Mercurial > vim
view src/userfunc.c @ 32601:c659c4a5aae2 v9.0.1632
patch 9.0.1632: not all cabal config files are recognized
Commit: https://github.com/vim/vim/commit/166cd7b801ebe4aa042a9bbd6007d1951800aaa9
Author: Marcin Szamotulski <coot@coot.me>
Date: Wed Jun 14 19:45:43 2023 +0100
patch 9.0.1632: not all cabal config files are recognized
Problem: Not all cabal config files are recognized.
Solution: Add a couple of patterns. (Marcin Szamotulski, closes https://github.com/vim/vim/issues/12463)
author | Bram Moolenaar <Bram@vim.org> |
---|---|
date | Wed, 14 Jun 2023 21:00:03 +0200 |
parents | 304341915488 |
children | 448aef880252 |
line wrap: on
line source
/* 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. */ /* * userfunc.c: User defined function support */ #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) /* * All user-defined functions are found in this hashtable. */ static hashtab_T func_hashtab; // Used by get_func_tv() static garray_T funcargs = GA_EMPTY; // pointer to funccal for currently active function static funccall_T *current_funccal = NULL; // Pointer to list of previously used funccal, still around because some // item in it is still being used. static funccall_T *previous_funccal = NULL; static void funccal_unref(funccall_T *fc, ufunc_T *fp, int force); static void func_clear(ufunc_T *fp, int force); static int func_free(ufunc_T *fp, int force); static char_u *untrans_function_name(char_u *name); static void handle_defer_one(funccall_T *funccal); void func_init(void) { hash_init(&func_hashtab); } /* * Return the function hash table */ hashtab_T * func_tbl_get(void) { return &func_hashtab; } /* * Get one function argument. * If "argtypes" is not NULL also get the type: "arg: type" (:def function). * If "types_optional" is TRUE a missing type is OK, use "any". * If "evalarg" is not NULL use it to check for an already declared name. * If "eap" is not NULL use it to check for an already declared name. * Return a pointer to after the type. * When something is wrong return "arg". */ static char_u * one_function_arg( char_u *arg, garray_T *newargs, garray_T *argtypes, int types_optional, evalarg_T *evalarg, exarg_T *eap, int is_vararg, int skip) { char_u *p = arg; char_u *arg_copy = NULL; int is_underscore = FALSE; while (ASCII_ISALNUM(*p) || *p == '_') ++p; if (arg == p || isdigit(*arg) || (argtypes == NULL && ((p - arg == 9 && STRNCMP(arg, "firstline", 9) == 0) || (p - arg == 8 && STRNCMP(arg, "lastline", 8) == 0)))) { if (!skip) semsg(_(e_illegal_argument_str), arg); return arg; } // Extra checks in Vim9 script. if (!skip && argtypes != NULL) { int c = *p; *p = NUL; int r = check_reserved_name(arg, FALSE); *p = c; if (r == FAIL) return arg; // Cannot use script var name for argument. In function: also check // local vars and arguments. if (check_defined(arg, p - arg, evalarg == NULL ? NULL : evalarg->eval_cctx, eap == NULL ? NULL : eap->cstack, TRUE) == FAIL) return arg; } if (newargs != NULL && ga_grow(newargs, 1) == FAIL) return arg; if (newargs != NULL) { int c; int i; c = *p; *p = NUL; arg_copy = vim_strsave(arg); if (arg_copy == NULL) { *p = c; return arg; } is_underscore = arg_copy[0] == '_' && arg_copy[1] == NUL; if (argtypes == NULL || !is_underscore) // Check for duplicate argument name. for (i = 0; i < newargs->ga_len; ++i) if (STRCMP(((char_u **)(newargs->ga_data))[i], arg_copy) == 0) { semsg(_(e_duplicate_argument_name_str), arg_copy); vim_free(arg_copy); return arg; } ((char_u **)(newargs->ga_data))[newargs->ga_len] = arg_copy; newargs->ga_len++; *p = c; } // get any type from "arg: type" if (argtypes != NULL && (skip || ga_grow(argtypes, 1) == OK)) { char_u *type = NULL; if (VIM_ISWHITE(*p) && *skipwhite(p) == ':') { semsg(_(e_no_white_space_allowed_before_colon_str), arg_copy == NULL ? arg : arg_copy); p = skipwhite(p); } if (*p == ':') { ++p; if (!skip && !VIM_ISWHITE(*p)) { semsg(_(e_white_space_required_after_str_str), ":", p - 1); return arg; } type = skipwhite(p); p = skip_type(type, TRUE); if (!skip) type = vim_strnsave(type, p - type); } else if (*skipwhite(p) != '=' && !types_optional && !is_underscore) { semsg(_(e_missing_argument_type_for_str), arg_copy == NULL ? arg : arg_copy); return arg; } if (!skip) { if (type == NULL && types_optional) // lambda arguments default to "any" type type = vim_strsave((char_u *) (is_vararg ? "list<any>" : "any")); ((char_u **)argtypes->ga_data)[argtypes->ga_len++] = type; } } return p; } /* * Handle line continuation in function arguments or body. * Get a next line, store it in "eap" if appropriate and put the line in * "lines_to_free" to free the line later. */ static char_u * get_function_line( exarg_T *eap, garray_T *lines_to_free, int indent, getline_opt_T getline_options) { char_u *theline; if (eap->getline == NULL) theline = getcmdline(':', 0L, indent, 0); else theline = eap->getline(':', eap->cookie, indent, getline_options); if (theline != NULL) { if (lines_to_free->ga_len > 0 && eap->cmdlinep != NULL && *eap->cmdlinep == ((char_u **)lines_to_free->ga_data) [lines_to_free->ga_len - 1]) *eap->cmdlinep = theline; (void)ga_add_string(lines_to_free, theline); } return theline; } /* * Get function arguments. * "argp" should point to just after the "(", possibly to white space. * "argp" is advanced just after "endchar". */ static int get_function_args( char_u **argp, char_u endchar, garray_T *newargs, garray_T *argtypes, // NULL unless using :def int types_optional, // types optional if "argtypes" is not NULL evalarg_T *evalarg, // context or NULL int *varargs, garray_T *default_args, int skip, exarg_T *eap, // can be NULL int in_class, // non-zero when inside a class or interface garray_T *newlines, // function body lines garray_T *lines_to_free) { int mustend = FALSE; char_u *arg; char_u *p; int c; int any_default = FALSE; char_u *whitep = *argp; if (newargs != NULL) ga_init2(newargs, sizeof(char_u *), 3); if (argtypes != NULL) ga_init2(argtypes, sizeof(char_u *), 3); if (!skip && default_args != NULL) ga_init2(default_args, sizeof(char_u *), 3); if (varargs != NULL) *varargs = FALSE; /* * Isolate the arguments: "arg1, arg2, ...)" */ arg = skipwhite(*argp); p = arg; while (*p != endchar) { while (eap != NULL && eap->getline != NULL && (*p == NUL || (VIM_ISWHITE(*whitep) && *p == '#'))) { // End of the line, get the next one. char_u *theline = get_function_line(eap, lines_to_free, 0, GETLINE_CONCAT_CONT); if (theline == NULL) break; whitep = (char_u *)" "; p = skipwhite(theline); } if (mustend && *p != endchar) { if (!skip) semsg(_(e_invalid_argument_str), *argp); goto err_ret; } if (*p == endchar) break; if (p[0] == '.' && p[1] == '.' && p[2] == '.') { if (varargs != NULL) *varargs = TRUE; p += 3; mustend = TRUE; if (argtypes != NULL) { // ...name: list<type> if (!eval_isnamec1(*p)) { if (!skip) emsg(_(e_missing_name_after_dots)); goto err_ret; } arg = p; p = one_function_arg(p, newargs, argtypes, types_optional, evalarg, eap, TRUE, skip); if (p == arg) break; if (*skipwhite(p) == '=') { emsg(_(e_cannot_use_default_for_variable_arguments)); break; } } } else if (in_class && STRNCMP(p, "this.", 5) == 0) { // this.memberName p += 5; arg = p; while (ASCII_ISALNUM(*p) || *p == '_') ++p; char_u *argend = p; if (*skipwhite(p) == '=') { char_u *defval = skipwhite(skipwhite(p) + 1); if (STRNCMP(defval, "v:none", 6) != 0) { semsg(_(e_constructor_default_value_must_be_vnone_str), p); goto err_ret; } any_default = TRUE; p = defval + 6; if (ga_grow(default_args, 1) == FAIL) goto err_ret; char_u *expr = vim_strsave((char_u *)"v:none"); if (expr == NULL) goto err_ret; ((char_u **)(default_args->ga_data)) [default_args->ga_len] = expr; default_args->ga_len++; } else if (any_default) { emsg(_(e_non_default_argument_follows_default_argument)); goto err_ret; } // TODO: check the argument is indeed a member if (newargs != NULL && ga_grow(newargs, 1) == FAIL) return FAIL; if (newargs != NULL) { ((char_u **)(newargs->ga_data))[newargs->ga_len] = vim_strnsave(arg, argend - arg); newargs->ga_len++; if (argtypes != NULL && ga_grow(argtypes, 1) == OK) { // TODO: use the actual type ((char_u **)argtypes->ga_data)[argtypes->ga_len++] = vim_strsave((char_u *)"any"); // Add a line to the function body for the assignment. if (ga_grow(newlines, 1) == OK) { // "this.name = name" int len = 5 + (argend - arg) + 3 + (argend - arg) + 1; if (any_default) len += 14 + 10; char_u *assignment = alloc(len); if (assignment != NULL) { c = *argend; *argend = NUL; if (any_default) vim_snprintf((char *)assignment, len, "ifargisset %d this.%s = %s", default_args->ga_len - 1, arg, arg); else vim_snprintf((char *)assignment, len, "this.%s = %s", arg, arg); *argend = c; ((char_u **)(newlines->ga_data))[ newlines->ga_len++] = assignment; } } } } if (*p == ',') ++p; } else { char_u *np; arg = p; p = one_function_arg(p, newargs, argtypes, types_optional, evalarg, eap, FALSE, skip); if (p == arg) break; // Recognize " = expr" but not " == expr". A lambda can have // "(a = expr" but "(a == expr" and "(a =~ expr" are not a lambda. np = skipwhite(p); if (*np == '=' && np[1] != '=' && np[1] != '~' && default_args != NULL) { typval_T rettv; // find the end of the expression (doesn't evaluate it) any_default = TRUE; p = skipwhite(np + 1); char_u *expr = p; if (eval1(&p, &rettv, NULL) != FAIL) { if (!skip) { if (ga_grow(default_args, 1) == FAIL) goto err_ret; // trim trailing whitespace while (p > expr && VIM_ISWHITE(p[-1])) p--; c = *p; *p = NUL; expr = vim_strsave(expr); if (expr == NULL) { *p = c; goto err_ret; } ((char_u **)(default_args->ga_data)) [default_args->ga_len] = expr; default_args->ga_len++; *p = c; } } else mustend = TRUE; } else if (any_default) { emsg(_(e_non_default_argument_follows_default_argument)); goto err_ret; } if (VIM_ISWHITE(*p) && *skipwhite(p) == ',') { // Be tolerant when skipping if (!skip) { semsg(_(e_no_white_space_allowed_before_str_str), ",", p); goto err_ret; } p = skipwhite(p); } if (*p == ',') { ++p; // Don't give this error when skipping, it makes the "->" not // found in "{k,v -> x}" and give a confusing error. // Allow missing space after comma in legacy functions. if (!skip && argtypes != NULL && !IS_WHITE_OR_NUL(*p) && *p != endchar) { semsg(_(e_white_space_required_after_str_str), ",", p - 1); goto err_ret; } } else mustend = TRUE; } whitep = p; p = skipwhite(p); } if (*p != endchar) goto err_ret; ++p; // skip "endchar" *argp = p; return OK; err_ret: if (newargs != NULL) ga_clear_strings(newargs); if (!skip && default_args != NULL) ga_clear_strings(default_args); return FAIL; } /* * Parse the argument types, filling "fp->uf_arg_types". * Return OK or FAIL. */ static int parse_argument_types(ufunc_T *fp, garray_T *argtypes, int varargs) { int len = 0; ga_init2(&fp->uf_type_list, sizeof(type_T *), 10); if (argtypes->ga_len > 0) { // When "varargs" is set the last name/type goes into uf_va_name // and uf_va_type. len = argtypes->ga_len - (varargs ? 1 : 0); if (len > 0) fp->uf_arg_types = ALLOC_CLEAR_MULT(type_T *, len); if (fp->uf_arg_types != NULL) { int i; type_T *type; for (i = 0; i < len; ++ i) { char_u *p = ((char_u **)argtypes->ga_data)[i]; if (p == NULL) // will get the type from the default value type = &t_unknown; else type = parse_type(&p, &fp->uf_type_list, TRUE); if (type == NULL) return FAIL; fp->uf_arg_types[i] = type; if (i < fp->uf_args.ga_len && (type->tt_type == VAR_FUNC || type->tt_type == VAR_PARTIAL) && var_wrong_func_name( ((char_u **)fp->uf_args.ga_data)[i], TRUE)) return FAIL; } } } if (varargs) { char_u *p; // Move the last argument "...name: type" to uf_va_name and // uf_va_type. --fp->uf_args.ga_len; fp->uf_va_name = ((char_u **)fp->uf_args.ga_data)[fp->uf_args.ga_len]; ((char_u **)fp->uf_args.ga_data)[fp->uf_args.ga_len] = NULL; p = ((char_u **)argtypes->ga_data)[len]; if (p == NULL) // TODO: get type from default value fp->uf_va_type = &t_list_any; else { fp->uf_va_type = parse_type(&p, &fp->uf_type_list, TRUE); if (fp->uf_va_type != NULL && fp->uf_va_type->tt_type != VAR_LIST) { semsg(_(e_variable_arguments_type_must_be_list_str), ((char_u **)argtypes->ga_data)[len]); return FAIL; } } if (fp->uf_va_type == NULL) return FAIL; } return OK; } static int parse_return_type(ufunc_T *fp, char_u *ret_type) { if (ret_type == NULL) fp->uf_ret_type = &t_void; else { char_u *p = ret_type; fp->uf_ret_type = parse_type(&p, &fp->uf_type_list, TRUE); if (fp->uf_ret_type == NULL) { fp->uf_ret_type = &t_void; return FAIL; } } return OK; } /* * Register function "fp" as using "current_funccal" as its scope. */ static int register_closure(ufunc_T *fp) { if (fp->uf_scoped == current_funccal) // no change return OK; funccal_unref(fp->uf_scoped, fp, FALSE); fp->uf_scoped = current_funccal; current_funccal->fc_refcount++; if (ga_grow(¤t_funccal->fc_ufuncs, 1) == FAIL) return FAIL; ((ufunc_T **)current_funccal->fc_ufuncs.ga_data) [current_funccal->fc_ufuncs.ga_len++] = fp; return OK; } static void set_ufunc_name(ufunc_T *fp, char_u *name) { // Add a type cast to avoid a warning for an overflow, the uf_name[] array // actually extends beyond the struct. STRCPY((void *)fp->uf_name, name); if (name[0] == K_SPECIAL) { fp->uf_name_exp = alloc(STRLEN(name) + 3); if (fp->uf_name_exp != NULL) { STRCPY(fp->uf_name_exp, "<SNR>"); STRCAT(fp->uf_name_exp, fp->uf_name + 3); } } } /* * If "name" starts with K_SPECIAL and "buf[bufsize]" is big enough * return "buf" filled with a readable function name. * Otherwise just return "name", thus the return value can always be used. * "name" and "buf" may be equal. */ char_u * make_ufunc_name_readable(char_u *name, char_u *buf, size_t bufsize) { size_t len; if (name[0] != K_SPECIAL) return name; len = STRLEN(name); if (len + 3 > bufsize) return name; mch_memmove(buf + 5, name + 3, len - 2); // Include trailing NUL mch_memmove(buf, "<SNR>", 5); return buf; } /* * Get a name for a lambda. Returned in static memory. */ char_u * get_lambda_name(void) { static char_u name[30]; static int lambda_no = 0; sprintf((char*)name, "<lambda>%d", ++lambda_no); return name; } /* * Allocate a "ufunc_T" for a function called "name". * Makes sure the size is right. */ static ufunc_T * alloc_ufunc(char_u *name) { // When the name is short we need to make sure we allocate enough bytes for // the whole struct, including any padding. size_t len = offsetof(ufunc_T, uf_name) + STRLEN(name) + 1; return alloc_clear(len < sizeof(ufunc_T) ? sizeof(ufunc_T) : len); } #if defined(FEAT_LUA) || defined(PROTO) /* * Registers a native C callback which can be called from Vim script. * Returns the name of the Vim script function. */ char_u * register_cfunc(cfunc_T cb, cfunc_free_T cb_free, void *state) { char_u *name = get_lambda_name(); ufunc_T *fp; fp = alloc_ufunc(name); if (fp == NULL) return NULL; fp->uf_def_status = UF_NOT_COMPILED; fp->uf_refcount = 1; fp->uf_varargs = TRUE; fp->uf_flags = FC_CFUNC | FC_LAMBDA; fp->uf_calls = 0; fp->uf_script_ctx = current_sctx; fp->uf_cb = cb; fp->uf_cb_free = cb_free; fp->uf_cb_state = state; set_ufunc_name(fp, name); hash_add(&func_hashtab, UF2HIKEY(fp), "add C function"); return name; } #endif /* * Skip over "->" or "=>" after the arguments of a lambda. * If ": type" is found make "ret_type" point to "type". * If "white_error" is not NULL check for correct use of white space and set * "white_error" to TRUE if there is an error. * Return NULL if no valid arrow found. */ static char_u * skip_arrow( char_u *start, int equal_arrow, char_u **ret_type, int *white_error) { char_u *s = start; char_u *bef = start - 2; // "start" points to > of -> if (equal_arrow) { if (*s == ':') { if (white_error != NULL && !VIM_ISWHITE(s[1])) { *white_error = TRUE; semsg(_(e_white_space_required_after_str_str), ":", s); return NULL; } s = skipwhite(s + 1); *ret_type = s; s = skip_type(s, TRUE); if (s == *ret_type) { emsg(_(e_missing_return_type)); return NULL; } } bef = s; s = skipwhite(s); if (*s != '=') return NULL; ++s; } if (*s != '>') return NULL; if (white_error != NULL && ((!VIM_ISWHITE(*bef) && *bef != '{') || !IS_WHITE_OR_NUL(s[1]))) { *white_error = TRUE; semsg(_(e_white_space_required_before_and_after_str_at_str), equal_arrow ? "=>" : "->", bef); return NULL; } return skipwhite(s + 1); } /* * Check if "*cmd" points to a function command and if so advance "*cmd" and * return TRUE. * Otherwise return FALSE; * Do not consider "function(" to be a command. */ static int is_function_cmd(char_u **cmd) { char_u *p = *cmd; if (checkforcmd(&p, "function", 2)) { if (*p == '(') return FALSE; *cmd = p; return TRUE; } return FALSE; } /* * Called when defining a function: The context may be needed for script * variables declared in a block that is visible now but not when the function * is compiled or called later. */ static void function_using_block_scopes(ufunc_T *fp, cstack_T *cstack) { if (cstack == NULL || cstack->cs_idx < 0) return; int count = cstack->cs_idx + 1; int i; fp->uf_block_ids = ALLOC_MULT(int, count); if (fp->uf_block_ids != NULL) { mch_memmove(fp->uf_block_ids, cstack->cs_block_id, sizeof(int) * count); fp->uf_block_depth = count; } // Set flag in each block to indicate a function was defined. This // is used to keep the variable when leaving the block, see // hide_script_var(). for (i = 0; i <= cstack->cs_idx; ++i) cstack->cs_flags[i] |= CSF_FUNC_DEF; } /* * Read the body of a function, put every line in "newlines". * This stops at "}", "endfunction" or "enddef". * "newlines" must already have been initialized. * "eap->cmdidx" is CMD_function, CMD_def or CMD_block; */ static int get_function_body( exarg_T *eap, garray_T *newlines, char_u *line_arg_in, garray_T *lines_to_free) { linenr_T sourcing_lnum_top = SOURCING_LNUM; linenr_T sourcing_lnum_off; int saved_wait_return = need_wait_return; char_u *line_arg = line_arg_in; int vim9_function = eap->cmdidx == CMD_def || eap->cmdidx == CMD_block; #define MAX_FUNC_NESTING 50 char nesting_def[MAX_FUNC_NESTING]; char nesting_inline[MAX_FUNC_NESTING]; int nesting = 0; getline_opt_T getline_options; int indent = 2; char_u *skip_until = NULL; int ret = FAIL; int is_heredoc = FALSE; int heredoc_concat_len = 0; garray_T heredoc_ga; char_u *heredoc_trimmed = NULL; ga_init2(&heredoc_ga, 1, 500); // Detect having skipped over comment lines to find the return // type. Add NULL lines to keep the line count correct. sourcing_lnum_off = get_sourced_lnum(eap->getline, eap->cookie); if (SOURCING_LNUM < sourcing_lnum_off) { sourcing_lnum_off -= SOURCING_LNUM; if (ga_grow(newlines, sourcing_lnum_off) == FAIL) goto theend; while (sourcing_lnum_off-- > 0) ((char_u **)(newlines->ga_data))[newlines->ga_len++] = NULL; } nesting_def[0] = vim9_function; nesting_inline[0] = eap->cmdidx == CMD_block; getline_options = vim9_function ? GETLINE_CONCAT_CONTBAR : GETLINE_CONCAT_CONT; for (;;) { char_u *theline; char_u *p; char_u *arg; if (KeyTyped) { msg_scroll = TRUE; saved_wait_return = FALSE; } need_wait_return = FALSE; if (line_arg != NULL) { // Use eap->arg, split up in parts by line breaks. theline = line_arg; p = vim_strchr(theline, '\n'); if (p == NULL) line_arg += STRLEN(line_arg); else { *p = NUL; line_arg = p + 1; } } else { theline = get_function_line(eap, lines_to_free, indent, getline_options); } if (KeyTyped) lines_left = Rows - 1; if (theline == NULL) { // Use the start of the function for the line number. SOURCING_LNUM = sourcing_lnum_top; if (skip_until != NULL) semsg(_(e_missing_heredoc_end_marker_str), skip_until); else if (nesting_inline[nesting]) emsg(_(e_missing_end_block)); else if (eap->cmdidx == CMD_def) emsg(_(e_missing_enddef)); else emsg(_(e_missing_endfunction)); goto theend; } // Detect line continuation: SOURCING_LNUM increased more than one. sourcing_lnum_off = get_sourced_lnum(eap->getline, eap->cookie); if (SOURCING_LNUM < sourcing_lnum_off) sourcing_lnum_off -= SOURCING_LNUM; else sourcing_lnum_off = 0; if (skip_until != NULL) { // Don't check for ":endfunc"/":enddef" between // * ":append" and "." // * ":python <<EOF" and "EOF" // * ":let {var-name} =<< [trim] {marker}" and "{marker}" if (heredoc_trimmed == NULL || (is_heredoc && skipwhite(theline) == theline) || STRNCMP(theline, heredoc_trimmed, STRLEN(heredoc_trimmed)) == 0) { if (heredoc_trimmed == NULL) p = theline; else if (is_heredoc) p = skipwhite(theline) == theline ? theline : theline + STRLEN(heredoc_trimmed); else p = theline + STRLEN(heredoc_trimmed); if (STRCMP(p, skip_until) == 0) { VIM_CLEAR(skip_until); VIM_CLEAR(heredoc_trimmed); getline_options = vim9_function ? GETLINE_CONCAT_CONTBAR : GETLINE_CONCAT_CONT; is_heredoc = FALSE; if (heredoc_concat_len > 0) { // Replace the starting line with all the concatenated // lines. ga_concat(&heredoc_ga, theline); vim_free(((char_u **)(newlines->ga_data))[ heredoc_concat_len - 1]); ((char_u **)(newlines->ga_data))[ heredoc_concat_len - 1] = heredoc_ga.ga_data; ga_init(&heredoc_ga); heredoc_concat_len = 0; theline += STRLEN(theline); // skip the "EOF" } } } } else { int c; char_u *end; char_u *cmd; // skip ':' and blanks for (p = theline; VIM_ISWHITE(*p) || *p == ':'; ++p) ; // Check for "endfunction", "enddef" or "}". // When a ":" follows it must be a dict key; "enddef: value," cmd = p; if (nesting_inline[nesting] ? *p == '}' : (checkforcmd(&p, nesting_def[nesting] ? "enddef" : "endfunction", 4) && *p != ':')) { if (!nesting_inline[nesting] && nesting_def[nesting] && p < cmd + 6) semsg(_(e_command_cannot_be_shortened_str), "enddef"); if (nesting-- == 0) { char_u *nextcmd = NULL; if (*p == '|' || *p == '}') nextcmd = p + 1; else if (line_arg != NULL && *skipwhite(line_arg) != NUL) nextcmd = line_arg; else if (*p != NUL && *p != (vim9_function ? '#' : '"') && (vim9_function || p_verbose > 0)) { SOURCING_LNUM = sourcing_lnum_top + newlines->ga_len + 1; if (eap->cmdidx == CMD_def) semsg(_(e_text_found_after_str_str), "enddef", p); else give_warning2((char_u *) _("W22: Text found after :endfunction: %s"), p, TRUE); } if (nextcmd != NULL && *skipwhite(nextcmd) != NUL) { // Another command follows. If the line came from "eap" // we can simply point into it, otherwise we need to // change "eap->cmdlinep" to point to the last fetched // line. eap->nextcmd = nextcmd; if (lines_to_free->ga_len > 0 && *eap->cmdlinep != ((char_u **)lines_to_free->ga_data) [lines_to_free->ga_len - 1]) { // *cmdlinep will be freed later, thus remove the // line from lines_to_free. vim_free(*eap->cmdlinep); *eap->cmdlinep = ((char_u **)lines_to_free->ga_data) [lines_to_free->ga_len - 1]; --lines_to_free->ga_len; } } break; } } // Check for mismatched "endfunc" or "enddef". // We don't check for "def" inside "func" thus we also can't check // for "enddef". // We continue to find the end of the function, although we might // not find it. else if (nesting_def[nesting]) { if (checkforcmd(&p, "endfunction", 4) && *p != ':') emsg(_(e_mismatched_endfunction)); } else if (eap->cmdidx == CMD_def && checkforcmd(&p, "enddef", 4)) emsg(_(e_mismatched_enddef)); // Increase indent inside "if", "while", "for" and "try", decrease // at "end". if (indent > 2 && (*p == '}' || STRNCMP(p, "end", 3) == 0)) indent -= 2; else if (STRNCMP(p, "if", 2) == 0 || STRNCMP(p, "wh", 2) == 0 || STRNCMP(p, "for", 3) == 0 || STRNCMP(p, "try", 3) == 0) indent += 2; // Check for defining a function inside this function. // Only recognize "def" inside "def", not inside "function", // For backwards compatibility, see Test_function_python(). c = *p; if (is_function_cmd(&p) || (eap->cmdidx == CMD_def && checkforcmd(&p, "def", 3))) { if (*p == '!') p = skipwhite(p + 1); p += eval_fname_script(p); vim_free(trans_function_name(&p, NULL, TRUE, 0)); if (*skipwhite(p) == '(') { if (nesting == MAX_FUNC_NESTING - 1) emsg(_(e_function_nesting_too_deep)); else { ++nesting; nesting_def[nesting] = (c == 'd'); nesting_inline[nesting] = FALSE; indent += 2; } } } if (nesting_def[nesting] ? *p != '#' : *p != '"') { // Not a comment line: check for nested inline function. end = p + STRLEN(p) - 1; while (end > p && VIM_ISWHITE(*end)) --end; if (end > p + 1 && *end == '{' && VIM_ISWHITE(end[-1])) { int is_block; // check for trailing "=> {": start of an inline function --end; while (end > p && VIM_ISWHITE(*end)) --end; is_block = end > p + 2 && end[-1] == '=' && end[0] == '>'; if (!is_block) { char_u *s = p; // check for line starting with "au" for :autocmd or // "com" for :command, these can use a {} block is_block = checkforcmd_noparen(&s, "autocmd", 2) || checkforcmd_noparen(&s, "command", 3); } if (is_block) { if (nesting == MAX_FUNC_NESTING - 1) emsg(_(e_function_nesting_too_deep)); else { ++nesting; nesting_def[nesting] = TRUE; nesting_inline[nesting] = TRUE; indent += 2; } } } } // Check for ":append", ":change", ":insert". Not for :def. p = skip_range(p, FALSE, NULL); if (!vim9_function && ((p[0] == 'a' && (!ASCII_ISALPHA(p[1]) || p[1] == 'p')) || (p[0] == 'c' && (!ASCII_ISALPHA(p[1]) || (p[1] == 'h' && (!ASCII_ISALPHA(p[2]) || (p[2] == 'a' && (STRNCMP(&p[3], "nge", 3) != 0 || !ASCII_ISALPHA(p[6]))))))) || (p[0] == 'i' && (!ASCII_ISALPHA(p[1]) || (p[1] == 'n' && (!ASCII_ISALPHA(p[2]) || (p[2] == 's' && (!ASCII_ISALPHA(p[3]) || p[3] == 'e')))))))) skip_until = vim_strsave((char_u *)"."); // Check for ":python <<EOF", ":tcl <<EOF", etc. arg = skipwhite(skiptowhite(p)); if (arg[0] == '<' && arg[1] =='<' && ((p[0] == 'p' && p[1] == 'y' && (!ASCII_ISALNUM(p[2]) || p[2] == 't' || ((p[2] == '3' || p[2] == 'x') && !ASCII_ISALPHA(p[3])))) || (p[0] == 'p' && p[1] == 'e' && (!ASCII_ISALPHA(p[2]) || p[2] == 'r')) || (p[0] == 't' && p[1] == 'c' && (!ASCII_ISALPHA(p[2]) || p[2] == 'l')) || (p[0] == 'l' && p[1] == 'u' && p[2] == 'a' && !ASCII_ISALPHA(p[3])) || (p[0] == 'r' && p[1] == 'u' && p[2] == 'b' && (!ASCII_ISALPHA(p[3]) || p[3] == 'y')) || (p[0] == 'm' && p[1] == 'z' && (!ASCII_ISALPHA(p[2]) || p[2] == 's')) )) { // ":python <<" continues until a dot, like ":append" p = skipwhite(arg + 2); if (STRNCMP(p, "trim", 4) == 0) { // Ignore leading white space. p = skipwhite(p + 4); heredoc_trimmed = vim_strnsave(theline, skipwhite(theline) - theline); } if (*p == NUL) skip_until = vim_strsave((char_u *)"."); else skip_until = vim_strnsave(p, skiptowhite(p) - p); getline_options = GETLINE_NONE; is_heredoc = TRUE; if (vim9_function && nesting == 0) heredoc_concat_len = newlines->ga_len + 1; } if (!is_heredoc) { // Check for ":cmd v =<< [trim] EOF" // and ":cmd [a, b] =<< [trim] EOF" // and "lines =<< [trim] EOF" for Vim9 // Where "cmd" can be "let", "var", "final" or "const". arg = p; if (checkforcmd(&arg, "let", 2) || checkforcmd(&arg, "var", 3) || checkforcmd(&arg, "final", 5) || checkforcmd(&arg, "const", 5) || vim9_function) { while (vim_strchr((char_u *)"$@&", *arg) != NULL) ++arg; arg = skipwhite(find_name_end(arg, NULL, NULL, FNE_INCL_BR | FNE_ALLOW_CURLY)); if (vim9_function && *arg == ':') arg = skipwhite(skip_type(skipwhite(arg + 1), FALSE)); if (arg[0] == '=' && arg[1] == '<' && arg[2] =='<') { p = skipwhite(arg + 3); while (TRUE) { if (STRNCMP(p, "trim", 4) == 0) { // Ignore leading white space. p = skipwhite(p + 4); heredoc_trimmed = vim_strnsave(theline, skipwhite(theline) - theline); continue; } if (STRNCMP(p, "eval", 4) == 0) { // Ignore leading white space. p = skipwhite(p + 4); continue; } break; } skip_until = vim_strnsave(p, skiptowhite(p) - p); getline_options = GETLINE_NONE; is_heredoc = TRUE; } } } } // Add the line to the function. if (ga_grow_id(newlines, 1 + sourcing_lnum_off, aid_get_func) == FAIL) goto theend; if (heredoc_concat_len > 0) { // For a :def function "python << EOF" concatenates all the lines, // to be used for the instruction later. ga_concat(&heredoc_ga, theline); ga_concat(&heredoc_ga, (char_u *)"\n"); p = vim_strsave((char_u *)""); } else { // Copy the line to newly allocated memory. get_one_sourceline() // allocates 250 bytes per line, this saves 80% on average. The // cost is an extra alloc/free. p = vim_strsave(theline); } if (p == NULL) goto theend; ((char_u **)(newlines->ga_data))[newlines->ga_len++] = p; // Add NULL lines for continuation lines, so that the line count is // equal to the index in the growarray. while (sourcing_lnum_off-- > 0) ((char_u **)(newlines->ga_data))[newlines->ga_len++] = NULL; // Check for end of eap->arg. if (line_arg != NULL && *line_arg == NUL) line_arg = NULL; } // Return OK when no error was detected. if (!did_emsg) ret = OK; theend: vim_free(skip_until); vim_free(heredoc_trimmed); vim_free(heredoc_ga.ga_data); need_wait_return |= saved_wait_return; return ret; } /* * Handle the body of a lambda. *arg points to the "{", process statements * until the matching "}". * When not evaluating "newargs" is NULL. * When successful "rettv" is set to a funcref. */ static int lambda_function_body( char_u **arg, typval_T *rettv, evalarg_T *evalarg, garray_T *newargs, garray_T *argtypes, int varargs, garray_T *default_args, char_u *ret_type) { char_u *start = *arg; int evaluate = (evalarg->eval_flags & EVAL_EVALUATE); garray_T *gap = &evalarg->eval_ga; garray_T *freegap = &evalarg->eval_freega; ufunc_T *ufunc = NULL; exarg_T eap; garray_T newlines; char_u *cmdline = NULL; int ret = FAIL; partial_T *pt; char_u *name; int lnum_save = -1; linenr_T sourcing_lnum_top = SOURCING_LNUM; *arg = skipwhite(*arg + 1); if (**arg == '|' || !ends_excmd2(start, *arg)) { semsg(_(e_trailing_characters_str), *arg); return FAIL; } CLEAR_FIELD(eap); eap.cmdidx = CMD_block; eap.forceit = FALSE; eap.cmdlinep = &cmdline; eap.skip = !evaluate; if (evalarg->eval_cctx != NULL) fill_exarg_from_cctx(&eap, evalarg->eval_cctx); else { eap.getline = evalarg->eval_getline; eap.cookie = evalarg->eval_cookie; } ga_init2(&newlines, sizeof(char_u *), 10); if (get_function_body(&eap, &newlines, NULL, &evalarg->eval_tofree_ga) == FAIL) goto erret; // When inside a lambda must add the function lines to evalarg.eval_ga. evalarg->eval_break_count += newlines.ga_len; if (gap->ga_itemsize > 0) { int idx; char_u *last; size_t plen; char_u *pnl; for (idx = 0; idx < newlines.ga_len; ++idx) { char_u *p = skipwhite(((char_u **)newlines.ga_data)[idx]); if (ga_grow(gap, 1) == FAIL || ga_grow(freegap, 1) == FAIL) goto erret; // Going to concatenate the lines after parsing. For an empty or // comment line use an empty string. // Insert NL characters at the start of each line, the string will // be split again later in .get_lambda_tv(). if (*p == NUL || vim9_comment_start(p)) p = (char_u *)""; plen = STRLEN(p); pnl = vim_strnsave((char_u *)"\n", plen + 1); if (pnl != NULL) mch_memmove(pnl + 1, p, plen + 1); ((char_u **)gap->ga_data)[gap->ga_len++] = pnl; ((char_u **)freegap->ga_data)[freegap->ga_len++] = pnl; } if (ga_grow(gap, 1) == FAIL || ga_grow(freegap, 1) == FAIL) goto erret; if (eap.nextcmd != NULL) // more is following after the "}", which was skipped last = cmdline; else // nothing is following the "}" last = (char_u *)"}"; plen = STRLEN(last); pnl = vim_strnsave((char_u *)"\n", plen + 1); if (pnl != NULL) mch_memmove(pnl + 1, last, plen + 1); ((char_u **)gap->ga_data)[gap->ga_len++] = pnl; ((char_u **)freegap->ga_data)[freegap->ga_len++] = pnl; } if (eap.nextcmd != NULL) { garray_T *tfgap = &evalarg->eval_tofree_ga; // Something comes after the "}". *arg = eap.nextcmd; // "arg" points into cmdline, need to keep the line and free it later. if (ga_grow(tfgap, 1) == OK) { ((char_u **)(tfgap->ga_data))[tfgap->ga_len++] = cmdline; evalarg->eval_using_cmdline = TRUE; } } else *arg = (char_u *)""; if (!evaluate) { ret = OK; goto erret; } name = get_lambda_name(); ufunc = alloc_ufunc(name); if (ufunc == NULL) goto erret; set_ufunc_name(ufunc, name); if (hash_add(&func_hashtab, UF2HIKEY(ufunc), "add function") == FAIL) goto erret; ufunc->uf_flags = FC_LAMBDA; ufunc->uf_refcount = 1; ufunc->uf_args = *newargs; newargs->ga_data = NULL; ufunc->uf_def_args = *default_args; default_args->ga_data = NULL; ufunc->uf_func_type = &t_func_any; // error messages are for the first function line lnum_save = SOURCING_LNUM; SOURCING_LNUM = sourcing_lnum_top; // parse argument types if (parse_argument_types(ufunc, argtypes, varargs) == FAIL) { SOURCING_LNUM = lnum_save; goto erret; } // parse the return type, if any if (parse_return_type(ufunc, ret_type) == FAIL) goto erret; pt = ALLOC_CLEAR_ONE(partial_T); if (pt == NULL) goto erret; pt->pt_func = ufunc; pt->pt_refcount = 1; ufunc->uf_lines = newlines; newlines.ga_data = NULL; if (sandbox) ufunc->uf_flags |= FC_SANDBOX; if (!ASCII_ISUPPER(*ufunc->uf_name)) ufunc->uf_flags |= FC_VIM9; ufunc->uf_script_ctx = current_sctx; ufunc->uf_script_ctx_version = current_sctx.sc_version; ufunc->uf_script_ctx.sc_lnum += sourcing_lnum_top; set_function_type(ufunc); function_using_block_scopes(ufunc, evalarg->eval_cstack); rettv->vval.v_partial = pt; rettv->v_type = VAR_PARTIAL; ufunc = NULL; ret = OK; erret: if (lnum_save >= 0) SOURCING_LNUM = lnum_save; ga_clear_strings(&newlines); if (newargs != NULL) ga_clear_strings(newargs); ga_clear_strings(default_args); if (ufunc != NULL) { func_clear(ufunc, TRUE); func_free(ufunc, TRUE); } return ret; } /* * Parse a lambda expression and get a Funcref from "*arg" into "rettv". * "arg" points to the { in "{arg -> expr}" or the ( in "(arg) => expr" * When "types_optional" is TRUE optionally take argument types. * Return OK or FAIL. Returns NOTDONE for dict or {expr}. */ int get_lambda_tv( char_u **arg, typval_T *rettv, int types_optional, evalarg_T *evalarg) { int evaluate = evalarg != NULL && (evalarg->eval_flags & EVAL_EVALUATE); garray_T newargs; garray_T newlines; garray_T *pnewargs; garray_T argtypes; garray_T default_args; ufunc_T *fp = NULL; partial_T *pt = NULL; int varargs; char_u *ret_type = NULL; int ret; char_u *s; char_u *start, *end; int *old_eval_lavars = eval_lavars_used; int eval_lavars = FALSE; char_u *tofree2 = NULL; int equal_arrow = **arg == '('; int white_error = FALSE; int called_emsg_start = called_emsg; int vim9script = in_vim9script(); long start_lnum = SOURCING_LNUM; if (equal_arrow && !vim9script) return NOTDONE; ga_init(&newargs); ga_init(&newlines); // First, check if this is really a lambda expression. "->" or "=>" must // be found after the arguments. s = *arg + 1; ret = get_function_args(&s, equal_arrow ? ')' : '-', NULL, types_optional ? &argtypes : NULL, types_optional, evalarg, NULL, &default_args, TRUE, NULL, FALSE, NULL, NULL); if (ret == FAIL || skip_arrow(s, equal_arrow, &ret_type, NULL) == NULL) { if (types_optional) ga_clear_strings(&argtypes); return called_emsg == called_emsg_start ? NOTDONE : FAIL; } // Parse the arguments for real. if (evaluate) pnewargs = &newargs; else pnewargs = NULL; *arg += 1; ret = get_function_args(arg, equal_arrow ? ')' : '-', pnewargs, types_optional ? &argtypes : NULL, types_optional, evalarg, &varargs, &default_args, FALSE, NULL, FALSE, NULL, NULL); if (ret == FAIL || (s = skip_arrow(*arg, equal_arrow, &ret_type, equal_arrow || vim9script ? &white_error : NULL)) == NULL) { if (types_optional) ga_clear_strings(&argtypes); ga_clear_strings(&newargs); return white_error ? FAIL : NOTDONE; } *arg = s; // Skipping over linebreaks may make "ret_type" invalid, make a copy. if (ret_type != NULL) { ret_type = vim_strsave(ret_type); tofree2 = ret_type; } // Set up a flag for checking local variables and arguments. if (evaluate) eval_lavars_used = &eval_lavars; *arg = skipwhite_and_linebreak(*arg, evalarg); // Recognize "{" as the start of a function body. if (equal_arrow && **arg == '{') { if (evalarg == NULL) // cannot happen? goto theend; SOURCING_LNUM = start_lnum; // used for where lambda is defined if (lambda_function_body(arg, rettv, evalarg, pnewargs, types_optional ? &argtypes : NULL, varargs, &default_args, ret_type) == FAIL) goto errret; goto theend; } if (default_args.ga_len > 0) { emsg(_(e_cannot_use_default_values_in_lambda)); goto errret; } // Get the start and the end of the expression. start = *arg; ret = skip_expr_concatenate(arg, &start, &end, evalarg); if (ret == FAIL) goto errret; if (!equal_arrow) { *arg = skipwhite_and_linebreak(*arg, evalarg); if (**arg != '}') { semsg(_(e_expected_right_curly_str), *arg); goto errret; } ++*arg; } if (evaluate) { int len; int flags = FC_LAMBDA; char_u *p; char_u *line_end; char_u *name = get_lambda_name(); fp = alloc_ufunc(name); if (fp == NULL) goto errret; fp->uf_def_status = UF_NOT_COMPILED; pt = ALLOC_CLEAR_ONE(partial_T); if (pt == NULL) goto errret; ga_init2(&newlines, sizeof(char_u *), 1); if (ga_grow(&newlines, 1) == FAIL) goto errret; // If there are line breaks, we need to split up the string. line_end = vim_strchr(start, '\n'); if (line_end == NULL || line_end > end) line_end = end; // Add "return " before the expression (or the first line). len = 7 + (int)(line_end - start) + 1; p = alloc(len); if (p == NULL) goto errret; ((char_u **)(newlines.ga_data))[newlines.ga_len++] = p; STRCPY(p, "return "); vim_strncpy(p + 7, start, line_end - start); if (line_end != end) { // Add more lines, split by line breaks. Thus is used when a // lambda with { cmds } is encountered. while (*line_end == '\n') { if (ga_grow(&newlines, 1) == FAIL) goto errret; start = line_end + 1; line_end = vim_strchr(start, '\n'); if (line_end == NULL) line_end = end; ((char_u **)(newlines.ga_data))[newlines.ga_len++] = vim_strnsave(start, line_end - start); } } if (strstr((char *)p + 7, "a:") == NULL) // No a: variables are used for sure. flags |= FC_NOARGS; fp->uf_refcount = 1; set_ufunc_name(fp, name); fp->uf_args = newargs; ga_init(&fp->uf_def_args); if (types_optional) { if (parse_argument_types(fp, &argtypes, vim9script && varargs) == FAIL) goto errret; if (ret_type != NULL) { fp->uf_ret_type = parse_type(&ret_type, &fp->uf_type_list, TRUE); if (fp->uf_ret_type == NULL) goto errret; } else fp->uf_ret_type = &t_unknown; } fp->uf_lines = newlines; if (current_funccal != NULL && eval_lavars) { flags |= FC_CLOSURE; if (register_closure(fp) == FAIL) goto errret; } #ifdef FEAT_PROFILE if (prof_def_func()) func_do_profile(fp); #endif if (sandbox) flags |= FC_SANDBOX; // In legacy script a lambda can be called with more args than // uf_args.ga_len. In Vim9 script "...name" has to be used. fp->uf_varargs = !vim9script || varargs; fp->uf_flags = flags; fp->uf_calls = 0; fp->uf_script_ctx = current_sctx; // Use the line number of the arguments. fp->uf_script_ctx.sc_lnum += start_lnum; function_using_block_scopes(fp, evalarg->eval_cstack); pt->pt_func = fp; pt->pt_refcount = 1; rettv->vval.v_partial = pt; rettv->v_type = VAR_PARTIAL; hash_add(&func_hashtab, UF2HIKEY(fp), "add lambda"); } theend: eval_lavars_used = old_eval_lavars; vim_free(tofree2); if (types_optional) ga_clear_strings(&argtypes); return OK; errret: ga_clear_strings(&newargs); ga_clear_strings(&newlines); ga_clear_strings(&default_args); if (types_optional) { ga_clear_strings(&argtypes); if (fp != NULL) vim_free(fp->uf_arg_types); } vim_free(fp); vim_free(pt); vim_free(tofree2); eval_lavars_used = old_eval_lavars; return FAIL; } /* * Check if "name" is a variable of type VAR_FUNC. If so, return the function * name it contains, otherwise return "name". * If "partialp" is not NULL, and "name" is of type VAR_PARTIAL also set * "partialp". * If "type" is not NULL and a Vim9 script-local variable is found look up the * type of the variable. * If "new_function" is TRUE the name is for a new function. * If "found_var" is not NULL and a variable was found set it to TRUE. */ char_u * deref_func_name( char_u *name, int *lenp, partial_T **partialp, type_T **type, int no_autoload, int new_function, int *found_var) { dictitem_T *v; typval_T *tv = NULL; int cc; char_u *s = NULL; hashtab_T *ht; int did_type = FALSE; if (partialp != NULL) *partialp = NULL; cc = name[*lenp]; name[*lenp] = NUL; v = find_var_also_in_script(name, &ht, no_autoload); name[*lenp] = cc; if (v != NULL) { tv = &v->di_tv; } else if (in_vim9script() || STRNCMP(name, "s:", 2) == 0) { imported_T *import; char_u *p = name; int len = *lenp; if (STRNCMP(name, "s:", 2) == 0) { p = name + 2; len -= 2; } import = find_imported(p, len, FALSE); // imported function from another script if (import != NULL) { name[len] = NUL; if (new_function) semsg(_(e_redefining_imported_item_str), name); else semsg(_(e_cannot_use_str_itself_it_is_imported), name); name[len] = cc; *lenp = 0; return (char_u *)""; // just in case } } if (tv != NULL) { if (found_var != NULL) *found_var = TRUE; if (tv->v_type == VAR_FUNC) { if (tv->vval.v_string == NULL) { *lenp = 0; return (char_u *)""; // just in case } s = tv->vval.v_string; *lenp = (int)STRLEN(s); } if (tv->v_type == VAR_PARTIAL) { partial_T *pt = tv->vval.v_partial; if (pt == NULL) { *lenp = 0; return (char_u *)""; // just in case } if (partialp != NULL) *partialp = pt; s = partial_name(pt); *lenp = (int)STRLEN(s); } if (s != NULL) { if (!did_type && type != NULL && ht == get_script_local_ht()) { svar_T *sv = find_typval_in_script(tv, 0, TRUE); if (sv != NULL) *type = sv->sv_type; } return s; } } return name; } /* * Give an error message with a function name. Handle <SNR> things. * "ermsg" is to be passed without translation, use N_() instead of _(). */ void emsg_funcname(char *ermsg, char_u *name) { char_u *p = name; if (name[0] == K_SPECIAL && name[1] != NUL && name[2] != NUL) p = concat_str((char_u *)"<SNR>", name + 3); semsg(_(ermsg), p); if (p != name) vim_free(p); } /* * Get function arguments at "*arg" and advance it. * Return them in "*argvars[MAX_FUNC_ARGS + 1]" and the count in "argcount". * On failure FAIL is returned but the "argvars[argcount]" are still set. */ int get_func_arguments( char_u **arg, evalarg_T *evalarg, int partial_argc, typval_T *argvars, int *argcount) { char_u *argp = *arg; int ret = OK; int vim9script = in_vim9script(); int evaluate = evalarg == NULL ? FALSE : (evalarg->eval_flags & EVAL_EVALUATE); while (*argcount < MAX_FUNC_ARGS - partial_argc) { // skip the '(' or ',' and possibly line breaks argp = skipwhite_and_linebreak(argp + 1, evalarg); if (*argp == ')' || *argp == ',' || *argp == NUL) break; if (eval1(&argp, &argvars[*argcount], evalarg) == FAIL) { ret = FAIL; break; } ++*argcount; // The comma should come right after the argument, but this wasn't // checked previously, thus only enforce it in Vim9 script. if (vim9script) { if (*argp != ',' && *skipwhite(argp) == ',') { if (evaluate) semsg(_(e_no_white_space_allowed_before_str_str), ",", argp); ret = FAIL; break; } } else argp = skipwhite(argp); if (*argp != ',') break; if (vim9script && !IS_WHITE_OR_NUL(argp[1])) { if (evaluate) semsg(_(e_white_space_required_after_str_str), ",", argp); ret = FAIL; break; } } argp = skipwhite_and_linebreak(argp, evalarg); if (*argp == ')') ++argp; else ret = FAIL; *arg = argp; return ret; } /* * Call a function and put the result in "rettv". * Return OK or FAIL. */ int get_func_tv( char_u *name, // name of the function int len, // length of "name" or -1 to use strlen() typval_T *rettv, char_u **arg, // argument, pointing to the '(' evalarg_T *evalarg, // for line continuation funcexe_T *funcexe) // various values { char_u *argp; int ret; typval_T argvars[MAX_FUNC_ARGS + 1]; // vars for arguments int argcount = 0; // number of arguments found int vim9script = in_vim9script(); int evaluate = evalarg == NULL ? FALSE : (evalarg->eval_flags & EVAL_EVALUATE); argp = *arg; ret = get_func_arguments(&argp, evalarg, (funcexe->fe_partial == NULL ? 0 : funcexe->fe_partial->pt_argc), argvars, &argcount); if (ret == OK) { int i = 0; int did_emsg_before = did_emsg; if (get_vim_var_nr(VV_TESTING)) { // Prepare for calling test_garbagecollect_now(), need to know // what variables are used on the call stack. if (funcargs.ga_itemsize == 0) ga_init2(&funcargs, sizeof(typval_T *), 50); for (i = 0; i < argcount; ++i) if (ga_grow(&funcargs, 1) == OK) ((typval_T **)funcargs.ga_data)[funcargs.ga_len++] = &argvars[i]; } ret = call_func(name, len, rettv, argcount, argvars, funcexe); if (vim9script && did_emsg > did_emsg_before) { // An error in a builtin function does not return FAIL, but we do // want to abort further processing if an error was given. ret = FAIL; clear_tv(rettv); } funcargs.ga_len -= i; } else if (!aborting() && evaluate) { if (argcount == MAX_FUNC_ARGS) emsg_funcname(e_too_many_arguments_for_function_str_2, name); else emsg_funcname(e_invalid_arguments_for_function_str, name); } while (--argcount >= 0) clear_tv(&argvars[argcount]); if (vim9script) *arg = argp; else *arg = skipwhite(argp); return ret; } /* * Return TRUE if "p" starts with "<SID>" or "s:". * Only works if eval_fname_script() returned non-zero for "p"! */ static int eval_fname_sid(char_u *p) { return (*p == 's' || TOUPPER_ASC(p[2]) == 'I'); } /* * In a script change <SID>name() and s:name() to K_SNR 123_name(). * Change <SNR>123_name() to K_SNR 123_name(). * Use "fname_buf[FLEN_FIXED + 1]" when it fits, otherwise allocate memory * and set "tofree". */ char_u * fname_trans_sid( char_u *name, char_u *fname_buf, char_u **tofree, funcerror_T *error) { int llen; char_u *fname; int i; llen = eval_fname_script(name); if (llen == 0) return name; // no prefix fname_buf[0] = K_SPECIAL; fname_buf[1] = KS_EXTRA; fname_buf[2] = (int)KE_SNR; i = 3; if (eval_fname_sid(name)) // "<SID>" or "s:" { if (current_sctx.sc_sid <= 0) *error = FCERR_SCRIPT; else { sprintf((char *)fname_buf + 3, "%ld_", (long)current_sctx.sc_sid); i = (int)STRLEN(fname_buf); } } if (i + STRLEN(name + llen) < FLEN_FIXED) { STRCPY(fname_buf + i, name + llen); fname = fname_buf; } else { fname = alloc(i + STRLEN(name + llen) + 1); if (fname == NULL) *error = FCERR_OTHER; else { *tofree = fname; mch_memmove(fname, fname_buf, (size_t)i); STRCPY(fname + i, name + llen); } } return fname; } /* * Concatenate the script ID and function name into "<SNR>99_name". * "buffer" must have size MAX_FUNC_NAME_LEN. */ void func_name_with_sid(char_u *name, int sid, char_u *buffer) { // A script-local function is stored as "<SNR>99_name". buffer[0] = K_SPECIAL; buffer[1] = KS_EXTRA; buffer[2] = (int)KE_SNR; vim_snprintf((char *)buffer + 3, MAX_FUNC_NAME_LEN - 3, "%ld_%s", (long)sid, name); } /* * Find a function "name" in script "sid". */ static ufunc_T * find_func_with_sid(char_u *name, int sid) { hashitem_T *hi; char_u buffer[MAX_FUNC_NAME_LEN]; if (!SCRIPT_ID_VALID(sid)) return NULL; // not in a script func_name_with_sid(name, sid, buffer); hi = hash_find(&func_hashtab, buffer); if (!HASHITEM_EMPTY(hi)) return HI2UF(hi); return NULL; } /* * Find a function "name" in script "sid" prefixing the autoload prefix. */ static ufunc_T * find_func_with_prefix(char_u *name, int sid) { hashitem_T *hi; char_u buffer[MAX_FUNC_NAME_LEN]; scriptitem_T *si; if (vim_strchr(name, AUTOLOAD_CHAR) != NULL) return NULL; // already has the prefix if (!SCRIPT_ID_VALID(sid)) return NULL; // not in a script si = SCRIPT_ITEM(sid); if (si->sn_autoload_prefix != NULL) { size_t len = STRLEN(si->sn_autoload_prefix) + STRLEN(name) + 1; char_u *auto_name; char_u *namep; // skip a "<SNR>99_" prefix namep = untrans_function_name(name); if (namep == NULL) namep = name; // An exported function in an autoload script is stored as // "dir#path#name". if (len < sizeof(buffer)) auto_name = buffer; else auto_name = alloc(len); if (auto_name != NULL) { vim_snprintf((char *)auto_name, len, "%s%s", si->sn_autoload_prefix, namep); hi = hash_find(&func_hashtab, auto_name); if (auto_name != buffer) vim_free(auto_name); if (!HASHITEM_EMPTY(hi)) return HI2UF(hi); } } return NULL; } /* * Find a function by name, return pointer to it in ufuncs. * When "flags" has FFED_IS_GLOBAL don't find script-local or imported * functions. * When "flags" has "FFED_NO_GLOBAL" don't find global functions. * Return NULL for unknown function. */ ufunc_T * find_func_even_dead(char_u *name, int flags) { hashitem_T *hi; ufunc_T *func; if ((flags & FFED_IS_GLOBAL) == 0) { // Find script-local function before global one. if (in_vim9script() && eval_isnamec1(*name) && (name[1] != ':' || *name == 's')) { func = find_func_with_sid(name[0] == 's' && name[1] == ':' ? name + 2 : name, current_sctx.sc_sid); if (func != NULL) return func; } if (in_vim9script() && STRNCMP(name, "<SNR>", 5) == 0) { char_u *p = name + 5; long sid; // printable "<SNR>123_Name" form sid = getdigits(&p); if (*p == '_') { func = find_func_with_sid(p + 1, (int)sid); if (func != NULL) return func; } } } if ((flags & FFED_NO_GLOBAL) == 0) { hi = hash_find(&func_hashtab, STRNCMP(name, "g:", 2) == 0 ? name + 2 : name); if (!HASHITEM_EMPTY(hi)) return HI2UF(hi); } // Find autoload function if this is an autoload script. return find_func_with_prefix(name[0] == 's' && name[1] == ':' ? name + 2 : name, current_sctx.sc_sid); } /* * Find a function by name, return pointer to it in ufuncs. * "cctx" is passed in a :def function to find imported functions. * Return NULL for unknown or dead function. */ ufunc_T * find_func(char_u *name, int is_global) { ufunc_T *fp = find_func_even_dead(name, is_global ? FFED_IS_GLOBAL : 0); if (fp != NULL && (fp->uf_flags & FC_DEAD) == 0) return fp; return NULL; } /* * Return TRUE if "ufunc" is a global function. */ int func_is_global(ufunc_T *ufunc) { return ufunc->uf_name[0] != K_SPECIAL; } /* * Return TRUE if "ufunc" must be called with a g: prefix in Vim9 script. */ int func_requires_g_prefix(ufunc_T *ufunc) { return ufunc->uf_name[0] != K_SPECIAL && (ufunc->uf_flags & FC_LAMBDA) == 0 && vim_strchr(ufunc->uf_name, AUTOLOAD_CHAR) == NULL && !isdigit(ufunc->uf_name[0]); } /* * Copy the function name of "fp" to buffer "buf". * "buf" must be able to hold the function name plus three bytes. * Takes care of script-local function names. */ static void cat_func_name(char_u *buf, ufunc_T *fp) { if (!func_is_global(fp)) { STRCPY(buf, "<SNR>"); STRCAT(buf, fp->uf_name + 3); } else STRCPY(buf, fp->uf_name); } /* * Add a number variable "name" to dict "dp" with value "nr". */ static void add_nr_var( dict_T *dp, dictitem_T *v, char *name, varnumber_T nr) { STRCPY(v->di_key, name); v->di_flags = DI_FLAGS_RO | DI_FLAGS_FIX; hash_add(&dp->dv_hashtab, DI2HIKEY(v), "add variable"); v->di_tv.v_type = VAR_NUMBER; v->di_tv.v_lock = VAR_FIXED; v->di_tv.vval.v_number = nr; } /* * Free "fc". */ static void free_funccal(funccall_T *fc) { int i; for (i = 0; i < fc->fc_ufuncs.ga_len; ++i) { ufunc_T *fp = ((ufunc_T **)(fc->fc_ufuncs.ga_data))[i]; // When garbage collecting a funccall_T may be freed before the // function that references it, clear its uf_scoped field. // The function may have been redefined and point to another // funccall_T, don't clear it then. if (fp != NULL && fp->uf_scoped == fc) fp->uf_scoped = NULL; } ga_clear(&fc->fc_ufuncs); func_ptr_unref(fc->fc_func); vim_free(fc); } /* * Free "fc" and what it contains. * Can be called only when "fc" is kept beyond the period of it called, * i.e. after cleanup_function_call(fc). */ static void free_funccal_contents(funccall_T *fc) { listitem_T *li; // Free all l: variables. vars_clear(&fc->fc_l_vars.dv_hashtab); // Free all a: variables. vars_clear(&fc->fc_l_avars.dv_hashtab); // Free the a:000 variables. FOR_ALL_LIST_ITEMS(&fc->fc_l_varlist, li) clear_tv(&li->li_tv); free_funccal(fc); } /* * Handle the last part of returning from a function: free the local hashtable. * Unless it is still in use by a closure. */ static void cleanup_function_call(funccall_T *fc) { int may_free_fc = fc->fc_refcount <= 0; int free_fc = TRUE; current_funccal = fc->fc_caller; // Free all l: variables if not referred. if (may_free_fc && fc->fc_l_vars.dv_refcount == DO_NOT_FREE_CNT) vars_clear(&fc->fc_l_vars.dv_hashtab); else free_fc = FALSE; // If the a:000 list and the l: and a: dicts are not referenced and // there is no closure using it, we can free the funccall_T and what's // in it. if (may_free_fc && fc->fc_l_avars.dv_refcount == DO_NOT_FREE_CNT) vars_clear_ext(&fc->fc_l_avars.dv_hashtab, FALSE); else { int todo; hashitem_T *hi; dictitem_T *di; free_fc = FALSE; // Make a copy of the a: variables, since we didn't do that above. todo = (int)fc->fc_l_avars.dv_hashtab.ht_used; FOR_ALL_HASHTAB_ITEMS(&fc->fc_l_avars.dv_hashtab, hi, todo) { if (!HASHITEM_EMPTY(hi)) { --todo; di = HI2DI(hi); copy_tv(&di->di_tv, &di->di_tv); } } } if (may_free_fc && fc->fc_l_varlist.lv_refcount == DO_NOT_FREE_CNT) fc->fc_l_varlist.lv_first = NULL; else { listitem_T *li; free_fc = FALSE; // Make a copy of the a:000 items, since we didn't do that above. FOR_ALL_LIST_ITEMS(&fc->fc_l_varlist, li) copy_tv(&li->li_tv, &li->li_tv); } if (free_fc) free_funccal(fc); else { static int made_copy = 0; // "fc" is still in use. This can happen when returning "a:000", // assigning "l:" to a global variable or defining a closure. // Link "fc" in the list for garbage collection later. fc->fc_caller = previous_funccal; previous_funccal = fc; if (want_garbage_collect) // If garbage collector is ready, clear count. made_copy = 0; else if (++made_copy >= (int)((4096 * 1024) / sizeof(*fc))) { // We have made a lot of copies, worth 4 Mbyte. This can happen // when repetitively calling a function that creates a reference to // itself somehow. Call the garbage collector soon to avoid using // too much memory. made_copy = 0; want_garbage_collect = TRUE; } } } /* * Return TRUE if "name" is a numbered function, ignoring a "g:" prefix. */ static int numbered_function(char_u *name) { return isdigit(*name) || (name[0] == 'g' && name[1] == ':' && isdigit(name[2])); } /* * There are two kinds of function names: * 1. ordinary names, function defined with :function or :def; * can start with "<SNR>123_" literally or with K_SPECIAL. * 2. Numbered functions and lambdas: "<lambda>123" * For the first we only count the name stored in func_hashtab as a reference, * using function() does not count as a reference, because the function is * looked up by name. */ int func_name_refcount(char_u *name) { return numbered_function(name) || (name[0] == '<' && name[1] == 'l'); } /* * Unreference "fc": decrement the reference count and free it when it * becomes zero. "fp" is detached from "fc". * When "force" is TRUE we are exiting. */ static void funccal_unref(funccall_T *fc, ufunc_T *fp, int force) { funccall_T **pfc; int i; if (fc == NULL) return; if (--fc->fc_refcount <= 0 && (force || ( fc->fc_l_varlist.lv_refcount == DO_NOT_FREE_CNT && fc->fc_l_vars.dv_refcount == DO_NOT_FREE_CNT && fc->fc_l_avars.dv_refcount == DO_NOT_FREE_CNT))) for (pfc = &previous_funccal; *pfc != NULL; pfc = &(*pfc)->fc_caller) { if (fc == *pfc) { *pfc = fc->fc_caller; free_funccal_contents(fc); return; } } for (i = 0; i < fc->fc_ufuncs.ga_len; ++i) if (((ufunc_T **)(fc->fc_ufuncs.ga_data))[i] == fp) ((ufunc_T **)(fc->fc_ufuncs.ga_data))[i] = NULL; } /* * Remove the function from the function hashtable. If the function was * deleted while it still has references this was already done. * Return TRUE if the entry was deleted, FALSE if it wasn't found. */ static int func_remove(ufunc_T *fp) { hashitem_T *hi; // Return if it was already virtually deleted. if (fp->uf_flags & FC_DEAD) return FALSE; hi = hash_find(&func_hashtab, UF2HIKEY(fp)); if (HASHITEM_EMPTY(hi)) return FALSE; // When there is a def-function index do not actually remove the // function, so we can find the index when defining the function again. // Do remove it when it's a copy. if (fp->uf_def_status == UF_COMPILED && (fp->uf_flags & FC_COPY) == 0) { fp->uf_flags |= FC_DEAD; return FALSE; } hash_remove(&func_hashtab, hi, "remove function"); fp->uf_flags |= FC_DELETED; return TRUE; } static void func_clear_items(ufunc_T *fp) { ga_clear_strings(&(fp->uf_args)); ga_clear_strings(&(fp->uf_def_args)); ga_clear_strings(&(fp->uf_lines)); VIM_CLEAR(fp->uf_arg_types); VIM_CLEAR(fp->uf_block_ids); VIM_CLEAR(fp->uf_va_name); clear_type_list(&fp->uf_type_list); // Increment the refcount of this function to avoid it being freed // recursively when the partial is freed. fp->uf_refcount += 3; partial_unref(fp->uf_partial); fp->uf_partial = NULL; fp->uf_refcount -= 3; #ifdef FEAT_LUA if (fp->uf_cb_free != NULL) { fp->uf_cb_free(fp->uf_cb_state); fp->uf_cb_free = NULL; } fp->uf_cb_state = NULL; fp->uf_cb = NULL; #endif #ifdef FEAT_PROFILE VIM_CLEAR(fp->uf_tml_count); VIM_CLEAR(fp->uf_tml_total); VIM_CLEAR(fp->uf_tml_self); #endif } /* * Free all things that a function contains. Does not free the function * itself, use func_free() for that. * When "force" is TRUE we are exiting. */ static void func_clear(ufunc_T *fp, int force) { if (fp->uf_cleared) return; fp->uf_cleared = TRUE; // clear this function func_clear_items(fp); funccal_unref(fp->uf_scoped, fp, force); unlink_def_function(fp); } /* * Free a function and remove it from the list of functions. Does not free * what a function contains, call func_clear() first. * When "force" is TRUE we are exiting. * Returns OK when the function was actually freed. */ static int func_free(ufunc_T *fp, int force) { // Only remove it when not done already, otherwise we would remove a newer // version of the function with the same name. if ((fp->uf_flags & (FC_DELETED | FC_REMOVED)) == 0) func_remove(fp); if ((fp->uf_flags & FC_DEAD) == 0 || force) { if (fp->uf_dfunc_idx > 0) unlink_def_function(fp); VIM_CLEAR(fp->uf_name_exp); vim_free(fp); return OK; } return FAIL; } /* * Free all things that a function contains and free the function itself. * When "force" is TRUE we are exiting. */ void func_clear_free(ufunc_T *fp, int force) { func_clear(fp, force); if (force || fp->uf_dfunc_idx == 0 || func_name_refcount(fp->uf_name) || (fp->uf_flags & FC_COPY)) func_free(fp, force); else fp->uf_flags |= FC_DEAD; } /* * Copy already defined function "lambda" to a new function with name "global". * This is for when a compiled function defines a global function. */ int copy_lambda_to_global_func( char_u *lambda, char_u *global, loopvarinfo_T *loopvarinfo, ectx_T *ectx) { ufunc_T *ufunc = find_func_even_dead(lambda, FFED_IS_GLOBAL); ufunc_T *fp = NULL; if (ufunc == NULL) { semsg(_(e_lambda_function_not_found_str), lambda); return FAIL; } fp = find_func(global, TRUE); if (fp != NULL) { // TODO: handle ! to overwrite semsg(_(e_function_str_already_exists_add_bang_to_replace), global); return FAIL; } fp = alloc_ufunc(global); if (fp == NULL) return FAIL; fp->uf_varargs = ufunc->uf_varargs; fp->uf_flags = (ufunc->uf_flags & ~FC_VIM9) | FC_COPY; fp->uf_def_status = ufunc->uf_def_status; fp->uf_dfunc_idx = ufunc->uf_dfunc_idx; if (ga_copy_strings(&ufunc->uf_args, &fp->uf_args) == FAIL || ga_copy_strings(&ufunc->uf_def_args, &fp->uf_def_args) == FAIL || ga_copy_strings(&ufunc->uf_lines, &fp->uf_lines) == FAIL) goto failed; if (ufunc->uf_arg_types != NULL) { fp->uf_arg_types = ALLOC_MULT(type_T *, fp->uf_args.ga_len); if (fp->uf_arg_types == NULL) goto failed; mch_memmove(fp->uf_arg_types, ufunc->uf_arg_types, sizeof(type_T *) * fp->uf_args.ga_len); } if (ufunc->uf_va_name != NULL) { fp->uf_va_name = vim_strsave(ufunc->uf_va_name); if (fp->uf_va_name == NULL) goto failed; } fp->uf_ret_type = ufunc->uf_ret_type; fp->uf_refcount = 1; fp->uf_name_exp = NULL; set_ufunc_name(fp, global); hash_add(&func_hashtab, UF2HIKEY(fp), "copy lambda"); // the referenced dfunc_T is now used one more time link_def_function(fp); // Create a partial to store the context of the function where it was // instantiated. Only needs to be done once. Do this on the original // function, "dfunc->df_ufunc" will point to it. if ((ufunc->uf_flags & FC_CLOSURE) && ufunc->uf_partial == NULL) { partial_T *pt = ALLOC_CLEAR_ONE(partial_T); if (pt == NULL) goto failed; if (fill_partial_and_closure(pt, ufunc, loopvarinfo, ectx) == FAIL) { vim_free(pt); goto failed; } ufunc->uf_partial = pt; } return OK; failed: func_clear_free(fp, TRUE); return FAIL; } static int funcdepth = 0; /* * Increment the function call depth count. * Return FAIL when going over 'maxfuncdepth'. * Otherwise return OK, must call funcdepth_decrement() later! */ int funcdepth_increment(void) { if (funcdepth >= p_mfd) { emsg(_(e_function_call_depth_is_higher_than_macfuncdepth)); return FAIL; } ++funcdepth; return OK; } void funcdepth_decrement(void) { --funcdepth; } /* * Get the current function call depth. */ int funcdepth_get(void) { return funcdepth; } /* * Restore the function call depth. This is for cases where there is no * guarantee funcdepth_decrement() can be called exactly the same number of * times as funcdepth_increment(). */ void funcdepth_restore(int depth) { funcdepth = depth; } /* * Allocate a funccall_T, link it in current_funccal and fill in "fp" and * "rettv". * Must be followed by one call to remove_funccal() or cleanup_function_call(). * Returns NULL when allocation fails. */ funccall_T * create_funccal(ufunc_T *fp, typval_T *rettv) { funccall_T *fc = ALLOC_CLEAR_ONE(funccall_T); if (fc == NULL) return NULL; fc->fc_caller = current_funccal; current_funccal = fc; fc->fc_func = fp; func_ptr_ref(fp); fc->fc_rettv = rettv; return fc; } /* * To be called when returning from a compiled function; restores * current_funccal. */ void remove_funccal(void) { funccall_T *fc = current_funccal; current_funccal = fc->fc_caller; free_funccal(fc); } /* * Call a user function. */ static funcerror_T call_user_func( ufunc_T *fp, // pointer to function int argcount, // nr of args typval_T *argvars, // arguments typval_T *rettv, // return value funcexe_T *funcexe, // context dict_T *selfdict) // Dictionary for "self" { sctx_T save_current_sctx; ectx_T *save_current_ectx; int using_sandbox = FALSE; int save_sticky_cmdmod_flags = sticky_cmdmod_flags; funccall_T *fc; int save_did_emsg; funcerror_T retval = FCERR_NONE; int default_arg_err = FALSE; dictitem_T *v; int fixvar_idx = 0; // index in fc_fixvar[] int i; int ai; int islambda = FALSE; char_u numbuf[NUMBUFLEN]; char_u *name; typval_T *tv_to_free[MAX_FUNC_ARGS]; int tv_to_free_len = 0; #ifdef FEAT_PROFILE profinfo_T profile_info; #endif ESTACK_CHECK_DECLARATION; #ifdef FEAT_PROFILE CLEAR_FIELD(profile_info); #endif // If depth of calling is getting too high, don't execute the function. if (funcdepth_increment() == FAIL) { rettv->v_type = VAR_NUMBER; rettv->vval.v_number = -1; return FCERR_FAILED; } line_breakcheck(); // check for CTRL-C hit fc = create_funccal(fp, rettv); if (fc == NULL) return FCERR_OTHER; fc->fc_level = ex_nesting_level; // Check if this function has a breakpoint. fc->fc_breakpoint = dbg_find_breakpoint(FALSE, fp->uf_name, (linenr_T)0); fc->fc_dbg_tick = debug_tick; // Set up fields for closure. ga_init2(&fc->fc_ufuncs, sizeof(ufunc_T *), 1); if (fp->uf_def_status != UF_NOT_COMPILED) { #ifdef FEAT_PROFILE ufunc_T *caller = fc->fc_caller == NULL ? NULL : fc->fc_caller->fc_func; #endif // Execute the function, possibly compiling it first. #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) profile_may_start_func(&profile_info, fp, caller); #endif sticky_cmdmod_flags = 0; if (call_def_function(fp, argcount, argvars, 0, funcexe->fe_partial, funcexe->fe_object, fc, rettv) == FAIL) retval = FCERR_FAILED; funcdepth_decrement(); #ifdef FEAT_PROFILE if (do_profiling == PROF_YES && (fp->uf_profiling || (caller != NULL && caller->uf_profiling))) profile_may_end_func(&profile_info, fp, caller); #endif remove_funccal(); sticky_cmdmod_flags = save_sticky_cmdmod_flags; return retval; } islambda = fp->uf_flags & FC_LAMBDA; /* * Note about using fc->fc_fixvar[]: This is an array of FIXVAR_CNT * variables with names up to VAR_SHORT_LEN long. This avoids having to * alloc/free each argument variable and saves a lot of time. */ /* * Init l: variables. */ init_var_dict(&fc->fc_l_vars, &fc->fc_l_vars_var, VAR_DEF_SCOPE); if (selfdict != NULL) { // Set l:self to "selfdict". Use "name" to avoid a warning from // some compiler that checks the destination size. v = &fc->fc_fixvar[fixvar_idx++].var; name = v->di_key; STRCPY(name, "self"); v->di_flags = DI_FLAGS_RO | DI_FLAGS_FIX; hash_add(&fc->fc_l_vars.dv_hashtab, DI2HIKEY(v), "set self dictionary"); v->di_tv.v_type = VAR_DICT; v->di_tv.v_lock = 0; v->di_tv.vval.v_dict = selfdict; ++selfdict->dv_refcount; } /* * Init a: variables, unless none found (in lambda). * Set a:0 to "argcount" less number of named arguments, if >= 0. * Set a:000 to a list with room for the "..." arguments. */ init_var_dict(&fc->fc_l_avars, &fc->fc_l_avars_var, VAR_SCOPE); if ((fp->uf_flags & FC_NOARGS) == 0) add_nr_var(&fc->fc_l_avars, &fc->fc_fixvar[fixvar_idx++].var, "0", (varnumber_T)(argcount >= fp->uf_args.ga_len ? argcount - fp->uf_args.ga_len : 0)); fc->fc_l_avars.dv_lock = VAR_FIXED; if ((fp->uf_flags & FC_NOARGS) == 0) { // Use "name" to avoid a warning from some compiler that checks the // destination size. v = &fc->fc_fixvar[fixvar_idx++].var; name = v->di_key; STRCPY(name, "000"); v->di_flags = DI_FLAGS_RO | DI_FLAGS_FIX; hash_add(&fc->fc_l_avars.dv_hashtab, DI2HIKEY(v), "function argument"); v->di_tv.v_type = VAR_LIST; v->di_tv.v_lock = VAR_FIXED; v->di_tv.vval.v_list = &fc->fc_l_varlist; } CLEAR_FIELD(fc->fc_l_varlist); fc->fc_l_varlist.lv_refcount = DO_NOT_FREE_CNT; fc->fc_l_varlist.lv_lock = VAR_FIXED; /* * Set a:firstline to "firstline" and a:lastline to "lastline". * Set a:name to named arguments. * Set a:N to the "..." arguments. * Skipped when no a: variables used (in lambda). */ if ((fp->uf_flags & FC_NOARGS) == 0) { add_nr_var(&fc->fc_l_avars, &fc->fc_fixvar[fixvar_idx++].var, "firstline", (varnumber_T)funcexe->fe_firstline); add_nr_var(&fc->fc_l_avars, &fc->fc_fixvar[fixvar_idx++].var, "lastline", (varnumber_T)funcexe->fe_lastline); } for (i = 0; i < argcount || i < fp->uf_args.ga_len; ++i) { int addlocal = FALSE; typval_T def_rettv; int isdefault = FALSE; ai = i - fp->uf_args.ga_len; if (ai < 0) { // named argument a:name name = FUNCARG(fp, i); if (islambda) addlocal = TRUE; // evaluate named argument default expression isdefault = ai + fp->uf_def_args.ga_len >= 0 && (i >= argcount || (argvars[i].v_type == VAR_SPECIAL && argvars[i].vval.v_number == VVAL_NONE)); if (isdefault) { char_u *default_expr = NULL; def_rettv.v_type = VAR_NUMBER; def_rettv.vval.v_number = -1; default_expr = ((char_u **)(fp->uf_def_args.ga_data)) [ai + fp->uf_def_args.ga_len]; if (eval1(&default_expr, &def_rettv, &EVALARG_EVALUATE) == FAIL) { default_arg_err = 1; break; } } } else { if ((fp->uf_flags & FC_NOARGS) != 0) // Bail out if no a: arguments used (in lambda). break; // "..." argument a:1, a:2, etc. sprintf((char *)numbuf, "%d", ai + 1); name = numbuf; } if (fixvar_idx < FIXVAR_CNT && STRLEN(name) <= VAR_SHORT_LEN) { v = &fc->fc_fixvar[fixvar_idx++].var; v->di_flags = DI_FLAGS_RO | DI_FLAGS_FIX; STRCPY(v->di_key, name); } else { v = dictitem_alloc(name); if (v == NULL) break; v->di_flags |= DI_FLAGS_RO | DI_FLAGS_FIX; } // Note: the values are copied directly to avoid alloc/free. // "argvars" must have VAR_FIXED for v_lock. v->di_tv = isdefault ? def_rettv : argvars[i]; v->di_tv.v_lock = VAR_FIXED; if (isdefault) // Need to free this later, no matter where it's stored. tv_to_free[tv_to_free_len++] = &v->di_tv; if (addlocal) { // Named arguments should be accessed without the "a:" prefix in // lambda expressions. Add to the l: dict. copy_tv(&v->di_tv, &v->di_tv); hash_add(&fc->fc_l_vars.dv_hashtab, DI2HIKEY(v), "local variable"); } else hash_add(&fc->fc_l_avars.dv_hashtab, DI2HIKEY(v), "add variable"); if (ai >= 0 && ai < MAX_FUNC_ARGS) { listitem_T *li = &fc->fc_l_listitems[ai]; li->li_tv = argvars[i]; li->li_tv.v_lock = VAR_FIXED; list_append(&fc->fc_l_varlist, li); } } // Don't redraw while executing the function. ++RedrawingDisabled; if (fp->uf_flags & FC_SANDBOX) { using_sandbox = TRUE; ++sandbox; } estack_push_ufunc(fp, 1); ESTACK_CHECK_SETUP; if (p_verbose >= 12) { ++no_wait_return; verbose_enter_scroll(); smsg(_("calling %s"), SOURCING_NAME); if (p_verbose >= 14) { char_u buf[MSG_BUF_LEN]; char_u numbuf2[NUMBUFLEN]; char_u *tofree; char_u *s; msg_puts("("); for (i = 0; i < argcount; ++i) { if (i > 0) msg_puts(", "); if (argvars[i].v_type == VAR_NUMBER) msg_outnum((long)argvars[i].vval.v_number); else { // Do not want errors such as E724 here. ++emsg_off; s = tv2string(&argvars[i], &tofree, numbuf2, 0); --emsg_off; if (s != NULL) { if (vim_strsize(s) > MSG_BUF_CLEN) { trunc_string(s, buf, MSG_BUF_CLEN, MSG_BUF_LEN); s = buf; } msg_puts((char *)s); vim_free(tofree); } } } msg_puts(")"); } msg_puts("\n"); // don't overwrite this either verbose_leave_scroll(); --no_wait_return; } #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) profile_may_start_func(&profile_info, fp, fc->fc_caller == NULL ? NULL : fc->fc_caller->fc_func); #endif // "legacy" does not apply to commands in the function sticky_cmdmod_flags = 0; // If called from a compiled :def function the execution context must be // hidden, any deferred functions need to be added to the function being // executed here. save_current_ectx = clear_current_ectx(); save_current_sctx = current_sctx; current_sctx = fp->uf_script_ctx; save_did_emsg = did_emsg; did_emsg = FALSE; if (default_arg_err && (fp->uf_flags & FC_ABORT)) { did_emsg = TRUE; retval = FCERR_FAILED; } else if (islambda) { char_u *p = *(char_u **)fp->uf_lines.ga_data + 7; // A Lambda always has the command "return {expr}". It is much faster // to evaluate {expr} directly. ++ex_nesting_level; (void)eval1(&p, rettv, &EVALARG_EVALUATE); --ex_nesting_level; } else // call do_cmdline() to execute the lines do_cmdline(NULL, get_func_line, (void *)fc, DOCMD_NOWAIT|DOCMD_VERBOSE|DOCMD_REPEAT); // Invoke functions added with ":defer". handle_defer_one(current_funccal); if (RedrawingDisabled > 0) --RedrawingDisabled; // when the function was aborted because of an error, return -1 if ((did_emsg && (fp->uf_flags & FC_ABORT)) || rettv->v_type == VAR_UNKNOWN) { clear_tv(rettv); rettv->v_type = VAR_NUMBER; rettv->vval.v_number = -1; // In corner cases returning a "failed" value is not backwards // compatible. Only do this for Vim9 script. if (in_vim9script()) retval = FCERR_FAILED; } #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) { ufunc_T *caller = fc->fc_caller == NULL ? NULL : fc->fc_caller->fc_func; if (fp->uf_profiling || (caller != NULL && caller->uf_profiling)) profile_may_end_func(&profile_info, fp, caller); } #endif // when being verbose, mention the return value if (p_verbose >= 12) { ++no_wait_return; verbose_enter_scroll(); if (aborting()) smsg(_("%s aborted"), SOURCING_NAME); else if (fc->fc_rettv->v_type == VAR_NUMBER) smsg(_("%s returning #%ld"), SOURCING_NAME, (long)fc->fc_rettv->vval.v_number); else { char_u buf[MSG_BUF_LEN]; char_u numbuf2[NUMBUFLEN]; char_u *tofree; char_u *s; // The value may be very long. Skip the middle part, so that we // have some idea how it starts and ends. smsg() would always // truncate it at the end. Don't want errors such as E724 here. ++emsg_off; s = tv2string(fc->fc_rettv, &tofree, numbuf2, 0); --emsg_off; if (s != NULL) { if (vim_strsize(s) > MSG_BUF_CLEN) { trunc_string(s, buf, MSG_BUF_CLEN, MSG_BUF_LEN); s = buf; } smsg(_("%s returning %s"), SOURCING_NAME, s); vim_free(tofree); } } msg_puts("\n"); // don't overwrite this either verbose_leave_scroll(); --no_wait_return; } ESTACK_CHECK_NOW; estack_pop(); current_sctx = save_current_sctx; restore_current_ectx(save_current_ectx); #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) script_prof_restore(&profile_info.pi_wait_start); #endif if (using_sandbox) --sandbox; sticky_cmdmod_flags = save_sticky_cmdmod_flags; if (p_verbose >= 12 && SOURCING_NAME != NULL) { ++no_wait_return; verbose_enter_scroll(); smsg(_("continuing in %s"), SOURCING_NAME); msg_puts("\n"); // don't overwrite this either verbose_leave_scroll(); --no_wait_return; } did_emsg |= save_did_emsg; funcdepth_decrement(); for (i = 0; i < tv_to_free_len; ++i) clear_tv(tv_to_free[i]); cleanup_function_call(fc); return retval; } /* * Check the argument count for user function "fp". * Return FCERR_UNKNOWN if OK, FCERR_TOOFEW or FCERR_TOOMANY otherwise. */ funcerror_T check_user_func_argcount(ufunc_T *fp, int argcount) { int regular_args = fp->uf_args.ga_len; if (argcount < regular_args - fp->uf_def_args.ga_len) return FCERR_TOOFEW; else if (!has_varargs(fp) && argcount > regular_args) return FCERR_TOOMANY; return FCERR_UNKNOWN; } /* * Call a user function after checking the arguments. */ funcerror_T call_user_func_check( ufunc_T *fp, int argcount, typval_T *argvars, typval_T *rettv, funcexe_T *funcexe, dict_T *selfdict) { funcerror_T error = FCERR_NONE; #ifdef FEAT_LUA if (fp->uf_flags & FC_CFUNC) { cfunc_T cb = fp->uf_cb; return (*cb)(argcount, argvars, rettv, fp->uf_cb_state); } #endif if (fp->uf_flags & FC_RANGE && funcexe->fe_doesrange != NULL) *funcexe->fe_doesrange = TRUE; error = check_user_func_argcount(fp, argcount); if (error != FCERR_UNKNOWN) return error; if ((fp->uf_flags & FC_DICT) && selfdict == NULL) { error = FCERR_DICT; } else { int did_save_redo = FALSE; save_redo_T save_redo; /* * Call the user function. * Save and restore search patterns, script variables and * redo buffer. */ save_search_patterns(); if (!ins_compl_active()) { saveRedobuff(&save_redo); did_save_redo = TRUE; } ++fp->uf_calls; error = call_user_func(fp, argcount, argvars, rettv, funcexe, (fp->uf_flags & FC_DICT) ? selfdict : NULL); if (--fp->uf_calls <= 0 && fp->uf_refcount <= 0) // Function was unreferenced while being used, free it now. func_clear_free(fp, FALSE); if (did_save_redo) restoreRedobuff(&save_redo); restore_search_patterns(); } return error; } static funccal_entry_T *funccal_stack = NULL; /* * Save the current function call pointer, and set it to NULL. * Used when executing autocommands and for ":source". */ void save_funccal(funccal_entry_T *entry) { entry->top_funccal = current_funccal; entry->next = funccal_stack; funccal_stack = entry; current_funccal = NULL; } void restore_funccal(void) { if (funccal_stack == NULL) internal_error("restore_funccal()"); else { current_funccal = funccal_stack->top_funccal; funccal_stack = funccal_stack->next; } } funccall_T * get_current_funccal(void) { return current_funccal; } /* * Return TRUE when currently at the script level: * - not in a function * - not executing an autocommand * Note that when an autocommand sources a script the result is FALSE; */ int at_script_level(void) { return current_funccal == NULL && autocmd_match == NULL; } /* * Mark all functions of script "sid" as deleted. */ void delete_script_functions(int sid) { hashitem_T *hi; ufunc_T *fp; long_u todo = 1; char_u buf[30]; size_t len; buf[0] = K_SPECIAL; buf[1] = KS_EXTRA; buf[2] = (int)KE_SNR; sprintf((char *)buf + 3, "%d_", sid); len = STRLEN(buf); while (todo > 0) { todo = func_hashtab.ht_used; FOR_ALL_HASHTAB_ITEMS(&func_hashtab, hi, todo) if (!HASHITEM_EMPTY(hi)) { fp = HI2UF(hi); if (STRNCMP(fp->uf_name, buf, len) == 0) { int changed = func_hashtab.ht_changed; fp->uf_flags |= FC_DEAD; if (fp->uf_calls > 0) { // Function is executing, don't free it but do remove // it from the hashtable. if (func_remove(fp)) fp->uf_refcount--; } else { func_clear(fp, TRUE); // When clearing a function another function can be // cleared as a side effect. When that happens start // over. if (changed != func_hashtab.ht_changed) break; } } --todo; } } } #if defined(EXITFREE) || defined(PROTO) void free_all_functions(void) { hashitem_T *hi; ufunc_T *fp; long_u skipped = 0; long_u todo = 1; int changed; // Clean up the current_funccal chain and the funccal stack. while (current_funccal != NULL) { clear_tv(current_funccal->fc_rettv); cleanup_function_call(current_funccal); if (current_funccal == NULL && funccal_stack != NULL) restore_funccal(); } // First clear what the functions contain. Since this may lower the // reference count of a function, it may also free a function and change // the hash table. Restart if that happens. while (todo > 0) { todo = func_hashtab.ht_used; FOR_ALL_HASHTAB_ITEMS(&func_hashtab, hi, todo) if (!HASHITEM_EMPTY(hi)) { // clear the def function index now fp = HI2UF(hi); fp->uf_flags &= ~FC_DEAD; fp->uf_def_status = UF_NOT_COMPILED; // Only free functions that are not refcounted, those are // supposed to be freed when no longer referenced. if (func_name_refcount(fp->uf_name)) ++skipped; else { changed = func_hashtab.ht_changed; func_clear(fp, TRUE); if (changed != func_hashtab.ht_changed) { skipped = 0; break; } } --todo; } } // Now actually free the functions. Need to start all over every time, // because func_free() may change the hash table. skipped = 0; while (func_hashtab.ht_used > skipped) { todo = func_hashtab.ht_used; FOR_ALL_HASHTAB_ITEMS(&func_hashtab, hi, todo) if (!HASHITEM_EMPTY(hi)) { --todo; // Only free functions that are not refcounted, those are // supposed to be freed when no longer referenced. fp = HI2UF(hi); if (func_name_refcount(fp->uf_name)) ++skipped; else { if (func_free(fp, FALSE) == OK) { skipped = 0; break; } // did not actually free it ++skipped; } } } if (skipped == 0) hash_clear(&func_hashtab); free_def_functions(); } #endif /* * Return TRUE if "name" looks like a builtin function name: starts with a * lower case letter, doesn't contain AUTOLOAD_CHAR or ':', no "." after the * name. * "len" is the length of "name", or -1 for NUL terminated. */ int builtin_function(char_u *name, int len) { int i; if (!ASCII_ISLOWER(name[0]) || name[1] == ':') return FALSE; for (i = 0; name[i] != NUL && (len < 0 || i < len); ++i) { if (name[i] == AUTOLOAD_CHAR) return FALSE; if (!eval_isnamec(name[i])) { // "name.something" is not a builtin function if (name[i] == '.') return FALSE; break; } } return TRUE; } int func_call( char_u *name, typval_T *args, partial_T *partial, dict_T *selfdict, typval_T *rettv) { list_T *l = args->vval.v_list; listitem_T *item; typval_T argv[MAX_FUNC_ARGS + 1]; int argc = 0; int r = 0; CHECK_LIST_MATERIALIZE(l); FOR_ALL_LIST_ITEMS(l, item) { if (argc == MAX_FUNC_ARGS - (partial == NULL ? 0 : partial->pt_argc)) { emsg(_(e_too_many_arguments)); break; } // Make a copy of each argument. This is needed to be able to set // v_lock to VAR_FIXED in the copy without changing the original list. copy_tv(&item->li_tv, &argv[argc++]); } if (item == NULL) { funcexe_T funcexe; CLEAR_FIELD(funcexe); funcexe.fe_firstline = curwin->w_cursor.lnum; funcexe.fe_lastline = curwin->w_cursor.lnum; funcexe.fe_evaluate = TRUE; funcexe.fe_partial = partial; funcexe.fe_selfdict = selfdict; r = call_func(name, -1, rettv, argc, argv, &funcexe); } // Free the arguments. while (argc > 0) clear_tv(&argv[--argc]); return r; } static int callback_depth = 0; int get_callback_depth(void) { return callback_depth; } /* * Invoke call_func() with a callback. * Returns FAIL if the callback could not be called. */ int call_callback( callback_T *callback, int len, // length of "name" or -1 to use strlen() typval_T *rettv, // return value goes here int argcount, // number of "argvars" typval_T *argvars) // vars for arguments, must have "argcount" // PLUS ONE elements! { funcexe_T funcexe; int ret; if (callback->cb_name == NULL || *callback->cb_name == NUL) return FAIL; CLEAR_FIELD(funcexe); funcexe.fe_evaluate = TRUE; funcexe.fe_partial = callback->cb_partial; ++callback_depth; ret = call_func(callback->cb_name, len, rettv, argcount, argvars, &funcexe); --callback_depth; // When a :def function was called that uses :try an error would be turned // into an exception. Need to give the error here. if (need_rethrow && current_exception != NULL && trylevel == 0) { need_rethrow = FALSE; handle_did_throw(); } return ret; } /* * call the 'callback' function and return the result as a number. * Returns -2 when calling the function fails. Uses argv[0] to argv[argc - 1] * for the function arguments. argv[argc] should have type VAR_UNKNOWN. */ varnumber_T call_callback_retnr( callback_T *callback, int argcount, // number of "argvars" typval_T *argvars) // vars for arguments, must have "argcount" // PLUS ONE elements! { typval_T rettv; varnumber_T retval; if (call_callback(callback, -1, &rettv, argcount, argvars) == FAIL) return -2; retval = tv_get_number_chk(&rettv, NULL); clear_tv(&rettv); return retval; } /* * Give an error message for the result of a function. * Nothing if "error" is FCERR_NONE. */ void user_func_error(funcerror_T error, char_u *name, int found_var) { switch (error) { case FCERR_UNKNOWN: if (found_var) emsg_funcname(e_not_callable_type_str, name); else emsg_funcname(e_unknown_function_str, name); break; case FCERR_NOTMETHOD: emsg_funcname(e_cannot_use_function_as_method_str, name); break; case FCERR_DELETED: emsg_funcname(e_function_was_deleted_str, name); break; case FCERR_TOOMANY: emsg_funcname(e_too_many_arguments_for_function_str, name); break; case FCERR_TOOFEW: emsg_funcname(e_not_enough_arguments_for_function_str, name); break; case FCERR_SCRIPT: emsg_funcname(e_using_sid_not_in_script_context_str, name); break; case FCERR_DICT: emsg_funcname(e_calling_dict_function_without_dictionary_str, name); break; case FCERR_OTHER: case FCERR_FAILED: // assume the error message was already given break; case FCERR_NONE: break; } } /* * Check the argument types "argvars[argcount]" for "name" using the * information in "funcexe". When "base_included" then "funcexe->fe_basetv" * is already included in "argvars[]". * Will do nothing if "funcexe->fe_check_type" is NULL or * "funcexe->fe_evaluate" is FALSE; * Returns an FCERR_ value. */ static funcerror_T may_check_argument_types( funcexe_T *funcexe, typval_T *argvars, int argcount, int base_included, char_u *name) { if (funcexe->fe_check_type != NULL && funcexe->fe_evaluate) { // Check that the argument types are OK for the types of the funcref. if (check_argument_types(funcexe->fe_check_type, argvars, argcount, base_included ? NULL : funcexe->fe_basetv, name) == FAIL) return FCERR_OTHER; } return FCERR_NONE; } /* * Call a function with its resolved parameters * * Return FAIL when the function can't be called, OK otherwise. * Also returns OK when an error was encountered while executing the function. */ int call_func( char_u *funcname, // name of the function int len, // length of "name" or -1 to use strlen() typval_T *rettv, // return value goes here int argcount_in, // number of "argvars" typval_T *argvars_in, // vars for arguments, must have "argcount" // PLUS ONE elements! funcexe_T *funcexe) // more arguments { int ret = FAIL; funcerror_T error = FCERR_NONE; int i; ufunc_T *fp = NULL; char_u fname_buf[FLEN_FIXED + 1]; char_u *tofree = NULL; char_u *fname = NULL; char_u *name = NULL; int argcount = argcount_in; typval_T *argvars = argvars_in; dict_T *selfdict = funcexe->fe_selfdict; typval_T argv[MAX_FUNC_ARGS + 1]; // used when "partial" or // "funcexe->fe_basetv" is not NULL int argv_clear = 0; int argv_base = 0; partial_T *partial = funcexe->fe_partial; type_T check_type; type_T *check_type_args[MAX_FUNC_ARGS]; // Initialize rettv so that it is safe for caller to invoke clear_tv(rettv) // even when call_func() returns FAIL. rettv->v_type = VAR_UNKNOWN; if (partial != NULL) fp = partial->pt_func; if (fp == NULL) fp = funcexe->fe_ufunc; if (fp == NULL) { // Make a copy of the name, if it comes from a funcref variable it // could be changed or deleted in the called function. name = len > 0 ? vim_strnsave(funcname, len) : vim_strsave(funcname); if (name == NULL) return ret; fname = fname_trans_sid(name, fname_buf, &tofree, &error); } if (funcexe->fe_doesrange != NULL) *funcexe->fe_doesrange = FALSE; if (partial != NULL) { // When the function has a partial with a dict and there is a dict // argument, use the dict argument. That is backwards compatible. // When the dict was bound explicitly use the one from the partial. if (partial->pt_dict != NULL && (selfdict == NULL || !partial->pt_auto)) selfdict = partial->pt_dict; if (error == FCERR_NONE && partial->pt_argc > 0) { for (argv_clear = 0; argv_clear < partial->pt_argc; ++argv_clear) { if (argv_clear + argcount_in >= MAX_FUNC_ARGS) { error = FCERR_TOOMANY; goto theend; } copy_tv(&partial->pt_argv[argv_clear], &argv[argv_clear]); } for (i = 0; i < argcount_in; ++i) argv[i + argv_clear] = argvars_in[i]; argvars = argv; argcount = partial->pt_argc + argcount_in; if (funcexe->fe_check_type != NULL && funcexe->fe_check_type->tt_argcount != -1) { // Now funcexe->fe_check_type is missing the added arguments, // make a copy of the type with the correction. check_type = *funcexe->fe_check_type; funcexe->fe_check_type = &check_type; check_type.tt_args = check_type_args; CLEAR_FIELD(check_type_args); for (i = 0; i < check_type.tt_argcount; ++i) check_type_args[i + partial->pt_argc] = check_type.tt_args[i]; check_type.tt_argcount += partial->pt_argc; check_type.tt_min_argcount += partial->pt_argc; } } } if (error == FCERR_NONE) // check the argument types if possible error = may_check_argument_types(funcexe, argvars, argcount, FALSE, (name != NULL) ? name : funcname); if (error == FCERR_NONE && funcexe->fe_evaluate) { char_u *rfname = fname; int is_global = FALSE; // Skip "g:" before a function name. if (fp == NULL && fname[0] == 'g' && fname[1] == ':') { is_global = TRUE; rfname = fname + 2; } rettv->v_type = VAR_NUMBER; // default rettv is number zero rettv->vval.v_number = 0; error = FCERR_UNKNOWN; if (fp != NULL || !builtin_function(rfname, -1)) { /* * User defined function. */ if (fp == NULL) { fp = find_func(rfname, is_global); if (fp != NULL && !is_global && in_vim9script() && func_requires_g_prefix(fp)) // In Vim9 script g: is required to find a global // non-autoload function. fp = NULL; } // Trigger FuncUndefined event, may load the function. if (fp == NULL && apply_autocmds(EVENT_FUNCUNDEFINED, rfname, rfname, TRUE, NULL) && !aborting()) { // executed an autocommand, search for the function again fp = find_func(rfname, is_global); } // Try loading a package. if (fp == NULL && script_autoload(rfname, TRUE) && !aborting()) { // loaded a package, search for the function again fp = find_func(rfname, is_global); } if (fp == NULL) { char_u *p = untrans_function_name(rfname); // If using Vim9 script try not local to the script. // Don't do this if the name starts with "s:". if (p != NULL && (funcname[0] != 's' || funcname[1] != ':')) fp = find_func(p, is_global); } if (fp != NULL && (fp->uf_flags & FC_DELETED)) error = FCERR_DELETED; else if (fp != NULL) { int need_arg_check = FALSE; if (funcexe->fe_check_type == NULL) { funcexe->fe_check_type = fp->uf_func_type; need_arg_check = TRUE; } if (funcexe->fe_argv_func != NULL) { // postponed filling in the arguments, do it now argcount = funcexe->fe_argv_func(argcount, argvars, argv_clear, fp); need_arg_check = TRUE; } if (funcexe->fe_basetv != NULL) { // Method call: base->Method() mch_memmove(&argv[1], argvars, sizeof(typval_T) * argcount); argv[0] = *funcexe->fe_basetv; argcount++; argvars = argv; argv_base = 1; need_arg_check = TRUE; } // Check the argument types now that the function type and all // argument values are known, if not done above. if (need_arg_check) error = may_check_argument_types(funcexe, argvars, argcount, TRUE, (name != NULL) ? name : funcname); if (error == FCERR_NONE || error == FCERR_UNKNOWN) error = call_user_func_check(fp, argcount, argvars, rettv, funcexe, selfdict); } } else if (funcexe->fe_basetv != NULL) { /* * expr->method(): Find the method name in the table, call its * implementation with the base as one of the arguments. */ error = call_internal_method(fname, argcount, argvars, rettv, funcexe->fe_basetv); } else { /* * Find the function name in the table, call its implementation. */ error = call_internal_func(fname, argcount, argvars, rettv); } /* * The function call (or "FuncUndefined" autocommand sequence) might * have been aborted by an error, an interrupt, or an explicitly thrown * exception that has not been caught so far. This situation can be * tested for by calling aborting(). For an error in an internal * function or for the "E132" error in call_user_func(), however, the * throw point at which the "force_abort" flag (temporarily reset by * emsg()) is normally updated has not been reached yet. We need to * update that flag first to make aborting() reliable. */ update_force_abort(); } if (error == FCERR_NONE) ret = OK; theend: /* * Report an error unless the argument evaluation or function call has been * cancelled due to an aborting error, an interrupt, or an exception. */ if (!aborting()) user_func_error(error, (name != NULL) ? name : funcname, funcexe->fe_found_var); // clear the copies made from the partial while (argv_clear > 0) clear_tv(&argv[--argv_clear + argv_base]); vim_free(tofree); vim_free(name); return ret; } /* * Call a function without arguments, partial or dict. * This is like call_func() when the call is only "FuncName()". * To be used by "expr" options. * Returns NOTDONE when the function could not be found. */ int call_simple_func( char_u *funcname, // name of the function int len, // length of "name" or -1 to use strlen() typval_T *rettv) // return value goes here { int ret = FAIL; funcerror_T error = FCERR_NONE; char_u fname_buf[FLEN_FIXED + 1]; char_u *tofree = NULL; char_u *name; char_u *fname; char_u *rfname; int is_global = FALSE; ufunc_T *fp; rettv->v_type = VAR_NUMBER; // default rettv is number zero rettv->vval.v_number = 0; // Make a copy of the name, an option can be changed in the function. name = vim_strnsave(funcname, len); if (name == NULL) return ret; fname = fname_trans_sid(name, fname_buf, &tofree, &error); // Skip "g:" before a function name. if (fname[0] == 'g' && fname[1] == ':') { is_global = TRUE; rfname = fname + 2; } else rfname = fname; fp = find_func(rfname, is_global); if (fp != NULL && !is_global && in_vim9script() && func_requires_g_prefix(fp)) // In Vim9 script g: is required to find a global non-autoload // function. fp = NULL; if (fp == NULL) ret = NOTDONE; else if (fp != NULL && (fp->uf_flags & FC_DELETED)) error = FCERR_DELETED; else if (fp != NULL) { typval_T argvars[1]; funcexe_T funcexe; argvars[0].v_type = VAR_UNKNOWN; CLEAR_FIELD(funcexe); funcexe.fe_evaluate = TRUE; error = call_user_func_check(fp, 0, argvars, rettv, &funcexe, NULL); if (error == FCERR_NONE) ret = OK; } user_func_error(error, name, FALSE); vim_free(tofree); vim_free(name); return ret; } char_u * printable_func_name(ufunc_T *fp) { return fp->uf_name_exp != NULL ? fp->uf_name_exp : fp->uf_name; } /* * When "prev_ht_changed" does not equal "ht_changed" give an error and return * TRUE. Otherwise return FALSE. */ static int function_list_modified(int prev_ht_changed) { if (prev_ht_changed != func_hashtab.ht_changed) { emsg(_(e_function_list_was_modified)); return TRUE; } return FALSE; } /* * List the head of the function: "function name(arg1, arg2)". */ static int list_func_head(ufunc_T *fp, int indent) { int prev_ht_changed = func_hashtab.ht_changed; int j; msg_start(); // a timer at the more prompt may have deleted the function if (function_list_modified(prev_ht_changed)) return FAIL; if (indent) msg_puts(" "); if (fp->uf_def_status != UF_NOT_COMPILED) msg_puts("def "); else msg_puts("function "); msg_puts((char *)printable_func_name(fp)); msg_putchar('('); for (j = 0; j < fp->uf_args.ga_len; ++j) { if (j) msg_puts(", "); msg_puts((char *)FUNCARG(fp, j)); if (fp->uf_arg_types != NULL) { char *tofree; msg_puts(": "); msg_puts(type_name(fp->uf_arg_types[j], &tofree)); vim_free(tofree); } if (j >= fp->uf_args.ga_len - fp->uf_def_args.ga_len) { msg_puts(" = "); msg_puts(((char **)(fp->uf_def_args.ga_data)) [j - fp->uf_args.ga_len + fp->uf_def_args.ga_len]); } } if (fp->uf_varargs) { if (j) msg_puts(", "); msg_puts("..."); } if (fp->uf_va_name != NULL) { if (!fp->uf_varargs) { if (j) msg_puts(", "); msg_puts("..."); } msg_puts((char *)fp->uf_va_name); if (fp->uf_va_type != NULL) { char *tofree; msg_puts(": "); msg_puts(type_name(fp->uf_va_type, &tofree)); vim_free(tofree); } } msg_putchar(')'); if (fp->uf_def_status != UF_NOT_COMPILED) { if (fp->uf_ret_type != &t_void) { char *tofree; msg_puts(": "); msg_puts(type_name(fp->uf_ret_type, &tofree)); vim_free(tofree); } } else if (fp->uf_flags & FC_ABORT) msg_puts(" abort"); if (fp->uf_flags & FC_RANGE) msg_puts(" range"); if (fp->uf_flags & FC_DICT) msg_puts(" dict"); if (fp->uf_flags & FC_CLOSURE) msg_puts(" closure"); msg_clr_eos(); if (p_verbose > 0) last_set_msg(fp->uf_script_ctx); return OK; } /* * Get a function name, translating "<SID>" and "<SNR>". * Also handles a Funcref in a List or Dictionary. * Returns the function name in allocated memory, or NULL for failure. * Set "*is_global" to TRUE when the function must be global, unless * "is_global" is NULL. * flags: * TFN_INT: internal function name OK * TFN_IN_CLASS: function in a class * TFN_QUIET: be quiet * TFN_NO_AUTOLOAD: do not use script autoloading * TFN_NO_DEREF: do not dereference a Funcref * Advances "pp" to just after the function name (if no error). */ char_u * trans_function_name( char_u **pp, int *is_global, int skip, // only find the end, don't evaluate int flags) { return trans_function_name_ext(pp, is_global, skip, flags, NULL, NULL, NULL, NULL); } /* * trans_function_name() with extra arguments. * "fdp", "partial", "type" and "ufunc" can be NULL. */ char_u * trans_function_name_ext( char_u **pp, int *is_global, int skip, // only find the end, don't evaluate int flags, funcdict_T *fdp, // return: info about dictionary used partial_T **partial, // return: partial of a FuncRef type_T **type, // return: type of funcref ufunc_T **ufunc) // return: function { char_u *name = NULL; char_u *start; char_u *end; int lead; char_u sid_buf[20]; int len; int extra = 0; int prefix_g = FALSE; lval_T lv; int vim9script = in_vim9script(); int vim9_local; if (fdp != NULL) CLEAR_POINTER(fdp); start = *pp; // Check for hard coded <SNR>: already translated function ID (from a user // command). if ((*pp)[0] == K_SPECIAL && (*pp)[1] == KS_EXTRA && (*pp)[2] == (int)KE_SNR) { *pp += 3; len = get_id_len(pp) + 3; return vim_strnsave(start, len); } // A name starting with "<SID>" or "<SNR>" is local to a script. But // don't skip over "s:", get_lval() needs it for "s:dict.func". lead = eval_fname_script(start); if (lead > 2) start += lead; // Note that TFN_ flags use the same values as GLV_ flags. end = get_lval(start, NULL, &lv, FALSE, skip, flags | GLV_READ_ONLY | GLV_PREFER_FUNC, lead > 2 ? 0 : FNE_CHECK_START); if (end == start || (vim9script && end != NULL && end[-1] == AUTOLOAD_CHAR && *end == '(')) { if (!skip) emsg(_(e_function_name_required)); goto theend; } if (end == NULL || (lv.ll_tv != NULL && (lead > 2 || lv.ll_range))) { /* * Report an invalid expression in braces, unless the expression * evaluation has been cancelled due to an aborting error, an * interrupt, or an exception. */ if (!aborting()) { if (end != NULL) semsg(_(e_invalid_argument_str), start); } else *pp = find_name_end(start, NULL, NULL, FNE_INCL_BR); goto theend; } if (lv.ll_ufunc != NULL) { if (ufunc != NULL) *ufunc = lv.ll_ufunc; name = vim_strsave(lv.ll_ufunc->uf_name); *pp = end; goto theend; } if (lv.ll_tv != NULL) { if (fdp != NULL) { fdp->fd_dict = lv.ll_dict; fdp->fd_newkey = lv.ll_newkey; lv.ll_newkey = NULL; fdp->fd_di = lv.ll_di; } if (lv.ll_tv->v_type == VAR_FUNC && lv.ll_tv->vval.v_string != NULL) { name = vim_strsave(lv.ll_tv->vval.v_string); *pp = end; } else if (lv.ll_tv->v_type == VAR_CLASS && lv.ll_tv->vval.v_class != NULL) { name = vim_strsave(lv.ll_tv->vval.v_class->class_name); *pp = end; } else if (lv.ll_tv->v_type == VAR_PARTIAL && lv.ll_tv->vval.v_partial != NULL) { name = vim_strsave(partial_name(lv.ll_tv->vval.v_partial)); *pp = end; if (partial != NULL) *partial = lv.ll_tv->vval.v_partial; } else { if (!skip && !(flags & TFN_QUIET) && (fdp == NULL || lv.ll_dict == NULL || fdp->fd_newkey == NULL)) emsg(_(e_funcref_required)); else *pp = end; name = NULL; } goto theend; } if (lv.ll_name == NULL) { // Error found, but continue after the function name. *pp = end; goto theend; } // Check if the name is a Funcref. If so, use the value. if (lv.ll_exp_name != NULL) { len = (int)STRLEN(lv.ll_exp_name); name = deref_func_name(lv.ll_exp_name, &len, partial, type, flags & TFN_NO_AUTOLOAD, flags & TFN_NEW_FUNC, NULL); if (name == lv.ll_exp_name) name = NULL; } else if (lv.ll_sid > 0) { scriptitem_T *si = SCRIPT_ITEM(lv.ll_sid); int cc = *lv.ll_name_end; // function in another script. Prefix <SNR>99_ or the autoload prefix. *lv.ll_name_end = NUL; if (si->sn_autoload_prefix != NULL) { name = concat_str(si->sn_autoload_prefix, lv.ll_name); } else { sid_buf[0] = K_SPECIAL; sid_buf[1] = KS_EXTRA; sid_buf[2] = (int)KE_SNR; vim_snprintf((char *)sid_buf + 3, sizeof(sid_buf) - 3, "%ld_", (long)lv.ll_sid); name = concat_str(sid_buf, lv.ll_name); } *lv.ll_name_end = cc; *pp = end; goto theend; } else if (!(flags & TFN_NO_DEREF)) { len = (int)(end - *pp); name = deref_func_name(*pp, &len, partial, type, flags & TFN_NO_AUTOLOAD, flags & TFN_NEW_FUNC, NULL); if (name == *pp) name = NULL; } if (name != NULL) { name = vim_strsave(name); *pp = end; if (STRNCMP(name, "<SNR>", 5) == 0) { // Change "<SNR>" to the byte sequence. name[0] = K_SPECIAL; name[1] = KS_EXTRA; name[2] = (int)KE_SNR; mch_memmove(name + 3, name + 5, STRLEN(name + 5) + 1); } goto theend; } if (lv.ll_exp_name != NULL) { len = (int)STRLEN(lv.ll_exp_name); if (lead <= 2 && lv.ll_name == lv.ll_exp_name && STRNCMP(lv.ll_name, "s:", 2) == 0) { // When there was "s:" already or the name expanded to get a // leading "s:" then remove it. lv.ll_name += 2; len -= 2; lead = 2; } } else { // skip over "s:" and "g:" if (lead == 2 || (lv.ll_name[0] == 'g' && lv.ll_name[1] == ':')) { if (lv.ll_name[0] == 'g') { if (is_global != NULL) { *is_global = TRUE; } else { // dropping "g:" without setting "is_global" won't work in // Vim9script, put it back later prefix_g = TRUE; extra = 2; } } lv.ll_name += 2; } len = (int)(end - lv.ll_name); } if (len <= 0) { if (!skip) emsg(_(e_function_name_required)); goto theend; } // In Vim9 script a user function is script-local by default, unless it // starts with a lower case character: dict.func(). Or when in a class. vim9_local = ASCII_ISUPPER(*start) && vim9script && (flags & TFN_IN_CLASS) == 0; /* * Copy the function name to allocated memory. * Accept <SID>name() inside a script, translate into <SNR>123_name(). * Accept <SNR>123_name() outside a script. */ if (skip) lead = 0; // do nothing else if (lead > 0 || vim9_local) { if (!vim9_local) { if (vim9script && lead == 2 && !ASCII_ISUPPER(*lv.ll_name) && current_script_is_vim9()) { semsg(_(e_function_name_must_start_with_capital_str), start); goto theend; } lead = 3; } if (vim9_local || (lv.ll_exp_name != NULL && eval_fname_sid(lv.ll_exp_name)) || eval_fname_sid(*pp)) { // It's script-local, "s:" or "<SID>" if (current_sctx.sc_sid <= 0) { emsg(_(e_using_sid_not_in_script_context)); goto theend; } sprintf((char *)sid_buf, "%ld_", (long)current_sctx.sc_sid); if (vim9_local) extra = 3 + (int)STRLEN(sid_buf); else lead += (int)STRLEN(sid_buf); } } else if (!(flags & TFN_INT) && (builtin_function(lv.ll_name, len) || (vim9script && *lv.ll_name == '_')) && !((flags & TFN_IN_CLASS) && STRNCMP(lv.ll_name, "new", 3) == 0)) { semsg(_(vim9script ? e_function_name_must_start_with_capital_str : e_function_name_must_start_with_capital_or_s_str), start); goto theend; } if (!skip && !(flags & TFN_QUIET) && !(flags & TFN_NO_DEREF)) { char_u *cp = vim_strchr(lv.ll_name, ':'); if (cp != NULL && cp < end) { semsg(_(e_function_name_cannot_contain_colon_str), start); goto theend; } } name = alloc(len + lead + extra + 1); if (name != NULL) { if (!skip && (lead > 0 || vim9_local)) { name[0] = K_SPECIAL; name[1] = KS_EXTRA; name[2] = (int)KE_SNR; if (vim9_local || lead > 3) // If it's "<SID>" STRCPY(name + 3, sid_buf); } else if (prefix_g) { name[0] = 'g'; name[1] = ':'; } mch_memmove(name + lead + extra, lv.ll_name, (size_t)len); name[lead + extra + len] = NUL; } *pp = end; theend: clear_lval(&lv); return name; } /* * Assuming "name" is the result of trans_function_name() and it was prefixed * to use the script-local name, return the unmodified name (points into * "name"). Otherwise return NULL. * This can be used to first search for a script-local function and fall back * to the global function if not found. */ static char_u * untrans_function_name(char_u *name) { char_u *p; if (*name == K_SPECIAL && in_vim9script()) { p = vim_strchr(name, '_'); if (p != NULL) return p + 1; } return NULL; } /* * If the 'funcname' starts with "s:" or "<SID>", then expands it to the * current script ID and returns the expanded function name. The caller should * free the returned name. If not called from a script context or the function * name doesn't start with these prefixes, then returns NULL. * This doesn't check whether the script-local function exists or not. */ char_u * get_scriptlocal_funcname(char_u *funcname) { char sid_buf[25]; int off; char_u *newname; char_u *p = funcname; if (funcname == NULL) return NULL; if (STRNCMP(funcname, "s:", 2) != 0 && STRNCMP(funcname, "<SID>", 5) != 0) { ufunc_T *ufunc; // The function name does not have a script-local prefix. Try finding // it when in a Vim9 script and there is no "g:" prefix. if (!in_vim9script() || STRNCMP(funcname, "g:", 2) == 0) return NULL; ufunc = find_func(funcname, FALSE); if (ufunc == NULL || func_is_global(ufunc) || (p = vim_strchr(ufunc->uf_name, '_')) == NULL) return NULL; ++p; off = 0; } else off = *funcname == 's' ? 2 : 5; if (!SCRIPT_ID_VALID(current_sctx.sc_sid)) { emsg(_(e_using_sid_not_in_script_context)); return NULL; } // Expand s: prefix into <SNR>nr_<name> vim_snprintf(sid_buf, sizeof(sid_buf), "<SNR>%ld_", (long)current_sctx.sc_sid); newname = alloc(STRLEN(sid_buf) + STRLEN(p + off) + 1); if (newname == NULL) return NULL; STRCPY(newname, sid_buf); STRCAT(newname, p + off); return newname; } /* * Return script-local "fname" with the 3-byte sequence replaced by * printable <SNR> in allocated memory. */ char_u * alloc_printable_func_name(char_u *fname) { char_u *n = alloc(STRLEN(fname + 3) + 6); if (n != NULL) { STRCPY(n, "<SNR>"); STRCPY(n + 5, fname + 3); } return n; } /* * Call trans_function_name(), except that a lambda is returned as-is. * Returns the name in allocated memory. */ char_u * save_function_name( char_u **name, int *is_global, int skip, int flags, funcdict_T *fudi) { char_u *p = *name; char_u *saved; if (STRNCMP(p, "<lambda>", 8) == 0) { p += 8; (void)getdigits(&p); saved = vim_strnsave(*name, p - *name); if (fudi != NULL) CLEAR_POINTER(fudi); } else saved = trans_function_name_ext(&p, is_global, skip, flags, fudi, NULL, NULL, NULL); *name = p; return saved; } /* * List functions. When "regmatch" is NULL all of then. * Otherwise functions matching "regmatch". */ void list_functions(regmatch_T *regmatch) { int prev_ht_changed = func_hashtab.ht_changed; long_u todo = func_hashtab.ht_used; hashitem_T *hi; for (hi = func_hashtab.ht_array; todo > 0 && !got_int; ++hi) { if (!HASHITEM_EMPTY(hi)) { ufunc_T *fp = HI2UF(hi); --todo; if ((fp->uf_flags & FC_DEAD) == 0 && (regmatch == NULL ? !message_filtered(fp->uf_name) && !func_name_refcount(fp->uf_name) : !isdigit(*fp->uf_name) && vim_regexec(regmatch, fp->uf_name, 0))) { if (list_func_head(fp, FALSE) == FAIL) return; if (function_list_modified(prev_ht_changed)) return; } } } } /* * ":function" also supporting nested ":def". * When "name_arg" is not NULL this is a nested function, using "name_arg" for * the function name. * "lines_to_free" is a list of strings to be freed later. * If "class_flags" has CF_CLASS then the function is defined inside a class. * With CF_INTERFACE the function is define inside an interface, only the * ":def"/":function" line is expected, no function body. * Returns a pointer to the function or NULL if no function defined. */ ufunc_T * define_function( exarg_T *eap, char_u *name_arg, garray_T *lines_to_free, int class_flags) { int j; int c; int saved_did_emsg = FALSE; char_u *name = name_arg; int is_global = FALSE; char_u *p; char_u *arg; char_u *whitep; char_u *line_arg = NULL; garray_T newargs; garray_T argtypes; garray_T default_args; garray_T newlines; int varargs = FALSE; int flags = 0; char_u *ret_type = NULL; ufunc_T *fp = NULL; int fp_allocated = FALSE; int free_fp = FALSE; int overwrite = FALSE; dictitem_T *v; funcdict_T fudi; static int func_nr = 0; // number for nameless function int paren; hashitem_T *hi; linenr_T sourcing_lnum_top; int vim9script = in_vim9script(); imported_T *import = NULL; /* * ":function" without argument: list functions. */ if (ends_excmd2(eap->cmd, eap->arg)) { if (!eap->skip) list_functions(NULL); set_nextcmd(eap, eap->arg); return NULL; } /* * ":function /pat": list functions matching pattern. */ if (*eap->arg == '/') { p = skip_regexp(eap->arg + 1, '/', TRUE); if (!eap->skip) { regmatch_T regmatch; c = *p; *p = NUL; regmatch.regprog = vim_regcomp(eap->arg + 1, RE_MAGIC); *p = c; if (regmatch.regprog != NULL) { regmatch.rm_ic = p_ic; list_functions(®match); vim_regfree(regmatch.regprog); } } if (*p == '/') ++p; set_nextcmd(eap, p); return NULL; } ga_init(&newargs); ga_init(&argtypes); ga_init(&default_args); /* * Get the function name. There are these situations: * func normal function name, also when "class_flags" is non-zero * "name" == func, "fudi.fd_dict" == NULL * dict.func new dictionary entry * "name" == NULL, "fudi.fd_dict" set, * "fudi.fd_di" == NULL, "fudi.fd_newkey" == func * dict.func existing dict entry with a Funcref * "name" == func, "fudi.fd_dict" set, * "fudi.fd_di" set, "fudi.fd_newkey" == NULL * dict.func existing dict entry that's not a Funcref * "name" == NULL, "fudi.fd_dict" set, * "fudi.fd_di" set, "fudi.fd_newkey" == NULL * s:func script-local function name * g:func global function name, same as "func" */ p = eap->arg; if (name_arg != NULL) { // nested function, argument is (args). paren = TRUE; CLEAR_FIELD(fudi); } else { if (vim9script) { if (p[0] == 's' && p[1] == ':') { semsg(_(e_cannot_use_s_colon_in_vim9_script_str), p); return NULL; } p = to_name_end(p, TRUE); if (*skipwhite(p) == '.' && vim_strchr(p, '(') != NULL) { semsg(_(e_cannot_define_dict_func_in_vim9_script_str), eap->arg); return NULL; } p = eap->arg; } int tfn_flags = TFN_NO_AUTOLOAD | TFN_NEW_FUNC | (class_flags != 0 ? TFN_IN_CLASS : 0); name = save_function_name(&p, &is_global, eap->skip, tfn_flags, &fudi); paren = (vim_strchr(p, '(') != NULL); if (name == NULL && (fudi.fd_dict == NULL || !paren) && !eap->skip) { /* * Return on an invalid expression in braces, unless the expression * evaluation has been cancelled due to an aborting error, an * interrupt, or an exception. */ if (!aborting()) { if (!eap->skip && fudi.fd_newkey != NULL) semsg(_(e_key_not_present_in_dictionary_str), fudi.fd_newkey); vim_free(fudi.fd_newkey); return NULL; } else eap->skip = TRUE; } // For "export def FuncName()" in an autoload script the function name // is stored with the legacy autoload name "dir#script#FuncName" so // that it can also be found in legacy script. if (is_export && name != NULL) { char_u *prefixed = may_prefix_autoload(name); if (prefixed != NULL && prefixed != name) { vim_free(name); name = prefixed; } } else if (paren && vim9script && name != NULL && vim_strchr(name, AUTOLOAD_CHAR) != NULL) { emsg(_(e_cannot_use_name_with_hash_in_vim9_script_use_export_instead)); goto ret_free; } } // An error in a function call during evaluation of an expression in magic // braces should not cause the function not to be defined. saved_did_emsg = did_emsg; did_emsg = FALSE; /* * ":function func" with only function name: list function. */ if (!paren) { if (!ends_excmd(*skipwhite(p))) { semsg(_(e_trailing_characters_str), p); goto ret_free; } set_nextcmd(eap, p); if (eap->nextcmd != NULL) *p = NUL; if (!eap->skip && !got_int) { fp = find_func(name, is_global); if (fp == NULL && ASCII_ISUPPER(*eap->arg)) { char_u *up = untrans_function_name(name); // With Vim9 script the name was made script-local, if not // found try again with the original name. if (up != NULL) fp = find_func(up, FALSE); } if (fp != NULL) { // Check no function was added or removed from a timer, e.g. at // the more prompt. "fp" may then be invalid. int prev_ht_changed = func_hashtab.ht_changed; if (list_func_head(fp, TRUE) == OK) { for (j = 0; j < fp->uf_lines.ga_len && !got_int; ++j) { if (FUNCLINE(fp, j) == NULL) continue; msg_putchar('\n'); msg_outnum((long)(j + 1)); if (j < 9) msg_putchar(' '); if (j < 99) msg_putchar(' '); if (function_list_modified(prev_ht_changed)) break; msg_prt_line(FUNCLINE(fp, j), FALSE); out_flush(); // show a line at a time ui_breakcheck(); } if (!got_int) { msg_putchar('\n'); if (!function_list_modified(prev_ht_changed)) { if (fp->uf_def_status != UF_NOT_COMPILED) msg_puts(" enddef"); else msg_puts(" endfunction"); } } } } else emsg_funcname(e_undefined_function_str, eap->arg); } goto ret_free; } /* * ":function name(arg1, arg2)" Define function. */ p = skipwhite(p); if (*p != '(') { if (!eap->skip) { semsg(_(e_missing_paren_str), eap->arg); goto ret_free; } // attempt to continue by skipping some text if (vim_strchr(p, '(') != NULL) p = vim_strchr(p, '('); } if ((vim9script || eap->cmdidx == CMD_def) && VIM_ISWHITE(p[-1])) { semsg(_(e_no_white_space_allowed_before_str_str), "(", p - 1); goto ret_free; } // In Vim9 script only global functions can be redefined. if (vim9script && eap->forceit && !is_global) { emsg(_(e_no_bang_allowed)); goto ret_free; } ga_init2(&newlines, sizeof(char_u *), 10); if (!eap->skip && name_arg == NULL) { // Check the name of the function. Unless it's a dictionary function // (that we are overwriting). if (name != NULL) arg = name; else arg = fudi.fd_newkey; if (arg != NULL && (fudi.fd_di == NULL || (fudi.fd_di->di_tv.v_type != VAR_FUNC && fudi.fd_di->di_tv.v_type != VAR_PARTIAL))) { char_u *name_base = arg; int i; if (*arg == K_SPECIAL) { name_base = vim_strchr(arg, '_'); if (name_base == NULL) name_base = arg + 3; else ++name_base; } for (i = 0; name_base[i] != NUL && (i == 0 ? eval_isnamec1(name_base[i]) : eval_isnamec(name_base[i])); ++i) ; if (name_base[i] != NUL) emsg_funcname(e_invalid_argument_str, arg); // In Vim9 script a function cannot have the same name as a // variable. if (vim9script && *arg == K_SPECIAL && eval_variable(name_base, (int)STRLEN(name_base), 0, NULL, NULL, EVAL_VAR_NOAUTOLOAD + EVAL_VAR_IMPORT + EVAL_VAR_NO_FUNC) == OK) { semsg(_(e_redefining_script_item_str), name_base); goto ret_free; } } // Disallow using the g: dict. if (fudi.fd_dict != NULL && fudi.fd_dict->dv_scope == VAR_DEF_SCOPE) { emsg(_(e_cannot_use_g_here)); goto ret_free; } } // This may get more lines and make the pointers into the first line // invalid. ++p; if (get_function_args(&p, ')', &newargs, eap->cmdidx == CMD_def ? &argtypes : NULL, FALSE, NULL, &varargs, &default_args, eap->skip, eap, class_flags, &newlines, lines_to_free) == FAIL) goto errret_2; whitep = p; if (eap->cmdidx == CMD_def) { // find the return type: :def Func(): type if (*skipwhite(p) == ':') { if (*p != ':') { semsg(_(e_no_white_space_allowed_before_colon_str), p); p = skipwhite(p); } else if (!IS_WHITE_OR_NUL(p[1])) semsg(_(e_white_space_required_after_str_str), ":", p); ret_type = skipwhite(p + 1); p = skip_type(ret_type, FALSE); if (p > ret_type) { ret_type = vim_strnsave(ret_type, p - ret_type); whitep = p; p = skipwhite(p); } else { semsg(_(e_expected_type_str), ret_type); ret_type = NULL; } } p = skipwhite(p); } else // find extra arguments "range", "dict", "abort" and "closure" for (;;) { whitep = p; p = skipwhite(p); if (STRNCMP(p, "range", 5) == 0) { flags |= FC_RANGE; p += 5; } else if (STRNCMP(p, "dict", 4) == 0) { flags |= FC_DICT; p += 4; } else if (STRNCMP(p, "abort", 5) == 0) { flags |= FC_ABORT; p += 5; } else if (STRNCMP(p, "closure", 7) == 0) { flags |= FC_CLOSURE; p += 7; if (current_funccal == NULL) { emsg_funcname(e_closure_function_should_not_be_at_top_level_str, name == NULL ? (char_u *)"" : name); goto erret; } } else break; } // When there is a line break use what follows for the function body. // Makes 'exe "func Test()\n...\nendfunc"' work. if (*p == '\n') line_arg = p + 1; else if (*p != NUL && !(*p == '"' && (!vim9script || eap->cmdidx == CMD_function) && eap->cmdidx != CMD_def) && !(VIM_ISWHITE(*whitep) && *p == '#' && (vim9script || eap->cmdidx == CMD_def)) && !eap->skip && !did_emsg) semsg(_(e_trailing_characters_str), p); /* * Read the body of the function, until "}", ":endfunction" or ":enddef" is * found. */ if (KeyTyped) { // Check if the function already exists, don't let the user type the // whole function before telling him it doesn't work! For a script we // need to skip the body to be able to find what follows. if (!eap->skip && !eap->forceit) { if (fudi.fd_dict != NULL && fudi.fd_newkey == NULL) emsg(_(e_dictionary_entry_already_exists)); else if (name != NULL && find_func(name, is_global) != NULL) emsg_funcname(e_function_str_already_exists_add_bang_to_replace, name); } if (!eap->skip && did_emsg) goto erret; msg_putchar('\n'); // don't overwrite the function name cmdline_row = msg_row; } // Save the starting line number. sourcing_lnum_top = SOURCING_LNUM; // Do not define the function when getting the body fails and when // skipping. if (((class_flags & CF_INTERFACE) == 0 && get_function_body(eap, &newlines, line_arg, lines_to_free) == FAIL) || eap->skip) goto erret; /* * If there are no errors, add the function */ if (fudi.fd_dict != NULL) { char numbuf[20]; fp = NULL; if (fudi.fd_newkey == NULL && !eap->forceit) { emsg(_(e_dictionary_entry_already_exists)); goto erret; } if (fudi.fd_di == NULL) { // Can't add a function to a locked dictionary if (value_check_lock(fudi.fd_dict->dv_lock, eap->arg, FALSE)) goto erret; } // Can't change an existing function if it is locked else if (value_check_lock(fudi.fd_di->di_tv.v_lock, eap->arg, FALSE)) goto erret; // Give the function a sequential number. Can only be used with a // Funcref! vim_free(name); sprintf(numbuf, "%d", ++func_nr); name = vim_strsave((char_u *)numbuf); if (name == NULL) goto erret; } else if (class_flags == 0) { hashtab_T *ht; char_u *find_name = name; int var_conflict = FALSE; int ffed_flags = is_global ? FFED_IS_GLOBAL : 0; v = find_var(name, &ht, TRUE); if (v != NULL && (vim9script || v->di_tv.v_type == VAR_FUNC)) var_conflict = TRUE; if (SCRIPT_ID_VALID(current_sctx.sc_sid)) { scriptitem_T *si = SCRIPT_ITEM(current_sctx.sc_sid); if (si->sn_autoload_prefix != NULL) { if (is_export) { find_name = name + STRLEN(si->sn_autoload_prefix); v = find_var(find_name, &ht, TRUE); if (v != NULL) var_conflict = TRUE; // Only check if the function already exists in the script, // global functions can be shadowed. ffed_flags |= FFED_NO_GLOBAL; } else { char_u *prefixed = may_prefix_autoload(name); if (prefixed != NULL && prefixed != name) { v = find_var(prefixed, &ht, TRUE); if (v != NULL) var_conflict = TRUE; vim_free(prefixed); } } } } if (var_conflict) { emsg_funcname(e_function_name_conflicts_with_variable_str, name); goto erret; } fp = find_func_even_dead(find_name, ffed_flags); if (vim9script) { char_u *uname = untrans_function_name(name); import = find_imported(uname == NULL ? name : uname, 0, FALSE); } if (fp != NULL || import != NULL) { int dead = fp != NULL && (fp->uf_flags & FC_DEAD); // Function can be replaced with "function!" and when sourcing the // same script again, but only once. // A name that is used by an import can not be overruled. if (import != NULL || (!dead && !eap->forceit && (fp->uf_script_ctx.sc_sid != current_sctx.sc_sid || fp->uf_script_ctx.sc_seq == current_sctx.sc_seq))) { SOURCING_LNUM = sourcing_lnum_top; if (vim9script) emsg_funcname(e_name_already_defined_str, name); else emsg_funcname(e_function_str_already_exists_add_bang_to_replace, name); goto erret; } if (fp->uf_calls > 0) { emsg_funcname( e_cannot_redefine_function_str_it_is_in_use, name); goto erret; } if (fp->uf_refcount > 1) { // This function is referenced somewhere, don't redefine it but // create a new one. --fp->uf_refcount; fp->uf_flags |= FC_REMOVED; fp = NULL; overwrite = TRUE; } else { char_u *exp_name = fp->uf_name_exp; // redefine existing function, keep the expanded name VIM_CLEAR(name); fp->uf_name_exp = NULL; func_clear_items(fp); fp->uf_name_exp = exp_name; fp->uf_flags &= ~FC_DEAD; #ifdef FEAT_PROFILE fp->uf_profiling = FALSE; fp->uf_prof_initialized = FALSE; #endif fp->uf_def_status = UF_NOT_COMPILED; } } } if (fp == NULL) { if (fudi.fd_dict == NULL && vim_strchr(name, AUTOLOAD_CHAR) != NULL) { int slen, plen; char_u *scriptname; // Check that the autoload name matches the script name. j = FAIL; if (SOURCING_NAME != NULL) { scriptname = autoload_name(name); if (scriptname != NULL) { p = vim_strchr(scriptname, '/'); plen = (int)STRLEN(p); slen = (int)STRLEN(SOURCING_NAME); if (slen > plen && fnamecmp(p, SOURCING_NAME + slen - plen) == 0) j = OK; vim_free(scriptname); } } if (j == FAIL) { linenr_T save_lnum = SOURCING_LNUM; SOURCING_LNUM = sourcing_lnum_top; semsg(_(e_function_name_does_not_match_script_file_name_str), name); SOURCING_LNUM = save_lnum; goto erret; } } fp = alloc_ufunc(name); if (fp == NULL) goto erret; fp_allocated = TRUE; if (fudi.fd_dict != NULL) { if (fudi.fd_di == NULL) { // add new dict entry fudi.fd_di = dictitem_alloc(fudi.fd_newkey); if (fudi.fd_di == NULL) { VIM_CLEAR(fp); goto erret; } if (dict_add(fudi.fd_dict, fudi.fd_di) == FAIL) { vim_free(fudi.fd_di); VIM_CLEAR(fp); goto erret; } } else // overwrite existing dict entry clear_tv(&fudi.fd_di->di_tv); fudi.fd_di->di_tv.v_type = VAR_FUNC; fudi.fd_di->di_tv.vval.v_string = vim_strsave(name); // behave like "dict" was used flags |= FC_DICT; } } fp->uf_args = newargs; fp->uf_def_args = default_args; fp->uf_ret_type = &t_any; fp->uf_func_type = &t_func_any; if (eap->cmdidx == CMD_def) { int lnum_save = SOURCING_LNUM; cstack_T *cstack = eap->cstack; fp->uf_def_status = UF_TO_BE_COMPILED; // error messages are for the first function line SOURCING_LNUM = sourcing_lnum_top; // The function may use script variables from the context. function_using_block_scopes(fp, cstack); if (parse_argument_types(fp, &argtypes, varargs) == FAIL) { SOURCING_LNUM = lnum_save; free_fp = fp_allocated; goto erret; } varargs = FALSE; // parse the return type, if any if (parse_return_type(fp, ret_type) == FAIL) { SOURCING_LNUM = lnum_save; free_fp = fp_allocated; goto erret; } SOURCING_LNUM = lnum_save; } else fp->uf_def_status = UF_NOT_COMPILED; if (fp_allocated) { // insert the new function in the function list set_ufunc_name(fp, name); if (overwrite) { hi = hash_find(&func_hashtab, name); hi->hi_key = UF2HIKEY(fp); } else if (class_flags == 0 && hash_add(&func_hashtab, UF2HIKEY(fp), "add function") == FAIL) { free_fp = TRUE; goto erret; } fp->uf_refcount = 1; } fp->uf_lines = newlines; newlines.ga_data = NULL; if ((flags & FC_CLOSURE) != 0) { if (register_closure(fp) == FAIL) goto erret; } else fp->uf_scoped = NULL; #ifdef FEAT_PROFILE if (prof_def_func()) func_do_profile(fp); #endif fp->uf_varargs = varargs; if (sandbox) flags |= FC_SANDBOX; if (vim9script && !ASCII_ISUPPER(*fp->uf_name)) flags |= FC_VIM9; fp->uf_flags = flags; fp->uf_calls = 0; fp->uf_cleared = FALSE; fp->uf_script_ctx = current_sctx; fp->uf_script_ctx_version = current_sctx.sc_version; fp->uf_script_ctx.sc_lnum += sourcing_lnum_top; if (is_export) { fp->uf_flags |= FC_EXPORT; // let do_one_cmd() know the export worked. is_export = FALSE; } if (eap->cmdidx == CMD_def) set_function_type(fp); else if (fp->uf_script_ctx.sc_version == SCRIPT_VERSION_VIM9) // :func does not use Vim9 script syntax, even in a Vim9 script file fp->uf_script_ctx.sc_version = SCRIPT_VERSION_MAX; goto ret_free; erret: if (fp != NULL) { // these were set to "newargs" and "default_args", which are cleared // below ga_init(&fp->uf_args); ga_init(&fp->uf_def_args); } errret_2: ga_clear_strings(&newargs); ga_clear_strings(&default_args); ga_clear_strings(&newlines); if (fp != NULL) { VIM_CLEAR(fp->uf_arg_types); VIM_CLEAR(fp->uf_va_name); clear_type_list(&fp->uf_type_list); } if (free_fp) VIM_CLEAR(fp); ret_free: ga_clear_strings(&argtypes); vim_free(fudi.fd_newkey); if (name != name_arg) vim_free(name); vim_free(ret_type); did_emsg |= saved_did_emsg; return fp; } /* * ":function" */ void ex_function(exarg_T *eap) { garray_T lines_to_free; ga_init2(&lines_to_free, sizeof(char_u *), 50); (void)define_function(eap, NULL, &lines_to_free, 0); ga_clear_strings(&lines_to_free); } /* * Find a function by name, including "<lambda>123". * Check for "profile" and "debug" arguments and set"compile_type". * Caller should initialize "compile_type" to CT_NONE. * Return NULL if not found. */ ufunc_T * find_func_by_name(char_u *name, compiletype_T *compile_type) { char_u *arg = name; char_u *fname; ufunc_T *ufunc; int is_global = FALSE; if (STRNCMP(arg, "profile", 7) == 0 && VIM_ISWHITE(arg[7])) { *compile_type = CT_PROFILE; arg = skipwhite(arg + 7); } else if (STRNCMP(arg, "debug", 5) == 0 && VIM_ISWHITE(arg[5])) { *compile_type = CT_DEBUG; arg = skipwhite(arg + 5); } if (STRNCMP(arg, "<lambda>", 8) == 0) { arg += 8; (void)getdigits(&arg); fname = vim_strnsave(name, arg - name); } else { // First try finding a method in a class, trans_function_name() will // give an error if the function is not found. ufunc = find_class_func(&arg); if (ufunc != NULL) return ufunc; fname = trans_function_name_ext(&arg, &is_global, FALSE, TFN_INT | TFN_QUIET | TFN_NO_AUTOLOAD | TFN_NO_DECL, NULL, NULL, NULL, &ufunc); if (ufunc != NULL) { vim_free(fname); return ufunc; } } if (fname == NULL) { semsg(_(e_invalid_argument_str), name); return NULL; } if (!ends_excmd2(name, arg)) { vim_free(fname); emsg(ex_errmsg(e_trailing_characters_str, arg)); return NULL; } ufunc = find_func(fname, is_global); if (ufunc == NULL) { char_u *p = untrans_function_name(fname); if (p != NULL) // Try again without making it script-local. ufunc = find_func(p, FALSE); } vim_free(fname); if (ufunc == NULL) semsg(_(e_cannot_find_function_str), name); return ufunc; } /* * :defcompile - compile all :def functions in the current script that need to * be compiled or the one specified by the argument. * Skips dead functions. Doesn't do profiling. */ void ex_defcompile(exarg_T *eap) { if (*eap->arg != NUL) { compiletype_T compile_type = CT_NONE; ufunc_T *ufunc = find_func_by_name(eap->arg, &compile_type); if (ufunc != NULL) { if (func_needs_compiling(ufunc, compile_type)) (void)compile_def_function(ufunc, FALSE, compile_type, NULL); else smsg(_("Function %s does not need compiling"), eap->arg); } } else { long todo = (long)func_hashtab.ht_used; int changed = func_hashtab.ht_changed; hashitem_T *hi; for (hi = func_hashtab.ht_array; todo > 0 && !got_int; ++hi) { if (!HASHITEM_EMPTY(hi)) { --todo; ufunc_T *ufunc = HI2UF(hi); if (ufunc->uf_script_ctx.sc_sid == current_sctx.sc_sid && ufunc->uf_def_status == UF_TO_BE_COMPILED && (ufunc->uf_flags & FC_DEAD) == 0) { (void)compile_def_function(ufunc, FALSE, CT_NONE, NULL); if (func_hashtab.ht_changed != changed) { // a function has been added or removed, need to start // over todo = (long)func_hashtab.ht_used; changed = func_hashtab.ht_changed; hi = func_hashtab.ht_array; --hi; } } } } } } /* * Return 5 if "p" starts with "<SID>" or "<SNR>" (ignoring case). * Return 2 if "p" starts with "s:". * Return 0 otherwise. */ int eval_fname_script(char_u *p) { // Use MB_STRICMP() because in Turkish comparing the "I" may not work with // the standard library function. if (p[0] == '<' && (MB_STRNICMP(p + 1, "SID>", 4) == 0 || MB_STRNICMP(p + 1, "SNR>", 4) == 0)) return 5; if (p[0] == 's' && p[1] == ':') return 2; return 0; } int translated_function_exists(char_u *name, int is_global) { if (builtin_function(name, -1)) return has_internal_func(name); return find_func(name, is_global) != NULL; } /* * Return TRUE when "ufunc" has old-style "..." varargs * or named varargs "...name: type". */ int has_varargs(ufunc_T *ufunc) { return ufunc->uf_varargs || ufunc->uf_va_name != NULL; } /* * Return TRUE if a function "name" exists. * If "no_defef" is TRUE, do not dereference a Funcref. */ int function_exists(char_u *name, int no_deref) { char_u *nm = name; char_u *p; int n = FALSE; int flag; int is_global = FALSE; flag = TFN_INT | TFN_QUIET | TFN_NO_AUTOLOAD; if (no_deref) flag |= TFN_NO_DEREF; p = trans_function_name(&nm, &is_global, FALSE, flag); nm = skipwhite(nm); // Only accept "funcname", "funcname ", "funcname (..." and // "funcname(...", not "funcname!...". if (p != NULL && (*nm == NUL || *nm == '(')) n = translated_function_exists(p, is_global); vim_free(p); return n; } #if defined(FEAT_PYTHON) || defined(FEAT_PYTHON3) || defined(PROTO) char_u * get_expanded_name(char_u *name, int check) { char_u *nm = name; char_u *p; int is_global = FALSE; p = trans_function_name(&nm, &is_global, FALSE, TFN_INT|TFN_QUIET); if (p != NULL && *nm == NUL && (!check || translated_function_exists(p, is_global))) return p; vim_free(p); return NULL; } #endif /* * Function given to ExpandGeneric() to obtain the list of user defined * function names. */ char_u * get_user_func_name(expand_T *xp, int idx) { static long_u done; static int changed; static hashitem_T *hi; ufunc_T *fp; if (idx == 0) { done = 0; hi = func_hashtab.ht_array; changed = func_hashtab.ht_changed; } if (changed == func_hashtab.ht_changed && done < func_hashtab.ht_used) { if (done++ > 0) ++hi; while (HASHITEM_EMPTY(hi)) ++hi; fp = HI2UF(hi); // don't show dead, dict and lambda functions if ((fp->uf_flags & FC_DEAD) || (fp->uf_flags & FC_DICT) || STRNCMP(fp->uf_name, "<lambda>", 8) == 0) return (char_u *)""; if (STRLEN(fp->uf_name) + 4 >= IOSIZE) return fp->uf_name; // prevents overflow cat_func_name(IObuff, fp); if (xp->xp_context != EXPAND_USER_FUNC && xp->xp_context != EXPAND_DISASSEMBLE) { STRCAT(IObuff, "("); if (!has_varargs(fp) && fp->uf_args.ga_len == 0) STRCAT(IObuff, ")"); } return IObuff; } return NULL; } /* * Make a copy of a function. * Intended to be used for a function defined on a base class that has a copy * on the child class. * The copy has uf_refcount set to one. * Returns NULL when out of memory. */ ufunc_T * copy_function(ufunc_T *fp) { ufunc_T *ufunc = alloc_ufunc(fp->uf_name); if (ufunc == NULL) return NULL; // Most things can just be copied. *ufunc = *fp; ufunc->uf_def_status = UF_TO_BE_COMPILED; ufunc->uf_dfunc_idx = 0; ufunc->uf_class = NULL; ga_copy_strings(&fp->uf_args, &ufunc->uf_args); ga_copy_strings(&fp->uf_def_args, &ufunc->uf_def_args); if (ufunc->uf_arg_types != NULL) { // "uf_arg_types" is an allocated array, make a copy. type_T **at = ALLOC_CLEAR_MULT(type_T *, ufunc->uf_args.ga_len); if (at != NULL) { mch_memmove(at, ufunc->uf_arg_types, sizeof(type_T *) * ufunc->uf_args.ga_len); ufunc->uf_arg_types = at; } } // TODO: how about the types themselves? they can be freed when the // original function is freed: // type_T **uf_arg_types; // type_T *uf_ret_type; // make uf_type_list empty ga_init(&ufunc->uf_type_list); // TODO: partial_T *uf_partial; if (ufunc->uf_va_name != NULL) ufunc->uf_va_name = vim_strsave(ufunc->uf_va_name); // TODO: // type_T *uf_va_type; // type_T *uf_func_type; ufunc->uf_block_depth = 0; ufunc->uf_block_ids = NULL; ga_copy_strings(&fp->uf_lines, &ufunc->uf_lines); ufunc->uf_refcount = 1; ufunc->uf_name_exp = NULL; STRCPY(ufunc->uf_name, fp->uf_name); return ufunc; } /* * ":delfunction {name}" */ void ex_delfunction(exarg_T *eap) { ufunc_T *fp = NULL; char_u *p; char_u *name; funcdict_T fudi; int is_global = FALSE; p = eap->arg; name = trans_function_name_ext(&p, &is_global, eap->skip, 0, &fudi, NULL, NULL, NULL); vim_free(fudi.fd_newkey); if (name == NULL) { if (fudi.fd_dict != NULL && !eap->skip) emsg(_(e_funcref_required)); return; } if (!ends_excmd(*skipwhite(p))) { vim_free(name); semsg(_(e_trailing_characters_str), p); return; } set_nextcmd(eap, p); if (eap->nextcmd != NULL) *p = NUL; if (numbered_function(name) && fudi.fd_dict == NULL) { if (!eap->skip) semsg(_(e_invalid_argument_str), eap->arg); vim_free(name); return; } if (!eap->skip) fp = find_func(name, is_global); vim_free(name); if (!eap->skip) { if (fp == NULL) { if (!eap->forceit) semsg(_(e_unknown_function_str), eap->arg); return; } if (fp->uf_calls > 0) { semsg(_(e_cannot_delete_function_str_it_is_in_use), eap->arg); return; } if (fp->uf_flags & FC_VIM9) { semsg(_(e_cannot_delete_vim9_script_function_str), eap->arg); return; } if (fudi.fd_dict != NULL) { // Delete the dict item that refers to the function, it will // invoke func_unref() and possibly delete the function. dictitem_remove(fudi.fd_dict, fudi.fd_di, "delfunction"); } else { // A normal function (not a numbered function or lambda) has a // refcount of 1 for the entry in the hashtable. When deleting // it and the refcount is more than one, it should be kept. // A numbered function and lambda should be kept if the refcount is // one or more. if (fp->uf_refcount > (func_name_refcount(fp->uf_name) ? 0 : 1)) { // Function is still referenced somewhere. Don't free it but // do remove it from the hashtable. if (func_remove(fp)) fp->uf_refcount--; } else func_clear_free(fp, FALSE); } } } /* * Unreference a Function: decrement the reference count and free it when it * becomes zero. */ void func_unref(char_u *name) { ufunc_T *fp = NULL; if (name == NULL || !func_name_refcount(name)) return; fp = find_func(name, FALSE); if (fp == NULL && numbered_function(name)) { #ifdef EXITFREE if (!entered_free_all_mem) #endif internal_error("func_unref()"); } func_ptr_unref(fp); } /* * Unreference a Function: decrement the reference count and free it when it * becomes zero. * Also when it becomes one and uf_partial points to the function. */ void func_ptr_unref(ufunc_T *fp) { if (fp != NULL && (--fp->uf_refcount <= 0 || (fp->uf_refcount == 1 && fp->uf_partial != NULL && fp->uf_partial->pt_refcount <= 1 && fp->uf_partial->pt_func == fp))) { // Only delete it when it's not being used. Otherwise it's done // when "uf_calls" becomes zero. if (fp->uf_calls == 0) func_clear_free(fp, FALSE); } } /* * Count a reference to a Function. */ void func_ref(char_u *name) { ufunc_T *fp; if (name == NULL || !func_name_refcount(name)) return; fp = find_func(name, FALSE); if (fp != NULL) ++fp->uf_refcount; else if (numbered_function(name)) // Only give an error for a numbered function. // Fail silently, when named or lambda function isn't found. internal_error("func_ref()"); } /* * Count a reference to a Function. */ void func_ptr_ref(ufunc_T *fp) { if (fp != NULL) ++fp->uf_refcount; } /* * Return TRUE if items in "fc" do not have "copyID". That means they are not * referenced from anywhere that is in use. */ static int can_free_funccal(funccall_T *fc, int copyID) { return (fc->fc_l_varlist.lv_copyID != copyID && fc->fc_l_vars.dv_copyID != copyID && fc->fc_l_avars.dv_copyID != copyID && fc->fc_copyID != copyID); } /* * ":return [expr]" */ void ex_return(exarg_T *eap) { char_u *arg = eap->arg; typval_T rettv; int returning = FALSE; evalarg_T evalarg; if (current_funccal == NULL) { emsg(_(e_return_not_inside_function)); return; } init_evalarg(&evalarg); evalarg.eval_flags = eap->skip ? 0 : EVAL_EVALUATE; if (eap->skip) ++emsg_skip; eap->nextcmd = NULL; if ((*arg != NUL && *arg != '|' && *arg != '\n') && eval0(arg, &rettv, eap, &evalarg) != FAIL) { if (!eap->skip) returning = do_return(eap, FALSE, TRUE, &rettv); else clear_tv(&rettv); } // It's safer to return also on error. else if (!eap->skip) { // In return statement, cause_abort should be force_abort. update_force_abort(); /* * Return unless the expression evaluation has been cancelled due to an * aborting error, an interrupt, or an exception. */ if (!aborting()) returning = do_return(eap, FALSE, TRUE, NULL); } // When skipping or the return gets pending, advance to the next command // in this line (!returning). Otherwise, ignore the rest of the line. // Following lines will be ignored by get_func_line(). if (returning) eap->nextcmd = NULL; else if (eap->nextcmd == NULL) // no argument set_nextcmd(eap, arg); if (eap->skip) --emsg_skip; clear_evalarg(&evalarg, eap); } /* * Lower level implementation of "call". Only called when not skipping. */ static int ex_call_inner( exarg_T *eap, char_u *name, char_u **arg, char_u *startarg, funcexe_T *funcexe_init, evalarg_T *evalarg) { linenr_T lnum; int doesrange; typval_T rettv; int failed = FALSE; lnum = eap->line1; for ( ; lnum <= eap->line2; ++lnum) { funcexe_T funcexe; if (eap->addr_count > 0) { if (lnum > curbuf->b_ml.ml_line_count) { // If the function deleted lines or switched to another buffer // the line number may become invalid. emsg(_(e_invalid_range)); break; } curwin->w_cursor.lnum = lnum; curwin->w_cursor.col = 0; curwin->w_cursor.coladd = 0; } *arg = startarg; funcexe = *funcexe_init; funcexe.fe_doesrange = &doesrange; rettv.v_type = VAR_UNKNOWN; // clear_tv() uses this if (get_func_tv(name, -1, &rettv, arg, evalarg, &funcexe) == FAIL) { failed = TRUE; break; } if (has_watchexpr()) dbg_check_breakpoint(eap); // Handle a function returning a Funcref, Dictionary or List. if (handle_subscript(arg, NULL, &rettv, &EVALARG_EVALUATE, TRUE) == FAIL) { failed = TRUE; break; } clear_tv(&rettv); if (doesrange) break; // Stop when immediately aborting on error, or when an interrupt // occurred or an exception was thrown but not caught. // get_func_tv() returned OK, so that the check for trailing // characters below is executed. if (aborting()) break; } return failed; } /* * Core part of ":defer func(arg)". "arg" points to the "(" and is advanced. * Returns FAIL or OK. */ static int ex_defer_inner( char_u *name, char_u **arg, type_T *type, partial_T *partial, evalarg_T *evalarg) { typval_T argvars[MAX_FUNC_ARGS + 1]; // vars for arguments int partial_argc = 0; // number of partial arguments int argcount = 0; // number of arguments found int r; if (current_funccal == NULL) { semsg(_(e_str_not_inside_function), "defer"); return FAIL; } if (partial != NULL) { if (partial->pt_dict != NULL) { emsg(_(e_cannot_use_partial_with_dictionary_for_defer)); return FAIL; } if (partial->pt_argc > 0) { int i; partial_argc = partial->pt_argc; for (i = 0; i < partial_argc; ++i) copy_tv(&partial->pt_argv[i], &argvars[i]); } } r = get_func_arguments(arg, evalarg, FALSE, argvars + partial_argc, &argcount); argcount += partial_argc; if (r == OK) { if (type != NULL) { // Check that the arguments are OK for the types of the funcref. r = check_argument_types(type, argvars, argcount, NULL, name); } else if (builtin_function(name, -1)) { int idx = find_internal_func(name); if (idx < 0) { emsg_funcname(e_unknown_function_str, name); r = FAIL; } else if (check_internal_func(idx, argcount) == -1) r = FAIL; } else { ufunc_T *ufunc = find_func(name, FALSE); // we tolerate an unknown function here, it might be defined later if (ufunc != NULL) { funcerror_T error = check_user_func_argcount(ufunc, argcount); if (error != FCERR_UNKNOWN) { user_func_error(error, name, FALSE); r = FAIL; } } } } if (r == FAIL) { while (--argcount >= 0) clear_tv(&argvars[argcount]); return FAIL; } return add_defer(name, argcount, argvars); } /* * Return TRUE if currently inside a function call. * Give an error message and return FALSE when not. */ int can_add_defer(void) { if (!in_def_function() && get_current_funccal() == NULL) { semsg(_(e_str_not_inside_function), "defer"); return FALSE; } return TRUE; } /* * Add a deferred call for "name" with arguments "argvars[argcount]". * Consumes "argvars[]". * Caller must check that in_def_function() returns TRUE or current_funccal is * not NULL. * Returns OK or FAIL. */ int add_defer(char_u *name, int argcount_arg, typval_T *argvars) { char_u *saved_name = vim_strsave(name); int argcount = argcount_arg; defer_T *dr; int ret = FAIL; if (saved_name == NULL) goto theend; if (in_def_function()) { if (add_defer_function(saved_name, argcount, argvars) == OK) argcount = 0; } else { if (current_funccal->fc_defer.ga_itemsize == 0) ga_init2(¤t_funccal->fc_defer, sizeof(defer_T), 10); if (ga_grow(¤t_funccal->fc_defer, 1) == FAIL) goto theend; dr = ((defer_T *)current_funccal->fc_defer.ga_data) + current_funccal->fc_defer.ga_len++; dr->dr_name = saved_name; dr->dr_argcount = argcount; while (argcount > 0) { --argcount; dr->dr_argvars[argcount] = argvars[argcount]; } } ret = OK; theend: while (--argcount >= 0) clear_tv(&argvars[argcount]); return ret; } /* * Invoked after a functions has finished: invoke ":defer" functions. */ static void handle_defer_one(funccall_T *funccal) { int idx; for (idx = funccal->fc_defer.ga_len - 1; idx >= 0; --idx) { defer_T *dr = ((defer_T *)funccal->fc_defer.ga_data) + idx; if (dr->dr_name == NULL) // already being called, can happen if function does ":qa" continue; funcexe_T funcexe; CLEAR_FIELD(funcexe); funcexe.fe_evaluate = TRUE; typval_T rettv; rettv.v_type = VAR_UNKNOWN; // clear_tv() uses this char_u *name = dr->dr_name; dr->dr_name = NULL; call_func(name, -1, &rettv, dr->dr_argcount, dr->dr_argvars, &funcexe); clear_tv(&rettv); vim_free(name); for (int i = dr->dr_argcount - 1; i >= 0; --i) clear_tv(&dr->dr_argvars[i]); } ga_clear(&funccal->fc_defer); } static void invoke_funccall_defer(funccall_T *fc) { if (fc->fc_ectx != NULL) { // :def function unwind_def_callstack(fc->fc_ectx); may_invoke_defer_funcs(fc->fc_ectx); } else { // legacy function handle_defer_one(fc); } } /* * Called when exiting: call all defer functions. */ void invoke_all_defer(void) { for (funccall_T *fc = current_funccal; fc != NULL; fc = fc->fc_caller) invoke_funccall_defer(fc); for (funccal_entry_T *fce = funccal_stack; fce != NULL; fce = fce->next) for (funccall_T *fc = fce->top_funccal; fc != NULL; fc = fc->fc_caller) invoke_funccall_defer(fc); } /* * ":1,25call func(arg1, arg2)" function call. * ":defer func(arg1, arg2)" deferred function call. */ void ex_call(exarg_T *eap) { char_u *arg = eap->arg; char_u *startarg; char_u *name; char_u *tofree; int len; int failed = FALSE; funcdict_T fudi; ufunc_T *ufunc = NULL; partial_T *partial = NULL; evalarg_T evalarg; type_T *type = NULL; int found_var = FALSE; int vim9script = in_vim9script(); fill_evalarg_from_eap(&evalarg, eap, eap->skip); if (eap->skip) { typval_T rettv; // trans_function_name() doesn't work well when skipping, use eval0() // instead to skip to any following command, e.g. for: // :if 0 | call dict.foo().bar() | endif ++emsg_skip; if (eval0(eap->arg, &rettv, eap, &evalarg) != FAIL) clear_tv(&rettv); --emsg_skip; clear_evalarg(&evalarg, eap); return; } tofree = trans_function_name_ext(&arg, NULL, FALSE, TFN_INT, &fudi, &partial, vim9script ? &type : NULL, &ufunc); if (fudi.fd_newkey != NULL) { // Still need to give an error message for missing key. semsg(_(e_key_not_present_in_dictionary_str), fudi.fd_newkey); vim_free(fudi.fd_newkey); } if (tofree == NULL) return; // Increase refcount on dictionary, it could get deleted when evaluating // the arguments. if (fudi.fd_dict != NULL) ++fudi.fd_dict->dv_refcount; // If it is the name of a variable of type VAR_FUNC or VAR_PARTIAL use its // contents. For VAR_PARTIAL get its partial, unless we already have one // from trans_function_name(). len = (int)STRLEN(tofree); name = deref_func_name(tofree, &len, partial != NULL ? NULL : &partial, vim9script && type == NULL ? &type : NULL, FALSE, FALSE, &found_var); // Skip white space to allow ":call func ()". Not good, but required for // backward compatibility. startarg = skipwhite(arg); if (*startarg != '(') { semsg(_(e_missing_parenthesis_str), eap->arg); goto end; } if (vim9script && startarg > arg) { semsg(_(e_no_white_space_allowed_before_str_str), "(", eap->arg); goto end; } if (eap->cmdidx == CMD_defer) { arg = startarg; failed = ex_defer_inner(name, &arg, type, partial, &evalarg) == FAIL; } else { funcexe_T funcexe; CLEAR_FIELD(funcexe); funcexe.fe_check_type = type; funcexe.fe_ufunc = ufunc; funcexe.fe_partial = partial; funcexe.fe_selfdict = fudi.fd_dict; funcexe.fe_firstline = eap->line1; funcexe.fe_lastline = eap->line2; funcexe.fe_found_var = found_var; funcexe.fe_evaluate = TRUE; failed = ex_call_inner(eap, name, &arg, startarg, &funcexe, &evalarg); } // When inside :try we need to check for following "| catch" or "| endtry". // Not when there was an error, but do check if an exception was thrown. if ((!aborting() || did_throw) && (!failed || eap->cstack->cs_trylevel > 0)) { // Check for trailing illegal characters and a following command. arg = skipwhite(arg); if (!ends_excmd2(eap->arg, arg)) { if (!failed && !aborting()) { emsg_severe = TRUE; semsg(_(e_trailing_characters_str), arg); } } else set_nextcmd(eap, arg); } // Must be after using "arg", it may point into memory cleared here. clear_evalarg(&evalarg, eap); end: dict_unref(fudi.fd_dict); vim_free(tofree); } /* * Return from a function. Possibly makes the return pending. Also called * for a pending return at the ":endtry" or after returning from an extra * do_cmdline(). "reanimate" is used in the latter case. "is_cmd" is set * when called due to a ":return" command. "rettv" may point to a typval_T * with the return rettv. Returns TRUE when the return can be carried out, * FALSE when the return gets pending. */ int do_return( exarg_T *eap, int reanimate, int is_cmd, void *rettv) { int idx; cstack_T *cstack = eap->cstack; if (reanimate) // Undo the return. current_funccal->fc_returned = FALSE; /* * Cleanup (and inactivate) conditionals, but stop when a try conditional * not in its finally clause (which then is to be executed next) is found. * In this case, make the ":return" pending for execution at the ":endtry". * Otherwise, return normally. */ idx = cleanup_conditionals(eap->cstack, 0, TRUE); if (idx >= 0) { cstack->cs_pending[idx] = CSTP_RETURN; if (!is_cmd && !reanimate) // A pending return again gets pending. "rettv" points to an // allocated variable with the rettv of the original ":return"'s // argument if present or is NULL else. cstack->cs_rettv[idx] = rettv; else { // When undoing a return in order to make it pending, get the stored // return rettv. if (reanimate) rettv = current_funccal->fc_rettv; if (rettv != NULL) { // Store the value of the pending return. if ((cstack->cs_rettv[idx] = alloc_tv()) != NULL) *(typval_T *)cstack->cs_rettv[idx] = *(typval_T *)rettv; else emsg(_(e_out_of_memory)); } else cstack->cs_rettv[idx] = NULL; if (reanimate) { // The pending return value could be overwritten by a ":return" // without argument in a finally clause; reset the default // return value. current_funccal->fc_rettv->v_type = VAR_NUMBER; current_funccal->fc_rettv->vval.v_number = 0; } } report_make_pending(CSTP_RETURN, rettv); } else { current_funccal->fc_returned = TRUE; // If the return is carried out now, store the return value. For // a return immediately after reanimation, the value is already // there. if (!reanimate && rettv != NULL) { clear_tv(current_funccal->fc_rettv); *current_funccal->fc_rettv = *(typval_T *)rettv; if (!is_cmd) vim_free(rettv); } } return idx < 0; } /* * Free the variable with a pending return value. */ void discard_pending_return(void *rettv) { free_tv((typval_T *)rettv); } /* * Generate a return command for producing the value of "rettv". The result * is an allocated string. Used by report_pending() for verbose messages. */ char_u * get_return_cmd(void *rettv) { char_u *s = NULL; char_u *tofree = NULL; char_u numbuf[NUMBUFLEN]; if (rettv != NULL) s = echo_string((typval_T *)rettv, &tofree, numbuf, 0); if (s == NULL) s = (char_u *)""; STRCPY(IObuff, ":return "); STRNCPY(IObuff + 8, s, IOSIZE - 8); if (STRLEN(s) + 8 >= IOSIZE) STRCPY(IObuff + IOSIZE - 4, "..."); vim_free(tofree); return vim_strsave(IObuff); } /* * Get next function line. * Called by do_cmdline() to get the next line. * Returns allocated string, or NULL for end of function. */ char_u * get_func_line( int c UNUSED, void *cookie, int indent UNUSED, getline_opt_T options UNUSED) { funccall_T *fcp = (funccall_T *)cookie; ufunc_T *fp = fcp->fc_func; char_u *retval; garray_T *gap; // growarray with function lines // If breakpoints have been added/deleted need to check for it. if (fcp->fc_dbg_tick != debug_tick) { fcp->fc_breakpoint = dbg_find_breakpoint(FALSE, fp->uf_name, SOURCING_LNUM); fcp->fc_dbg_tick = debug_tick; } #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) func_line_end(cookie); #endif gap = &fp->uf_lines; if (((fp->uf_flags & FC_ABORT) && did_emsg && !aborted_in_try()) || fcp->fc_returned) retval = NULL; else { // Skip NULL lines (continuation lines). while (fcp->fc_linenr < gap->ga_len && ((char_u **)(gap->ga_data))[fcp->fc_linenr] == NULL) ++fcp->fc_linenr; if (fcp->fc_linenr >= gap->ga_len) retval = NULL; else { retval = vim_strsave(((char_u **)(gap->ga_data))[fcp->fc_linenr++]); SOURCING_LNUM = fcp->fc_linenr; #ifdef FEAT_PROFILE if (do_profiling == PROF_YES) func_line_start(cookie, SOURCING_LNUM); #endif } } // Did we encounter a breakpoint? if (fcp->fc_breakpoint != 0 && fcp->fc_breakpoint <= SOURCING_LNUM) { dbg_breakpoint(fp->uf_name, SOURCING_LNUM); // Find next breakpoint. fcp->fc_breakpoint = dbg_find_breakpoint(FALSE, fp->uf_name, SOURCING_LNUM); fcp->fc_dbg_tick = debug_tick; } return retval; } /* * Return TRUE if the currently active function should be ended, because a * return was encountered or an error occurred. Used inside a ":while". */ int func_has_ended(void *cookie) { funccall_T *fcp = (funccall_T *)cookie; // Ignore the "abort" flag if the abortion behavior has been changed due to // an error inside a try conditional. return (((fcp->fc_func->uf_flags & FC_ABORT) && did_emsg && !aborted_in_try()) || fcp->fc_returned); } /* * return TRUE if cookie indicates a function which "abort"s on errors. */ int func_has_abort( void *cookie) { return ((funccall_T *)cookie)->fc_func->uf_flags & FC_ABORT; } /* * Turn "dict.Func" into a partial for "Func" bound to "dict". * Don't do this when "Func" is already a partial that was bound * explicitly (pt_auto is FALSE). * Changes "rettv" in-place. * Returns the updated "selfdict_in". */ dict_T * make_partial(dict_T *selfdict_in, typval_T *rettv) { char_u *fname; ufunc_T *fp = NULL; char_u fname_buf[FLEN_FIXED + 1]; dict_T *selfdict = selfdict_in; if (rettv->v_type == VAR_PARTIAL && rettv->vval.v_partial != NULL && rettv->vval.v_partial->pt_func != NULL) fp = rettv->vval.v_partial->pt_func; else { fname = rettv->v_type == VAR_FUNC ? rettv->vval.v_string : rettv->vval.v_partial == NULL ? NULL : rettv->vval.v_partial->pt_name; if (fname == NULL) { // There is no point binding a dict to a NULL function, just create // a function reference. rettv->v_type = VAR_FUNC; rettv->vval.v_string = NULL; } else { char_u *tofree = NULL; funcerror_T error; // Translate "s:func" to the stored function name. fname = fname_trans_sid(fname, fname_buf, &tofree, &error); fp = find_func(fname, FALSE); vim_free(tofree); } } if (fp != NULL && (fp->uf_flags & FC_DICT)) { partial_T *pt = ALLOC_CLEAR_ONE(partial_T); if (pt != NULL) { pt->pt_refcount = 1; pt->pt_dict = selfdict; pt->pt_auto = TRUE; selfdict = NULL; if (rettv->v_type == VAR_FUNC) { // Just a function: Take over the function name and use // selfdict. pt->pt_name = rettv->vval.v_string; } else { partial_T *ret_pt = rettv->vval.v_partial; int i; // Partial: copy the function name, use selfdict and copy // args. Can't take over name or args, the partial might // be referenced elsewhere. if (ret_pt->pt_name != NULL) { pt->pt_name = vim_strsave(ret_pt->pt_name); func_ref(pt->pt_name); } else { pt->pt_func = ret_pt->pt_func; func_ptr_ref(pt->pt_func); } if (ret_pt->pt_argc > 0) { pt->pt_argv = ALLOC_MULT(typval_T, ret_pt->pt_argc); if (pt->pt_argv == NULL) // out of memory: drop the arguments pt->pt_argc = 0; else { pt->pt_argc = ret_pt->pt_argc; for (i = 0; i < pt->pt_argc; i++) copy_tv(&ret_pt->pt_argv[i], &pt->pt_argv[i]); } } partial_unref(ret_pt); } rettv->v_type = VAR_PARTIAL; rettv->vval.v_partial = pt; } } return selfdict; } /* * Return the name of the executed function. */ char_u * func_name(void *cookie) { return ((funccall_T *)cookie)->fc_func->uf_name; } /* * Return the address holding the next breakpoint line for a funccall cookie. */ linenr_T * func_breakpoint(void *cookie) { return &((funccall_T *)cookie)->fc_breakpoint; } /* * Return the address holding the debug tick for a funccall cookie. */ int * func_dbg_tick(void *cookie) { return &((funccall_T *)cookie)->fc_dbg_tick; } /* * Return the nesting level for a funccall cookie. */ int func_level(void *cookie) { return ((funccall_T *)cookie)->fc_level; } /* * Return TRUE when a function was ended by a ":return" command. */ int current_func_returned(void) { return current_funccal->fc_returned; } int free_unref_funccal(int copyID, int testing) { int did_free = FALSE; int did_free_funccal = FALSE; funccall_T *fc, **pfc; for (pfc = &previous_funccal; *pfc != NULL; ) { if (can_free_funccal(*pfc, copyID)) { fc = *pfc; *pfc = fc->fc_caller; free_funccal_contents(fc); did_free = TRUE; did_free_funccal = TRUE; } else pfc = &(*pfc)->fc_caller; } if (did_free_funccal) // When a funccal was freed some more items might be garbage // collected, so run again. (void)garbage_collect(testing); return did_free; } /* * Get function call environment based on backtrace debug level */ static funccall_T * get_funccal(void) { int i; funccall_T *funccal; funccall_T *temp_funccal; funccal = current_funccal; if (debug_backtrace_level > 0) { for (i = 0; i < debug_backtrace_level; i++) { temp_funccal = funccal->fc_caller; if (temp_funccal) funccal = temp_funccal; else // backtrace level overflow. reset to max debug_backtrace_level = i; } } return funccal; } /* * Return the hashtable used for local variables in the current funccal. * Return NULL if there is no current funccal. */ hashtab_T * get_funccal_local_ht(void) { if (current_funccal == NULL || current_funccal->fc_l_vars.dv_refcount == 0) return NULL; return &get_funccal()->fc_l_vars.dv_hashtab; } /* * Return the l: scope variable. * Return NULL if there is no current funccal. */ dictitem_T * get_funccal_local_var(void) { if (current_funccal == NULL || current_funccal->fc_l_vars.dv_refcount == 0) return NULL; return &get_funccal()->fc_l_vars_var; } /* * Return the hashtable used for argument in the current funccal. * Return NULL if there is no current funccal. */ hashtab_T * get_funccal_args_ht(void) { if (current_funccal == NULL || current_funccal->fc_l_vars.dv_refcount == 0) return NULL; return &get_funccal()->fc_l_avars.dv_hashtab; } /* * Return the a: scope variable. * Return NULL if there is no current funccal. */ dictitem_T * get_funccal_args_var(void) { if (current_funccal == NULL || current_funccal->fc_l_vars.dv_refcount == 0) return NULL; return &get_funccal()->fc_l_avars_var; } /* * List function variables, if there is a function. */ void list_func_vars(int *first) { if (current_funccal != NULL && current_funccal->fc_l_vars.dv_refcount > 0) list_hashtable_vars(¤t_funccal->fc_l_vars.dv_hashtab, "l:", FALSE, first); } /* * If "ht" is the hashtable for local variables in the current funccal, return * the dict that contains it. * Otherwise return NULL. */ dict_T * get_current_funccal_dict(hashtab_T *ht) { if (current_funccal != NULL && ht == ¤t_funccal->fc_l_vars.dv_hashtab) return ¤t_funccal->fc_l_vars; return NULL; } /* * Search hashitem in parent scope. */ hashitem_T * find_hi_in_scoped_ht(char_u *name, hashtab_T **pht) { funccall_T *old_current_funccal = current_funccal; hashtab_T *ht; hashitem_T *hi = NULL; char_u *varname; if (current_funccal == NULL || current_funccal->fc_func->uf_scoped == NULL) return NULL; // Search in parent scope, which can be referenced from a lambda. current_funccal = current_funccal->fc_func->uf_scoped; while (current_funccal != NULL) { ht = find_var_ht(name, &varname); if (ht != NULL && *varname != NUL) { hi = hash_find(ht, varname); if (!HASHITEM_EMPTY(hi)) { *pht = ht; break; } } if (current_funccal == current_funccal->fc_func->uf_scoped) break; current_funccal = current_funccal->fc_func->uf_scoped; } current_funccal = old_current_funccal; return hi; } /* * Search variable in parent scope. */ dictitem_T * find_var_in_scoped_ht(char_u *name, int no_autoload) { dictitem_T *v = NULL; funccall_T *old_current_funccal = current_funccal; hashtab_T *ht; char_u *varname; if (current_funccal == NULL || current_funccal->fc_func->uf_scoped == NULL) return NULL; // Search in parent scope which is possible to reference from lambda current_funccal = current_funccal->fc_func->uf_scoped; while (current_funccal) { ht = find_var_ht(name, &varname); if (ht != NULL && *varname != NUL) { v = find_var_in_ht(ht, *name, varname, no_autoload); if (v != NULL) break; } if (current_funccal == current_funccal->fc_func->uf_scoped) break; current_funccal = current_funccal->fc_func->uf_scoped; } current_funccal = old_current_funccal; return v; } /* * Set "copyID + 1" in previous_funccal and callers. */ int set_ref_in_previous_funccal(int copyID) { funccall_T *fc; for (fc = previous_funccal; fc != NULL; fc = fc->fc_caller) { fc->fc_copyID = copyID + 1; if (set_ref_in_ht(&fc->fc_l_vars.dv_hashtab, copyID + 1, NULL) || set_ref_in_ht(&fc->fc_l_avars.dv_hashtab, copyID + 1, NULL) || set_ref_in_list_items(&fc->fc_l_varlist, copyID + 1, NULL)) return TRUE; } return FALSE; } static int set_ref_in_funccal(funccall_T *fc, int copyID) { if (fc->fc_copyID != copyID) { fc->fc_copyID = copyID; if (set_ref_in_ht(&fc->fc_l_vars.dv_hashtab, copyID, NULL) || set_ref_in_ht(&fc->fc_l_avars.dv_hashtab, copyID, NULL) || set_ref_in_list_items(&fc->fc_l_varlist, copyID, NULL) || set_ref_in_func(NULL, fc->fc_func, copyID)) return TRUE; } return FALSE; } /* * Set "copyID" in all local vars and arguments in the call stack. */ int set_ref_in_call_stack(int copyID) { funccall_T *fc; funccal_entry_T *entry; for (fc = current_funccal; fc != NULL; fc = fc->fc_caller) if (set_ref_in_funccal(fc, copyID)) return TRUE; // Also go through the funccal_stack. for (entry = funccal_stack; entry != NULL; entry = entry->next) for (fc = entry->top_funccal; fc != NULL; fc = fc->fc_caller) if (set_ref_in_funccal(fc, copyID)) return TRUE; return FALSE; } /* * Set "copyID" in all functions available by name. */ int set_ref_in_functions(int copyID) { int todo; hashitem_T *hi = NULL; ufunc_T *fp; todo = (int)func_hashtab.ht_used; for (hi = func_hashtab.ht_array; todo > 0 && !got_int; ++hi) { if (!HASHITEM_EMPTY(hi)) { --todo; fp = HI2UF(hi); if (!func_name_refcount(fp->uf_name) && set_ref_in_func(NULL, fp, copyID)) return TRUE; } } return FALSE; } /* * Set "copyID" in all function arguments. */ int set_ref_in_func_args(int copyID) { int i; for (i = 0; i < funcargs.ga_len; ++i) if (set_ref_in_item(((typval_T **)funcargs.ga_data)[i], copyID, NULL, NULL)) return TRUE; return FALSE; } /* * Mark all lists and dicts referenced through function "name" with "copyID". * Returns TRUE if setting references failed somehow. */ int set_ref_in_func(char_u *name, ufunc_T *fp_in, int copyID) { ufunc_T *fp = fp_in; funccall_T *fc; funcerror_T error = FCERR_NONE; char_u fname_buf[FLEN_FIXED + 1]; char_u *tofree = NULL; char_u *fname; int abort = FALSE; if (name == NULL && fp_in == NULL) return FALSE; if (fp_in == NULL) { fname = fname_trans_sid(name, fname_buf, &tofree, &error); fp = find_func(fname, FALSE); } if (fp != NULL) { for (fc = fp->uf_scoped; fc != NULL; fc = fc->fc_func->uf_scoped) abort = abort || set_ref_in_funccal(fc, copyID); } vim_free(tofree); return abort; } #endif // FEAT_EVAL