, subpath[1:])
# Create the directory if it does not already exist.
if not os.path.exists(directory_path):
os.makedirs(directory_path)
# In an effort to preserve comments (which aren't parsed), read in
# the original file and extract the comments. We only know how to
# associate comments that prefix a section name.
f = open(infos[0]._source_path)
comments_map = {}
comment_block = ""
for ln in f:
if ln.startswith(';'):
comment_block += ln
elif ln.startswith('[') and ln.endswith(']\n'):
comments_map[ln[1:-2]] = comment_block
else:
comment_block = ""
f.close()
# Create the LLVMBuild fil[e.
file_path = os.path.join(directory_path, 'LLVMBuild.txt')
f = open(file_path, "w")
# Write the header.
header_fmt = ';===- %s %s-*- Conf -*--===;'
header_name = '.' + os.path.join(subpath, 'LLVMBuild.txt')
header_pad = '-' * (80 - len(header_fmt % (header_name, '')))
header_string = header_fmt % (header_name, header_pad)
f.write("""\
%s
;
; The LLVM Compiler Infrastructure
;
; This file is distributed under the University of Illinois Open Source
; License. See LICENSE.TXT for details.
;
;===------------------------------------------------------------------------===;
;
; This is an LLVMBuild description file for the components in this subdirectory.
;
; For more information on the LLVMBuild system, please see:
;
; http://llvm.org/docs/LLVMBuild.html
;
;===------------------------------------------------------------------------===;
""" % header_string)
# Write out each fragment.each component fragment.
for name,fragment in fragments:
comment = comments_map.get(name)
if comment is not None:
f.write(comment)
f.write("[%s]\n" % name)
f.write(fragment)
if fragment is not fragments[-1][1]:
f.write('\n')
f.close()
def write_library_table(self, output_path, enabled_optional_components):
# Write out the mapping from component names to required libraries.
#
# We do this in topological order so that we know we can append the
# dependencies for added library groups.
entries = {}
for c in self.ordered_component_infos:
# Skip optional components which are not enabled.
if c.type_name == 'OptionalLibrary' \
and c.name not in enabled_optional_components:
continue
# Skip target groups which are not enabled.
tg = c.get_parent_target_group()
if tg and not tg.enabled:
continue
# Only certain components are in the table.
if c.type_name not in ('Library', 'OptionalLibrary', \
'LibraryGroup', 'TargetGroup'):
continue
# Compute the llvm-config "component name". For historical reasons,
# this is lowercased based on the library name.
llvmconfig_component_name = c.get_llvmconfig_component_name()
# Get the library name, or None for LibraryGroups.
if c.type_name == 'Library' or c.type_name == 'OptionalLibrary':
library_name = c.get_prefixed_library_name()
is_installed = c.installed
else:
library_name = None
is_installed = True
# Get the component names of all the required libraries.
required_llvmconfig_component_names = [
self.component_info_map[dep].get_llvmconfig_component_name()
for dep in c.required_libraries]
# Insert the entries for library groups we should add to.
for dep in c.add_to_library_groups:
entries[dep][2].append(llvmconfig_component_name)
# Add the entry.
entries[c.name] = (llvmconfig_component_name, library_name,
required_llvmconfig_component_names,
is_installed)
# Convert to a list of entries and sort by name.
entries = list(entries.values())
# Create an 'all' pseudo component. We keep the dependency list small by
# only listing entries that have no other dependents.
root_entries = set(e[0] for e in entries)
for _,_,deps,_ in entries:
root_entries -= set(deps)
entries.append(('all', None, root_entries, True))
entries.sort()
# Compute the maximum number of required libraries, plus one so there is
# always a sentinel.
max_required_libraries = max(len(deps)
for _,_,deps,_ in entries) + 1
# Write out the library table.
make_install_dir(os.path.dirname(output_path))
f = open(output_path+'.new', 'w')
f.write("""\
//===- llvm-build generated file --------------------------------*- C++ -*-===//
//
// Component Library Depenedency Table
//
// Automatically generated file, do not edit!
//
//===----------------------------------------------------------------------===//
""")
f.write('struct AvailableComponent {\n')
f.write(' /// The name of the component.\n')
f.write(' const char *Name;\n')
f.write('\n')
f.write(' /// The name of the library for this component (or NULL).\n')
f.write(' const char *Library;\n')
f.write('\n')
f.write(' /// Whether the component is installed.\n')
f.write(' bool IsInstalled;\n')
f.write('\n')
f.write('\
/// The list of libraries required when linking this component.\n')
f.write(' const char *RequiredLibraries[%d];\n' % (
max_required_libraries))
f.write('} AvailableComponents[%d] = {\n' % len(entries))
for name,library_name,required_names,is_installed in entries:
if library_name is None:
library_name_as_cstr = 'nullptr'
else:
library_name_as_cstr = '"%s"' % library_name
if is_installed:
is_installed_as_cstr = 'true'
else:
is_installed_as_cstr = 'false'
f.write(' { "%s", %s, %s, { %s } },\n' % (
name, library_name_as_cstr, is_installed_as_cstr,
', '.join('"%s"' % dep
for dep in required_names)))
f.write('};\n')
f.close()
if not os.path.isfile(output_path):
os.rename(output_path+'.new', output_path)
elif filecmp.cmp(output_path, output_path+'.new'):
os.remove(output_path+'.new')
else:
os.remove(output_path)
os.rename(output_path+'.new', output_path)
def get_required_libraries_for_component(self, ci, traverse_groups = False):
"""
get_required_libraries_for_component(component_info) -> iter
Given a Library component info descriptor, return an iterator over all
of the directly required libraries for linking with this component. If
traverse_groups is True, then library and target groups will be
traversed to include their required libraries.
"""
assert ci.type_name in ('Library', 'OptionalLibrary', 'LibraryGroup', 'TargetGroup')
for name in ci.required_libraries:
# Get the dependency info.
dep = self.component_info_map[name]
# If it is a library, yield it.
if dep.type_name == 'Library' or dep.type_name == 'OptionalLibrary':
yield dep
continue
# Otherwise if it is a group, yield or traverse depending on what
# was requested.
if dep.type_name in ('LibraryGroup', 'TargetGroup'):
if not traverse_groups:
yield dep
continue
for res in self.get_required_libraries_for_component(dep, True):
yield res
def get_fragment_dependencies(self):
"""
get_fragment_dependencies() -> iter
Compute the list of files (as absolute paths) on which the output
fragments depend (i.e., files for which a modification should trigger a
rebuild of the fragment).
"""
# Construct a list of all the dependencies of the Makefile fragment
# itself. These include all the LLVMBuild files themselves, as well as
# all of our own sources.
#
# Many components may come from the same file, so we make sure to unique
# these.
build_paths = set()
for ci in self.component_infos:
p = os.path.join(self.source_root, ci.subpath[1:], 'LLVMBuild.txt')
if p not in build_paths:
yield p
build_paths.add(p)
# Gather the list of necessary sources by just finding all loaded
# modules that are inside the LLVM source tree.
for module in sys.modules.values():
# Find the module path.
if not hasattr(module, '__file__'):
continue
path = getattr(module, '__file__')
if not path:
continue
# Strip off any compiled suffix.
if os.path.splitext(path)[1] in ['.pyc', '.pyo', '.pyd']:
path = path[:-1]
# If the path exists and is in the source tree, consider it a
# dependency.
if (path.startswith(self.source_root) and os.path.exists(path)):
yield path
def foreach_cmake_library(self, f,
enabled_optional_components,
skip_disabled,
skip_not_installed):
for ci in self.ordered_component_infos:
# Skip optional components which are not enabled.
if ci.type_name == 'OptionalLibrary' \
and ci.name not in enabled_optional_components:
continue
# We only write the information for libraries currently.
if ci.type_name not in ('Library', 'OptionalLibrary'):
continue
# Skip disabled targets.
if skip_disabled:
tg = ci.get_parent_target_group()
if tg and not tg.enabled:
continue
# Skip targets that will not be installed
if skip_not_installed and not ci.installed:
continue
f(ci)
def write_cmake_fragment(self, output_path, enabled_optional_components):
"""
write_cmake_fragment(output_path) -> None
Generate a CMake fragment which includes all of the collated LLVMBuild
information in a format that is easily digestible by a CMake. The exact
contents of this are closely tied to how the CMake configuration
integrates LLVMBuild, see CMakeLists.txt in the top-level.
"""
dependencies = list(self.get_fragment_dependencies())
# Write out the CMake fragment.
make_install_dir(os.path.dirname(output_path))
f = open(output_path, 'w')
# Write the header.
header_fmt = '\
#===-- %s - LLVMBuild Configuration for LLVM %s-*- CMake -*--===#'
header_name = os.path.basename(output_path)
header_pad = '-' * (80 - len(header_fmt % (header_name, '')))
header_string = header_fmt % (header_name, header_pad)
f.write("""\
%s
#
# The LLVM Compiler Infrastructure
#
# This file is distributed under the University of Illinois Open Source
# License. See LICENSE.TXT for details.
#
#===------------------------------------------------------------------------===#
#
# This file contains the LLVMBuild project information in a format easily
# consumed by the CMake based build system.
#
# This file is autogenerated by llvm-build, do not edit!
#
#===------------------------------------------------------------------------===#
""" % header_string)
# Write the dependency information in the best way we can.
f.write("""
# LLVMBuild CMake fragment dependencies.
#
# CMake has no builtin way to declare that the configuration depends on
# a particular file. However, a side effect of configure_file is to add
# said input file to CMake's internal dependency list. So, we use that
# and a dummy output file to communicate the dependency information to
# CMake.
#
# FIXME: File a CMake RFE to get a properly supported version of this
# feature.
""")
for dep in dependencies:
f.write("""\
configure_file(\"%s\"
${CMAKE_CURRENT_BINARY_DIR}/DummyConfigureOutput)\n""" % (
cmake_quote_path(dep),))
# Write the properties we use to encode the required library dependency
# information in a form CMake can easily use directly.
f.write("""
# Explicit library dependency information.
#
# The following property assignments effectively create a map from component
# names to required libraries, in a way that is easily accessed from CMake.
""")
self.foreach_cmake_library(
lambda ci:
f.write("""\
set_property(GLOBAL PROPERTY LLVMBUILD_LIB_DEPS_%s %s)\n""" % (
ci.get_prefixed_library_name(), " ".join(sorted(
dep.get_prefixed_library_name()
for dep in self.get_required_libraries_for_component(ci)))))
,
enabled_optional_components,
skip_disabled = False,
skip_not_installed = False # Dependency info must be emitted for internals libs too
)
f.close()
def write_cmake_exports_fragment(self, output_path, enabled_optional_components):
"""
write_cmake_exports_fragment(output_path) -> None
Generate a CMake fragment which includes LLVMBuild library
dependencies expressed similarly to how CMake would write
them via install(EXPORT).
"""
dependencies = list(self.get_fragment_dependencies())
# Write out the CMake exports fragment.
make_install_dir(os.path.dirname(output_path))
f = open(output_path, 'w')
f.write("""\
# Explicit library dependency information.
#
# The following property assignments tell CMake about link
# dependencies of libraries imported from LLVM.
""")
self.foreach_cmake_library(
lambda ci:
f.write("""\
set_property(TARGET %s PROPERTY IMPORTED_LINK_INTERFACE_LIBRARIES %s)\n""" % (
ci.get_prefixed_library_name(), " ".join(sorted(
dep.get_prefixed_library_name()
for dep in self.get_required_libraries_for_component(ci)))))
,
enabled_optional_components,
skip_disabled = True,
skip_not_installed = True # Do not export internal libraries like gtest
)
f.close()
def add_magic_target_components(parser, project, opts):
"""add_magic_target_components(project, opts) -> None
Add the "magic" target based components to the project, which can only be
determined based on the target configuration options.
This currently is responsible for populating the required_libraries list of
the "all-targets", "Native", "NativeCodeGen", and "Engine" components.
"""
# Determine the available targets.
available_targets = dict((ci.name,ci)
for ci in project.component_infos
if ci.type_name == 'TargetGroup')
# Find the configured native target.
# We handle a few special cases of target names here for historical
# reasons, as these are the names configure currently comes up with.
native_target_name = { 'x86' : 'X86',
'x86_64' : 'X86',
'Unknown' : None }.get(opts.native_target,
opts.native_target)
if native_target_name is None:
native_target = None
else:
native_target = available_targets.get(native_target_name)
if native_target is None:
parser.error("invalid native target: %r (not in project)" % (
opts.native_target,))
if native_target.type_name != 'TargetGroup':
parser.error("invalid native target: %r (not a target)" % (
opts.native_target,))
# Find the list of targets to enable.
if opts.enable_targets is None:
enable_targets = available_targets.values()
else:
# We support both space separated and semi-colon separated lists.
if opts.enable_targets == '':
enable_target_names = []
elif ' ' in opts.enable_targets:
enable_target_names = opts.enable_targets.split()
else:
enable_target_names = opts.enable_targets.split(';')
enable_targets = []
for name in enable_target_names:
target = available_targets.get(name)
if target is None:
parser.error("invalid target to enable: %r (not in project)" % (
name,))
if target.type_name != 'TargetGroup':
parser.error("invalid target to enable: %r (not a target)" % (
name,))
enable_targets.append(target)
# Find the special library groups we are going to populate. We enforce that
# these appear in the project (instead of just adding them) so that they at
# least have an explicit representation in the project LLVMBuild files (and
# comments explaining how they are populated).
def find_special_group(name):
info = info_map.get(name)
if info is None:
fatal("expected project to contain special %r component" % (
name,))
if info.type_name != 'LibraryGroup':
fatal("special component %r should be a LibraryGroup" % (
name,))
if info.required_libraries:
fatal("special component %r must have empty %r list" % (
name, 'required_libraries'))
if info.add_to_library_groups:
fatal("special component %r must have empty %r list" % (
name, 'add_to_library_groups'))
info._is_special_group = True
return info
info_map = dict((ci.name, ci) for ci in project.component_infos)
all_targets = find_special_group('all-targets')
native_group = find_special_group('Native')
native_codegen_group = find_special_group('NativeCodeGen')
engine_group = find_special_group('Engine')
# Set the enabled bit in all the target groups, and append to the
# all-targets list.
for ci in enable_targets:
all_targets.required_libraries.append(ci.name)
ci.enabled = True
# If we have a native target, then that defines the native and
# native_codegen libraries.
if native_target and native_target.enabled:
native_group.required_libraries.append(native_target.name)
native_codegen_group.required_libraries.append(
'%sCodeGen' % native_target.name)
# If we have a native target with a JIT, use that for the engine. Otherwise,
# use the interpreter.
if native_target and native_target.enabled and native_target.has_jit:
engine_group.required_libraries.append('MCJIT')
engine_group.required_libraries.append(native_group.name)
else:
engine_group.required_libraries.append('Interpreter')
def main():
from optparse import OptionParser, OptionGroup
parser = OptionParser("usage: %prog [options]")
group = OptionGroup(parser, "Input Options")
group.add_option("", "--source-root", dest="source_root", metavar="PATH",
help="Path to the LLVM source (inferred if not given)",
action="store", default=None)
group.add_option("", "--llvmbuild-source-root",
dest="llvmbuild_source_root",
help=(
"If given, an alternate path to search for LLVMBuild.txt files"),
action="store", default=None, metavar="PATH")
group.add_option("", "--build-root", dest="build_root", metavar="PATH",
help="Path to the build directory (if needed) [%default]",
action="store", default=None)
parser.add_option_group(group)
group = OptionGroup(parser, "Output Options")
group.add_option("", "--print-tree", dest="print_tree",
help="Print out the project component tree [%default]",
action="store_true", default=False)
group.add_option("", "--write-llvmbuild", dest="write_llvmbuild",
help="Write out the LLVMBuild.txt files to PATH",
action="store", default=None, metavar="PATH")
group.add_option("", "--write-library-table",
dest="write_library_table", metavar="PATH",
help="Write the C++ library dependency table to PATH",
action="store", default=None)
group.add_option("", "--write-cmake-fragment",
dest="write_cmake_fragment", metavar="PATH",
help="Write the CMake project information to PATH",
action="store", default=None)
group.add_option("", "--write-cmake-exports-fragment",
dest="write_cmake_exports_fragment", metavar="PATH",
help="Write the CMake exports information to PATH",
action="store", default=None)
group.add_option("", "--configure-target-def-file",
dest="configure_target_def_files",
help="""Configure the given file at SUBPATH (relative to
the inferred or given source root, and with a '.in' suffix) by replacing certain
substitution variables with lists of targets that support certain features (for
example, targets with AsmPrinters) and write the result to the build root (as
given by --build-root) at the same SUBPATH""",
metavar="SUBPATH", action="append", default=None)
parser.add_option_group(group)
group = OptionGroup(parser, "Configuration Options")
group.add_option("", "--native-target",
dest="native_target", metavar="NAME",
help=("Treat the named target as the 'native' one, if "
"given [%default]"),
action="store", default=None)
group.add_option("", "--enable-targets",
dest="enable_targets", metavar="NAMES",
help=("Enable the given space or semi-colon separated "
"list of targets, or all targets if not present"),
action="store", default=None)
group.add_option("", "--enable-optional-components",
dest="optional_components", metavar="NAMES",
help=("Enable the given space or semi-colon separated "
"list of optional components"),
action="store", default="")
parser.add_option_group(group)
(opts, args) = parser.parse_args()
# Determine the LLVM source path, if not given.
source_root = opts.source_root
if source_root:
if not os.path.exists(os.path.join(source_root, 'lib', 'IR',
'Function.cpp')):
parser.error('invalid LLVM source root: %r' % source_root)
else:
llvmbuild_path = os.path.dirname(__file__)
llvm_build_path = os.path.dirname(llvmbuild_path)
utils_path = os.path.dirname(llvm_build_path)
source_root = os.path.dirname(utils_path)
if not os.path.exists(os.path.join(source_root, 'lib', 'IR',
'Function.cpp')):
parser.error('unable to infer LLVM source root, please specify')
# Construct the LLVM project information.
llvmbuild_source_root = opts.llvmbuild_source_root or source_root
project_info = LLVMProjectInfo.load_from_path(
source_root, llvmbuild_source_root)
# Add the magic target based components.
add_magic_target_components(parser, project_info, opts)
# Validate the project component info.
project_info.validate_components()
# Print the component tree, if requested.
if opts.print_tree:
project_info.print_tree()
# Write out the components, if requested. This is useful for auto-upgrading
# the schema.
if opts.write_llvmbuild:
project_info.write_components(opts.write_llvmbuild)
# Write out the required library table, if requested.
if opts.write_library_table:
project_info.write_library_table(opts.write_library_table,
opts.optional_components)
# Write out the cmake fragment, if requested.
if opts.write_cmake_fragment:
project_info.write_cmake_fragment(opts.write_cmake_fragment,
opts.optional_components)
if opts.write_cmake_exports_fragment:
project_info.write_cmake_exports_fragment(opts.write_cmake_exports_fragment,
opts.optional_components)
# Configure target definition files, if requested.
if opts.configure_target_def_files:
# Verify we were given a build root.
if not opts.build_root:
parser.error("must specify --build-root when using "
"--configure-target-def-file")
# Create the substitution list.
available_targets = [ci for ci in project_info.component_infos
if ci.type_name == 'TargetGroup']
substitutions = [
("@LLVM_ENUM_TARGETS@",
' '.join('LLVM_TARGET(%s)' % ci.name
for ci in available_targets)),
("@LLVM_ENUM_ASM_PRINTERS@",
' '.join('LLVM_ASM_PRINTER(%s)' % ci.name
for ci in available_targets
if ci.has_asmprinter)),
("@LLVM_ENUM_ASM_PARSERS@",
' '.join('LLVM_ASM_PARSER(%s)' % ci.name
for ci in available_targets
if ci.has_asmparser)),
("@LLVM_ENUM_DISASSEMBLERS@",
' '.join('LLVM_DISASSEMBLER(%s)' % ci.name
for ci in available_targets
if ci.has_disassembler))]
# Configure the given files.
for subpath in opts.configure_target_def_files:
inpath = os.path.join(source_root, subpath + '.in')
outpath = os.path.join(opts.build_root, subpath)
result = configutil.configure_file(inpath, outpath, substitutions)
if not result:
note("configured file %r hasn't changed" % outpath)
if __name__=='__main__':
main()