/* 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. */ /* * typval.c: functions that deal with a typval */ #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) /* * Allocate memory for a variable type-value, and make it empty (0 or NULL * value). */ typval_T * alloc_tv(void) { return ALLOC_CLEAR_ONE(typval_T); } /* * Allocate memory for a variable type-value, and assign a string to it. * The string "s" must have been allocated, it is consumed. * Return NULL for out of memory, the variable otherwise. */ typval_T * alloc_string_tv(char_u *s) { typval_T *rettv; rettv = alloc_tv(); if (rettv != NULL) { rettv->v_type = VAR_STRING; rettv->vval.v_string = s; } else vim_free(s); return rettv; } /* * Free the memory for a variable type-value. */ void free_tv(typval_T *varp) { if (varp == NULL) return; switch (varp->v_type) { case VAR_FUNC: func_unref(varp->vval.v_string); // FALLTHROUGH case VAR_STRING: vim_free(varp->vval.v_string); break; case VAR_PARTIAL: partial_unref(varp->vval.v_partial); break; case VAR_BLOB: blob_unref(varp->vval.v_blob); break; case VAR_LIST: list_unref(varp->vval.v_list); break; case VAR_DICT: dict_unref(varp->vval.v_dict); break; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL job_unref(varp->vval.v_job); break; #endif case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL channel_unref(varp->vval.v_channel); break; #endif case VAR_CLASS: class_unref(varp->vval.v_class); break; case VAR_OBJECT: object_unref(varp->vval.v_object); break; case VAR_NUMBER: case VAR_FLOAT: case VAR_ANY: case VAR_UNKNOWN: case VAR_VOID: case VAR_BOOL: case VAR_SPECIAL: case VAR_INSTR: break; } vim_free(varp); } /* * Free the memory for a variable value and set the value to NULL or 0. */ void clear_tv(typval_T *varp) { if (varp == NULL) return; switch (varp->v_type) { case VAR_FUNC: func_unref(varp->vval.v_string); // FALLTHROUGH case VAR_STRING: VIM_CLEAR(varp->vval.v_string); break; case VAR_PARTIAL: partial_unref(varp->vval.v_partial); varp->vval.v_partial = NULL; break; case VAR_BLOB: blob_unref(varp->vval.v_blob); varp->vval.v_blob = NULL; break; case VAR_LIST: list_unref(varp->vval.v_list); varp->vval.v_list = NULL; break; case VAR_DICT: dict_unref(varp->vval.v_dict); varp->vval.v_dict = NULL; break; case VAR_NUMBER: case VAR_BOOL: case VAR_SPECIAL: varp->vval.v_number = 0; break; case VAR_FLOAT: varp->vval.v_float = 0.0; break; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL job_unref(varp->vval.v_job); varp->vval.v_job = NULL; #endif break; case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL channel_unref(varp->vval.v_channel); varp->vval.v_channel = NULL; #endif break; case VAR_INSTR: VIM_CLEAR(varp->vval.v_instr); break; case VAR_CLASS: class_unref(varp->vval.v_class); varp->vval.v_class = NULL; break; case VAR_OBJECT: object_unref(varp->vval.v_object); varp->vval.v_object = NULL; break; case VAR_UNKNOWN: case VAR_ANY: case VAR_VOID: break; } varp->v_lock = 0; } /* * Set the value of a variable to NULL without freeing items. */ void init_tv(typval_T *varp) { if (varp != NULL) CLEAR_POINTER(varp); } static varnumber_T tv_get_bool_or_number_chk(typval_T *varp, int *denote, int want_bool) { varnumber_T n = 0L; switch (varp->v_type) { case VAR_NUMBER: if (in_vim9script() && want_bool && varp->vval.v_number != 0 && varp->vval.v_number != 1) { semsg(_(e_using_number_as_bool_nr), varp->vval.v_number); break; } return varp->vval.v_number; case VAR_FLOAT: emsg(_(e_using_float_as_number)); break; case VAR_FUNC: case VAR_PARTIAL: emsg(_(e_using_funcref_as_number)); break; case VAR_STRING: if (in_vim9script()) { emsg_using_string_as(varp, !want_bool); break; } if (varp->vval.v_string != NULL) vim_str2nr(varp->vval.v_string, NULL, NULL, STR2NR_ALL, &n, NULL, 0, FALSE); return n; case VAR_LIST: emsg(_(e_using_list_as_number)); break; case VAR_DICT: emsg(_(e_using_dictionary_as_number)); break; case VAR_BOOL: case VAR_SPECIAL: if (!want_bool && in_vim9script()) { if (varp->v_type == VAR_BOOL) emsg(_(e_using_bool_as_number)); else emsg(_(e_using_special_as_number)); break; } return varp->vval.v_number == VVAL_TRUE ? 1 : 0; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL emsg(_(e_using_job_as_number)); break; #endif case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL emsg(_(e_using_channel_as_number)); break; #endif case VAR_BLOB: emsg(_(e_using_blob_as_number)); break; case VAR_CLASS: emsg(_(e_using_class_as_number)); break; case VAR_OBJECT: emsg(_(e_using_object_as_number)); break; case VAR_VOID: emsg(_(e_cannot_use_void_value)); break; case VAR_UNKNOWN: case VAR_ANY: case VAR_INSTR: internal_error_no_abort("tv_get_number(UNKNOWN)"); break; } if (denote == NULL) // useful for values that must be unsigned n = -1; else *denote = TRUE; return n; } /* * Get the number value of a variable. * If it is a String variable, uses vim_str2nr(). * For incompatible types, return 0. * tv_get_number_chk() is similar to tv_get_number(), but informs the * caller of incompatible types: it sets *denote to TRUE if "denote" * is not NULL or returns -1 otherwise. */ varnumber_T tv_get_number(typval_T *varp) { int error = FALSE; return tv_get_number_chk(varp, &error); // return 0L on error } varnumber_T tv_get_number_chk(typval_T *varp, int *denote) { return tv_get_bool_or_number_chk(varp, denote, FALSE); } /* * Get the boolean value of "varp". This is like tv_get_number_chk(), * but in Vim9 script accepts Number (0 and 1) and Bool/Special. */ varnumber_T tv_get_bool(typval_T *varp) { return tv_get_bool_or_number_chk(varp, NULL, TRUE); } /* * Get the boolean value of "varp". This is like tv_get_number_chk(), * but in Vim9 script accepts Number and Bool. */ varnumber_T tv_get_bool_chk(typval_T *varp, int *denote) { return tv_get_bool_or_number_chk(varp, denote, TRUE); } static float_T tv_get_float_chk(typval_T *varp, int *error) { switch (varp->v_type) { case VAR_NUMBER: return (float_T)(varp->vval.v_number); case VAR_FLOAT: return varp->vval.v_float; case VAR_FUNC: case VAR_PARTIAL: emsg(_(e_using_funcref_as_float)); break; case VAR_STRING: emsg(_(e_using_string_as_float)); break; case VAR_LIST: emsg(_(e_using_list_as_float)); break; case VAR_DICT: emsg(_(e_using_dictionary_as_float)); break; case VAR_BOOL: emsg(_(e_using_boolean_value_as_float)); break; case VAR_SPECIAL: emsg(_(e_using_special_value_as_float)); break; case VAR_JOB: # ifdef FEAT_JOB_CHANNEL emsg(_(e_using_job_as_float)); break; # endif case VAR_CHANNEL: # ifdef FEAT_JOB_CHANNEL emsg(_(e_using_channel_as_float)); break; # endif case VAR_BLOB: emsg(_(e_using_blob_as_float)); break; case VAR_CLASS: emsg(_(e_using_class_as_float)); break; case VAR_OBJECT: emsg(_(e_using_object_as_float)); break; case VAR_VOID: emsg(_(e_cannot_use_void_value)); break; case VAR_UNKNOWN: case VAR_ANY: case VAR_INSTR: internal_error_no_abort("tv_get_float(UNKNOWN)"); break; } if (error != NULL) *error = TRUE; return 0; } float_T tv_get_float(typval_T *varp) { return tv_get_float_chk(varp, NULL); } /* * Give an error and return FAIL unless "args[idx]" is unknown */ int check_for_unknown_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_UNKNOWN) { semsg(_(e_too_many_arguments), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a string. */ int check_for_string_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING) { semsg(_(e_string_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a non-empty string. */ int check_for_nonempty_string_arg(typval_T *args, int idx) { if (check_for_string_arg(args, idx) == FAIL) return FAIL; if (args[idx].vval.v_string == NULL || *args[idx].vval.v_string == NUL) { semsg(_(e_non_empty_string_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional string argument at 'idx' */ int check_for_opt_string_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_string_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a number. */ int check_for_number_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_NUMBER) { semsg(_(e_number_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional number argument at 'idx' */ int check_for_opt_number_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_number_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a float or a number. */ int check_for_float_or_nr_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_FLOAT && args[idx].v_type != VAR_NUMBER) { semsg(_(e_float_or_number_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a bool. */ int check_for_bool_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_BOOL && !(args[idx].v_type == VAR_NUMBER && (args[idx].vval.v_number == 0 || args[idx].vval.v_number == 1))) { semsg(_(e_bool_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional bool argument at 'idx'. * Return FAIL if the type is wrong. */ int check_for_opt_bool_arg(typval_T *args, int idx) { if (args[idx].v_type == VAR_UNKNOWN) return OK; return check_for_bool_arg(args, idx); } /* * Give an error and return FAIL unless "args[idx]" is a blob. */ int check_for_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_BLOB) { semsg(_(e_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a list. */ int check_for_list_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_LIST) { semsg(_(e_list_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a non-NULL list. */ int check_for_nonnull_list_arg(typval_T *args, int idx) { if (check_for_list_arg(args, idx) == FAIL) return FAIL; if (args[idx].vval.v_list == NULL) { semsg(_(e_non_null_list_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional list argument at 'idx' */ int check_for_opt_list_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_list_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a dict. */ int check_for_dict_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_DICT) { semsg(_(e_dict_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a non-NULL dict. */ int check_for_nonnull_dict_arg(typval_T *args, int idx) { if (check_for_dict_arg(args, idx) == FAIL) return FAIL; if (args[idx].vval.v_dict == NULL) { semsg(_(e_non_null_dict_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional dict argument at 'idx' */ int check_for_opt_dict_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_dict_arg(args, idx) != FAIL) ? OK : FAIL; } #if defined(FEAT_JOB_CHANNEL) || defined(PROTO) /* * Give an error and return FAIL unless "args[idx]" is a channel or a job. */ int check_for_chan_or_job_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_CHANNEL && args[idx].v_type != VAR_JOB) { semsg(_(e_chan_or_job_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is an optional channel or a * job. */ int check_for_opt_chan_or_job_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_chan_or_job_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a job. */ int check_for_job_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_JOB) { semsg(_(e_job_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional job argument at 'idx'. */ int check_for_opt_job_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_job_arg(args, idx) != FAIL) ? OK : FAIL; } #else /* * Give an error and return FAIL unless "args[idx]" is an optional channel or a * job. Used without the +channel feature, thus only VAR_UNKNOWN is accepted. */ int check_for_opt_chan_or_job_arg(typval_T *args, int idx) { return args[idx].v_type == VAR_UNKNOWN ? OK : FAIL; } #endif /* * Give an error and return FAIL unless "args[idx]" is a string or * a number. */ int check_for_string_or_number_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_NUMBER) { semsg(_(e_string_or_number_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional string or number argument at 'idx'. */ int check_for_opt_string_or_number_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_string_or_number_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a buffer number. * Buffer number can be a number or a string. */ int check_for_buffer_arg(typval_T *args, int idx) { return check_for_string_or_number_arg(args, idx); } /* * Check for an optional buffer argument at 'idx' */ int check_for_opt_buffer_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_buffer_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a line number. * Line number can be a number or a string. */ int check_for_lnum_arg(typval_T *args, int idx) { return check_for_string_or_number_arg(args, idx); } /* * Check for an optional line number argument at 'idx' */ int check_for_opt_lnum_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_lnum_arg(args, idx) != FAIL) ? OK : FAIL; } #if defined(FEAT_JOB_CHANNEL) || defined(PROTO) /* * Give an error and return FAIL unless "args[idx]" is a string or a blob. */ int check_for_string_or_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_BLOB) { semsg(_(e_string_or_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } #endif /* * Give an error and return FAIL unless "args[idx]" is a string or a list. */ int check_for_string_or_list_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_LIST) { semsg(_(e_string_or_list_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a string, a list or a * blob. */ int check_for_string_or_list_or_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_BLOB) { semsg(_(e_string_list_or_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Check for an optional string or list argument at 'idx' */ int check_for_opt_string_or_list_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_string_or_list_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a string or a dict. */ int check_for_string_or_dict_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_DICT) { semsg(_(e_string_or_dict_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a string or a number * or a list. */ int check_for_string_or_number_or_list_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_NUMBER && args[idx].v_type != VAR_LIST) { semsg(_(e_string_number_or_list_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is an optional string * or number or a list */ int check_for_opt_string_or_number_or_list_arg(typval_T *args, int idx) { return (args[idx].v_type == VAR_UNKNOWN || check_for_string_or_number_or_list_arg(args, idx) != FAIL) ? OK : FAIL; } /* * Give an error and return FAIL unless "args[idx]" is a string or a number * or a list or a blob. */ int check_for_string_or_number_or_list_or_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_NUMBER && args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_BLOB) { semsg(_(e_string_number_list_or_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a string or a list * or a dict. */ int check_for_string_or_list_or_dict_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_DICT) { semsg(_(e_string_list_or_dict_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a string * or a function reference. */ int check_for_string_or_func_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_PARTIAL && args[idx].v_type != VAR_FUNC && args[idx].v_type != VAR_STRING) { semsg(_(e_string_or_function_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a list or a blob. */ int check_for_list_or_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_BLOB) { semsg(_(e_list_or_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a list or dict */ int check_for_list_or_dict_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_DICT) { semsg(_(e_list_or_dict_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a list or dict or a * blob. */ int check_for_list_or_dict_or_blob_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_DICT && args[idx].v_type != VAR_BLOB) { semsg(_(e_list_dict_or_blob_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is a list or dict or a * blob or a string. */ int check_for_list_or_dict_or_blob_or_string_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_LIST && args[idx].v_type != VAR_DICT && args[idx].v_type != VAR_BLOB && args[idx].v_type != VAR_STRING) { semsg(_(e_list_dict_blob_or_string_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Give an error and return FAIL unless "args[idx]" is an optional buffer * number or a dict. */ int check_for_opt_buffer_or_dict_arg(typval_T *args, int idx) { if (args[idx].v_type != VAR_UNKNOWN && args[idx].v_type != VAR_STRING && args[idx].v_type != VAR_NUMBER && args[idx].v_type != VAR_DICT) { semsg(_(e_string_required_for_argument_nr), idx + 1); return FAIL; } return OK; } /* * Get the string value of a variable. * If it is a Number variable, the number is converted into a string. * tv_get_string() uses a single, static buffer. YOU CAN ONLY USE IT ONCE! * tv_get_string_buf() uses a given buffer. * If the String variable has never been set, return an empty string. * Never returns NULL; * tv_get_string_chk() and tv_get_string_buf_chk() are similar, but return * NULL on error. */ char_u * tv_get_string(typval_T *varp) { static char_u mybuf[NUMBUFLEN]; return tv_get_string_buf(varp, mybuf); } /* * Like tv_get_string() but don't allow number to string conversion for Vim9. */ char_u * tv_get_string_strict(typval_T *varp) { static char_u mybuf[NUMBUFLEN]; char_u *res = tv_get_string_buf_chk_strict( varp, mybuf, in_vim9script()); return res != NULL ? res : (char_u *)""; } char_u * tv_get_string_buf(typval_T *varp, char_u *buf) { char_u *res = tv_get_string_buf_chk(varp, buf); return res != NULL ? res : (char_u *)""; } /* * Careful: This uses a single, static buffer. YOU CAN ONLY USE IT ONCE! */ char_u * tv_get_string_chk(typval_T *varp) { static char_u mybuf[NUMBUFLEN]; return tv_get_string_buf_chk(varp, mybuf); } char_u * tv_get_string_buf_chk(typval_T *varp, char_u *buf) { return tv_get_string_buf_chk_strict(varp, buf, FALSE); } char_u * tv_get_string_buf_chk_strict(typval_T *varp, char_u *buf, int strict) { switch (varp->v_type) { case VAR_NUMBER: if (strict) { emsg(_(e_using_number_as_string)); break; } vim_snprintf((char *)buf, NUMBUFLEN, "%lld", (varnumber_T)varp->vval.v_number); return buf; case VAR_FUNC: case VAR_PARTIAL: emsg(_(e_using_funcref_as_string)); break; case VAR_LIST: emsg(_(e_using_list_as_string)); break; case VAR_DICT: emsg(_(e_using_dictionary_as_string)); break; case VAR_FLOAT: if (strict) { emsg(_(e_using_float_as_string)); break; } vim_snprintf((char *)buf, NUMBUFLEN, "%g", varp->vval.v_float); return buf; case VAR_STRING: if (varp->vval.v_string != NULL) return varp->vval.v_string; return (char_u *)""; case VAR_BOOL: case VAR_SPECIAL: STRCPY(buf, get_var_special_name(varp->vval.v_number)); return buf; case VAR_BLOB: emsg(_(e_using_blob_as_string)); break; case VAR_CLASS: emsg(_(e_using_class_as_string)); break; case VAR_OBJECT: emsg(_(e_using_object_as_string)); break; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL if (in_vim9script()) { semsg(_(e_using_invalid_value_as_string_str), "job"); break; } return job_to_string_buf(varp, buf); #endif break; case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL if (in_vim9script()) { semsg(_(e_using_invalid_value_as_string_str), "channel"); break; } return channel_to_string_buf(varp, buf); #endif break; case VAR_VOID: emsg(_(e_cannot_use_void_value)); break; case VAR_UNKNOWN: case VAR_ANY: case VAR_INSTR: semsg(_(e_using_invalid_value_as_string_str), vartype_name(varp->v_type)); break; } return NULL; } /* * Turn a typeval into a string. Similar to tv_get_string_buf() but uses * string() on Dict, List, etc. */ char_u * tv_stringify(typval_T *varp, char_u *buf) { if (varp->v_type == VAR_LIST || varp->v_type == VAR_DICT || varp->v_type == VAR_BLOB || varp->v_type == VAR_FUNC || varp->v_type == VAR_PARTIAL || varp->v_type == VAR_FLOAT) { typval_T tmp; f_string(varp, &tmp); tv_get_string_buf(&tmp, buf); clear_tv(varp); *varp = tmp; return tmp.vval.v_string; } return tv_get_string_buf(varp, buf); } /* * Return TRUE if typeval "tv" and its value are set to be locked (immutable). * Also give an error message, using "name" or _("name") when use_gettext is * TRUE. */ int tv_check_lock(typval_T *tv, char_u *name, int use_gettext) { int lock = 0; switch (tv->v_type) { case VAR_BLOB: if (tv->vval.v_blob != NULL) lock = tv->vval.v_blob->bv_lock; break; case VAR_LIST: if (tv->vval.v_list != NULL) lock = tv->vval.v_list->lv_lock; break; case VAR_DICT: if (tv->vval.v_dict != NULL) lock = tv->vval.v_dict->dv_lock; break; default: break; } return value_check_lock(tv->v_lock, name, use_gettext) || (lock != 0 && value_check_lock(lock, name, use_gettext)); } /* * Copy the values from typval_T "from" to typval_T "to". * When needed allocates string or increases reference count. * Does not make a copy of a list, blob or dict but copies the reference! * It is OK for "from" and "to" to point to the same item. This is used to * make a copy later. */ void copy_tv(typval_T *from, typval_T *to) { to->v_type = from->v_type; to->v_lock = 0; switch (from->v_type) { case VAR_NUMBER: case VAR_BOOL: case VAR_SPECIAL: to->vval.v_number = from->vval.v_number; break; case VAR_FLOAT: to->vval.v_float = from->vval.v_float; break; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL to->vval.v_job = from->vval.v_job; if (to->vval.v_job != NULL) ++to->vval.v_job->jv_refcount; break; #endif case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL to->vval.v_channel = from->vval.v_channel; if (to->vval.v_channel != NULL) ++to->vval.v_channel->ch_refcount; break; #endif case VAR_INSTR: to->vval.v_instr = from->vval.v_instr; break; case VAR_CLASS: copy_class(from, to); break; case VAR_OBJECT: copy_object(from, to); break; case VAR_STRING: case VAR_FUNC: if (from->vval.v_string == NULL) to->vval.v_string = NULL; else { to->vval.v_string = vim_strsave(from->vval.v_string); if (from->v_type == VAR_FUNC) func_ref(to->vval.v_string); } break; case VAR_PARTIAL: if (from->vval.v_partial == NULL) to->vval.v_partial = NULL; else { to->vval.v_partial = from->vval.v_partial; ++to->vval.v_partial->pt_refcount; } break; case VAR_BLOB: if (from->vval.v_blob == NULL) to->vval.v_blob = NULL; else { to->vval.v_blob = from->vval.v_blob; ++to->vval.v_blob->bv_refcount; } break; case VAR_LIST: if (from->vval.v_list == NULL) to->vval.v_list = NULL; else { to->vval.v_list = from->vval.v_list; ++to->vval.v_list->lv_refcount; } break; case VAR_DICT: if (from->vval.v_dict == NULL) to->vval.v_dict = NULL; else { to->vval.v_dict = from->vval.v_dict; ++to->vval.v_dict->dv_refcount; } break; case VAR_VOID: emsg(_(e_cannot_use_void_value)); break; case VAR_UNKNOWN: case VAR_ANY: internal_error_no_abort("copy_tv(UNKNOWN)"); break; } } /* * Compare "tv1" and "tv2". * Put the result in "tv1". Caller should clear "tv2". */ int typval_compare( typval_T *tv1, // first operand typval_T *tv2, // second operand exprtype_T type, // operator int ic) // ignore case { varnumber_T n1, n2; int res = 0; int type_is = type == EXPR_IS || type == EXPR_ISNOT; if (type_is && tv1->v_type != tv2->v_type) { // For "is" a different type always means FALSE, for "isnot" // it means TRUE. n1 = (type == EXPR_ISNOT); } else if (((tv1->v_type == VAR_SPECIAL && tv1->vval.v_number == VVAL_NULL) || (tv2->v_type == VAR_SPECIAL && tv2->vval.v_number == VVAL_NULL)) && tv1->v_type != tv2->v_type && (type == EXPR_EQUAL || type == EXPR_NEQUAL)) { n1 = typval_compare_null(tv1, tv2); if (n1 == MAYBE) { clear_tv(tv1); return FAIL; } if (type == EXPR_NEQUAL) n1 = !n1; } else if (tv1->v_type == VAR_BLOB || tv2->v_type == VAR_BLOB) { if (typval_compare_blob(tv1, tv2, type, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } else if (tv1->v_type == VAR_LIST || tv2->v_type == VAR_LIST) { if (typval_compare_list(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } else if (tv1->v_type == VAR_CLASS || tv2->v_type == VAR_CLASS) { if (typval_compare_class(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } else if (tv1->v_type == VAR_OBJECT || tv2->v_type == VAR_OBJECT) { if (typval_compare_object(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } else if (tv1->v_type == VAR_DICT || tv2->v_type == VAR_DICT) { if (typval_compare_dict(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } else if (tv1->v_type == VAR_FUNC || tv2->v_type == VAR_FUNC || tv1->v_type == VAR_PARTIAL || tv2->v_type == VAR_PARTIAL) { if (typval_compare_func(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } // If one of the two variables is a float, compare as a float. // When using "=~" or "!~", always compare as string. else if ((tv1->v_type == VAR_FLOAT || tv2->v_type == VAR_FLOAT) && type != EXPR_MATCH && type != EXPR_NOMATCH) { float_T f1, f2; int error = FALSE; f1 = tv_get_float_chk(tv1, &error); if (!error) f2 = tv_get_float_chk(tv2, &error); if (error) { clear_tv(tv1); return FAIL; } n1 = FALSE; switch (type) { case EXPR_IS: case EXPR_EQUAL: n1 = (f1 == f2); break; case EXPR_ISNOT: case EXPR_NEQUAL: n1 = (f1 != f2); break; case EXPR_GREATER: n1 = (f1 > f2); break; case EXPR_GEQUAL: n1 = (f1 >= f2); break; case EXPR_SMALLER: n1 = (f1 < f2); break; case EXPR_SEQUAL: n1 = (f1 <= f2); break; case EXPR_UNKNOWN: case EXPR_MATCH: default: break; // avoid gcc warning } } // If one of the two variables is a number, compare as a number. // When using "=~" or "!~", always compare as string. else if ((tv1->v_type == VAR_NUMBER || tv2->v_type == VAR_NUMBER) && type != EXPR_MATCH && type != EXPR_NOMATCH) { int error = FALSE; n1 = tv_get_number_chk(tv1, &error); if (!error) n2 = tv_get_number_chk(tv2, &error); if (error) { clear_tv(tv1); return FAIL; } switch (type) { case EXPR_IS: case EXPR_EQUAL: n1 = (n1 == n2); break; case EXPR_ISNOT: case EXPR_NEQUAL: n1 = (n1 != n2); break; case EXPR_GREATER: n1 = (n1 > n2); break; case EXPR_GEQUAL: n1 = (n1 >= n2); break; case EXPR_SMALLER: n1 = (n1 < n2); break; case EXPR_SEQUAL: n1 = (n1 <= n2); break; case EXPR_UNKNOWN: case EXPR_MATCH: default: break; // avoid gcc warning } } else if (in_vim9script() && (tv1->v_type == VAR_BOOL || tv2->v_type == VAR_BOOL || (tv1->v_type == VAR_SPECIAL && tv2->v_type == VAR_SPECIAL))) { if (tv1->v_type != tv2->v_type) { semsg(_(e_cannot_compare_str_with_str), vartype_name(tv1->v_type), vartype_name(tv2->v_type)); clear_tv(tv1); return FAIL; } n1 = tv1->vval.v_number; n2 = tv2->vval.v_number; switch (type) { case EXPR_IS: case EXPR_EQUAL: n1 = (n1 == n2); break; case EXPR_ISNOT: case EXPR_NEQUAL: n1 = (n1 != n2); break; default: semsg(_(e_invalid_operation_for_str), vartype_name(tv1->v_type)); clear_tv(tv1); return FAIL; } } #ifdef FEAT_JOB_CHANNEL else if (tv1->v_type == tv2->v_type && (tv1->v_type == VAR_CHANNEL || tv1->v_type == VAR_JOB) && (type == EXPR_NEQUAL || type == EXPR_EQUAL)) { if (tv1->v_type == VAR_CHANNEL) n1 = tv1->vval.v_channel == tv2->vval.v_channel; else n1 = tv1->vval.v_job == tv2->vval.v_job; if (type == EXPR_NEQUAL) n1 = !n1; } #endif else { if (typval_compare_string(tv1, tv2, type, ic, &res) == FAIL) { clear_tv(tv1); return FAIL; } n1 = res; } clear_tv(tv1); if (in_vim9script()) { tv1->v_type = VAR_BOOL; tv1->vval.v_number = n1 ? VVAL_TRUE : VVAL_FALSE; } else { tv1->v_type = VAR_NUMBER; tv1->vval.v_number = n1; } return OK; } /* * Compare "tv1" to "tv2" as lists according to "type" and "ic". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_list( typval_T *tv1, typval_T *tv2, exprtype_T type, int ic, int *res) { int val = 0; if (type == EXPR_IS || type == EXPR_ISNOT) { val = (tv1->v_type == tv2->v_type && tv1->vval.v_list == tv2->vval.v_list); if (type == EXPR_ISNOT) val = !val; } else if (tv1->v_type != tv2->v_type || (type != EXPR_EQUAL && type != EXPR_NEQUAL)) { if (tv1->v_type != tv2->v_type) emsg(_(e_can_only_compare_list_with_list)); else emsg(_(e_invalid_operation_for_list)); return FAIL; } else { val = list_equal(tv1->vval.v_list, tv2->vval.v_list, ic, FALSE); if (type == EXPR_NEQUAL) val = !val; } *res = val; return OK; } /* * Compare v:null with another type. Return TRUE if the value is NULL. */ int typval_compare_null(typval_T *tv1, typval_T *tv2) { if ((tv1->v_type == VAR_SPECIAL && tv1->vval.v_number == VVAL_NULL) || (tv2->v_type == VAR_SPECIAL && tv2->vval.v_number == VVAL_NULL)) { typval_T *tv = tv1->v_type == VAR_SPECIAL ? tv2 : tv1; switch (tv->v_type) { case VAR_BLOB: return tv->vval.v_blob == NULL; #ifdef FEAT_JOB_CHANNEL case VAR_CHANNEL: return tv->vval.v_channel == NULL; #endif case VAR_DICT: return tv->vval.v_dict == NULL; case VAR_FUNC: return tv->vval.v_string == NULL; #ifdef FEAT_JOB_CHANNEL case VAR_JOB: return tv->vval.v_job == NULL; #endif case VAR_LIST: return tv->vval.v_list == NULL; case VAR_PARTIAL: return tv->vval.v_partial == NULL; case VAR_STRING: return tv->vval.v_string == NULL; case VAR_NUMBER: if (!in_vim9script()) return tv->vval.v_number == 0; break; case VAR_FLOAT: if (!in_vim9script()) return tv->vval.v_float == 0.0; break; default: break; } } // although comparing null with number, float or bool is not very useful // we won't give an error return FALSE; } /* * Compare "tv1" to "tv2" as blobs according to "type". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_blob( typval_T *tv1, typval_T *tv2, exprtype_T type, int *res) { int val = 0; if (type == EXPR_IS || type == EXPR_ISNOT) { val = (tv1->v_type == tv2->v_type && tv1->vval.v_blob == tv2->vval.v_blob); if (type == EXPR_ISNOT) val = !val; } else if (tv1->v_type != tv2->v_type || (type != EXPR_EQUAL && type != EXPR_NEQUAL)) { if (tv1->v_type != tv2->v_type) emsg(_(e_can_only_compare_blob_with_blob)); else emsg(_(e_invalid_operation_for_blob)); return FAIL; } else { val = blob_equal(tv1->vval.v_blob, tv2->vval.v_blob); if (type == EXPR_NEQUAL) val = !val; } *res = val; return OK; } /* * Compare "tv1" to "tv2" as classes according to "type". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_class( typval_T *tv1, typval_T *tv2, exprtype_T type UNUSED, int ic UNUSED, int *res) { // TODO: use "type" *res = tv1->vval.v_class == tv2->vval.v_class; return OK; } /* * Compare "tv1" to "tv2" as objects according to "type". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_object( typval_T *tv1, typval_T *tv2, exprtype_T type, int ic, int *res) { int res_match = type == EXPR_EQUAL || type == EXPR_IS ? TRUE : FALSE; if (tv1->vval.v_object == NULL && tv2->vval.v_object == NULL) { *res = res_match; return OK; } if (tv1->vval.v_object == NULL || tv2->vval.v_object == NULL) { *res = !res_match; return OK; } class_T *cl1 = tv1->vval.v_object->obj_class; class_T *cl2 = tv2->vval.v_object->obj_class; if (cl1 != cl2 || cl1 == NULL || cl2 == NULL) { *res = !res_match; return OK; } object_T *obj1 = tv1->vval.v_object; object_T *obj2 = tv2->vval.v_object; if (type == EXPR_IS || type == EXPR_ISNOT) { *res = obj1 == obj2 ? res_match : !res_match; return OK; } for (int i = 0; i < cl1->class_obj_member_count; ++i) if (!tv_equal((typval_T *)(obj1 + 1) + i, (typval_T *)(obj2 + 1) + i, ic, TRUE)) { *res = !res_match; return OK; } *res = res_match; return OK; } /* * Compare "tv1" to "tv2" as dictionaries according to "type" and "ic". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_dict( typval_T *tv1, typval_T *tv2, exprtype_T type, int ic, int *res) { int val; if (type == EXPR_IS || type == EXPR_ISNOT) { val = (tv1->v_type == tv2->v_type && tv1->vval.v_dict == tv2->vval.v_dict); if (type == EXPR_ISNOT) val = !val; } else if (tv1->v_type != tv2->v_type || (type != EXPR_EQUAL && type != EXPR_NEQUAL)) { if (tv1->v_type != tv2->v_type) emsg(_(e_can_only_compare_dictionary_with_dictionary)); else emsg(_(e_invalid_operation_for_dictionary)); return FAIL; } else { val = dict_equal(tv1->vval.v_dict, tv2->vval.v_dict, ic, FALSE); if (type == EXPR_NEQUAL) val = !val; } *res = val; return OK; } /* * Compare "tv1" to "tv2" as funcrefs according to "type" and "ic". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_func( typval_T *tv1, typval_T *tv2, exprtype_T type, int ic, int *res) { int val = 0; if (type != EXPR_EQUAL && type != EXPR_NEQUAL && type != EXPR_IS && type != EXPR_ISNOT) { emsg(_(e_invalid_operation_for_funcrefs)); return FAIL; } if ((tv1->v_type == VAR_PARTIAL && tv1->vval.v_partial == NULL) || (tv2->v_type == VAR_PARTIAL && tv2->vval.v_partial == NULL)) // When both partials are NULL, then they are equal. // Otherwise they are not equal. val = (tv1->vval.v_partial == tv2->vval.v_partial); else if (type == EXPR_IS || type == EXPR_ISNOT) { if (tv1->v_type == VAR_FUNC && tv2->v_type == VAR_FUNC) // strings are considered the same if their value is // the same val = tv_equal(tv1, tv2, ic, FALSE); else if (tv1->v_type == VAR_PARTIAL && tv2->v_type == VAR_PARTIAL) val = (tv1->vval.v_partial == tv2->vval.v_partial); else val = FALSE; } else val = tv_equal(tv1, tv2, ic, FALSE); if (type == EXPR_NEQUAL || type == EXPR_ISNOT) val = !val; *res = val; return OK; } /* * Compare "tv1" to "tv2" as strings according to "type" and "ic". * Put the result, false or true, in "res". * Return FAIL and give an error message when the comparison can't be done. */ int typval_compare_string( typval_T *tv1, typval_T *tv2, exprtype_T type, int ic, int *res) { int i = 0; int val = FALSE; char_u *s1, *s2; char_u buf1[NUMBUFLEN], buf2[NUMBUFLEN]; if (in_vim9script() && ((tv1->v_type != VAR_STRING && tv1->v_type != VAR_SPECIAL) || (tv2->v_type != VAR_STRING && tv2->v_type != VAR_SPECIAL))) { semsg(_(e_cannot_compare_str_with_str), vartype_name(tv1->v_type), vartype_name(tv2->v_type)); return FAIL; } s1 = tv_get_string_buf(tv1, buf1); s2 = tv_get_string_buf(tv2, buf2); if (type != EXPR_MATCH && type != EXPR_NOMATCH) i = ic ? MB_STRICMP(s1, s2) : STRCMP(s1, s2); switch (type) { case EXPR_IS: if (in_vim9script()) { // Really check it is the same string, not just // the same value. val = tv1->vval.v_string == tv2->vval.v_string; break; } // FALLTHROUGH case EXPR_EQUAL: val = (i == 0); break; case EXPR_ISNOT: if (in_vim9script()) { // Really check it is not the same string, not // just a different value. val = tv1->vval.v_string != tv2->vval.v_string; break; } // FALLTHROUGH case EXPR_NEQUAL: val = (i != 0); break; case EXPR_GREATER: val = (i > 0); break; case EXPR_GEQUAL: val = (i >= 0); break; case EXPR_SMALLER: val = (i < 0); break; case EXPR_SEQUAL: val = (i <= 0); break; case EXPR_MATCH: case EXPR_NOMATCH: val = pattern_match(s2, s1, ic); if (type == EXPR_NOMATCH) val = !val; break; default: break; // avoid gcc warning } *res = val; return OK; } /* * Convert any type to a string, never give an error. * When "quotes" is TRUE add quotes to a string. * Returns an allocated string. */ char_u * typval_tostring(typval_T *arg, int quotes) { char_u *tofree; char_u numbuf[NUMBUFLEN]; char_u *ret = NULL; if (arg == NULL) return vim_strsave((char_u *)"(does not exist)"); if (!quotes && arg->v_type == VAR_STRING) { ret = vim_strsave(arg->vval.v_string == NULL ? (char_u *)"" : arg->vval.v_string); } else { ret = tv2string(arg, &tofree, numbuf, 0); // Make a copy if we have a value but it's not in allocated memory. if (ret != NULL && tofree == NULL) ret = vim_strsave(ret); } return ret; } /* * Return TRUE if typeval "tv" is locked: Either that value is locked itself * or it refers to a List or Dictionary that is locked. */ int tv_islocked(typval_T *tv) { return (tv->v_lock & VAR_LOCKED) || (tv->v_type == VAR_LIST && tv->vval.v_list != NULL && (tv->vval.v_list->lv_lock & VAR_LOCKED)) || (tv->v_type == VAR_DICT && tv->vval.v_dict != NULL && (tv->vval.v_dict->dv_lock & VAR_LOCKED)); } static int func_equal( typval_T *tv1, typval_T *tv2, int ic) // ignore case { char_u *s1, *s2; dict_T *d1, *d2; int a1, a2; int i; // empty and NULL function name considered the same s1 = tv1->v_type == VAR_FUNC ? tv1->vval.v_string : partial_name(tv1->vval.v_partial); if (s1 != NULL && *s1 == NUL) s1 = NULL; s2 = tv2->v_type == VAR_FUNC ? tv2->vval.v_string : partial_name(tv2->vval.v_partial); if (s2 != NULL && *s2 == NUL) s2 = NULL; if (s1 == NULL || s2 == NULL) { if (s1 != s2) return FALSE; } else if (STRCMP(s1, s2) != 0) return FALSE; // empty dict and NULL dict is different d1 = tv1->v_type == VAR_FUNC ? NULL : tv1->vval.v_partial->pt_dict; d2 = tv2->v_type == VAR_FUNC ? NULL : tv2->vval.v_partial->pt_dict; if (d1 == NULL || d2 == NULL) { if (d1 != d2) return FALSE; } else if (!dict_equal(d1, d2, ic, TRUE)) return FALSE; // empty list and no list considered the same a1 = tv1->v_type == VAR_FUNC ? 0 : tv1->vval.v_partial->pt_argc; a2 = tv2->v_type == VAR_FUNC ? 0 : tv2->vval.v_partial->pt_argc; if (a1 != a2) return FALSE; for (i = 0; i < a1; ++i) if (!tv_equal(tv1->vval.v_partial->pt_argv + i, tv2->vval.v_partial->pt_argv + i, ic, TRUE)) return FALSE; return TRUE; } /* * Return TRUE if "tv1" and "tv2" have the same value. * Compares the items just like "==" would compare them, but strings and * numbers are different. Floats and numbers are also different. */ int tv_equal( typval_T *tv1, typval_T *tv2, int ic, // ignore case int recursive) // TRUE when used recursively { char_u buf1[NUMBUFLEN], buf2[NUMBUFLEN]; char_u *s1, *s2; static int recursive_cnt = 0; // catch recursive loops int r; static int tv_equal_recurse_limit; // Catch lists and dicts that have an endless loop by limiting // recursiveness to a limit. We guess they are equal then. // A fixed limit has the problem of still taking an awful long time. // Reduce the limit every time running into it. That should work fine for // deeply linked structures that are not recursively linked and catch // recursiveness quickly. if (!recursive) tv_equal_recurse_limit = 1000; if (recursive_cnt >= tv_equal_recurse_limit) { --tv_equal_recurse_limit; return TRUE; } // For VAR_FUNC and VAR_PARTIAL compare the function name, bound dict and // arguments. if ((tv1->v_type == VAR_FUNC || (tv1->v_type == VAR_PARTIAL && tv1->vval.v_partial != NULL)) && (tv2->v_type == VAR_FUNC || (tv2->v_type == VAR_PARTIAL && tv2->vval.v_partial != NULL))) { ++recursive_cnt; r = func_equal(tv1, tv2, ic); --recursive_cnt; return r; } if (tv1->v_type != tv2->v_type && ((tv1->v_type != VAR_BOOL && tv1->v_type != VAR_SPECIAL) || (tv2->v_type != VAR_BOOL && tv2->v_type != VAR_SPECIAL))) return FALSE; switch (tv1->v_type) { case VAR_LIST: ++recursive_cnt; r = list_equal(tv1->vval.v_list, tv2->vval.v_list, ic, TRUE); --recursive_cnt; return r; case VAR_DICT: ++recursive_cnt; r = dict_equal(tv1->vval.v_dict, tv2->vval.v_dict, ic, TRUE); --recursive_cnt; return r; case VAR_BLOB: return blob_equal(tv1->vval.v_blob, tv2->vval.v_blob); case VAR_NUMBER: case VAR_BOOL: case VAR_SPECIAL: return tv1->vval.v_number == tv2->vval.v_number; case VAR_STRING: s1 = tv_get_string_buf(tv1, buf1); s2 = tv_get_string_buf(tv2, buf2); return ((ic ? MB_STRICMP(s1, s2) : STRCMP(s1, s2)) == 0); case VAR_FLOAT: return tv1->vval.v_float == tv2->vval.v_float; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL return tv1->vval.v_job == tv2->vval.v_job; #endif case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL return tv1->vval.v_channel == tv2->vval.v_channel; #endif case VAR_INSTR: return tv1->vval.v_instr == tv2->vval.v_instr; case VAR_CLASS: // A class only exists once, equality is identity. return tv1->vval.v_class == tv2->vval.v_class; case VAR_OBJECT: (void)typval_compare_object(tv1, tv2, EXPR_EQUAL, ic, &r); return r; case VAR_PARTIAL: return tv1->vval.v_partial == tv2->vval.v_partial; case VAR_FUNC: return tv1->vval.v_string == tv2->vval.v_string; case VAR_UNKNOWN: case VAR_ANY: case VAR_VOID: break; } // VAR_UNKNOWN can be the result of a invalid expression, let's say it // does not equal anything, not even itself. return FALSE; } /* * Get an option value. * "arg" points to the '&' or '+' before the option name. * "arg" is advanced to character after the option name. * Return OK or FAIL. */ int eval_option( char_u **arg, typval_T *rettv, // when NULL, only check if option exists int evaluate) { char_u *option_end; long numval; char_u *stringval; getoption_T opt_type; int c; int working = (**arg == '+'); // has("+option") int ret = OK; int scope; // Isolate the option name and find its value. option_end = find_option_end(arg, &scope); if (option_end == NULL) { if (rettv != NULL) semsg(_(e_option_name_missing_str), *arg); return FAIL; } if (!evaluate) { *arg = option_end; return OK; } c = *option_end; *option_end = NUL; opt_type = get_option_value(*arg, &numval, rettv == NULL ? NULL : &stringval, NULL, scope); if (opt_type == gov_unknown) { if (rettv != NULL) semsg(_(e_unknown_option_str), *arg); ret = FAIL; } else if (rettv != NULL) { rettv->v_lock = 0; if (opt_type == gov_hidden_string) { rettv->v_type = VAR_STRING; rettv->vval.v_string = NULL; } else if (opt_type == gov_hidden_bool || opt_type == gov_hidden_number) { rettv->v_type = in_vim9script() && opt_type == gov_hidden_bool ? VAR_BOOL : VAR_NUMBER; rettv->vval.v_number = 0; } else if (opt_type == gov_bool || opt_type == gov_number) { if (in_vim9script() && opt_type == gov_bool) { rettv->v_type = VAR_BOOL; rettv->vval.v_number = numval ? VVAL_TRUE : VVAL_FALSE; } else { rettv->v_type = VAR_NUMBER; rettv->vval.v_number = numval; } } else // string option { rettv->v_type = VAR_STRING; rettv->vval.v_string = stringval; } } else if (working && (opt_type == gov_hidden_bool || opt_type == gov_hidden_number || opt_type == gov_hidden_string)) ret = FAIL; *option_end = c; // put back for error messages *arg = option_end; return ret; } /* * Allocate a variable for a number constant. Also deals with "0z" for blob. * Return OK or FAIL. */ int eval_number( char_u **arg, typval_T *rettv, int evaluate, int want_string UNUSED) { int len; int skip_quotes = !in_old_script(4); char_u *p; int get_float = FALSE; // We accept a float when the format matches // "[0-9]\+\.[0-9]\+\([eE][+-]\?[0-9]\+\)\?". This is very // strict to avoid backwards compatibility problems. // With script version 2 and later the leading digit can be // omitted. // Don't look for a float after the "." operator, so that // ":let vers = 1.2.3" doesn't fail. if (**arg == '.') p = *arg; else { p = *arg + 1; if (skip_quotes) for (;;) { if (*p == '\'') ++p; if (!vim_isdigit(*p)) break; p = skipdigits(p); } else p = skipdigits(p); } if (!want_string && p[0] == '.' && vim_isdigit(p[1])) { get_float = TRUE; p = skipdigits(p + 2); if (*p == 'e' || *p == 'E') { ++p; if (*p == '-' || *p == '+') ++p; if (!vim_isdigit(*p)) get_float = FALSE; else p = skipdigits(p + 1); } if (ASCII_ISALPHA(*p) || *p == '.') get_float = FALSE; } if (get_float) { float_T f; *arg += string2float(*arg, &f, skip_quotes); if (evaluate) { rettv->v_type = VAR_FLOAT; rettv->vval.v_float = f; } } else if (**arg == '0' && ((*arg)[1] == 'z' || (*arg)[1] == 'Z')) { char_u *bp; blob_T *blob = NULL; // init for gcc // Blob constant: 0z0123456789abcdef if (evaluate) blob = blob_alloc(); for (bp = *arg + 2; vim_isxdigit(bp[0]); bp += 2) { if (!vim_isxdigit(bp[1])) { if (blob != NULL) { emsg(_(e_blob_literal_should_have_an_even_number_of_hex_characters)); ga_clear(&blob->bv_ga); VIM_CLEAR(blob); } return FAIL; } if (blob != NULL) ga_append(&blob->bv_ga, (hex2nr(*bp) << 4) + hex2nr(*(bp+1))); if (bp[2] == '.' && vim_isxdigit(bp[3])) ++bp; } if (blob != NULL) rettv_blob_set(rettv, blob); *arg = bp; } else { varnumber_T n; // decimal, hex or octal number vim_str2nr(*arg, NULL, &len, skip_quotes ? STR2NR_NO_OCT + STR2NR_QUOTE : STR2NR_ALL, &n, NULL, 0, TRUE); if (len == 0) { if (evaluate) semsg(_(e_invalid_expression_str), *arg); return FAIL; } *arg += len; if (evaluate) { rettv->v_type = VAR_NUMBER; rettv->vval.v_number = n; } } return OK; } /* * Evaluate a string constant and put the result in "rettv". * "*arg" points to the double quote or to after it when "interpolate" is TRUE. * When "interpolate" is TRUE reduce "{{" to "{", reduce "}}" to "}" and stop * at a single "{". * Return OK or FAIL. */ int eval_string(char_u **arg, typval_T *rettv, int evaluate, int interpolate) { char_u *p; char_u *end; int extra = interpolate ? 1 : 0; int off = interpolate ? 0 : 1; int len; // Find the end of the string, skipping backslashed characters. for (p = *arg + off; *p != NUL && *p != '"'; MB_PTR_ADV(p)) { if (*p == '\\' && p[1] != NUL) { ++p; // A "\" form occupies at least 4 characters, and produces up // to 9 characters (6 for the char and 3 for a modifier): // reserve space for 5 extra. if (*p == '<') { int modifiers = 0; int flags = FSK_KEYCODE | FSK_IN_STRING; extra += 5; // Skip to the '>' to avoid using '{' inside for string // interpolation. if (p[1] != '*') flags |= FSK_SIMPLIFY; if (find_special_key(&p, &modifiers, flags, NULL) != 0) --p; // leave "p" on the ">" } } else if (interpolate && (*p == '{' || *p == '}')) { if (*p == '{' && p[1] != '{') // start of expression break; ++p; if (p[-1] == '}' && *p != '}') // single '}' is an error { semsg(_(e_stray_closing_curly_str), *arg); return FAIL; } --extra; // "{{" becomes "{", "}}" becomes "}" } } if (*p != '"' && !(interpolate && *p == '{')) { semsg(_(e_missing_double_quote_str), *arg); return FAIL; } // If only parsing, set *arg and return here if (!evaluate) { *arg = p + off; return OK; } // Copy the string into allocated memory, handling backslashed // characters. rettv->v_type = VAR_STRING; len = (int)(p - *arg + extra); rettv->vval.v_string = alloc(len); if (rettv->vval.v_string == NULL) return FAIL; end = rettv->vval.v_string; for (p = *arg + off; *p != NUL && *p != '"'; ) { if (*p == '\\') { switch (*++p) { case 'b': *end++ = BS; ++p; break; case 'e': *end++ = ESC; ++p; break; case 'f': *end++ = FF; ++p; break; case 'n': *end++ = NL; ++p; break; case 'r': *end++ = CAR; ++p; break; case 't': *end++ = TAB; ++p; break; case 'X': // hex: "\x1", "\x12" case 'x': case 'u': // Unicode: "\u0023" case 'U': if (vim_isxdigit(p[1])) { int n, nr; int c = toupper(*p); if (c == 'X') n = 2; else if (*p == 'u') n = 4; else n = 8; nr = 0; while (--n >= 0 && vim_isxdigit(p[1])) { ++p; nr = (nr << 4) + hex2nr(*p); } ++p; // For "\u" store the number according to // 'encoding'. if (c != 'X') end += (*mb_char2bytes)(nr, end); else *end++ = nr; } break; // octal: "\1", "\12", "\123" case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': *end = *p++ - '0'; if (*p >= '0' && *p <= '7') { *end = (*end << 3) + *p++ - '0'; if (*p >= '0' && *p <= '7') *end = (*end << 3) + *p++ - '0'; } ++end; break; // Special key, e.g.: "\" case '<': { int flags = FSK_KEYCODE | FSK_IN_STRING; if (p[1] != '*') flags |= FSK_SIMPLIFY; extra = trans_special(&p, end, flags, FALSE, NULL); if (extra != 0) { end += extra; if (end >= rettv->vval.v_string + len) iemsg("eval_string() used more space than allocated"); break; } } // FALLTHROUGH default: MB_COPY_CHAR(p, end); break; } } else { if (interpolate && (*p == '{' || *p == '}')) { if (*p == '{' && p[1] != '{') // start of expression break; ++p; // reduce "{{" to "{" and "}}" to "}" } MB_COPY_CHAR(p, end); } } *end = NUL; if (*p == '"' && !interpolate) ++p; *arg = p; return OK; } /* * Allocate a variable for a 'str''ing' constant. * When "interpolate" is TRUE reduce "{{" to "{" and stop at a single "{". * Return OK when a "rettv" was set to the string. * Return FAIL on error, "rettv" is not set. */ int eval_lit_string(char_u **arg, typval_T *rettv, int evaluate, int interpolate) { char_u *p; char_u *str; int reduce = interpolate ? -1 : 0; int off = interpolate ? 0 : 1; // Find the end of the string, skipping ''. for (p = *arg + off; *p != NUL; MB_PTR_ADV(p)) { if (*p == '\'') { if (p[1] != '\'') break; ++reduce; ++p; } else if (interpolate) { if (*p == '{') { if (p[1] != '{') break; ++p; ++reduce; } else if (*p == '}') { ++p; if (*p != '}') { semsg(_(e_stray_closing_curly_str), *arg); return FAIL; } ++reduce; } } } if (*p != '\'' && !(interpolate && *p == '{')) { semsg(_(e_missing_single_quote_str), *arg); return FAIL; } // If only parsing return after setting "*arg" if (!evaluate) { *arg = p + off; return OK; } // Copy the string into allocated memory, handling '' to ' reduction and // any expressions. str = alloc((p - *arg) - reduce); if (str == NULL) return FAIL; rettv->v_type = VAR_STRING; rettv->vval.v_string = str; for (p = *arg + off; *p != NUL; ) { if (*p == '\'') { if (p[1] != '\'') break; ++p; } else if (interpolate && (*p == '{' || *p == '}')) { if (*p == '{' && p[1] != '{') break; ++p; } MB_COPY_CHAR(p, str); } *str = NUL; *arg = p + off; return OK; } /* * Evaluate a single or double quoted string possibly containing expressions. * "arg" points to the '$'. The result is put in "rettv". * Returns OK or FAIL. */ int eval_interp_string(char_u **arg, typval_T *rettv, int evaluate) { typval_T tv; int ret = OK; int quote; garray_T ga; char_u *p; ga_init2(&ga, 1, 80); // *arg is on the '$' character, move it to the first string character. ++*arg; quote = **arg; ++*arg; for (;;) { // Get the string up to the matching quote or to a single '{'. // "arg" is advanced to either the quote or the '{'. if (quote == '"') ret = eval_string(arg, &tv, evaluate, TRUE); else ret = eval_lit_string(arg, &tv, evaluate, TRUE); if (ret == FAIL) break; if (evaluate) { ga_concat(&ga, tv.vval.v_string); clear_tv(&tv); } if (**arg != '{') { // found terminating quote ++*arg; break; } p = eval_one_expr_in_str(*arg, &ga, evaluate); if (p == NULL) { ret = FAIL; break; } *arg = p; } rettv->v_type = VAR_STRING; if (ret == FAIL || !evaluate || ga_append(&ga, NUL) == FAIL) { ga_clear(&ga); rettv->vval.v_string = NULL; return ret; } rettv->vval.v_string = ga.ga_data; return OK; } /* * Return a string with the string representation of a variable. * If the memory is allocated "tofree" is set to it, otherwise NULL. * "numbuf" is used for a number. * Puts quotes around strings, so that they can be parsed back by eval(). * May return NULL. */ char_u * tv2string( typval_T *tv, char_u **tofree, char_u *numbuf, int copyID) { return echo_string_core(tv, tofree, numbuf, copyID, FALSE, TRUE, FALSE); } /* * Get the value of an environment variable. * "arg" is pointing to the '$'. It is advanced to after the name. * If the environment variable was not set, silently assume it is empty. * Return FAIL if the name is invalid. */ int eval_env_var(char_u **arg, typval_T *rettv, int evaluate) { char_u *string = NULL; int len; int cc; char_u *name; int mustfree = FALSE; ++*arg; name = *arg; len = get_env_len(arg); if (evaluate) { if (len == 0) return FAIL; // invalid empty name cc = name[len]; name[len] = NUL; // first try vim_getenv(), fast for normal environment vars string = vim_getenv(name, &mustfree); if (string != NULL && *string != NUL) { if (!mustfree) string = vim_strsave(string); } else { if (mustfree) vim_free(string); // next try expanding things like $VIM and ${HOME} string = expand_env_save(name - 1); if (string != NULL && *string == '$') VIM_CLEAR(string); } name[len] = cc; rettv->v_type = VAR_STRING; rettv->vval.v_string = string; rettv->v_lock = 0; } return OK; } /* * Get the lnum from the first argument. * Also accepts ".", "$", etc., but that only works for the current buffer. * Returns -1 on error. */ linenr_T tv_get_lnum(typval_T *argvars) { linenr_T lnum = -1; int did_emsg_before = did_emsg; if (argvars[0].v_type != VAR_STRING || !in_vim9script()) lnum = (linenr_T)tv_get_number_chk(&argvars[0], NULL); if (lnum <= 0 && did_emsg_before == did_emsg && argvars[0].v_type != VAR_NUMBER) { int fnum; pos_T *fp; // no valid number, try using arg like line() fp = var2fpos(&argvars[0], TRUE, &fnum, FALSE); if (fp != NULL) lnum = fp->lnum; } return lnum; } /* * Get the lnum from the first argument. * Also accepts "$", then "buf" is used. * Returns 0 on error. */ linenr_T tv_get_lnum_buf(typval_T *argvars, buf_T *buf) { if (argvars[0].v_type == VAR_STRING && argvars[0].vval.v_string != NULL && argvars[0].vval.v_string[0] == '$' && argvars[0].vval.v_string[1] == NUL && buf != NULL) return buf->b_ml.ml_line_count; return (linenr_T)tv_get_number_chk(&argvars[0], NULL); } /* * Get buffer by number or pattern. */ buf_T * tv_get_buf(typval_T *tv, int curtab_only) { char_u *name = tv->vval.v_string; buf_T *buf; if (tv->v_type == VAR_NUMBER) return buflist_findnr((int)tv->vval.v_number); if (tv->v_type != VAR_STRING) return NULL; if (name == NULL || *name == NUL) return curbuf; if (name[0] == '$' && name[1] == NUL) return lastbuf; buf = buflist_find_by_name(name, curtab_only); // If not found, try expanding the name, like done for bufexists(). if (buf == NULL) buf = find_buffer(tv); return buf; } /* * Like tv_get_buf() but give an error message is the type is wrong. */ buf_T * tv_get_buf_from_arg(typval_T *tv) { buf_T *buf; ++emsg_off; buf = tv_get_buf(tv, FALSE); --emsg_off; if (buf == NULL && tv->v_type != VAR_NUMBER && tv->v_type != VAR_STRING) // issue errmsg for type error (void)tv_get_number(tv); return buf; } #endif // FEAT_EVAL