#!/usr/bin/env python import os import re import sys output_template = '''\ /* Automatically generated by generate_psa_constant.py. DO NOT EDIT. */ static const char *psa_strerror(psa_status_t status) { switch (status) { %(status_cases)s default: return NULL; } } static const char *psa_ecc_curve_name(psa_ecc_curve_t curve) { switch (curve) { %(ecc_curve_cases)s default: return NULL; } } static const char *psa_hash_algorithm_name(psa_algorithm_t hash_alg) { switch (hash_alg) { %(hash_algorithm_cases)s default: return NULL; } } static int psa_snprint_key_type(char *buffer, size_t buffer_size, psa_key_type_t type) { size_t required_size = 0; switch (type) { %(key_type_cases)s default: %(key_type_code)s{ return snprintf(buffer, buffer_size, "0x%%08lx", (unsigned long) type); } break; } buffer[0] = 0; return (int) required_size; } static int psa_snprint_algorithm(char *buffer, size_t buffer_size, psa_algorithm_t alg) { size_t required_size = 0; psa_algorithm_t core_alg = alg; unsigned long length_modifier = 0; if (PSA_ALG_IS_MAC(alg)) { core_alg = PSA_ALG_TRUNCATED_MAC(alg, 0); if (core_alg != alg) { append(&buffer, buffer_size, &required_size, "PSA_ALG_TRUNCATED_MAC(", 22); length_modifier = PSA_MAC_TRUNCATED_LENGTH(alg); } } else if (PSA_ALG_IS_AEAD(alg)) { core_alg = PSA_ALG_AEAD_WITH_DEFAULT_TAG_LENGTH(alg); if (core_alg != alg) { append(&buffer, buffer_size, &required_size, "PSA_ALG_AEAD_WITH_TAG_LENGTH(", 29); length_modifier = PSA_AEAD_TAG_LENGTH(alg); } } switch (core_alg) { %(algorithm_cases)s default: %(algorithm_code)s{ append_integer(&buffer, buffer_size, &required_size, "0x%%08lx", (unsigned long) alg); } break; } if (core_alg != alg) { append(&buffer, buffer_size, &required_size, ", ", 2); append_integer(&buffer, buffer_size, &required_size, "%%lu", length_modifier); append(&buffer, buffer_size, &required_size, ")", 1); } buffer[0] = 0; return (int) required_size; } static int psa_snprint_key_usage(char *buffer, size_t buffer_size, psa_key_usage_t usage) { size_t required_size = 0; if (usage == 0) { if (buffer_size > 1) { buffer[0] = '0'; buffer[1] = 0; } else if (buffer_size == 1) { buffer[0] = 0; } return 1; } %(key_usage_code)s if (usage != 0) { if (required_size != 0) { append(&buffer, buffer_size, &required_size, " | ", 3); } append_integer(&buffer, buffer_size, &required_size, "0x%%08lx", (unsigned long) usage); } else { buffer[0] = 0; } return (int) required_size; } /* End of automatically generated file. */ ''' key_type_from_curve_template = '''if (%(tester)s(type)) { append_with_curve(&buffer, buffer_size, &required_size, "%(builder)s", %(builder_length)s, PSA_KEY_TYPE_GET_CURVE(type)); } else ''' algorithm_from_hash_template = '''if (%(tester)s(core_alg)) { append_with_hash(&buffer, buffer_size, &required_size, "%(builder)s", %(builder_length)s, PSA_ALG_GET_HASH(core_alg)); } else ''' bit_test_template = '''\ if (%(var)s & %(flag)s) { if (required_size != 0) { append(&buffer, buffer_size, &required_size, " | ", 3); } append(&buffer, buffer_size, &required_size, "%(flag)s", %(length)d); %(var)s ^= %(flag)s; }\ ''' class MacroCollector: def __init__(self): self.statuses = set() self.key_types = set() self.key_types_from_curve = {} self.ecc_curves = set() self.algorithms = set() self.hash_algorithms = set() self.algorithms_from_hash = {} self.key_usages = set() # "#define" followed by a macro name with either no parameters # or a single parameter. Grab the macro name in group 1, the # parameter name if any in group 2 and the definition in group 3. definition_re = re.compile(r'\s*#\s*define\s+(\w+)(?:\s+|\((\w+)\)\s*)(.+)(?:/[*/])?') def read_line(self, line): m = re.match(self.definition_re, line) if not m: return name, parameter, definition = m.groups() if name.endswith('_FLAG') or name.endswith('MASK'): # Macro only to build actual values return elif (name.startswith('PSA_ERROR_') or name == 'PSA_SUCCESS') \ and not parameter: self.statuses.add(name) elif name.startswith('PSA_KEY_TYPE_') and not parameter: self.key_types.add(name) elif name.startswith('PSA_KEY_TYPE_') and parameter == 'curve': self.key_types_from_curve[name] = name[:13] + 'IS_' + name[13:] elif name.startswith('PSA_ECC_CURVE_') and not parameter: self.ecc_curves.add(name) elif name.startswith('PSA_ALG_') and not parameter: if name in ['PSA_ALG_ECDSA_BASE', 'PSA_ALG_RSA_PKCS1V15_SIGN_BASE']: # Ad hoc skipping of duplicate names for some numerical values return self.algorithms.add(name) # Ad hoc detection of hash algorithms if re.search(r'0x010000[0-9A-Fa-f]{2}', definition): self.hash_algorithms.add(name) elif name.startswith('PSA_ALG_') and parameter == 'hash_alg': if name in ['PSA_ALG_DSA', 'PSA_ALG_ECDSA']: # A naming irregularity tester = name[:8] + 'IS_RANDOMIZED_' + name[8:] else: tester = name[:8] + 'IS_' + name[8:] self.algorithms_from_hash[name] = tester elif name.startswith('PSA_KEY_USAGE_') and not parameter: self.key_usages.add(name) else: # Other macro without parameter return def read_file(self, header_file): for line in header_file: self.read_line(line) def make_return_case(self, name): return 'case %(name)s: return "%(name)s";' % {'name': name} def make_append_case(self, name): template = ('case %(name)s: ' 'append(&buffer, buffer_size, &required_size, "%(name)s", %(length)d); ' 'break;') return template % {'name': name, 'length': len(name)} def make_inner_append_case(self, name): template = ('case %(name)s: ' 'append(buffer, buffer_size, required_size, "%(name)s", %(length)d); ' 'break;') return template % {'name': name, 'length': len(name)} def make_bit_test(self, var, flag): return bit_test_template % {'var': var, 'flag': flag, 'length': len(flag)} def make_status_cases(self): return '\n '.join(map(self.make_return_case, sorted(self.statuses))) def make_ecc_curve_cases(self): return '\n '.join(map(self.make_return_case, sorted(self.ecc_curves))) def make_key_type_cases(self): return '\n '.join(map(self.make_append_case, sorted(self.key_types))) def make_key_type_from_curve_code(self, builder, tester): return key_type_from_curve_template % {'builder': builder, 'builder_length': len(builder), 'tester': tester} def make_key_type_code(self): d = self.key_types_from_curve make = self.make_key_type_from_curve_code return ''.join([make(k, d[k]) for k in sorted(d.keys())]) def make_hash_algorithm_cases(self): return '\n '.join(map(self.make_return_case, sorted(self.hash_algorithms))) def make_algorithm_cases(self): return '\n '.join(map(self.make_append_case, sorted(self.algorithms))) def make_algorithm_from_hash_code(self, builder, tester): return algorithm_from_hash_template % {'builder': builder, 'builder_length': len(builder), 'tester': tester} def make_algorithm_code(self): d = self.algorithms_from_hash make = self.make_algorithm_from_hash_code return ''.join([make(k, d[k]) for k in sorted(d.keys())]) def make_key_usage_code(self): return '\n'.join([self.make_bit_test('usage', bit) for bit in sorted(self.key_usages)]) def write_file(self, output_file): data = {} data['status_cases'] = self.make_status_cases() data['ecc_curve_cases'] = self.make_ecc_curve_cases() data['key_type_cases'] = self.make_key_type_cases() data['key_type_code'] = self.make_key_type_code() data['hash_algorithm_cases'] = self.make_hash_algorithm_cases() data['algorithm_cases'] = self.make_algorithm_cases() data['algorithm_code'] = self.make_algorithm_code() data['key_usage_code'] = self.make_key_usage_code() output_file.write(output_template % data) def generate_psa_constants(header_file_name, output_file_name): collector = MacroCollector() with open(header_file_name) as header_file: collector.read_file(header_file) temp_file_name = output_file_name + '.tmp' with open(temp_file_name, 'w') as output_file: collector.write_file(output_file) os.rename(temp_file_name, output_file_name) if __name__ == '__main__': if not os.path.isdir('programs') and os.path.isdir('../programs'): os.chdir('..') generate_psa_constants('include/psa/crypto.h', 'programs/psa/psa_constant_names_generated.c')