"""Generate C code for a Python C extension module from Python source code.""" # FIXME: Basically nothing in this file operates on the level of a # single module and it should be renamed. import os import json from mypy.backports import OrderedDict from typing import List, Tuple, Dict, Iterable, Set, TypeVar, Optional from mypy.nodes import MypyFile from mypy.build import ( BuildSource, BuildResult, State, build, sorted_components, get_cache_names, create_metastore, compute_hash, ) from mypy.errors import CompileError from mypy.options import Options from mypy.plugin import Plugin, ReportConfigContext from mypy.fscache import FileSystemCache from mypy.util import hash_digest from mypyc.irbuild.main import build_ir from mypyc.irbuild.prepare import load_type_map from mypyc.irbuild.mapper import Mapper from mypyc.common import ( PREFIX, TOP_LEVEL_NAME, MODULE_PREFIX, RUNTIME_C_FILES, short_id_from_name, use_fastcall, use_vectorcall, shared_lib_name, ) from mypyc.codegen.cstring import c_string_initializer from mypyc.codegen.literals import Literals from mypyc.codegen.emit import EmitterContext, Emitter, HeaderDeclaration from mypyc.codegen.emitfunc import generate_native_function, native_function_header from mypyc.codegen.emitclass import generate_class_type_decl, generate_class from mypyc.codegen.emitwrapper import ( generate_wrapper_function, wrapper_function_header, generate_legacy_wrapper_function, legacy_wrapper_function_header, ) from mypyc.ir.ops import DeserMaps, LoadLiteral from mypyc.ir.rtypes import RType, RTuple from mypyc.ir.func_ir import FuncIR from mypyc.ir.class_ir import ClassIR from mypyc.ir.module_ir import ModuleIR, ModuleIRs, deserialize_modules from mypyc.options import CompilerOptions from mypyc.transform.uninit import insert_uninit_checks from mypyc.transform.refcount import insert_ref_count_opcodes from mypyc.transform.exceptions import insert_exception_handling from mypyc.namegen import NameGenerator, exported_name from mypyc.errors import Errors # All of the modules being compiled are divided into "groups". A group # is a set of modules that are placed into the same shared library. # Two common configurations are that every module is placed in a group # by itself (fully separate compilation) and that every module is # placed in the same group (fully whole-program compilation), but we # support finer-grained control of the group as well. # # In fully whole-program compilation, we will generate N+1 extension # modules: one shim per module and one shared library containing all # the actual code. # In fully separate compilation, we (unfortunately) will generate 2*N # extension modules: one shim per module and also one library containing # each module's actual code. (This might be fixable in the future, # but allows a clean separation between setup of the export tables # (see generate_export_table) and running module top levels.) # # A group is represented as a list of BuildSources containing all of # its modules along with the name of the group. (Which can be None # only if we are compiling only a single group with a single file in it # and not using shared libraries). Group = Tuple[List[BuildSource], Optional[str]] Groups = List[Group] # A list of (file name, file contents) pairs. FileContents = List[Tuple[str, str]] class MarkedDeclaration: """Add a mark, useful for topological sort.""" def __init__(self, declaration: HeaderDeclaration, mark: bool) -> None: self.declaration = declaration self.mark = False class MypycPlugin(Plugin): """Plugin for making mypyc interoperate properly with mypy incremental mode. Basically the point of this plugin is to force mypy to recheck things based on the demands of mypyc in a couple situations: * Any modules in the same group must be compiled together, so we tell mypy that modules depend on all their groupmates. * If the IR metadata is missing or stale or any of the generated C source files associated missing or stale, then we need to recompile the module so we mark it as stale. """ def __init__( self, options: Options, compiler_options: CompilerOptions, groups: Groups) -> None: super().__init__(options) self.group_map: Dict[str, Tuple[Optional[str], List[str]]] = {} for sources, name in groups: modules = sorted(source.module for source in sources) for id in modules: self.group_map[id] = (name, modules) self.compiler_options = compiler_options self.metastore = create_metastore(options) def report_config_data( self, ctx: ReportConfigContext) -> Optional[Tuple[Optional[str], List[str]]]: # The config data we report is the group map entry for the module. # If the data is being used to check validity, we do additional checks # that the IR cache exists and matches the metadata cache and all # output source files exist and are up to date. id, path, is_check = ctx.id, ctx.path, ctx.is_check if id not in self.group_map: return None # If we aren't doing validity checks, just return the cache data if not is_check: return self.group_map[id] # Load the metadata and IR cache meta_path, _, _ = get_cache_names(id, path, self.options) ir_path = get_ir_cache_name(id, path, self.options) try: meta_json = self.metastore.read(meta_path) ir_json = self.metastore.read(ir_path) except FileNotFoundError: # This could happen if mypyc failed after mypy succeeded # in the previous run or if some cache files got # deleted. No big deal, just fail to load the cache. return None ir_data = json.loads(ir_json) # Check that the IR cache matches the metadata cache if compute_hash(meta_json) != ir_data['meta_hash']: return None # Check that all of the source files are present and as # expected. The main situation where this would come up is the # user deleting the build directory without deleting # .mypy_cache, which we should handle gracefully. for path, hash in ir_data['src_hashes'].items(): try: with open(os.path.join(self.compiler_options.target_dir, path), 'rb') as f: contents = f.read() except FileNotFoundError: return None real_hash = hash_digest(contents) if hash != real_hash: return None return self.group_map[id] def get_additional_deps(self, file: MypyFile) -> List[Tuple[int, str, int]]: # Report dependency on modules in the module's group return [(10, id, -1) for id in self.group_map.get(file.fullname, (None, []))[1]] def parse_and_typecheck( sources: List[BuildSource], options: Options, compiler_options: CompilerOptions, groups: Groups, fscache: Optional[FileSystemCache] = None, alt_lib_path: Optional[str] = None ) -> BuildResult: assert options.strict_optional, 'strict_optional must be turned on' result = build(sources=sources, options=options, alt_lib_path=alt_lib_path, fscache=fscache, extra_plugins=[MypycPlugin(options, compiler_options, groups)]) if result.errors: raise CompileError(result.errors) return result def compile_scc_to_ir( scc: List[MypyFile], result: BuildResult, mapper: Mapper, compiler_options: CompilerOptions, errors: Errors, ) -> ModuleIRs: """Compile an SCC into ModuleIRs. Any modules that this SCC depends on must have either compiled or loaded from a cache into mapper. Arguments: scc: The list of MypyFiles to compile result: The BuildResult from the mypy front-end mapper: The Mapper object mapping mypy ASTs to class and func IRs compiler_options: The compilation options errors: Where to report any errors encountered Returns the IR of the modules. """ if compiler_options.verbose: print("Compiling {}".format(", ".join(x.name for x in scc))) # Generate basic IR, with missing exception and refcount handling. modules = build_ir( scc, result.graph, result.types, mapper, compiler_options, errors ) if errors.num_errors > 0: return modules # Insert uninit checks. for module in modules.values(): for fn in module.functions: insert_uninit_checks(fn) # Insert exception handling. for module in modules.values(): for fn in module.functions: insert_exception_handling(fn) # Insert refcount handling. for module in modules.values(): for fn in module.functions: insert_ref_count_opcodes(fn) return modules def compile_modules_to_ir( result: BuildResult, mapper: Mapper, compiler_options: CompilerOptions, errors: Errors, ) -> ModuleIRs: """Compile a collection of modules into ModuleIRs. The modules to compile are specified as part of mapper's group_map. Returns the IR of the modules. """ deser_ctx = DeserMaps({}, {}) modules = {} # Process the graph by SCC in topological order, like we do in mypy.build for scc in sorted_components(result.graph): scc_states = [result.graph[id] for id in scc] trees = [st.tree for st in scc_states if st.id in mapper.group_map and st.tree] if not trees: continue fresh = all(id not in result.manager.rechecked_modules for id in scc) if fresh: load_scc_from_cache(trees, result, mapper, deser_ctx) else: scc_ir = compile_scc_to_ir(trees, result, mapper, compiler_options, errors) modules.update(scc_ir) return modules def compile_ir_to_c( groups: Groups, modules: ModuleIRs, result: BuildResult, mapper: Mapper, compiler_options: CompilerOptions, ) -> Dict[Optional[str], List[Tuple[str, str]]]: """Compile a collection of ModuleIRs to C source text. Returns a dictionary mapping group names to a list of (file name, file text) pairs. """ source_paths = {source.module: result.graph[source.module].xpath for sources, _ in groups for source in sources} names = NameGenerator([[source.module for source in sources] for sources, _ in groups]) # Generate C code for each compilation group. Each group will be # compiled into a separate extension module. ctext: Dict[Optional[str], List[Tuple[str, str]]] = {} for group_sources, group_name in groups: group_modules = [(source.module, modules[source.module]) for source in group_sources if source.module in modules] if not group_modules: ctext[group_name] = [] continue generator = GroupGenerator( group_modules, source_paths, group_name, mapper.group_map, names, compiler_options ) ctext[group_name] = generator.generate_c_for_modules() return ctext def get_ir_cache_name(id: str, path: str, options: Options) -> str: meta_path, _, _ = get_cache_names(id, path, options) return meta_path.replace('.meta.json', '.ir.json') def get_state_ir_cache_name(state: State) -> str: return get_ir_cache_name(state.id, state.xpath, state.options) def write_cache( modules: ModuleIRs, result: BuildResult, group_map: Dict[str, Optional[str]], ctext: Dict[Optional[str], List[Tuple[str, str]]], ) -> None: """Write out the cache information for modules. Each module has the following cache information written (which is in addition to the cache information written by mypy itself): * A serialized version of its mypyc IR, minus the bodies of functions. This allows code that depends on it to use these serialized data structures when compiling against it instead of needing to recompile it. (Compiling against a module requires access to both its mypy and mypyc data structures.) * The hash of the mypy metadata cache file for the module. This is used to ensure that the mypyc cache and the mypy cache are in sync and refer to the same version of the code. This is particularly important if mypyc crashes/errors/is stopped after mypy has written its cache but before mypyc has. * The hashes of all of the source file outputs for the group the module is in. This is so that the module will be recompiled if the source outputs are missing. """ hashes = {} for name, files in ctext.items(): hashes[name] = {file: compute_hash(data) for file, data in files} # Write out cache data for id, module in modules.items(): st = result.graph[id] meta_path, _, _ = get_cache_names(id, st.xpath, result.manager.options) # If the metadata isn't there, skip writing the cache. try: meta_data = result.manager.metastore.read(meta_path) except OSError: continue newpath = get_state_ir_cache_name(st) ir_data = { 'ir': module.serialize(), 'meta_hash': compute_hash(meta_data), 'src_hashes': hashes[group_map[id]], } result.manager.metastore.write(newpath, json.dumps(ir_data)) result.manager.metastore.commit() def load_scc_from_cache( scc: List[MypyFile], result: BuildResult, mapper: Mapper, ctx: DeserMaps, ) -> ModuleIRs: """Load IR for an SCC of modules from the cache. Arguments and return are as compile_scc_to_ir. """ cache_data = { k.fullname: json.loads( result.manager.metastore.read(get_state_ir_cache_name(result.graph[k.fullname])) )['ir'] for k in scc } modules = deserialize_modules(cache_data, ctx) load_type_map(mapper, scc, ctx) return modules def compile_modules_to_c( result: BuildResult, compiler_options: CompilerOptions, errors: Errors, groups: Groups, ) -> Tuple[ModuleIRs, List[FileContents]]: """Compile Python module(s) to the source of Python C extension modules. This generates the source code for the "shared library" module for each group. The shim modules are generated in mypyc.build. Each shared library module provides, for each module in its group, a PyCapsule containing an initialization function. Additionally, it provides a capsule containing an export table of pointers to all of the group's functions and static variables. Arguments: result: The BuildResult from the mypy front-end compiler_options: The compilation options errors: Where to report any errors encountered groups: The groups that we are compiling. See documentation of Groups type above. ops: Optionally, where to dump stringified ops for debugging. Returns the IR of the modules and a list containing the generated files for each group. """ # Construct a map from modules to what group they belong to group_map = {source.module: lib_name for group, lib_name in groups for source in group} mapper = Mapper(group_map) # Sometimes when we call back into mypy, there might be errors. # We don't want to crash when that happens. result.manager.errors.set_file('', module=None, scope=None) modules = compile_modules_to_ir(result, mapper, compiler_options, errors) ctext = compile_ir_to_c(groups, modules, result, mapper, compiler_options) if errors.num_errors == 0: write_cache(modules, result, group_map, ctext) return modules, [ctext[name] for _, name in groups] def generate_function_declaration(fn: FuncIR, emitter: Emitter) -> None: emitter.context.declarations[emitter.native_function_name(fn.decl)] = HeaderDeclaration( f'{native_function_header(fn.decl, emitter)};', needs_export=True) if fn.name != TOP_LEVEL_NAME: if is_fastcall_supported(fn, emitter.capi_version): emitter.context.declarations[PREFIX + fn.cname(emitter.names)] = HeaderDeclaration( f'{wrapper_function_header(fn, emitter.names)};') else: emitter.context.declarations[PREFIX + fn.cname(emitter.names)] = HeaderDeclaration( f'{legacy_wrapper_function_header(fn, emitter.names)};') def pointerize(decl: str, name: str) -> str: """Given a C decl and its name, modify it to be a declaration to a pointer.""" # This doesn't work in general but does work for all our types... if '(' in decl: # Function pointer. Stick an * in front of the name and wrap it in parens. return decl.replace(name, f'(*{name})') else: # Non-function pointer. Just stick an * in front of the name. return decl.replace(name, f'*{name}') def group_dir(group_name: str) -> str: """Given a group name, return the relative directory path for it. """ return os.sep.join(group_name.split('.')[:-1]) class GroupGenerator: def __init__(self, modules: List[Tuple[str, ModuleIR]], source_paths: Dict[str, str], group_name: Optional[str], group_map: Dict[str, Optional[str]], names: NameGenerator, compiler_options: CompilerOptions) -> None: """Generator for C source for a compilation group. The code for a compilation group contains an internal and an external .h file, and then one .c if not in multi_file mode or one .c file per module if in multi_file mode.) Arguments: modules: (name, ir) pairs for each module in the group source_paths: Map from module names to source file paths group_name: The name of the group (or None if this is single-module compilation) group_map: A map of modules to their group names names: The name generator for the compilation multi_file: Whether to put each module in its own source file regardless of group structure. """ self.modules = modules self.source_paths = source_paths self.context = EmitterContext(names, group_name, group_map) self.names = names # Initializations of globals to simple values that we can't # do statically because the windows loader is bad. self.simple_inits: List[Tuple[str, str]] = [] self.group_name = group_name self.use_shared_lib = group_name is not None self.compiler_options = compiler_options self.multi_file = compiler_options.multi_file @property def group_suffix(self) -> str: return '_' + exported_name(self.group_name) if self.group_name else '' @property def short_group_suffix(self) -> str: return '_' + exported_name(self.group_name.split('.')[-1]) if self.group_name else '' def generate_c_for_modules(self) -> List[Tuple[str, str]]: file_contents = [] multi_file = self.use_shared_lib and self.multi_file # Collect all literal refs in IR. for _, module in self.modules: for fn in module.functions: collect_literals(fn, self.context.literals) base_emitter = Emitter(self.context) # Optionally just include the runtime library c files to # reduce the number of compiler invocations needed if self.compiler_options.include_runtime_files: for name in RUNTIME_C_FILES: base_emitter.emit_line(f'#include "{name}"') base_emitter.emit_line(f'#include "__native{self.short_group_suffix}.h"') base_emitter.emit_line(f'#include "__native_internal{self.short_group_suffix}.h"') emitter = base_emitter self.generate_literal_tables() for module_name, module in self.modules: if multi_file: emitter = Emitter(self.context) emitter.emit_line(f'#include "__native{self.short_group_suffix}.h"') emitter.emit_line( f'#include "__native_internal{self.short_group_suffix}.h"') self.declare_module(module_name, emitter) self.declare_internal_globals(module_name, emitter) self.declare_imports(module.imports, emitter) for cl in module.classes: if cl.is_ext_class: generate_class(cl, module_name, emitter) # Generate Python extension module definitions and module initialization functions. self.generate_module_def(emitter, module_name, module) for fn in module.functions: emitter.emit_line() generate_native_function(fn, emitter, self.source_paths[module_name], module_name) if fn.name != TOP_LEVEL_NAME: emitter.emit_line() if is_fastcall_supported(fn, emitter.capi_version): generate_wrapper_function( fn, emitter, self.source_paths[module_name], module_name) else: generate_legacy_wrapper_function( fn, emitter, self.source_paths[module_name], module_name) if multi_file: name = (f'__native_{emitter.names.private_name(module_name)}.c') file_contents.append((name, ''.join(emitter.fragments))) # The external header file contains type declarations while # the internal contains declarations of functions and objects # (which are shared between shared libraries via dynamic # exports tables and not accessed directly.) ext_declarations = Emitter(self.context) ext_declarations.emit_line(f'#ifndef MYPYC_NATIVE{self.group_suffix}_H') ext_declarations.emit_line(f'#define MYPYC_NATIVE{self.group_suffix}_H') ext_declarations.emit_line('#include ') ext_declarations.emit_line('#include ') declarations = Emitter(self.context) declarations.emit_line(f'#ifndef MYPYC_NATIVE_INTERNAL{self.group_suffix}_H') declarations.emit_line(f'#define MYPYC_NATIVE_INTERNAL{self.group_suffix}_H') declarations.emit_line('#include ') declarations.emit_line('#include ') declarations.emit_line(f'#include "__native{self.short_group_suffix}.h"') declarations.emit_line() declarations.emit_line('int CPyGlobalsInit(void);') declarations.emit_line() for module_name, module in self.modules: self.declare_finals(module_name, module.final_names, declarations) for cl in module.classes: generate_class_type_decl(cl, emitter, ext_declarations, declarations) for fn in module.functions: generate_function_declaration(fn, declarations) for lib in sorted(self.context.group_deps): elib = exported_name(lib) short_lib = exported_name(lib.split('.')[-1]) declarations.emit_lines( '#include <{}>'.format( os.path.join(group_dir(lib), f"__native_{short_lib}.h") ), f'struct export_table_{elib} exports_{elib};' ) sorted_decls = self.toposort_declarations() emitter = base_emitter self.generate_globals_init(emitter) emitter.emit_line() for declaration in sorted_decls: decls = ext_declarations if declaration.is_type else declarations if not declaration.is_type: decls.emit_lines( f'extern {declaration.decl[0]}', *declaration.decl[1:]) # If there is a definition, emit it. Otherwise repeat the declaration # (without an extern). if declaration.defn: emitter.emit_lines(*declaration.defn) else: emitter.emit_lines(*declaration.decl) else: decls.emit_lines(*declaration.decl) if self.group_name: self.generate_export_table(ext_declarations, emitter) self.generate_shared_lib_init(emitter) ext_declarations.emit_line('#endif') declarations.emit_line('#endif') output_dir = group_dir(self.group_name) if self.group_name else '' return file_contents + [ (os.path.join(output_dir, f'__native{self.short_group_suffix}.c'), ''.join(emitter.fragments)), (os.path.join(output_dir, f'__native_internal{self.short_group_suffix}.h'), ''.join(declarations.fragments)), (os.path.join(output_dir, f'__native{self.short_group_suffix}.h'), ''.join(ext_declarations.fragments)), ] def generate_literal_tables(self) -> None: """Generate tables containing descriptions of Python literals to construct. We will store the constructed literals in a single array that contains literals of all types. This way we can refer to an arbitrary literal by its index. """ literals = self.context.literals # During module initialization we store all the constructed objects here self.declare_global('PyObject *[%d]' % literals.num_literals(), 'CPyStatics') # Descriptions of str literals init_str = c_string_array_initializer(literals.encoded_str_values()) self.declare_global('const char * const []', 'CPyLit_Str', initializer=init_str) # Descriptions of bytes literals init_bytes = c_string_array_initializer(literals.encoded_bytes_values()) self.declare_global('const char * const []', 'CPyLit_Bytes', initializer=init_bytes) # Descriptions of int literals init_int = c_string_array_initializer(literals.encoded_int_values()) self.declare_global('const char * const []', 'CPyLit_Int', initializer=init_int) # Descriptions of float literals init_floats = c_array_initializer(literals.encoded_float_values()) self.declare_global('const double []', 'CPyLit_Float', initializer=init_floats) # Descriptions of complex literals init_complex = c_array_initializer(literals.encoded_complex_values()) self.declare_global('const double []', 'CPyLit_Complex', initializer=init_complex) # Descriptions of tuple literals init_tuple = c_array_initializer(literals.encoded_tuple_values()) self.declare_global('const int []', 'CPyLit_Tuple', initializer=init_tuple) def generate_export_table(self, decl_emitter: Emitter, code_emitter: Emitter) -> None: """Generate the declaration and definition of the group's export struct. To avoid needing to deal with deeply platform specific issues involving dynamic library linking (and some possibly insurmountable issues involving cyclic dependencies), compiled code accesses functions and data in other compilation groups via an explicit "export struct". Each group declares a struct type that contains a pointer to every function and static variable it exports. It then populates this struct and stores a pointer to it in a capsule stored as an attribute named 'exports' on the group's shared library's python module. On load, a group's init function will import all of its dependencies' exports tables using the capsule mechanism and copy the contents into a local copy of the table (to eliminate the need for a pointer indirection when accessing it). Then, all calls to functions in another group and accesses to statics from another group are done indirectly via the export table. For example, a group containing a module b, where b contains a class B and a function bar, would declare an export table like: struct export_table_b { PyTypeObject **CPyType_B; PyObject *(*CPyDef_B)(CPyTagged cpy_r_x); CPyTagged (*CPyDef_B___foo)(PyObject *cpy_r_self, CPyTagged cpy_r_y); tuple_T2OI (*CPyDef_bar)(PyObject *cpy_r_x); char (*CPyDef___top_level__)(void); }; that would be initialized with: static struct export_table_b exports = { &CPyType_B, &CPyDef_B, &CPyDef_B___foo, &CPyDef_bar, &CPyDef___top_level__, }; To call `b.foo`, then, a function in another group would do `exports_b.CPyDef_bar(...)`. """ decls = decl_emitter.context.declarations decl_emitter.emit_lines( '', f'struct export_table{self.group_suffix} {{', ) for name, decl in decls.items(): if decl.needs_export: decl_emitter.emit_line(pointerize('\n'.join(decl.decl), name)) decl_emitter.emit_line('};') code_emitter.emit_lines( '', f'static struct export_table{self.group_suffix} exports = {{', ) for name, decl in decls.items(): if decl.needs_export: code_emitter.emit_line(f'&{name},') code_emitter.emit_line('};') def generate_shared_lib_init(self, emitter: Emitter) -> None: """Generate the init function for a shared library. A shared library contains all of the actual code for a compilation group. The init function is responsible for creating Capsules that wrap pointers to the initialization function of all the real init functions for modules in this shared library as well as the export table containing all of the exported functions and values from all the modules. These capsules are stored in attributes of the shared library. """ assert self.group_name is not None emitter.emit_line() emitter.emit_lines( 'PyMODINIT_FUNC PyInit_{}(void)'.format( shared_lib_name(self.group_name).split('.')[-1]), '{', ('static PyModuleDef def = {{ PyModuleDef_HEAD_INIT, "{}", NULL, -1, NULL, NULL }};' .format(shared_lib_name(self.group_name))), 'int res;', 'PyObject *capsule;', 'PyObject *tmp;', 'static PyObject *module;', 'if (module) {', 'Py_INCREF(module);', 'return module;', '}', 'module = PyModule_Create(&def);', 'if (!module) {', 'goto fail;', '}', '', ) emitter.emit_lines( 'capsule = PyCapsule_New(&exports, "{}.exports", NULL);'.format( shared_lib_name(self.group_name)), 'if (!capsule) {', 'goto fail;', '}', 'res = PyObject_SetAttrString(module, "exports", capsule);', 'Py_DECREF(capsule);', 'if (res < 0) {', 'goto fail;', '}', '', ) for mod, _ in self.modules: name = exported_name(mod) emitter.emit_lines( f'extern PyObject *CPyInit_{name}(void);', 'capsule = PyCapsule_New((void *)CPyInit_{}, "{}.init_{}", NULL);'.format( name, shared_lib_name(self.group_name), name), 'if (!capsule) {', 'goto fail;', '}', f'res = PyObject_SetAttrString(module, "init_{name}", capsule);', 'Py_DECREF(capsule);', 'if (res < 0) {', 'goto fail;', '}', '', ) for group in sorted(self.context.group_deps): egroup = exported_name(group) emitter.emit_lines( 'tmp = PyImport_ImportModule("{}"); if (!tmp) goto fail; Py_DECREF(tmp);'.format( shared_lib_name(group)), 'struct export_table_{} *pexports_{} = PyCapsule_Import("{}.exports", 0);'.format( egroup, egroup, shared_lib_name(group)), f'if (!pexports_{egroup}) {{', 'goto fail;', '}', 'memcpy(&exports_{group}, pexports_{group}, sizeof(exports_{group}));'.format( group=egroup), '', ) emitter.emit_lines( 'return module;', 'fail:', 'Py_XDECREF(module);', 'return NULL;', '}', ) def generate_globals_init(self, emitter: Emitter) -> None: emitter.emit_lines( '', 'int CPyGlobalsInit(void)', '{', 'static int is_initialized = 0;', 'if (is_initialized) return 0;', '' ) emitter.emit_line('CPy_Init();') for symbol, fixup in self.simple_inits: emitter.emit_line(f'{symbol} = {fixup};') values = 'CPyLit_Str, CPyLit_Bytes, CPyLit_Int, CPyLit_Float, CPyLit_Complex, CPyLit_Tuple' emitter.emit_lines(f'if (CPyStatics_Initialize(CPyStatics, {values}) < 0) {{', 'return -1;', '}') emitter.emit_lines( 'is_initialized = 1;', 'return 0;', '}', ) def generate_module_def(self, emitter: Emitter, module_name: str, module: ModuleIR) -> None: """Emit the PyModuleDef struct for a module and the module init function.""" # Emit module methods module_prefix = emitter.names.private_name(module_name) emitter.emit_line(f'static PyMethodDef {module_prefix}module_methods[] = {{') for fn in module.functions: if fn.class_name is not None or fn.name == TOP_LEVEL_NAME: continue name = short_id_from_name(fn.name, fn.decl.shortname, fn.line) if is_fastcall_supported(fn, emitter.capi_version): flag = 'METH_FASTCALL' else: flag = 'METH_VARARGS' emitter.emit_line( ('{{"{name}", (PyCFunction){prefix}{cname}, {flag} | METH_KEYWORDS, ' 'NULL /* docstring */}},').format( name=name, cname=fn.cname(emitter.names), prefix=PREFIX, flag=flag)) emitter.emit_line('{NULL, NULL, 0, NULL}') emitter.emit_line('};') emitter.emit_line() # Emit module definition struct emitter.emit_lines(f'static struct PyModuleDef {module_prefix}module = {{', 'PyModuleDef_HEAD_INIT,', f'"{module_name}",', 'NULL, /* docstring */', '-1, /* size of per-interpreter state of the module,', ' or -1 if the module keeps state in global variables. */', f'{module_prefix}module_methods', '};') emitter.emit_line() # Emit module init function. If we are compiling just one module, this # will be the C API init function. If we are compiling 2+ modules, we # generate a shared library for the modules and shims that call into # the shared library, and in this case we use an internal module # initialized function that will be called by the shim. if not self.use_shared_lib: declaration = f'PyMODINIT_FUNC PyInit_{module_name}(void)' else: declaration = f'PyObject *CPyInit_{exported_name(module_name)}(void)' emitter.emit_lines(declaration, '{') emitter.emit_line('PyObject* modname = NULL;') # Store the module reference in a static and return it when necessary. # This is separate from the *global* reference to the module that will # be populated when it is imported by a compiled module. We want that # reference to only be populated when the module has been successfully # imported, whereas this we want to have to stop a circular import. module_static = self.module_internal_static_name(module_name, emitter) emitter.emit_lines(f'if ({module_static}) {{', f'Py_INCREF({module_static});', f'return {module_static};', '}') emitter.emit_lines(f'{module_static} = PyModule_Create(&{module_prefix}module);', f'if (unlikely({module_static} == NULL))', ' goto fail;') emitter.emit_line( 'modname = PyObject_GetAttrString((PyObject *){}, "__name__");'.format( module_static)) module_globals = emitter.static_name('globals', module_name) emitter.emit_lines(f'{module_globals} = PyModule_GetDict({module_static});', f'if (unlikely({module_globals} == NULL))', ' goto fail;') # HACK: Manually instantiate generated classes here type_structs: List[str] = [] for cl in module.classes: type_struct = emitter.type_struct_name(cl) type_structs.append(type_struct) if cl.is_generated: emitter.emit_lines( '{t} = (PyTypeObject *)CPyType_FromTemplate(' '(PyObject *){t}_template, NULL, modname);' .format(t=type_struct)) emitter.emit_lines(f'if (unlikely(!{type_struct}))', ' goto fail;') emitter.emit_lines('if (CPyGlobalsInit() < 0)', ' goto fail;') self.generate_top_level_call(module, emitter) emitter.emit_lines('Py_DECREF(modname);') emitter.emit_line(f'return {module_static};') emitter.emit_lines('fail:', f'Py_CLEAR({module_static});', 'Py_CLEAR(modname);') for name, typ in module.final_names: static_name = emitter.static_name(name, module_name) emitter.emit_dec_ref(static_name, typ, is_xdec=True) undef = emitter.c_undefined_value(typ) emitter.emit_line(f'{static_name} = {undef};') # the type objects returned from CPyType_FromTemplate are all new references # so we have to decref them for t in type_structs: emitter.emit_line(f'Py_CLEAR({t});') emitter.emit_line('return NULL;') emitter.emit_line('}') def generate_top_level_call(self, module: ModuleIR, emitter: Emitter) -> None: """Generate call to function representing module top level.""" # Optimization: we tend to put the top level last, so reverse iterate for fn in reversed(module.functions): if fn.name == TOP_LEVEL_NAME: emitter.emit_lines( f'char result = {emitter.native_function_name(fn.decl)}();', 'if (result == 2)', ' goto fail;', ) break def toposort_declarations(self) -> List[HeaderDeclaration]: """Topologically sort the declaration dict by dependencies. Declarations can require other declarations to come prior in C (such as declaring structs). In order to guarantee that the C output will compile the declarations will thus need to be properly ordered. This simple DFS guarantees that we have a proper ordering. This runs in O(V + E). """ result = [] marked_declarations: Dict[str, MarkedDeclaration] = OrderedDict() for k, v in self.context.declarations.items(): marked_declarations[k] = MarkedDeclaration(v, False) def _toposort_visit(name: str) -> None: decl = marked_declarations[name] if decl.mark: return for child in decl.declaration.dependencies: _toposort_visit(child) result.append(decl.declaration) decl.mark = True for name, marked_declaration in marked_declarations.items(): _toposort_visit(name) return result def declare_global(self, type_spaced: str, name: str, *, initializer: Optional[str] = None) -> None: if '[' not in type_spaced: base = f'{type_spaced}{name}' else: a, b = type_spaced.split('[', 1) base = f'{a}{name}[{b}' if not initializer: defn = None else: defn = [f'{base} = {initializer};'] if name not in self.context.declarations: self.context.declarations[name] = HeaderDeclaration( f'{base};', defn=defn, ) def declare_internal_globals(self, module_name: str, emitter: Emitter) -> None: static_name = emitter.static_name('globals', module_name) self.declare_global('PyObject *', static_name) def module_internal_static_name(self, module_name: str, emitter: Emitter) -> str: return emitter.static_name(module_name + '_internal', None, prefix=MODULE_PREFIX) def declare_module(self, module_name: str, emitter: Emitter) -> None: # We declare two globals for each module: # one used internally in the implementation of module init to cache results # and prevent infinite recursion in import cycles, and one used # by other modules to refer to it. internal_static_name = self.module_internal_static_name(module_name, emitter) self.declare_global('CPyModule *', internal_static_name, initializer='NULL') static_name = emitter.static_name(module_name, None, prefix=MODULE_PREFIX) self.declare_global('CPyModule *', static_name) self.simple_inits.append((static_name, 'Py_None')) def declare_imports(self, imps: Iterable[str], emitter: Emitter) -> None: for imp in imps: self.declare_module(imp, emitter) def declare_finals( self, module: str, final_names: Iterable[Tuple[str, RType]], emitter: Emitter) -> None: for name, typ in final_names: static_name = emitter.static_name(name, module) emitter.context.declarations[static_name] = HeaderDeclaration( f'{emitter.ctype_spaced(typ)}{static_name};', [self.final_definition(module, name, typ, emitter)], needs_export=True) def final_definition( self, module: str, name: str, typ: RType, emitter: Emitter) -> str: static_name = emitter.static_name(name, module) # Here we rely on the fact that undefined value and error value are always the same if isinstance(typ, RTuple): # We need to inline because initializer must be static undefined = '{{ {} }}'.format(''.join(emitter.tuple_undefined_value_helper(typ))) else: undefined = emitter.c_undefined_value(typ) return f'{emitter.ctype_spaced(typ)}{static_name} = {undefined};' def declare_static_pyobject(self, identifier: str, emitter: Emitter) -> None: symbol = emitter.static_name(identifier, None) self.declare_global('PyObject *', symbol) def sort_classes(classes: List[Tuple[str, ClassIR]]) -> List[Tuple[str, ClassIR]]: mod_name = {ir: name for name, ir in classes} irs = [ir for _, ir in classes] deps: Dict[ClassIR, Set[ClassIR]] = OrderedDict() for ir in irs: if ir not in deps: deps[ir] = set() if ir.base: deps[ir].add(ir.base) deps[ir].update(ir.traits) sorted_irs = toposort(deps) return [(mod_name[ir], ir) for ir in sorted_irs] T = TypeVar('T') def toposort(deps: Dict[T, Set[T]]) -> List[T]: """Topologically sort a dict from item to dependencies. This runs in O(V + E). """ result = [] visited: Set[T] = set() def visit(item: T) -> None: if item in visited: return for child in deps[item]: visit(child) result.append(item) visited.add(item) for item in deps: visit(item) return result def is_fastcall_supported(fn: FuncIR, capi_version: Tuple[int, int]) -> bool: if fn.class_name is not None: if fn.name == '__call__': # We can use vectorcalls (PEP 590) when supported return use_vectorcall(capi_version) # TODO: Support fastcall for __init__. return use_fastcall(capi_version) and fn.name != '__init__' return use_fastcall(capi_version) def collect_literals(fn: FuncIR, literals: Literals) -> None: """Store all Python literal object refs in fn. Collecting literals must happen only after we have the final IR. This way we won't include literals that have been optimized away. """ for block in fn.blocks: for op in block.ops: if isinstance(op, LoadLiteral): literals.record_literal(op.value) def c_array_initializer(components: List[str]) -> str: """Construct an initializer for a C array variable. Components are C expressions valid in an initializer. For example, if components are ["1", "2"], the result would be "{1, 2}", which can be used like this: int a[] = {1, 2}; If the result is long, split it into multiple lines. """ res = [] current: List[str] = [] cur_len = 0 for c in components: if not current or cur_len + 2 + len(c) < 70: current.append(c) cur_len += len(c) + 2 else: res.append(', '.join(current)) current = [c] cur_len = len(c) if not res: # Result fits on a single line return '{%s}' % ', '.join(current) # Multi-line result res.append(', '.join(current)) return '{\n ' + ',\n '.join(res) + '\n}' def c_string_array_initializer(components: List[bytes]) -> str: result = [] result.append('{\n') for s in components: result.append(' ' + c_string_initializer(s) + ',\n') result.append('}') return ''.join(result)