# This script is used as a bitbake task to create a new python manifest # $ bitbake python -c create_manifest # # Our goal is to keep python-core as small as posible and add other python # packages only when the user needs them, hence why we split upstream python # into several packages. # # In a very simplistic way what this does is: # Launch python and see specifically what is required for it to run at a minimum # # Go through the python-manifest file and launch a separate task for every single # one of the files on each package, this task will check what was required for that # specific module to run, these modules will be called dependencies. # The output of such task will be a list of the modules or dependencies that were # found for that file. # # Such output will be parsed by this script, we will look for each dependency on the # manifest and if we find that another package already includes it, then we will add # that package as an RDEPENDS to the package we are currently checking; in case we dont # find the current dependency on any other package we will add it to the current package # as part of FILES. # # # This way we will create a new manifest from the data structure that was built during # this process, ont this new manifest each package will contain specifically only # what it needs to run. # # There are some caveats which we try to deal with, such as repeated files on different # packages, packages that include folders, wildcards, and special packages. # Its also important to note that this method only works for python files, and shared # libraries. Static libraries, header files and binaries need to be dealt with manually. # # This script differs from its python2 version mostly on how shared libraries are handled # The manifest file for python3 has an extra field which contains the cached files for # each package. # Tha method to handle cached files does not work when a module includes a folder which # itself contains the pycache folder, gladly this is almost never the case. # # Author: Alejandro Enedino Hernandez Samaniego "aehs29" import sys import subprocess import json import os import collections # Get python version from ${PYTHON_MAJMIN} pyversion = str(sys.argv[1]) # Hack to get native python search path (for folders), not fond of it but it works for now pivot = 'recipe-sysroot-native' for p in sys.path: if pivot in p: nativelibfolder = p[:p.find(pivot)+len(pivot)] # Empty dict to hold the whole manifest new_manifest = collections.OrderedDict() # Check for repeated files, folders and wildcards allfiles = [] repeated = [] wildcards = [] hasfolders = [] allfolders = [] def isFolder(value): value = value.replace('${PYTHON_MAJMIN}',pyversion) if os.path.isdir(value.replace('${libdir}',nativelibfolder+'/usr/lib')) or os.path.isdir(value.replace('${libdir}',nativelibfolder+'/usr/lib64')) or os.path.isdir(value.replace('${libdir}',nativelibfolder+'/usr/lib32')): return True else: return False def isCached(item): if '__pycache__' in item: return True else: return False # Read existing JSON manifest with open('python3-manifest.json') as manifest: old_manifest = json.load(manifest, object_pairs_hook=collections.OrderedDict) # # First pass to get core-package functionality, because we base everything on the fact that core is actually working # Not exactly the same so it should not be a function # print ('Getting dependencies for package: core') # This special call gets the core dependencies and # appends to the old manifest so it doesnt hurt what it # currently holds. # This way when other packages check for dependencies # on the new core package, they will still find them # even when checking the old_manifest output = subprocess.check_output([sys.executable, 'get_module_deps3.py', 'python-core-package']).decode('utf8') for coredep in output.split(): coredep = coredep.replace(pyversion,'${PYTHON_MAJMIN}') if isCached(coredep): if coredep not in old_manifest['core']['cached']: old_manifest['core']['cached'].append(coredep) else: if coredep not in old_manifest['core']['files']: old_manifest['core']['files'].append(coredep) # The second step is to loop through the existing files contained in the core package # according to the old manifest, identify if they are modules, or some other type # of file that we cant import (directories, binaries, configs) in which case we # can only assume they were added correctly (manually) so we ignore those and # pass them to the manifest directly. for filedep in old_manifest['core']['files']: if isFolder(filedep): if isCached(filedep): if filedep not in old_manifest['core']['cached']: old_manifest['core']['cached'].append(filedep) else: if filedep not in old_manifest['core']['files']: old_manifest['core']['files'].append(filedep) continue if '${bindir}' in filedep: if filedep not in old_manifest['core']['files']: old_manifest['core']['files'].append(filedep) continue if filedep == '': continue if '${includedir}' in filedep: if filedep not in old_manifest['core']['files']: old_manifest['core']['files'].append(filedep) continue # Get actual module name , shouldnt be affected by libdir/bindir, etc. pymodule = os.path.splitext(os.path.basename(os.path.normpath(filedep)))[0] # We now know that were dealing with a python module, so we can import it # and check what its dependencies are. # We launch a separate task for each module for deterministic behavior. # Each module will only import what is necessary for it to work in specific. # The output of each task will contain each module's dependencies print ('Getting dependencies for module: %s' % pymodule) output = subprocess.check_output([sys.executable, 'get_module_deps3.py', '%s' % pymodule]).decode('utf8') print ('The following dependencies were found for module %s:\n' % pymodule) print (output) for pymodule_dep in output.split(): pymodule_dep = pymodule_dep.replace(pyversion,'${PYTHON_MAJMIN}') if isCached(pymodule_dep): if pymodule_dep not in old_manifest['core']['cached']: old_manifest['core']['cached'].append(pymodule_dep) else: if pymodule_dep not in old_manifest['core']['files']: old_manifest['core']['files'].append(pymodule_dep) # At this point we are done with the core package. # The old_manifest dictionary is updated only for the core package because # all others will use this a base. # To improve the script speed, we check which packages contain directories # since we will be looping through (only) those later. for pypkg in old_manifest: for filedep in old_manifest[pypkg]['files']: if isFolder(filedep): print ('%s is a folder' % filedep) if pypkg not in hasfolders: hasfolders.append(pypkg) if filedep not in allfolders: allfolders.append(filedep) # This is the main loop that will handle each package. # It works in a similar fashion than the step before, but # we will now be updating a new dictionary that will eventually # become the new manifest. # # The following loops though all packages in the manifest, # through all files on each of them, and checks whether or not # they are modules and can be imported. # If they can be imported, then it checks for dependencies for # each of them by launching a separate task. # The output of that task is then parsed and the manifest is updated # accordingly, wether it should add the module on FILES for the current package # or if that module already belongs to another package then the current one # will RDEPEND on it for pypkg in old_manifest: # Use an empty dict as data structure to hold data for each package and fill it up new_manifest[pypkg] = collections.OrderedDict() new_manifest[pypkg]['summary'] = old_manifest[pypkg]['summary'] new_manifest[pypkg]['rdepends'] = [] new_manifest[pypkg]['files'] = [] new_manifest[pypkg]['cached'] = old_manifest[pypkg]['cached'] # All packages should depend on core if pypkg != 'core': new_manifest[pypkg]['rdepends'].append('core') new_manifest[pypkg]['cached'] = [] print('\n') print('--------------------------') print ('Handling package %s' % pypkg) print('--------------------------') # Handle special cases, we assume that when they were manually added # to the manifest we knew what we were doing. special_packages = ['misc', 'modules', 'dev', 'tests', 'sqlite3-tests'] if pypkg in special_packages or 'staticdev' in pypkg: print('Passing %s package directly' % pypkg) new_manifest[pypkg] = old_manifest[pypkg] continue for filedep in old_manifest[pypkg]['files']: # We already handled core on the first pass, we can ignore it now if pypkg == 'core': if filedep not in new_manifest[pypkg]['files']: new_manifest[pypkg]['files'].append(filedep) continue # Handle/ignore what we cant import if isFolder(filedep): new_manifest[pypkg]['files'].append(filedep) # Asyncio (and others) are both the package and the folder name, we should not skip those... path,mod = os.path.split(filedep) if mod != pypkg: continue if '${bindir}' in filedep: if filedep not in new_manifest[pypkg]['files']: new_manifest[pypkg]['files'].append(filedep) continue if filedep == '': continue if '${includedir}' in filedep: if filedep not in new_manifest[pypkg]['files']: new_manifest[pypkg]['files'].append(filedep) continue # Get actual module name , shouldnt be affected by libdir/bindir, etc. # We need to check if the imported module comes from another (e.g. sqlite3.dump) path,pymodule = os.path.split(filedep) path = os.path.basename(path) pymodule = os.path.splitext(os.path.basename(pymodule))[0] # If this condition is met, it means we need to import it from another module # or its the folder itself (e.g. unittest) if path == pypkg: if pymodule: pymodule = path + '.' + pymodule else: pymodule = path # We now know that were dealing with a python module, so we can import it # and check what its dependencies are. # We launch a separate task for each module for deterministic behavior. # Each module will only import what is necessary for it to work in specific. # The output of each task will contain each module's dependencies print ('\nGetting dependencies for module: %s' % pymodule) output = subprocess.check_output([sys.executable, 'get_module_deps3.py', '%s' % pymodule]).decode('utf8') print ('The following dependencies were found for module %s:\n' % pymodule) print (output) reportFILES = [] reportRDEPS = [] for pymodule_dep in output.split(): # Warning: This first part is ugly # One of the dependencies that was found, could be inside of one of the folders included by another package # We need to check if this happens so we can add the package containing the folder as an rdependency # e.g. Folder encodings contained in codecs # This would be solved if no packages included any folders # This can be done in two ways: # 1 - We assume that if we take out the filename from the path we would get # the folder string, then we would check if folder string is in the list of folders # This would not work if a package contains a folder which contains another folder # e.g. path/folder1/folder2/filename folder_string= path/folder1/folder2 # folder_string would not match any value contained in the list of folders # # 2 - We do it the other way around, checking if the folder is contained in the path # e.g. path/folder1/folder2/filename folder_string= path/folder1/folder2 # is folder_string inside path/folder1/folder2/filename?, # Yes, it works, but we waste a couple of milliseconds. pymodule_dep = pymodule_dep.replace(pyversion,'${PYTHON_MAJMIN}') inFolders = False for folder in allfolders: if folder in pymodule_dep: inFolders = True # Did we find a folder? folderFound = False # Second flag to break inner for # Loop only through packages which contain folders for pypkg_with_folder in hasfolders: if (folderFound == False): # print('Checking folder %s on package %s' % (pymodule_dep,pypkg_with_folder)) for folder_dep in old_manifest[pypkg_with_folder]['files'] or folder_dep in old_manifest[pypkg_with_folder]['cached']: if folder_dep == folder: print ('%s folder found in %s' % (folder, pypkg_with_folder)) folderFound = True if pypkg_with_folder not in new_manifest[pypkg]['rdepends'] and pypkg_with_folder != pypkg: new_manifest[pypkg]['rdepends'].append(pypkg_with_folder) else: break # A folder was found so we're done with this item, we can go on if inFolders: continue # No directories beyond this point # We might already have this module on the dictionary since it could depend on a (previously checked) module if pymodule_dep not in new_manifest[pypkg]['files'] and pymodule_dep not in new_manifest[pypkg]['cached']: # Handle core as a special package, we already did it so we pass it to NEW data structure directly if pypkg == 'core': print('Adding %s to %s FILES' % (pymodule_dep, pypkg)) if pymodule_dep.endswith('*'): wildcards.append(pymodule_dep) if isCached(pymodule_dep): new_manifest[pypkg]['cached'].append(pymodule_dep) else: new_manifest[pypkg]['files'].append(pymodule_dep) # Check for repeated files if pymodule_dep not in allfiles: allfiles.append(pymodule_dep) else: if pymodule_dep not in repeated: repeated.append(pymodule_dep) else: # Last step: Figure out if we this belongs to FILES or RDEPENDS # We check if this module is already contained on another package, so we add that one # as an RDEPENDS, or if its not, it means it should be contained on the current # package, and we should add it to FILES for possible_rdep in old_manifest: # Debug # print('Checking %s ' % pymodule_dep + ' in %s' % possible_rdep) if pymodule_dep in old_manifest[possible_rdep]['files'] or pymodule_dep in old_manifest[possible_rdep]['cached']: # Since were nesting, we need to check its not the same pypkg if(possible_rdep != pypkg): if possible_rdep not in new_manifest[pypkg]['rdepends']: # Add it to the new manifest data struct as RDEPENDS since it contains something this module needs reportRDEPS.append('Adding %s to %s RDEPENDS, because it contains %s\n' % (possible_rdep, pypkg, pymodule_dep)) new_manifest[pypkg]['rdepends'].append(possible_rdep) break else: # Since this module wasnt found on another package, it is not an RDEP, # so we add it to FILES for this package. # A module shouldn't contain itself (${libdir}/python3/sqlite3 shouldnt be on sqlite3 files) if os.path.basename(pymodule_dep) != pypkg: reportFILES.append(('Adding %s to %s FILES\n' % (pymodule_dep, pypkg))) if isCached(pymodule_dep): new_manifest[pypkg]['cached'].append(pymodule_dep) else: new_manifest[pypkg]['files'].append(pymodule_dep) if pymodule_dep.endswith('*'): wildcards.append(pymodule_dep) if pymodule_dep not in allfiles: allfiles.append(pymodule_dep) else: if pymodule_dep not in repeated: repeated.append(pymodule_dep) print('\n') print('#################################') print('Summary for module %s' % pymodule) print('FILES found for module %s:' % pymodule) print(''.join(reportFILES)) print('RDEPENDS found for module %s:' % pymodule) print(''.join(reportRDEPS)) print('#################################') print('The following FILES contain wildcards, please check if they are necessary') print(wildcards) print('The following FILES contain folders, please check if they are necessary') print(hasfolders) # Sort it just so it looks nicer for pypkg in new_manifest: new_manifest[pypkg]['files'].sort() new_manifest[pypkg]['cached'].sort() new_manifest[pypkg]['rdepends'].sort() # Create the manifest from the data structure that was built with open('python3-manifest.json.new','w') as outfile: json.dump(new_manifest,outfile, indent=4) outfile.write('\n') if (repeated): error_msg = '\n\nERROR:\n' error_msg += 'The following files are repeated (contained in more than one package),\n' error_msg += 'this is likely to happen when new files are introduced after an upgrade,\n' error_msg += 'please check which package should get it,\n modify the manifest accordingly and re-run the create_manifest task:\n' error_msg += '\n'.join(repeated) error_msg += '\n' sys.exit(error_msg)