/** * @file basic_functions.c * @author Ambroz Bizjak * * @section LICENSE * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. Neither the name of the author nor the * names of its contributors may be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include // Trivial functions. static void error_eval (NCDCall call) { FunctionLog(&call, BLOG_ERROR, "error: failing"); } static void identity_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 1) { return FunctionLog(&call, BLOG_ERROR, "identity: need one argument"); } NCDCall_SetResult(&call, NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call))); } // Logical functions. static void if_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 3) { return FunctionLog(&call, BLOG_ERROR, "if: need three arguments"); } NCDValRef cond = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(cond)) { return; } int cond_val; if (!ncd_read_boolean(cond, &cond_val)) { return FunctionLog(&call, BLOG_ERROR, "if: bad condition"); } int eval_arg = 2 - cond_val; NCDCall_SetResult(&call, NCDCall_EvalArg(&call, eval_arg, NCDCall_ResMem(&call))); } static void ifel_eval (NCDCall call) { size_t count = NCDCall_ArgCount(&call); if (count % 2 == 0) { return FunctionLog(&call, BLOG_ERROR, "ifel: need an odd number of arguments"); } NCDValRef value; size_t j = 0; while (1) { NCDValRef arg = NCDCall_EvalArg(&call, j, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } if (j == count - 1) { value = arg; break; } NCDValRef arg2 = NCDCall_EvalArg(&call, j + 1, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg2)) { return; } int arg_val; if (!ncd_read_boolean(arg, &arg_val)) { return FunctionLog(&call, BLOG_ERROR, "ifel: bad condition"); } if (arg_val) { value = arg2; break; } j += 2; } NCDCall_SetResult(&call, value); } static void bool_not_eval (NCDCall call, int negate, char const *name) { if (NCDCall_ArgCount(&call) != 1) { return FunctionLog(&call, BLOG_ERROR, "%s: need one argument", name); } NCDValRef arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } int arg_val; if (!ncd_read_boolean(arg, &arg_val)) { return FunctionLog(&call, BLOG_ERROR, "%s: bad argument", name); } int res = (arg_val != negate); NCDCall_SetResult(&call, ncd_make_boolean(NCDCall_ResMem(&call), res, NCDCall_Iparams(&call)->string_index)); } static void bool_eval (NCDCall call) { return bool_not_eval(call, 0, "bool"); } static void not_eval (NCDCall call) { return bool_not_eval(call, 1, "not"); } static void and_or_eval (NCDCall call, int is_and, char const *name) { size_t count = NCDCall_ArgCount(&call); int res = is_and; for (size_t i = 0; i < count; i++) { NCDValRef arg = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } int arg_val; if (!ncd_read_boolean(arg, &arg_val)) { return FunctionLog(&call, BLOG_ERROR, "%s: bad argument", name); } if (arg_val != is_and) { res = !is_and; break; } } NCDCall_SetResult(&call, ncd_make_boolean(NCDCall_ResMem(&call), res, NCDCall_Iparams(&call)->string_index)); } static void and_eval (NCDCall call) { return and_or_eval(call, 1, "and"); } static void or_eval (NCDCall call) { return and_or_eval(call, 0, "or"); } static void imp_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 2) { return FunctionLog(&call, BLOG_ERROR, "imp: need two arguments"); } int res = 0; for (size_t i = 0; i < 2; i++) { NCDValRef arg = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } int arg_val; if (!ncd_read_boolean(arg, &arg_val)) { return FunctionLog(&call, BLOG_ERROR, "imp: bad argument"); } if (arg_val == i) { res = 1; break; } } NCDCall_SetResult(&call, ncd_make_boolean(NCDCall_ResMem(&call), res, NCDCall_Iparams(&call)->string_index)); } // Value comparison functions. typedef int (*value_compare_func) (int cmp); static void value_compare_eval (NCDCall call, value_compare_func func) { if (NCDCall_ArgCount(&call) != 2) { return FunctionLog(&call, BLOG_ERROR, "value_compare: need two arguments"); } NCDValRef vals[2]; for (int i = 0; i < 2; i++) { vals[i] = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(vals[i])) { return; } } int res = func(NCDVal_Compare(vals[0], vals[1])); NCDCall_SetResult(&call, ncd_make_boolean(NCDCall_ResMem(&call), res, NCDCall_Iparams(&call)->string_index)); } #define DEFINE_VALUE_COMPARE(name, expr) \ static int value_compare_##name##_func (int cmp) { return expr; } \ static void value_compare_##name##_eval (NCDCall call) { return value_compare_eval(call, value_compare_##name##_func); } DEFINE_VALUE_COMPARE(lesser, (cmp < 0)) DEFINE_VALUE_COMPARE(greater, (cmp > 0)) DEFINE_VALUE_COMPARE(lesser_equal, (cmp <= 0)) DEFINE_VALUE_COMPARE(greater_equal, (cmp >= 0)) DEFINE_VALUE_COMPARE(equal, (cmp == 0)) DEFINE_VALUE_COMPARE(different, (cmp != 0)) // Concatenation functions. static int concat_recurser (ExpString *estr, NCDValRef arg, NCDCall const *call) { if (NCDVal_IsString(arg)) { if (!ExpString_AppendBinaryMr(estr, NCDVal_StringMemRef(arg))) { FunctionLog(call, BLOG_ERROR, "ExpString_AppendBinaryMr failed"); return 0; } } else if (NCDVal_IsList(arg)) { size_t count = NCDVal_ListCount(arg); for (size_t i = 0; i < count; i++) { if (!concat_recurser(estr, NCDVal_ListGet(arg, i), call)) { return 0; } } } else { FunctionLog(call, BLOG_ERROR, "concat: value is not a string or list"); return 0; } return 1; } static void concat_eval (NCDCall call) { ExpString estr; if (!ExpString_Init(&estr)) { FunctionLog(&call, BLOG_ERROR, "ExpString_Init failed"); goto fail0; } size_t count = NCDCall_ArgCount(&call); for (size_t i = 0; i < count; i++) { NCDValRef arg = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { goto fail1; } if (!concat_recurser(&estr, arg, &call)) { goto fail1; } } NCDCall_SetResult(&call, NCDVal_NewStringBinMr(NCDCall_ResMem(&call), ExpString_GetMr(&estr))); fail1: ExpString_Free(&estr); fail0: return; } static void concatlist_eval (NCDCall call) { NCDValRef args_list; if (!ncd_eval_func_args(&call, NCDCall_ResMem(&call), &args_list)) { return; } size_t arg_count = NCDVal_ListCount(args_list); bsize_t elem_count = bsize_fromsize(0); for (size_t i = 0; i < arg_count; i++) { NCDValRef arg = NCDVal_ListGet(args_list, i); if (!NCDVal_IsList(arg)) { return FunctionLog(&call, BLOG_ERROR, "concatlist: argument is not a list"); } elem_count = bsize_add(elem_count, bsize_fromsize(NCDVal_ListCount(arg))); } if (elem_count.is_overflow) { return FunctionLog(&call, BLOG_ERROR, "concatlist: count overflow"); } NCDValRef res = NCDVal_NewList(NCDCall_ResMem(&call), elem_count.value); if (NCDVal_IsInvalid(res)) { return; } for (size_t i = 0; i < arg_count; i++) { NCDValRef arg = NCDVal_ListGet(args_list, i); size_t arg_list_count = NCDVal_ListCount(arg); for (size_t j = 0; j < arg_list_count; j++) { NCDValRef copy = NCDVal_NewCopy(NCDCall_ResMem(&call), NCDVal_ListGet(arg, j)); if (NCDVal_IsInvalid(copy)) { return; } if (!NCDVal_ListAppend(res, copy)) { return; } } } NCDCall_SetResult(&call, res); } // Integer comparison functions. typedef int (*integer_compare_func) (uintmax_t n1, uintmax_t n2); static void integer_compare_eval (NCDCall call, integer_compare_func func) { if (NCDCall_ArgCount(&call) != 2) { return FunctionLog(&call, BLOG_ERROR, "integer_compare: need two arguments"); } uintmax_t ints[2]; for (int i = 0; i < 2; i++) { NCDValRef arg = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } if (!ncd_read_uintmax(arg, &ints[i])) { return FunctionLog(&call, BLOG_ERROR, "integer_compare: wrong value"); } } int res = func(ints[0], ints[1]); NCDCall_SetResult(&call, ncd_make_boolean(NCDCall_ResMem(&call), res, NCDCall_Iparams(&call)->string_index)); } #define DEFINE_INT_COMPARE(name, expr) \ static int integer_compare_##name##_func (uintmax_t n1, uintmax_t n2) { return expr; } \ static void integer_compare_##name##_eval (NCDCall call) { return integer_compare_eval(call, integer_compare_##name##_func); } DEFINE_INT_COMPARE(lesser, (n1 < n2)) DEFINE_INT_COMPARE(greater, (n1 > n2)) DEFINE_INT_COMPARE(lesser_equal, (n1 <= n2)) DEFINE_INT_COMPARE(greater_equal, (n1 >= n2)) DEFINE_INT_COMPARE(equal, (n1 == n2)) DEFINE_INT_COMPARE(different, (n1 != n2)) // Integer operators. typedef int (*integer_operator_func) (uintmax_t n1, uintmax_t n2, uintmax_t *out, NCDCall const *call); static void integer_operator_eval (NCDCall call, integer_operator_func func) { if (NCDCall_ArgCount(&call) != 2) { return FunctionLog(&call, BLOG_ERROR, "integer_operator: need two arguments"); } uintmax_t ints[2]; for (int i = 0; i < 2; i++) { NCDValRef arg = NCDCall_EvalArg(&call, i, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } if (!ncd_read_uintmax(arg, &ints[i])) { return FunctionLog(&call, BLOG_ERROR, "integer_operator: wrong value"); } } uintmax_t res; if (!func(ints[0], ints[1], &res, &call)) { return; } NCDCall_SetResult(&call, ncd_make_uintmax(NCDCall_ResMem(&call), res)); } #define DEFINE_INT_OPERATOR(name, expr, check_expr, check_err_str) \ static int integer_operator_##name##_func (uintmax_t n1, uintmax_t n2, uintmax_t *out, NCDCall const *call) \ { \ if (check_expr) { \ FunctionLog(call, BLOG_ERROR, check_err_str); \ return 0; \ } \ *out = expr; \ return 1; \ } \ static void integer_operator_##name##_eval (NCDCall call) { return integer_operator_eval(call, integer_operator_##name##_func); } DEFINE_INT_OPERATOR(add, (n1 + n2), (n1 > UINTMAX_MAX - n2), "addition overflow") DEFINE_INT_OPERATOR(subtract, (n1 - n2), (n1 < n2), "subtraction underflow") DEFINE_INT_OPERATOR(multiply, (n1 * n2), (n2 != 0 && n1 > UINTMAX_MAX / n2), "multiplication overflow") DEFINE_INT_OPERATOR(divide, (n1 / n2), (n2 == 0), "division quotient is zero") DEFINE_INT_OPERATOR(modulo, (n1 % n2), (n2 == 0), "modulo modulus is zero") DEFINE_INT_OPERATOR(min, (n1 < n2 ? n1 : n2), (0), "") DEFINE_INT_OPERATOR(max, (n1 > n2 ? n1 : n2), (0), "") // Encode and decode value. static void encode_value_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 1) { return FunctionLog(&call, BLOG_ERROR, "encode_value: need one argument"); } NCDValRef arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } char *str = NCDValGenerator_Generate(arg); if (!str) { return FunctionLog(&call, BLOG_ERROR, "encode_value: NCDValGenerator_Generate failed"); } NCDCall_SetResult(&call, NCDVal_NewString(NCDCall_ResMem(&call), str)); free(str); } static void decode_value_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 1) { return FunctionLog(&call, BLOG_ERROR, "decode_value: need one argument"); } // Evaluate the string to a temporary mem, not ResMem. // Otherwise the ResMem could get resized while we're // parsing a string within it, and boom. NCDValMem temp_mem; NCDValMem_Init(&temp_mem); NCDValRef arg = NCDCall_EvalArg(&call, 0, &temp_mem); if (NCDVal_IsInvalid(arg)) { goto fail1; } if (!NCDVal_IsString(arg)) { FunctionLog(&call, BLOG_ERROR, "decode_value: argument not a string"); goto fail1; } NCDValRef value; int res = NCDValParser_Parse(NCDVal_StringMemRef(arg), NCDCall_ResMem(&call), &value); if (!res) { FunctionLog(&call, BLOG_ERROR, "decode_value: NCDValParser_Parse failed"); goto fail1; } NCDCall_SetResult(&call, value); fail1: NCDValMem_Free(&temp_mem); } // ASCII case conversion typedef char (*perchar_func) (char ch); static void perchar_eval (NCDCall call, perchar_func func) { if (NCDCall_ArgCount(&call) != 1) { return FunctionLog(&call, BLOG_ERROR, "tolower: need one argument"); } NCDValRef arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { return; } if (!NCDVal_IsString(arg)) { return FunctionLog(&call, BLOG_ERROR, "tolower: argument not a string"); } NCDValRef value = NCDVal_NewStringUninitialized(NCDCall_ResMem(&call), NCDVal_StringLength(arg)); if (NCDVal_IsInvalid(value)) { return; } char *out_data = (char *)NCDVal_StringData(value); MEMREF_LOOP_CHARS(NCDVal_StringMemRef(arg), i, ch, { out_data[i] = func(ch); }) NCDCall_SetResult(&call, value); } #define DEFINE_PERCHAR(name, expr) \ static char perchar_##name##_func (char ch) { return expr; } \ static void perchar_##name##_eval (NCDCall call) { return perchar_eval(call, perchar_##name##_func); } DEFINE_PERCHAR(tolower, b_ascii_tolower(ch)) DEFINE_PERCHAR(toupper, b_ascii_toupper(ch)) // struct_encode, struct_decode static int read_integer_encoding (NCDValRef encoding, int *out_big, int *out_size) { if (!NCDVal_IsString(encoding)) { return 0; } int big; int size; if (NCDVal_StringEquals(encoding, "u8")) { big = 0; size = 1; } else if ((big = NCDVal_StringEquals(encoding, "u16b")) || NCDVal_StringEquals(encoding, "u16l")) { size = 2; } else if ((big = NCDVal_StringEquals(encoding, "u32b")) || NCDVal_StringEquals(encoding, "u32l")) { size = 4; } else if ((big = NCDVal_StringEquals(encoding, "u64b")) || NCDVal_StringEquals(encoding, "u64l")) { size = 8; } else { return 0; } *out_big = big; *out_size = size; return 1; } static int struct_encode_single (NCDCall call, ExpString *estr, NCDValRef encoding, NCDValRef value) { uintmax_t val_int; if (!ncd_read_uintmax(value, &val_int)) { FunctionLog(&call, BLOG_ERROR, "struct_encode: value must be an integer"); return 0; } int big; int size; if (!read_integer_encoding(encoding, &big, &size)) { FunctionLog(&call, BLOG_ERROR, "struct_encode: invalid encoding specified"); return 0; } uint8_t results[8]; for (int i = 0; i < size; i++) { results[big ? (size - 1 - i) : i] = val_int; val_int >>= 8; } if (val_int > 0) { FunctionLog(&call, BLOG_ERROR, "struct_encode: value is out of range"); return 0; } if (!ExpString_AppendBinaryMr(estr, MemRef_Make((char const *)results, size))) { FunctionLog(&call, BLOG_ERROR, "ExpString_AppendBinaryMr failed"); return 0; } return 1; } static void struct_encode_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 1) { FunctionLog(&call, BLOG_ERROR, "struct_encode: need one argument"); goto fail0; } NCDValRef arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(arg)) { goto fail0; } if (!NCDVal_IsList(arg)) { FunctionLog(&call, BLOG_ERROR, "struct_encode: argument must be a list"); goto fail0; } ExpString estr; if (!ExpString_Init(&estr)) { FunctionLog(&call, BLOG_ERROR, "ExpString_Init failed"); goto fail0; } size_t count = NCDVal_ListCount(arg); for (size_t i = 0; i < count; i++) { NCDValRef elem = NCDVal_ListGet(arg, i); if (!NCDVal_IsList(elem)) { FunctionLog(&call, BLOG_ERROR, "struct_encode: element must be a list"); goto fail1; } NCDValRef encoding; NCDValRef value; if (!NCDVal_ListRead(elem, 2, &encoding, &value)) { FunctionLog(&call, BLOG_ERROR, "struct_encode: element list must have two elements"); goto fail1; } if (!struct_encode_single(call, &estr, encoding, value)) { goto fail1; } } NCDCall_SetResult(&call, NCDVal_NewStringBinMr(NCDCall_ResMem(&call), ExpString_GetMr(&estr))); fail1: ExpString_Free(&estr); fail0: return; } static int struct_decode_single (NCDCall call, MemRef *data, NCDValRef encoding, NCDValRef result_list) { int big; int size; if (!read_integer_encoding(encoding, &big, &size)) { FunctionLog(&call, BLOG_ERROR, "struct_decode: invalid encoding specified"); return 0; } if (data->len < size) { FunctionLog(&call, BLOG_ERROR, "struct_decode: insufficient data available"); return 0; } uintmax_t val_int = 0; for (int i = 0; i < size; i++) { val_int <<= 8; val_int |= *(uint8_t const *)(data->ptr + (big ? i : (size - 1 - i))); } *data = MemRef_SubFrom(*data, size); NCDValRef value = ncd_make_uintmax(NCDCall_ResMem(&call), val_int); if (NCDVal_IsInvalid(value)) { return 0; } if (!NCDVal_ListAppend(result_list, value)) { return 0; } return 1; } static void struct_decode_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 2) { FunctionLog(&call, BLOG_ERROR, "struct_decode: need two arguments"); goto fail0; } NCDValRef format_arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(format_arg)) { goto fail0; } if (!NCDVal_IsList(format_arg)) { FunctionLog(&call, BLOG_ERROR, "struct_decode: format argument must be a list"); goto fail0; } // Evaluate the data string to temp mem, so the pointer doesn't change. NCDValMem temp_mem; NCDValMem_Init(&temp_mem); NCDValRef data_arg = NCDCall_EvalArg(&call, 1, &temp_mem); if (NCDVal_IsInvalid(data_arg)) { goto fail1; } if (!NCDVal_IsString(data_arg)) { FunctionLog(&call, BLOG_ERROR, "struct_decode: data argument must be a string"); goto fail1; } size_t count = NCDVal_ListCount(format_arg); NCDValRef result_list = NCDVal_NewList(NCDCall_ResMem(&call), count); if (NCDVal_IsInvalid(result_list)) { goto fail1; } MemRef data = NCDVal_StringMemRef(data_arg); for (size_t i = 0; i < count; i++) { NCDValRef encoding = NCDVal_ListGet(format_arg, i); if (!struct_decode_single(call, &data, encoding, result_list)) { goto fail1; } } if (data.len > 0) { FunctionLog(&call, BLOG_ERROR, "struct_decode: not all data was consumed"); goto fail1; } NCDCall_SetResult(&call, result_list); fail1: NCDValMem_Free(&temp_mem); fail0: return; } // checksum static void checksum_eval (NCDCall call) { if (NCDCall_ArgCount(&call) != 2) { FunctionLog(&call, BLOG_ERROR, "checksum: need two arguments"); return; } NCDValRef algorithm_arg = NCDCall_EvalArg(&call, 0, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(algorithm_arg)) { return; } if (!NCDVal_IsString(algorithm_arg)) { FunctionLog(&call, BLOG_ERROR, "checksum: algorithm argument must be a string"); return; } NCDValRef data_arg = NCDCall_EvalArg(&call, 1, NCDCall_ResMem(&call)); if (NCDVal_IsInvalid(data_arg)) { return; } if (!NCDVal_IsString(data_arg)) { FunctionLog(&call, BLOG_ERROR, "checksum: data argument must be a string"); return; } MemRef data = NCDVal_StringMemRef(data_arg); uintmax_t result; if (NCDVal_StringEquals(algorithm_arg, "inverted_sum_bytes")) { uint8_t s = 0; for (size_t i = 0; i < data.len; i++) { s += *(uint8_t const *)(data.ptr + i); } result = (uint8_t)~s; } else { FunctionLog(&call, BLOG_ERROR, "checksum: unknown algorithm"); return; } NCDCall_SetResult(&call, ncd_make_uintmax(NCDCall_ResMem(&call), result)); } static struct NCDModuleFunction const functions[] = { { .func_name = "error", .func_eval = error_eval }, { .func_name = "identity", .func_eval = identity_eval }, { .func_name = "if", .func_eval = if_eval }, { .func_name = "ifel", .func_eval = ifel_eval }, { .func_name = "bool", .func_eval = bool_eval }, { .func_name = "not", .func_eval = not_eval }, { .func_name = "and", .func_eval = and_eval }, { .func_name = "or", .func_eval = or_eval }, { .func_name = "imp", .func_eval = imp_eval }, { .func_name = "val_lesser", .func_eval = value_compare_lesser_eval }, { .func_name = "val_greater", .func_eval = value_compare_greater_eval }, { .func_name = "val_lesser_equal", .func_eval = value_compare_lesser_equal_eval }, { .func_name = "val_greater_equal", .func_eval = value_compare_greater_equal_eval }, { .func_name = "val_equal", .func_eval = value_compare_equal_eval }, { .func_name = "val_different", .func_eval = value_compare_different_eval }, { .func_name = "concat", .func_eval = concat_eval }, { .func_name = "concatlist", .func_eval = concatlist_eval }, { .func_name = "num_lesser", .func_eval = integer_compare_lesser_eval }, { .func_name = "num_greater", .func_eval = integer_compare_greater_eval }, { .func_name = "num_lesser_equal", .func_eval = integer_compare_lesser_equal_eval }, { .func_name = "num_greater_equal", .func_eval = integer_compare_greater_equal_eval }, { .func_name = "num_equal", .func_eval = integer_compare_equal_eval }, { .func_name = "num_different", .func_eval = integer_compare_different_eval }, { .func_name = "num_add", .func_eval = integer_operator_add_eval }, { .func_name = "num_subtract", .func_eval = integer_operator_subtract_eval }, { .func_name = "num_multiply", .func_eval = integer_operator_multiply_eval }, { .func_name = "num_divide", .func_eval = integer_operator_divide_eval }, { .func_name = "num_modulo", .func_eval = integer_operator_modulo_eval }, { .func_name = "num_min", .func_eval = integer_operator_min_eval }, { .func_name = "num_max", .func_eval = integer_operator_max_eval }, { .func_name = "encode_value", .func_eval = encode_value_eval }, { .func_name = "decode_value", .func_eval = decode_value_eval }, { .func_name = "tolower", .func_eval = perchar_tolower_eval }, { .func_name = "toupper", .func_eval = perchar_toupper_eval }, { .func_name = "struct_encode", .func_eval = struct_encode_eval }, { .func_name = "struct_decode", .func_eval = struct_decode_eval }, { .func_name = "checksum", .func_eval = checksum_eval }, { .func_name = NULL } }; const struct NCDModuleGroup ncdmodule_basic_functions = { .functions = functions };