/* +----------------------------------------------------------------------+ | HipHop for PHP | +----------------------------------------------------------------------+ | Copyright (c) 2010- Facebook, Inc. (http://www.facebook.com) | | Copyright (c) 1997-2010 The PHP Group | +----------------------------------------------------------------------+ | This source file is subject to version 3.01 of the PHP license, | | that is bundled with this package in the file LICENSE, and is | | available through the world-wide-web at the following url: | | http://www.php.net/license/3_01.txt | | If you did not receive a copy of the PHP license and are unable to | | obtain it through the world-wide-web, please send a note to | | license@php.net so we can mail you a copy immediately. | +----------------------------------------------------------------------+ */ #include #include #include #include #include #include #include namespace HPHP { /* HPHP::Variant HPHP::f_mcrypt_module_open(HPHP::String const&, HPHP::String const&, HPHP::String const&, HPHP::String const&) _ZN4HPHP20f_mcrypt_module_openERKNS_6StringES2_S2_S2_ (return value) => rax _rv => rdi algorithm => rsi algorithm_directory => rdx mode => rcx mode_directory => r8 */ TypedValue* fh_mcrypt_module_open(TypedValue* _rv, Value* algorithm, Value* algorithm_directory, Value* mode, Value* mode_directory) asm("_ZN4HPHP20f_mcrypt_module_openERKNS_6StringES2_S2_S2_"); TypedValue * fg1_mcrypt_module_open(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_open(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (!IS_STRING_TYPE((args-3)->m_type)) { tvCastToStringInPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_module_open((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_module_open(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 4LL) { if (IS_STRING_TYPE((args-3)->m_type) && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_module_open((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 4); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_open(&rv, ar, count); frame_free_locals_no_this_inl(ar, 4); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_open", count, 4, 4, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 4); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_module_close(HPHP::Object const&) _ZN4HPHP21f_mcrypt_module_closeERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_module_close(Value* td) asm("_ZN4HPHP21f_mcrypt_module_closeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_module_close(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_close(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_module_close(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_module_close(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_module_close(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_close(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_close", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Array HPHP::f_mcrypt_list_algorithms(HPHP::String const&) _ZN4HPHP24f_mcrypt_list_algorithmsERKNS_6StringE (return value) => rax _rv => rdi lib_dir => rsi */ Value* fh_mcrypt_list_algorithms(Value* _rv, Value* lib_dir) asm("_ZN4HPHP24f_mcrypt_list_algorithmsERKNS_6StringE"); TypedValue * fg1_mcrypt_list_algorithms(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_list_algorithms(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfArray; tvCastToStringInPlace(args-0); fh_mcrypt_list_algorithms((&rv->m_data), (count > 0) ? &args[-0].m_data : (Value*)(&null_string)); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_list_algorithms(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count <= 1LL) { if ((count <= 0 || IS_STRING_TYPE((args-0)->m_type))) { rv.m_type = KindOfArray; fh_mcrypt_list_algorithms((&rv.m_data), (count > 0) ? &args[-0].m_data : (Value*)(&null_string)); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_list_algorithms(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_toomany_arguments_nr("mcrypt_list_algorithms", 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Array HPHP::f_mcrypt_list_modes(HPHP::String const&) _ZN4HPHP19f_mcrypt_list_modesERKNS_6StringE (return value) => rax _rv => rdi lib_dir => rsi */ Value* fh_mcrypt_list_modes(Value* _rv, Value* lib_dir) asm("_ZN4HPHP19f_mcrypt_list_modesERKNS_6StringE"); TypedValue * fg1_mcrypt_list_modes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_list_modes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfArray; tvCastToStringInPlace(args-0); fh_mcrypt_list_modes((&rv->m_data), (count > 0) ? &args[-0].m_data : (Value*)(&null_string)); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_list_modes(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count <= 1LL) { if ((count <= 0 || IS_STRING_TYPE((args-0)->m_type))) { rv.m_type = KindOfArray; fh_mcrypt_list_modes((&rv.m_data), (count > 0) ? &args[-0].m_data : (Value*)(&null_string)); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_list_modes(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_toomany_arguments_nr("mcrypt_list_modes", 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_module_get_algo_block_size(HPHP::String const&, HPHP::String const&) _ZN4HPHP35f_mcrypt_module_get_algo_block_sizeERKNS_6StringES2_ (return value) => rax algorithm => rdi lib_dir => rsi */ long fh_mcrypt_module_get_algo_block_size(Value* algorithm, Value* lib_dir) asm("_ZN4HPHP35f_mcrypt_module_get_algo_block_sizeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_get_algo_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_get_algo_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (int64_t)fh_mcrypt_module_get_algo_block_size(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); return rv; } TypedValue* fg_mcrypt_module_get_algo_block_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_module_get_algo_block_size(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_get_algo_block_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_get_algo_block_size", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_module_get_algo_key_size(HPHP::String const&, HPHP::String const&) _ZN4HPHP33f_mcrypt_module_get_algo_key_sizeERKNS_6StringES2_ (return value) => rax algorithm => rdi lib_dir => rsi */ long fh_mcrypt_module_get_algo_key_size(Value* algorithm, Value* lib_dir) asm("_ZN4HPHP33f_mcrypt_module_get_algo_key_sizeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_get_algo_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_get_algo_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (int64_t)fh_mcrypt_module_get_algo_key_size(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); return rv; } TypedValue* fg_mcrypt_module_get_algo_key_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_module_get_algo_key_size(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_get_algo_key_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_get_algo_key_size", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Array HPHP::f_mcrypt_module_get_supported_key_sizes(HPHP::String const&, HPHP::String const&) _ZN4HPHP39f_mcrypt_module_get_supported_key_sizesERKNS_6StringES2_ (return value) => rax _rv => rdi algorithm => rsi lib_dir => rdx */ Value* fh_mcrypt_module_get_supported_key_sizes(Value* _rv, Value* algorithm, Value* lib_dir) asm("_ZN4HPHP39f_mcrypt_module_get_supported_key_sizesERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_get_supported_key_sizes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_get_supported_key_sizes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfArray; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_module_get_supported_key_sizes((&rv->m_data), &args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_module_get_supported_key_sizes(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfArray; fh_mcrypt_module_get_supported_key_sizes((&rv.m_data), &args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_get_supported_key_sizes(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_get_supported_key_sizes", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_module_is_block_algorithm_mode(HPHP::String const&, HPHP::String const&) _ZN4HPHP39f_mcrypt_module_is_block_algorithm_modeERKNS_6StringES2_ (return value) => rax mode => rdi lib_dir => rsi */ bool fh_mcrypt_module_is_block_algorithm_mode(Value* mode, Value* lib_dir) asm("_ZN4HPHP39f_mcrypt_module_is_block_algorithm_modeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_is_block_algorithm_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_is_block_algorithm_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (fh_mcrypt_module_is_block_algorithm_mode(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_module_is_block_algorithm_mode(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_module_is_block_algorithm_mode(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_is_block_algorithm_mode(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_is_block_algorithm_mode", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_module_is_block_algorithm(HPHP::String const&, HPHP::String const&) _ZN4HPHP34f_mcrypt_module_is_block_algorithmERKNS_6StringES2_ (return value) => rax algorithm => rdi lib_dir => rsi */ bool fh_mcrypt_module_is_block_algorithm(Value* algorithm, Value* lib_dir) asm("_ZN4HPHP34f_mcrypt_module_is_block_algorithmERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_is_block_algorithm(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_is_block_algorithm(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (fh_mcrypt_module_is_block_algorithm(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_module_is_block_algorithm(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_module_is_block_algorithm(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_is_block_algorithm(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_is_block_algorithm", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_module_is_block_mode(HPHP::String const&, HPHP::String const&) _ZN4HPHP29f_mcrypt_module_is_block_modeERKNS_6StringES2_ (return value) => rax mode => rdi lib_dir => rsi */ bool fh_mcrypt_module_is_block_mode(Value* mode, Value* lib_dir) asm("_ZN4HPHP29f_mcrypt_module_is_block_modeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_is_block_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_is_block_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (fh_mcrypt_module_is_block_mode(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_module_is_block_mode(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_module_is_block_mode(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_is_block_mode(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_is_block_mode", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_module_self_test(HPHP::String const&, HPHP::String const&) _ZN4HPHP25f_mcrypt_module_self_testERKNS_6StringES2_ (return value) => rax algorithm => rdi lib_dir => rsi */ bool fh_mcrypt_module_self_test(Value* algorithm, Value* lib_dir) asm("_ZN4HPHP25f_mcrypt_module_self_testERKNS_6StringES2_"); TypedValue * fg1_mcrypt_module_self_test(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_module_self_test(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (fh_mcrypt_module_self_test(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_module_self_test(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_module_self_test(&args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string))) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_module_self_test(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_module_self_test", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_create_iv(int, int) _ZN4HPHP18f_mcrypt_create_ivEii (return value) => rax _rv => rdi size => rsi source => rdx */ TypedValue* fh_mcrypt_create_iv(TypedValue* _rv, int size, int source) asm("_ZN4HPHP18f_mcrypt_create_ivEii"); TypedValue * fg1_mcrypt_create_iv(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_create_iv(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 2 if ((args-1)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-1); } case 1: break; } if ((args-0)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-0); } fh_mcrypt_create_iv((rv), (int)(args[-0].m_data.num), (count > 1) ? (int)(args[-1].m_data.num) : (int)(0)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_create_iv(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || (args-1)->m_type == KindOfInt64) && (args-0)->m_type == KindOfInt64) { fh_mcrypt_create_iv((&(rv)), (int)(args[-0].m_data.num), (count > 1) ? (int)(args[-1].m_data.num) : (int)(0)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_create_iv(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_create_iv", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_encrypt(HPHP::String const&, HPHP::String const&, HPHP::String const&, HPHP::String const&, HPHP::String const&) _ZN4HPHP16f_mcrypt_encryptERKNS_6StringES2_S2_S2_S2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_encrypt(TypedValue* _rv, Value* cipher, Value* key, Value* data, Value* mode, Value* iv) asm("_ZN4HPHP16f_mcrypt_encryptERKNS_6StringES2_S2_S2_S2_"); TypedValue * fg1_mcrypt_encrypt(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_encrypt(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if (!IS_STRING_TYPE((args-3)->m_type)) { tvCastToStringInPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_encrypt((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data, (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_encrypt(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && IS_STRING_TYPE((args-3)->m_type) && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_encrypt((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data, (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_encrypt(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_encrypt", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_decrypt(HPHP::String const&, HPHP::String const&, HPHP::String const&, HPHP::String const&, HPHP::String const&) _ZN4HPHP16f_mcrypt_decryptERKNS_6StringES2_S2_S2_S2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_decrypt(TypedValue* _rv, Value* cipher, Value* key, Value* data, Value* mode, Value* iv) asm("_ZN4HPHP16f_mcrypt_decryptERKNS_6StringES2_S2_S2_S2_"); TypedValue * fg1_mcrypt_decrypt(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_decrypt(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if (!IS_STRING_TYPE((args-3)->m_type)) { tvCastToStringInPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_decrypt((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data, (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_decrypt(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && IS_STRING_TYPE((args-3)->m_type) && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_decrypt((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, &args[-3].m_data, (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_decrypt(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_decrypt", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_cbc(HPHP::String const&, HPHP::String const&, HPHP::String const&, int, HPHP::String const&) _ZN4HPHP12f_mcrypt_cbcERKNS_6StringES2_S2_iS2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_cbc(TypedValue* _rv, Value* cipher, Value* key, Value* data, int mode, Value* iv) asm("_ZN4HPHP12f_mcrypt_cbcERKNS_6StringES2_S2_iS2_"); TypedValue * fg1_mcrypt_cbc(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_cbc(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if ((args-3)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_cbc((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_cbc(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && (args-3)->m_type == KindOfInt64 && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_cbc((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_cbc(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_cbc", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_cfb(HPHP::String const&, HPHP::String const&, HPHP::String const&, int, HPHP::String const&) _ZN4HPHP12f_mcrypt_cfbERKNS_6StringES2_S2_iS2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_cfb(TypedValue* _rv, Value* cipher, Value* key, Value* data, int mode, Value* iv) asm("_ZN4HPHP12f_mcrypt_cfbERKNS_6StringES2_S2_iS2_"); TypedValue * fg1_mcrypt_cfb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_cfb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if ((args-3)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_cfb((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_cfb(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && (args-3)->m_type == KindOfInt64 && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_cfb((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_cfb(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_cfb", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_ecb(HPHP::String const&, HPHP::String const&, HPHP::String const&, int, HPHP::String const&) _ZN4HPHP12f_mcrypt_ecbERKNS_6StringES2_S2_iS2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_ecb(TypedValue* _rv, Value* cipher, Value* key, Value* data, int mode, Value* iv) asm("_ZN4HPHP12f_mcrypt_ecbERKNS_6StringES2_S2_iS2_"); TypedValue * fg1_mcrypt_ecb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_ecb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if ((args-3)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_ecb((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_ecb(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && (args-3)->m_type == KindOfInt64 && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_ecb((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_ecb(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_ecb", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_ofb(HPHP::String const&, HPHP::String const&, HPHP::String const&, int, HPHP::String const&) _ZN4HPHP12f_mcrypt_ofbERKNS_6StringES2_S2_iS2_ (return value) => rax _rv => rdi cipher => rsi key => rdx data => rcx mode => r8 iv => r9 */ TypedValue* fh_mcrypt_ofb(TypedValue* _rv, Value* cipher, Value* key, Value* data, int mode, Value* iv) asm("_ZN4HPHP12f_mcrypt_ofbERKNS_6StringES2_S2_iS2_"); TypedValue * fg1_mcrypt_ofb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_ofb(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 5 if (!IS_STRING_TYPE((args-4)->m_type)) { tvCastToStringInPlace(args-4); } case 4: break; } if ((args-3)->m_type != KindOfInt64) { tvCastToInt64InPlace(args-3); } if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_ofb((rv), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_ofb(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 4LL && count <= 5LL) { if ((count <= 4 || IS_STRING_TYPE((args-4)->m_type)) && (args-3)->m_type == KindOfInt64 && IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_ofb((&(rv)), &args[-0].m_data, &args[-1].m_data, &args[-2].m_data, (int)(args[-3].m_data.num), (count > 4) ? &args[-4].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_ofb(&rv, ar, count); frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_ofb", count, 4, 5, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 5); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_get_block_size(HPHP::String const&, HPHP::String const&) _ZN4HPHP23f_mcrypt_get_block_sizeERKNS_6StringES2_ (return value) => rax _rv => rdi cipher => rsi module => rdx */ TypedValue* fh_mcrypt_get_block_size(TypedValue* _rv, Value* cipher, Value* module) asm("_ZN4HPHP23f_mcrypt_get_block_sizeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_get_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_get_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; switch (count) { default: // count >= 2 if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } case 1: break; } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_get_block_size((rv), &args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_get_block_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count >= 1LL && count <= 2LL) { if ((count <= 1 || IS_STRING_TYPE((args-1)->m_type)) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_get_block_size((&(rv)), &args[-0].m_data, (count > 1) ? &args[-1].m_data : (Value*)(&null_string)); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_get_block_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_get_block_size", count, 1, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_get_cipher_name(HPHP::String const&) _ZN4HPHP24f_mcrypt_get_cipher_nameERKNS_6StringE (return value) => rax _rv => rdi cipher => rsi */ TypedValue* fh_mcrypt_get_cipher_name(TypedValue* _rv, Value* cipher) asm("_ZN4HPHP24f_mcrypt_get_cipher_nameERKNS_6StringE"); TypedValue * fg1_mcrypt_get_cipher_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_get_cipher_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; tvCastToStringInPlace(args-0); fh_mcrypt_get_cipher_name((rv), &args[-0].m_data); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_get_cipher_name(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if (IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_get_cipher_name((&(rv)), &args[-0].m_data); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_get_cipher_name(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_get_cipher_name", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_get_iv_size(HPHP::String const&, HPHP::String const&) _ZN4HPHP20f_mcrypt_get_iv_sizeERKNS_6StringES2_ (return value) => rax _rv => rdi cipher => rsi mode => rdx */ TypedValue* fh_mcrypt_get_iv_size(TypedValue* _rv, Value* cipher, Value* mode) asm("_ZN4HPHP20f_mcrypt_get_iv_sizeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_get_iv_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_get_iv_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } fh_mcrypt_get_iv_size((rv), &args[-0].m_data, &args[-1].m_data); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_get_iv_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 2LL) { if (IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { fh_mcrypt_get_iv_size((&(rv)), &args[-0].m_data, &args[-1].m_data); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_get_iv_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_get_iv_size", count, 2, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_get_key_size(HPHP::String const&, HPHP::String const&) _ZN4HPHP21f_mcrypt_get_key_sizeERKNS_6StringES2_ (return value) => rax cipher => rdi module => rsi */ long fh_mcrypt_get_key_size(Value* cipher, Value* module) asm("_ZN4HPHP21f_mcrypt_get_key_sizeERKNS_6StringES2_"); TypedValue * fg1_mcrypt_get_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_get_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if (!IS_STRING_TYPE((args-0)->m_type)) { tvCastToStringInPlace(args-0); } rv->m_data.num = (int64_t)fh_mcrypt_get_key_size(&args[-0].m_data, &args[-1].m_data); return rv; } TypedValue* fg_mcrypt_get_key_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 2LL) { if (IS_STRING_TYPE((args-1)->m_type) && IS_STRING_TYPE((args-0)->m_type)) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_get_key_size(&args[-0].m_data, &args[-1].m_data); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_get_key_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_get_key_size", count, 2, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::String HPHP::f_mcrypt_enc_get_algorithms_name(HPHP::Object const&) _ZN4HPHP32f_mcrypt_enc_get_algorithms_nameERKNS_6ObjectE (return value) => rax _rv => rdi td => rsi */ Value* fh_mcrypt_enc_get_algorithms_name(Value* _rv, Value* td) asm("_ZN4HPHP32f_mcrypt_enc_get_algorithms_nameERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_algorithms_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_algorithms_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfString; tvCastToObjectInPlace(args-0); fh_mcrypt_enc_get_algorithms_name((&rv->m_data), &args[-0].m_data); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_enc_get_algorithms_name(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfString; fh_mcrypt_enc_get_algorithms_name((&rv.m_data), &args[-0].m_data); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_algorithms_name(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_algorithms_name", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_enc_get_block_size(HPHP::Object const&) _ZN4HPHP27f_mcrypt_enc_get_block_sizeERKNS_6ObjectE (return value) => rax td => rdi */ long fh_mcrypt_enc_get_block_size(Value* td) asm("_ZN4HPHP27f_mcrypt_enc_get_block_sizeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_block_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; tvCastToObjectInPlace(args-0); rv->m_data.num = (int64_t)fh_mcrypt_enc_get_block_size(&args[-0].m_data); return rv; } TypedValue* fg_mcrypt_enc_get_block_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_enc_get_block_size(&args[-0].m_data); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_block_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_block_size", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_enc_get_iv_size(HPHP::Object const&) _ZN4HPHP24f_mcrypt_enc_get_iv_sizeERKNS_6ObjectE (return value) => rax td => rdi */ long fh_mcrypt_enc_get_iv_size(Value* td) asm("_ZN4HPHP24f_mcrypt_enc_get_iv_sizeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_iv_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_iv_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; tvCastToObjectInPlace(args-0); rv->m_data.num = (int64_t)fh_mcrypt_enc_get_iv_size(&args[-0].m_data); return rv; } TypedValue* fg_mcrypt_enc_get_iv_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_enc_get_iv_size(&args[-0].m_data); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_iv_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_iv_size", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_enc_get_key_size(HPHP::Object const&) _ZN4HPHP25f_mcrypt_enc_get_key_sizeERKNS_6ObjectE (return value) => rax td => rdi */ long fh_mcrypt_enc_get_key_size(Value* td) asm("_ZN4HPHP25f_mcrypt_enc_get_key_sizeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_key_size(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; tvCastToObjectInPlace(args-0); rv->m_data.num = (int64_t)fh_mcrypt_enc_get_key_size(&args[-0].m_data); return rv; } TypedValue* fg_mcrypt_enc_get_key_size(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_enc_get_key_size(&args[-0].m_data); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_key_size(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_key_size", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::String HPHP::f_mcrypt_enc_get_modes_name(HPHP::Object const&) _ZN4HPHP27f_mcrypt_enc_get_modes_nameERKNS_6ObjectE (return value) => rax _rv => rdi td => rsi */ Value* fh_mcrypt_enc_get_modes_name(Value* _rv, Value* td) asm("_ZN4HPHP27f_mcrypt_enc_get_modes_nameERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_modes_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_modes_name(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfString; tvCastToObjectInPlace(args-0); fh_mcrypt_enc_get_modes_name((&rv->m_data), &args[-0].m_data); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_enc_get_modes_name(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfString; fh_mcrypt_enc_get_modes_name((&rv.m_data), &args[-0].m_data); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_modes_name(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_modes_name", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Array HPHP::f_mcrypt_enc_get_supported_key_sizes(HPHP::Object const&) _ZN4HPHP36f_mcrypt_enc_get_supported_key_sizesERKNS_6ObjectE (return value) => rax _rv => rdi td => rsi */ Value* fh_mcrypt_enc_get_supported_key_sizes(Value* _rv, Value* td) asm("_ZN4HPHP36f_mcrypt_enc_get_supported_key_sizesERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_get_supported_key_sizes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_get_supported_key_sizes(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfArray; tvCastToObjectInPlace(args-0); fh_mcrypt_enc_get_supported_key_sizes((&rv->m_data), &args[-0].m_data); if (rv->m_data.num == 0LL) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_enc_get_supported_key_sizes(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfArray; fh_mcrypt_enc_get_supported_key_sizes((&rv.m_data), &args[-0].m_data); if (rv.m_data.num == 0LL) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_get_supported_key_sizes(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_get_supported_key_sizes", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_enc_is_block_algorithm_mode(HPHP::Object const&) _ZN4HPHP36f_mcrypt_enc_is_block_algorithm_modeERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_enc_is_block_algorithm_mode(Value* td) asm("_ZN4HPHP36f_mcrypt_enc_is_block_algorithm_modeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_is_block_algorithm_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_is_block_algorithm_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_enc_is_block_algorithm_mode(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_enc_is_block_algorithm_mode(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_enc_is_block_algorithm_mode(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_is_block_algorithm_mode(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_is_block_algorithm_mode", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_enc_is_block_algorithm(HPHP::Object const&) _ZN4HPHP31f_mcrypt_enc_is_block_algorithmERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_enc_is_block_algorithm(Value* td) asm("_ZN4HPHP31f_mcrypt_enc_is_block_algorithmERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_is_block_algorithm(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_is_block_algorithm(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_enc_is_block_algorithm(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_enc_is_block_algorithm(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_enc_is_block_algorithm(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_is_block_algorithm(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_is_block_algorithm", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_enc_is_block_mode(HPHP::Object const&) _ZN4HPHP26f_mcrypt_enc_is_block_modeERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_enc_is_block_mode(Value* td) asm("_ZN4HPHP26f_mcrypt_enc_is_block_modeERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_is_block_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_is_block_mode(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_enc_is_block_mode(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_enc_is_block_mode(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_enc_is_block_mode(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_is_block_mode(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_is_block_mode", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_enc_self_test(HPHP::Object const&) _ZN4HPHP22f_mcrypt_enc_self_testERKNS_6ObjectE (return value) => rax td => rdi */ long fh_mcrypt_enc_self_test(Value* td) asm("_ZN4HPHP22f_mcrypt_enc_self_testERKNS_6ObjectE"); TypedValue * fg1_mcrypt_enc_self_test(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_enc_self_test(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; tvCastToObjectInPlace(args-0); rv->m_data.num = (int64_t)fh_mcrypt_enc_self_test(&args[-0].m_data); return rv; } TypedValue* fg_mcrypt_enc_self_test(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_enc_self_test(&args[-0].m_data); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_enc_self_test(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_enc_self_test", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mcrypt_generic(HPHP::Object const&, HPHP::String const&) _ZN4HPHP16f_mcrypt_genericERKNS_6ObjectERKNS_6StringE (return value) => rax _rv => rdi td => rsi data => rdx */ TypedValue* fh_mcrypt_generic(TypedValue* _rv, Value* td, Value* data) asm("_ZN4HPHP16f_mcrypt_genericERKNS_6ObjectERKNS_6StringE"); TypedValue * fg1_mcrypt_generic(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_generic(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if ((args-0)->m_type != KindOfObject) { tvCastToObjectInPlace(args-0); } fh_mcrypt_generic((rv), &args[-0].m_data, &args[-1].m_data); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mcrypt_generic(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 2LL) { if (IS_STRING_TYPE((args-1)->m_type) && (args-0)->m_type == KindOfObject) { fh_mcrypt_generic((&(rv)), &args[-0].m_data, &args[-1].m_data); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_generic(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_generic", count, 2, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* long HPHP::f_mcrypt_generic_init(HPHP::Object const&, HPHP::String const&, HPHP::String const&) _ZN4HPHP21f_mcrypt_generic_initERKNS_6ObjectERKNS_6StringES5_ (return value) => rax td => rdi key => rsi iv => rdx */ long fh_mcrypt_generic_init(Value* td, Value* key, Value* iv) asm("_ZN4HPHP21f_mcrypt_generic_initERKNS_6ObjectERKNS_6StringES5_"); TypedValue * fg1_mcrypt_generic_init(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_generic_init(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfInt64; if (!IS_STRING_TYPE((args-2)->m_type)) { tvCastToStringInPlace(args-2); } if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if ((args-0)->m_type != KindOfObject) { tvCastToObjectInPlace(args-0); } rv->m_data.num = (int64_t)fh_mcrypt_generic_init(&args[-0].m_data, &args[-1].m_data, &args[-2].m_data); return rv; } TypedValue* fg_mcrypt_generic_init(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 3LL) { if (IS_STRING_TYPE((args-2)->m_type) && IS_STRING_TYPE((args-1)->m_type) && (args-0)->m_type == KindOfObject) { rv.m_type = KindOfInt64; rv.m_data.num = (int64_t)fh_mcrypt_generic_init(&args[-0].m_data, &args[-1].m_data, &args[-2].m_data); frame_free_locals_no_this_inl(ar, 3); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_generic_init(&rv, ar, count); frame_free_locals_no_this_inl(ar, 3); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_generic_init", count, 3, 3, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 3); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* HPHP::Variant HPHP::f_mdecrypt_generic(HPHP::Object const&, HPHP::String const&) _ZN4HPHP18f_mdecrypt_genericERKNS_6ObjectERKNS_6StringE (return value) => rax _rv => rdi td => rsi data => rdx */ TypedValue* fh_mdecrypt_generic(TypedValue* _rv, Value* td, Value* data) asm("_ZN4HPHP18f_mdecrypt_genericERKNS_6ObjectERKNS_6StringE"); TypedValue * fg1_mdecrypt_generic(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mdecrypt_generic(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (!IS_STRING_TYPE((args-1)->m_type)) { tvCastToStringInPlace(args-1); } if ((args-0)->m_type != KindOfObject) { tvCastToObjectInPlace(args-0); } fh_mdecrypt_generic((rv), &args[-0].m_data, &args[-1].m_data); if (rv->m_type == KindOfUninit) rv->m_type = KindOfNull; return rv; } TypedValue* fg_mdecrypt_generic(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 2LL) { if (IS_STRING_TYPE((args-1)->m_type) && (args-0)->m_type == KindOfObject) { fh_mdecrypt_generic((&(rv)), &args[-0].m_data, &args[-1].m_data); if (rv.m_type == KindOfUninit) rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mdecrypt_generic(&rv, ar, count); frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mdecrypt_generic", count, 2, 2, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 2); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_generic_deinit(HPHP::Object const&) _ZN4HPHP23f_mcrypt_generic_deinitERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_generic_deinit(Value* td) asm("_ZN4HPHP23f_mcrypt_generic_deinitERKNS_6ObjectE"); TypedValue * fg1_mcrypt_generic_deinit(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_generic_deinit(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_generic_deinit(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_generic_deinit(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_generic_deinit(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_generic_deinit(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_generic_deinit", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } /* bool HPHP::f_mcrypt_generic_end(HPHP::Object const&) _ZN4HPHP20f_mcrypt_generic_endERKNS_6ObjectE (return value) => rax td => rdi */ bool fh_mcrypt_generic_end(Value* td) asm("_ZN4HPHP20f_mcrypt_generic_endERKNS_6ObjectE"); TypedValue * fg1_mcrypt_generic_end(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) __attribute__((noinline,cold)); TypedValue * fg1_mcrypt_generic_end(TypedValue* rv, HPHP::VM::ActRec* ar, int64_t count) { TypedValue* args UNUSED = ((TypedValue*)ar) - 1; rv->m_type = KindOfBoolean; tvCastToObjectInPlace(args-0); rv->m_data.num = (fh_mcrypt_generic_end(&args[-0].m_data)) ? 1LL : 0LL; return rv; } TypedValue* fg_mcrypt_generic_end(HPHP::VM::ActRec *ar) { TypedValue rv; int64_t count = ar->numArgs(); TypedValue* args UNUSED = ((TypedValue*)ar) - 1; if (count == 1LL) { if ((args-0)->m_type == KindOfObject) { rv.m_type = KindOfBoolean; rv.m_data.num = (fh_mcrypt_generic_end(&args[-0].m_data)) ? 1LL : 0LL; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } else { fg1_mcrypt_generic_end(&rv, ar, count); frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; } } else { throw_wrong_arguments_nr("mcrypt_generic_end", count, 1, 1, 1); } rv.m_data.num = 0LL; rv.m_type = KindOfNull; frame_free_locals_no_this_inl(ar, 1); memcpy(&ar->m_r, &rv, sizeof(TypedValue)); return &ar->m_r; return &ar->m_r; } } // !HPHP