Mercurial > vim
view src/vim9type.c @ 22670:1ec5fdb8244e
Added tag v8.2.1883 for changeset 3ceb24835183301af44a0b9d8bd37b112ed962b4
author | Bram Moolenaar <Bram@vim.org> |
---|---|
date | Wed, 21 Oct 2020 21:15:04 +0200 |
parents | 4c21f7f6f9e3 |
children | af26fadf333d |
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/* vi:set ts=8 sts=4 sw=4 noet: * * VIM - Vi IMproved by Bram Moolenaar * * Do ":help uganda" in Vim to read copying and usage conditions. * Do ":help credits" in Vim to see a list of people who contributed. * See README.txt for an overview of the Vim source code. */ /* * vim9type.c: handling of types */ #define USING_FLOAT_STUFF #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) #ifdef VMS # include <float.h> #endif /* * Allocate memory for a type_T and add the pointer to type_gap, so that it can * be easily freed later. */ type_T * get_type_ptr(garray_T *type_gap) { type_T *type; if (ga_grow(type_gap, 1) == FAIL) return NULL; type = ALLOC_CLEAR_ONE(type_T); if (type != NULL) { ((type_T **)type_gap->ga_data)[type_gap->ga_len] = type; ++type_gap->ga_len; } return type; } void clear_type_list(garray_T *gap) { while (gap->ga_len > 0) vim_free(((type_T **)gap->ga_data)[--gap->ga_len]); ga_clear(gap); } /* * Take a type that is using entries in a growarray and turn it into a type * with allocated entries. */ type_T * alloc_type(type_T *type) { type_T *ret; if (type == NULL) return NULL; // A fixed type never contains allocated types, return as-is. if (type->tt_flags & TTFLAG_STATIC) return type; ret = ALLOC_ONE(type_T); *ret = *type; if (ret->tt_member != NULL) ret->tt_member = alloc_type(ret->tt_member); if (type->tt_args != NULL) { int i; ret->tt_args = ALLOC_MULT(type_T *, type->tt_argcount); if (ret->tt_args != NULL) for (i = 0; i < type->tt_argcount; ++i) ret->tt_args[i] = alloc_type(type->tt_args[i]); } return ret; } /* * Free a type that was created with alloc_type(). */ void free_type(type_T *type) { int i; if (type == NULL || (type->tt_flags & TTFLAG_STATIC)) return; if (type->tt_args != NULL) { for (i = 0; i < type->tt_argcount; ++i) free_type(type->tt_args[i]); vim_free(type->tt_args); } free_type(type->tt_member); vim_free(type); } type_T * get_list_type(type_T *member_type, garray_T *type_gap) { type_T *type; // recognize commonly used types if (member_type->tt_type == VAR_ANY) return &t_list_any; if (member_type->tt_type == VAR_VOID || member_type->tt_type == VAR_UNKNOWN) return &t_list_empty; if (member_type->tt_type == VAR_BOOL) return &t_list_bool; if (member_type->tt_type == VAR_NUMBER) return &t_list_number; if (member_type->tt_type == VAR_STRING) return &t_list_string; // Not a common type, create a new entry. type = get_type_ptr(type_gap); if (type == NULL) return &t_any; type->tt_type = VAR_LIST; type->tt_member = member_type; type->tt_argcount = 0; type->tt_args = NULL; return type; } type_T * get_dict_type(type_T *member_type, garray_T *type_gap) { type_T *type; // recognize commonly used types if (member_type->tt_type == VAR_ANY) return &t_dict_any; if (member_type->tt_type == VAR_VOID || member_type->tt_type == VAR_UNKNOWN) return &t_dict_empty; if (member_type->tt_type == VAR_BOOL) return &t_dict_bool; if (member_type->tt_type == VAR_NUMBER) return &t_dict_number; if (member_type->tt_type == VAR_STRING) return &t_dict_string; // Not a common type, create a new entry. type = get_type_ptr(type_gap); if (type == NULL) return &t_any; type->tt_type = VAR_DICT; type->tt_member = member_type; type->tt_argcount = 0; type->tt_args = NULL; return type; } /* * Allocate a new type for a function. */ type_T * alloc_func_type(type_T *ret_type, int argcount, garray_T *type_gap) { type_T *type = get_type_ptr(type_gap); if (type == NULL) return &t_any; type->tt_type = VAR_FUNC; type->tt_member = ret_type; type->tt_argcount = argcount; type->tt_args = NULL; return type; } /* * Get a function type, based on the return type "ret_type". * If "argcount" is -1 or 0 a predefined type can be used. * If "argcount" > 0 always create a new type, so that arguments can be added. */ type_T * get_func_type(type_T *ret_type, int argcount, garray_T *type_gap) { // recognize commonly used types if (argcount <= 0) { if (ret_type == &t_unknown) { // (argcount == 0) is not possible return &t_func_unknown; } if (ret_type == &t_void) { if (argcount == 0) return &t_func_0_void; else return &t_func_void; } if (ret_type == &t_any) { if (argcount == 0) return &t_func_0_any; else return &t_func_any; } if (ret_type == &t_number) { if (argcount == 0) return &t_func_0_number; else return &t_func_number; } if (ret_type == &t_string) { if (argcount == 0) return &t_func_0_string; else return &t_func_string; } } return alloc_func_type(ret_type, argcount, type_gap); } /* * For a function type, reserve space for "argcount" argument types (including * vararg). */ int func_type_add_arg_types( type_T *functype, int argcount, garray_T *type_gap) { // To make it easy to free the space needed for the argument types, add the // pointer to type_gap. if (ga_grow(type_gap, 1) == FAIL) return FAIL; functype->tt_args = ALLOC_CLEAR_MULT(type_T *, argcount); if (functype->tt_args == NULL) return FAIL; ((type_T **)type_gap->ga_data)[type_gap->ga_len] = (void *)functype->tt_args; ++type_gap->ga_len; return OK; } /* * Get a type_T for a typval_T. * "type_gap" is used to temporarily create types in. */ static type_T * typval2type_int(typval_T *tv, garray_T *type_gap) { type_T *type; type_T *member_type = &t_any; int argcount = 0; if (tv->v_type == VAR_NUMBER) return &t_number; if (tv->v_type == VAR_BOOL) return &t_bool; if (tv->v_type == VAR_STRING) return &t_string; if (tv->v_type == VAR_LIST) { list_T *l = tv->vval.v_list; listitem_T *li; if (l == NULL || l->lv_first == NULL) return &t_list_empty; if (l->lv_first == &range_list_item) return &t_list_number; // Use the common type of all members. member_type = typval2type(&l->lv_first->li_tv, type_gap); for (li = l->lv_first->li_next; li != NULL; li = li->li_next) common_type(typval2type(&li->li_tv, type_gap), member_type, &member_type, type_gap); return get_list_type(member_type, type_gap); } if (tv->v_type == VAR_DICT) { dict_iterator_T iter; typval_T *value; if (tv->vval.v_dict == NULL || tv->vval.v_dict->dv_hashtab.ht_used == 0) return &t_dict_empty; // Use the common type of all values. dict_iterate_start(tv, &iter); dict_iterate_next(&iter, &value); member_type = typval2type(value, type_gap); while (dict_iterate_next(&iter, &value) != NULL) common_type(typval2type(value, type_gap), member_type, &member_type, type_gap); return get_dict_type(member_type, type_gap); } if (tv->v_type == VAR_FUNC || tv->v_type == VAR_PARTIAL) { char_u *name = NULL; ufunc_T *ufunc = NULL; if (tv->v_type == VAR_PARTIAL) { if (tv->vval.v_partial->pt_func != NULL) ufunc = tv->vval.v_partial->pt_func; else name = tv->vval.v_partial->pt_name; } else name = tv->vval.v_string; if (name != NULL) { int idx = find_internal_func(name); if (idx >= 0) { // TODO: get actual arg count and types argcount = -1; member_type = internal_func_ret_type(idx, 0, NULL); } else ufunc = find_func(name, FALSE, NULL); } if (ufunc != NULL) { // May need to get the argument types from default values by // compiling the function. if (ufunc->uf_def_status == UF_TO_BE_COMPILED && compile_def_function(ufunc, TRUE, NULL) == FAIL) return NULL; if (ufunc->uf_func_type != NULL) return ufunc->uf_func_type; } } type = get_type_ptr(type_gap); if (type == NULL) return NULL; type->tt_type = tv->v_type; type->tt_argcount = argcount; type->tt_member = member_type; return type; } /* * Return TRUE if "tv" is not a bool but should be converted to bool. */ int need_convert_to_bool(type_T *type, typval_T *tv) { return type != NULL && type == &t_bool && tv->v_type != VAR_BOOL && (tv->v_type == VAR_NUMBER && (tv->vval.v_number == 0 || tv->vval.v_number == 1)); } /* * Get a type_T for a typval_T. * "type_list" is used to temporarily create types in. */ type_T * typval2type(typval_T *tv, garray_T *type_gap) { type_T *type = typval2type_int(tv, type_gap); if (type != NULL && type != &t_bool && (tv->v_type == VAR_NUMBER && (tv->vval.v_number == 0 || tv->vval.v_number == 1))) { type_T *newtype = get_type_ptr(type_gap); // Number 0 and 1 and expression with "&&" or "||" can also be used // for bool. if (newtype != NULL) { *newtype = *type; newtype->tt_flags = TTFLAG_BOOL_OK; type = newtype; } } return type; } /* * Get a type_T for a typval_T, used for v: variables. * "type_list" is used to temporarily create types in. */ type_T * typval2type_vimvar(typval_T *tv, garray_T *type_gap) { if (tv->v_type == VAR_LIST) // e.g. for v:oldfiles return &t_list_string; if (tv->v_type == VAR_DICT) // e.g. for v:completed_item return &t_dict_any; return typval2type(tv, type_gap); } /* * Return FAIL if "expected" and "actual" don't match. */ int check_typval_type(type_T *expected, typval_T *actual_tv, int argidx) { garray_T type_list; type_T *actual_type; int res = FAIL; ga_init2(&type_list, sizeof(type_T *), 10); actual_type = typval2type(actual_tv, &type_list); if (actual_type != NULL) res = check_type(expected, actual_type, TRUE, argidx); clear_type_list(&type_list); return res; } void type_mismatch(type_T *expected, type_T *actual) { arg_type_mismatch(expected, actual, 0); } void arg_type_mismatch(type_T *expected, type_T *actual, int argidx) { char *tofree1, *tofree2; char *typename1 = type_name(expected, &tofree1); char *typename2 = type_name(actual, &tofree2); if (argidx > 0) semsg(_(e_argument_nr_type_mismatch_expected_str_but_got_str), argidx, typename1, typename2); else semsg(_(e_type_mismatch_expected_str_but_got_str), typename1, typename2); vim_free(tofree1); vim_free(tofree2); } /* * Check if the expected and actual types match. * Does not allow for assigning "any" to a specific type. * When "argidx" > 0 it is included in the error message. */ int check_type(type_T *expected, type_T *actual, int give_msg, int argidx) { int ret = OK; // When expected is "unknown" we accept any actual type. // When expected is "any" we accept any actual type except "void". if (expected->tt_type != VAR_UNKNOWN && !(expected->tt_type == VAR_ANY && actual->tt_type != VAR_VOID)) { // tt_type should match, except that a "partial" can be assigned to a // variable with type "func". if (!(expected->tt_type == actual->tt_type || (expected->tt_type == VAR_FUNC && actual->tt_type == VAR_PARTIAL))) { if (expected->tt_type == VAR_BOOL && (actual->tt_flags & TTFLAG_BOOL_OK)) // Using number 0 or 1 for bool is OK. return OK; if (give_msg) arg_type_mismatch(expected, actual, argidx); return FAIL; } if (expected->tt_type == VAR_DICT || expected->tt_type == VAR_LIST) { // "unknown" is used for an empty list or dict if (actual->tt_member != &t_unknown) ret = check_type(expected->tt_member, actual->tt_member, FALSE, 0); } else if (expected->tt_type == VAR_FUNC) { if (expected->tt_member != &t_unknown) ret = check_type(expected->tt_member, actual->tt_member, FALSE, 0); if (ret == OK && expected->tt_argcount != -1 && actual->tt_argcount != -1 && (actual->tt_argcount < expected->tt_min_argcount || actual->tt_argcount > expected->tt_argcount)) ret = FAIL; if (expected->tt_args != NULL && actual->tt_args != NULL) { int i; for (i = 0; i < expected->tt_argcount; ++i) // Allow for using "any" argument type, lambda's have them. if (actual->tt_args[i] != &t_any && check_type( expected->tt_args[i], actual->tt_args[i], FALSE, 0) == FAIL) { ret = FAIL; break; } } } if (ret == FAIL && give_msg) arg_type_mismatch(expected, actual, argidx); } return ret; } /* * Skip over a type definition and return a pointer to just after it. * When "optional" is TRUE then a leading "?" is accepted. */ char_u * skip_type(char_u *start, int optional) { char_u *p = start; if (optional && *p == '?') ++p; while (ASCII_ISALNUM(*p) || *p == '_') ++p; // Skip over "<type>"; this is permissive about white space. if (*skipwhite(p) == '<') { p = skipwhite(p); p = skip_type(skipwhite(p + 1), FALSE); p = skipwhite(p); if (*p == '>') ++p; } else if ((*p == '(' || (*p == ':' && VIM_ISWHITE(p[1]))) && STRNCMP("func", start, 4) == 0) { if (*p == '(') { // handle func(args): type ++p; while (*p != ')' && *p != NUL) { char_u *sp = p; if (STRNCMP(p, "...", 3) == 0) p += 3; p = skip_type(p, TRUE); if (p == sp) return p; // syntax error if (*p == ',') p = skipwhite(p + 1); } if (*p == ')') { if (p[1] == ':') p = skip_type(skipwhite(p + 2), FALSE); else ++p; } } else { // handle func: return_type p = skip_type(skipwhite(p + 1), FALSE); } } return p; } /* * Parse the member type: "<type>" and return "type" with the member set. * Use "type_gap" if a new type needs to be added. * Returns NULL in case of failure. */ static type_T * parse_type_member(char_u **arg, type_T *type, garray_T *type_gap) { type_T *member_type; int prev_called_emsg = called_emsg; if (**arg != '<') { if (*skipwhite(*arg) == '<') semsg(_(e_no_white_space_allowed_before_str), "<"); else emsg(_(e_missing_type)); return type; } *arg = skipwhite(*arg + 1); member_type = parse_type(arg, type_gap); *arg = skipwhite(*arg); if (**arg != '>' && called_emsg == prev_called_emsg) { emsg(_(e_missing_gt_after_type)); return type; } ++*arg; if (type->tt_type == VAR_LIST) return get_list_type(member_type, type_gap); return get_dict_type(member_type, type_gap); } /* * Parse a type at "arg" and advance over it. * Return &t_any for failure. */ type_T * parse_type(char_u **arg, garray_T *type_gap) { char_u *p = *arg; size_t len; // skip over the first word while (ASCII_ISALNUM(*p) || *p == '_') ++p; len = p - *arg; switch (**arg) { case 'a': if (len == 3 && STRNCMP(*arg, "any", len) == 0) { *arg += len; return &t_any; } break; case 'b': if (len == 4 && STRNCMP(*arg, "bool", len) == 0) { *arg += len; return &t_bool; } if (len == 4 && STRNCMP(*arg, "blob", len) == 0) { *arg += len; return &t_blob; } break; case 'c': if (len == 7 && STRNCMP(*arg, "channel", len) == 0) { *arg += len; return &t_channel; } break; case 'd': if (len == 4 && STRNCMP(*arg, "dict", len) == 0) { *arg += len; return parse_type_member(arg, &t_dict_any, type_gap); } break; case 'f': if (len == 5 && STRNCMP(*arg, "float", len) == 0) { #ifdef FEAT_FLOAT *arg += len; return &t_float; #else emsg(_(e_this_vim_is_not_compiled_with_float_support)); return &t_any; #endif } if (len == 4 && STRNCMP(*arg, "func", len) == 0) { type_T *type; type_T *ret_type = &t_unknown; int argcount = -1; int flags = 0; int first_optional = -1; type_T *arg_type[MAX_FUNC_ARGS + 1]; // func({type}, ...{type}): {type} *arg += len; if (**arg == '(') { // "func" may or may not return a value, "func()" does // not return a value. ret_type = &t_void; p = ++*arg; argcount = 0; while (*p != NUL && *p != ')') { if (*p == '?') { if (first_optional == -1) first_optional = argcount; ++p; } else if (STRNCMP(p, "...", 3) == 0) { flags |= TTFLAG_VARARGS; p += 3; } else if (first_optional != -1) { emsg(_(e_mandatory_argument_after_optional_argument)); return &t_any; } arg_type[argcount++] = parse_type(&p, type_gap); // Nothing comes after "...{type}". if (flags & TTFLAG_VARARGS) break; if (*p != ',' && *skipwhite(p) == ',') { semsg(_(e_no_white_space_allowed_before_str), ","); return &t_any; } if (*p == ',') { ++p; if (!VIM_ISWHITE(*p)) { semsg(_(e_white_space_required_after_str), ","); return &t_any; } } p = skipwhite(p); if (argcount == MAX_FUNC_ARGS) { emsg(_(e_too_many_argument_types)); return &t_any; } } p = skipwhite(p); if (*p != ')') { emsg(_(e_missing_close)); return &t_any; } *arg = p + 1; } if (**arg == ':') { // parse return type ++*arg; if (!VIM_ISWHITE(**arg)) semsg(_(e_white_space_required_after_str), ":"); *arg = skipwhite(*arg); ret_type = parse_type(arg, type_gap); } if (flags == 0 && first_optional == -1 && argcount <= 0) type = get_func_type(ret_type, argcount, type_gap); else { type = alloc_func_type(ret_type, argcount, type_gap); type->tt_flags = flags; if (argcount > 0) { type->tt_argcount = argcount; type->tt_min_argcount = first_optional == -1 ? argcount : first_optional; if (func_type_add_arg_types(type, argcount, type_gap) == FAIL) return &t_any; mch_memmove(type->tt_args, arg_type, sizeof(type_T *) * argcount); } } return type; } break; case 'j': if (len == 3 && STRNCMP(*arg, "job", len) == 0) { *arg += len; return &t_job; } break; case 'l': if (len == 4 && STRNCMP(*arg, "list", len) == 0) { *arg += len; return parse_type_member(arg, &t_list_any, type_gap); } break; case 'n': if (len == 6 && STRNCMP(*arg, "number", len) == 0) { *arg += len; return &t_number; } break; case 's': if (len == 6 && STRNCMP(*arg, "string", len) == 0) { *arg += len; return &t_string; } break; case 'v': if (len == 4 && STRNCMP(*arg, "void", len) == 0) { *arg += len; return &t_void; } break; } semsg(_(e_type_not_recognized_str), *arg); return &t_any; } /* * Check if "type1" and "type2" are exactly the same. */ static int equal_type(type_T *type1, type_T *type2) { int i; if (type1->tt_type != type2->tt_type) return FALSE; switch (type1->tt_type) { case VAR_UNKNOWN: case VAR_ANY: case VAR_VOID: case VAR_SPECIAL: case VAR_BOOL: case VAR_NUMBER: case VAR_FLOAT: case VAR_STRING: case VAR_BLOB: case VAR_JOB: case VAR_CHANNEL: break; // not composite is always OK case VAR_LIST: case VAR_DICT: return equal_type(type1->tt_member, type2->tt_member); case VAR_FUNC: case VAR_PARTIAL: if (!equal_type(type1->tt_member, type2->tt_member) || type1->tt_argcount != type2->tt_argcount) return FALSE; if (type1->tt_argcount < 0 || type1->tt_args == NULL || type2->tt_args == NULL) return TRUE; for (i = 0; i < type1->tt_argcount; ++i) if (!equal_type(type1->tt_args[i], type2->tt_args[i])) return FALSE; return TRUE; } return TRUE; } /* * Find the common type of "type1" and "type2" and put it in "dest". * "type2" and "dest" may be the same. */ void common_type(type_T *type1, type_T *type2, type_T **dest, garray_T *type_gap) { if (equal_type(type1, type2)) { *dest = type1; return; } // If either is VAR_UNKNOWN use the other type. An empty list/dict has no // specific type. if (type1->tt_type == VAR_UNKNOWN) { *dest = type2; return; } if (type2->tt_type == VAR_UNKNOWN) { *dest = type1; return; } if (type1->tt_type == type2->tt_type) { if (type1->tt_type == VAR_LIST || type2->tt_type == VAR_DICT) { type_T *common; common_type(type1->tt_member, type2->tt_member, &common, type_gap); if (type1->tt_type == VAR_LIST) *dest = get_list_type(common, type_gap); else *dest = get_dict_type(common, type_gap); return; } if (type1->tt_type == VAR_FUNC) { type_T *common; common_type(type1->tt_member, type2->tt_member, &common, type_gap); if (type1->tt_argcount == type2->tt_argcount && type1->tt_argcount >= 0) { int argcount = type1->tt_argcount; int i; *dest = alloc_func_type(common, argcount, type_gap); if (type1->tt_args != NULL && type2->tt_args != NULL) { if (func_type_add_arg_types(*dest, argcount, type_gap) == OK) for (i = 0; i < argcount; ++i) common_type(type1->tt_args[i], type2->tt_args[i], &(*dest)->tt_args[i], type_gap); } } else *dest = alloc_func_type(common, -1, type_gap); // Use the minimum of min_argcount. (*dest)->tt_min_argcount = type1->tt_min_argcount < type2->tt_min_argcount ? type1->tt_min_argcount : type2->tt_min_argcount; return; } } *dest = &t_any; } /* * Get the member type of a dict or list from the items on the stack. * "stack_top" points just after the last type on the type stack. * For a list "skip" is 1, for a dict "skip" is 2, keys are skipped. * Returns &t_void for an empty list or dict. * Otherwise finds the common type of all items. */ type_T * get_member_type_from_stack( type_T **stack_top, int count, int skip, garray_T *type_gap) { int i; type_T *result; type_T *type; // Use "any" for an empty list or dict. if (count == 0) return &t_unknown; // Use the first value type for the list member type, then find the common // type from following items. result = *(stack_top -(count * skip) + skip - 1); for (i = 1; i < count; ++i) { if (result == &t_any) break; // won't get more common type = *(stack_top -((count - i) * skip) + skip - 1); common_type(type, result, &result, type_gap); } return result; } char * vartype_name(vartype_T type) { switch (type) { case VAR_UNKNOWN: break; case VAR_ANY: return "any"; case VAR_VOID: return "void"; case VAR_SPECIAL: return "special"; case VAR_BOOL: return "bool"; case VAR_NUMBER: return "number"; case VAR_FLOAT: return "float"; case VAR_STRING: return "string"; case VAR_BLOB: return "blob"; case VAR_JOB: return "job"; case VAR_CHANNEL: return "channel"; case VAR_LIST: return "list"; case VAR_DICT: return "dict"; case VAR_FUNC: case VAR_PARTIAL: return "func"; } return "unknown"; } /* * Return the name of a type. * The result may be in allocated memory, in which case "tofree" is set. */ char * type_name(type_T *type, char **tofree) { char *name = vartype_name(type->tt_type); *tofree = NULL; if (type->tt_type == VAR_LIST || type->tt_type == VAR_DICT) { char *member_free; char *member_name = type_name(type->tt_member, &member_free); size_t len; len = STRLEN(name) + STRLEN(member_name) + 3; *tofree = alloc(len); if (*tofree != NULL) { vim_snprintf(*tofree, len, "%s<%s>", name, member_name); vim_free(member_free); return *tofree; } } if (type->tt_type == VAR_FUNC) { garray_T ga; int i; int varargs = (type->tt_flags & TTFLAG_VARARGS) ? 1 : 0; ga_init2(&ga, 1, 100); if (ga_grow(&ga, 20) == FAIL) return "[unknown]"; STRCPY(ga.ga_data, "func("); ga.ga_len += 5; for (i = 0; i < type->tt_argcount; ++i) { char *arg_free; char *arg_type; int len; if (type->tt_args == NULL) arg_type = "[unknown]"; else arg_type = type_name(type->tt_args[i], &arg_free); if (i > 0) { STRCPY((char *)ga.ga_data + ga.ga_len, ", "); ga.ga_len += 2; } len = (int)STRLEN(arg_type); if (ga_grow(&ga, len + 8) == FAIL) { vim_free(arg_free); ga_clear(&ga); return "[unknown]"; } if (varargs && i == type->tt_argcount - 1) ga_concat(&ga, (char_u *)"..."); else if (i >= type->tt_min_argcount) *((char *)ga.ga_data + ga.ga_len++) = '?'; ga_concat(&ga, (char_u *)arg_type); vim_free(arg_free); } if (type->tt_argcount < 0) // any number of arguments ga_concat(&ga, (char_u *)"..."); if (type->tt_member == &t_void) STRCPY((char *)ga.ga_data + ga.ga_len, ")"); else { char *ret_free; char *ret_name = type_name(type->tt_member, &ret_free); int len; len = (int)STRLEN(ret_name) + 4; if (ga_grow(&ga, len) == FAIL) { vim_free(ret_free); ga_clear(&ga); return "[unknown]"; } STRCPY((char *)ga.ga_data + ga.ga_len, "): "); STRCPY((char *)ga.ga_data + ga.ga_len + 3, ret_name); vim_free(ret_free); } *tofree = ga.ga_data; return ga.ga_data; } return name; } #endif // FEAT_EVAL