Mercurial > vim
view src/vim9cmds.c @ 33802:b857615e5d42 v9.0.2117
patch 9.0.2117: [security] use-after-free in qf_free_items
Commit: https://github.com/vim/vim/commit/567cae2630a51efddc07eacff3b38a295e1f5671
Author: Christian Brabandt <cb@256bit.org>
Date: Sun Nov 19 16:19:27 2023 +0100
patch 9.0.2117: [security] use-after-free in qf_free_items
Problem: [security] use-after-free in qf_free_items
Solution: only access qfpnext, if it hasn't been freed
Coverity discovered a possible use-after-free in qf_free_items. When
freeing the qfline items, we may access freed memory, when qfp ==
qfpnext.
So only access qfpnext, when it hasn't been freed.
Signed-off-by: Christian Brabandt <cb@256bit.org>
author | Christian Brabandt <cb@256bit.org> |
---|---|
date | Tue, 21 Nov 2023 20:15:05 +0100 |
parents | c470d4fd5eba |
children | bdd408288d95 |
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. */ /* * vim9cmds.c: Dealing with commands of a compiled function */ #define USING_FLOAT_STUFF #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) // When not generating protos this is included in proto.h #ifdef PROTO # include "vim9.h" #endif /* * Get the index of the current instruction. * This compensates for a preceding ISN_CMDMOD and ISN_PROF_START. */ static int current_instr_idx(cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; int idx = instr->ga_len; while (idx > 0) { if (cctx->ctx_has_cmdmod && ((isn_T *)instr->ga_data)[idx - 1] .isn_type == ISN_CMDMOD) { --idx; continue; } #ifdef FEAT_PROFILE if (((isn_T *)instr->ga_data)[idx - 1].isn_type == ISN_PROF_START) { --idx; continue; } #endif if (((isn_T *)instr->ga_data)[idx - 1].isn_type == ISN_DEBUG) { --idx; continue; } break; } return idx; } /* * Remove local variables above "new_top". * Do this by clearing the name. If "keep" is TRUE do not reset the length, a * closure may still need location of the variable. */ static void unwind_locals(cctx_T *cctx, int new_top, int keep) { if (cctx->ctx_locals.ga_len > new_top) for (int idx = new_top; idx < cctx->ctx_locals.ga_len; ++idx) { lvar_T *lvar = ((lvar_T *)cctx->ctx_locals.ga_data) + idx; VIM_CLEAR(lvar->lv_name); } if (!keep) cctx->ctx_locals.ga_len = new_top; } /* * Free all local variables. */ void free_locals(cctx_T *cctx) { unwind_locals(cctx, 0, FALSE); ga_clear(&cctx->ctx_locals); } /* * Check if "name" can be "unlet". */ int check_vim9_unlet(char_u *name) { if (*name == NUL) { semsg(_(e_argument_required_for_str), "unlet"); return FAIL; } if (name[1] != ':' || vim_strchr((char_u *)"gwtb", *name) == NULL) { // "unlet s:var" is allowed in legacy script. if (*name == 's' && !script_is_vim9()) return OK; semsg(_(e_cannot_unlet_str), name); return FAIL; } return OK; } /* * Callback passed to ex_unletlock(). */ static int compile_unlet( lval_T *lvp, char_u *name_end, exarg_T *eap, int deep UNUSED, void *coookie) { cctx_T *cctx = coookie; char_u *p = lvp->ll_name; int cc = *name_end; int ret = OK; if (cctx->ctx_skip == SKIP_YES) return OK; *name_end = NUL; if (*p == '$') { // :unlet $ENV_VAR ret = generate_UNLET(cctx, ISN_UNLETENV, p + 1, eap->forceit); } else if (vim_strchr(p, '.') != NULL || vim_strchr(p, '[') != NULL) { lhs_T lhs; // This is similar to assigning: lookup the list/dict, compile the // idx/key. Then instead of storing the value unlet the item. // unlet {list}[idx] // unlet {dict}[key] dict.key // // Figure out the LHS type and other properties. // ret = compile_lhs(p, &lhs, CMD_unlet, FALSE, FALSE, 0, cctx); // Use the info in "lhs" to unlet the item at the index in the // list or dict. if (ret == OK) { if (!lhs.lhs_has_index) { semsg(_(e_cannot_unlet_imported_item_str), p); ret = FAIL; } else ret = compile_assign_unlet(p, &lhs, FALSE, &t_void, cctx); } vim_free(lhs.lhs_name); } else if (check_vim9_unlet(p) == FAIL) { ret = FAIL; } else { // Normal name. Only supports g:, w:, t: and b: namespaces. ret = generate_UNLET(cctx, ISN_UNLET, p, eap->forceit); } *name_end = cc; return ret; } /* * Callback passed to ex_unletlock(). */ static int compile_lock_unlock( lval_T *lvp, char_u *name_end, exarg_T *eap, int deep, void *coookie) { cctx_T *cctx = coookie; int cc = *name_end; char_u *p = lvp->ll_name; int ret = OK; char_u *buf; isntype_T isn = ISN_EXEC; char *cmd = eap->cmdidx == CMD_lockvar ? "lockvar" : "unlockvar"; int is_arg = FALSE; #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: compile_lock_unlock(): cookie %p, name %s", coookie, p); #endif if (cctx->ctx_skip == SKIP_YES) return OK; if (*p == NUL) { semsg(_(e_argument_required_for_str), cmd); return FAIL; } // Cannot use :lockvar and :unlockvar on local variables. if (p[1] != ':') { char_u *end = find_name_end(p, NULL, NULL, FNE_CHECK_START); // The most important point is that something like // name[idx].member... needs to be resolved at runtime, get_lval(), // starting from the root "name". // These checks are reminiscent of the variable_exists function. // But most of the matches require special handling. // If bare name is is locally accessible, except for local var, // then put it on the stack to use with ISN_LOCKUNLOCK. // This could be v.memb, v[idx_key]; bare class variable, // function arg. The item on the stack, will be passed // to ex_lockvar() indirectly and be used as the root for get_lval. // A bare script variable name needs no special handling. char_u *name = NULL; int len = end - p; if (lookup_local(p, len, NULL, cctx) == OK) { // Handle "this", "this.val", "anyvar[idx]" if (*end != '.' && *end != '[' && (len != 4 || STRNCMP("this", p, len) != 0)) { emsg(_(e_cannot_lock_unlock_local_variable)); return FAIL; } // Push the local on the stack, could be "this". name = p; #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... lookup_local: name %s", name); #endif } if (name == NULL) { class_T *cl; if (cctx_class_member_idx(cctx, p, len, &cl) >= 0) { if (*end != '.' && *end != '[') { // Push the class of the bare class variable name name = cl->class_name; len = (int)STRLEN(name); #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... cctx_class_member: name %s", name); #endif } } } if (name == NULL) { // Can lockvar any function arg. if (arg_exists(p, len, NULL, NULL, NULL, cctx) == OK) { name = p; is_arg = TRUE; #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... arg_exists: name %s", name); #endif } } if (name == NULL) { // No special handling for a bare script variable; but // if followed by '[' or '.', it's a root for get_lval(). if (script_var_exists(p, len, cctx, NULL) == OK && (*end == '.' || *end == '[')) { name = p; #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... script_var_exists: name %s", name); #endif } } if (name != NULL) { #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... INS_LOCKUNLOCK %s", name); #endif if (compile_load(&name, name + len, cctx, FALSE, FALSE) == FAIL) return FAIL; isn = ISN_LOCKUNLOCK; } } // Checking is done at runtime. *name_end = NUL; size_t len = name_end - p + 20; buf = alloc(len); if (buf == NULL) ret = FAIL; else { if (deep < 0) vim_snprintf((char *)buf, len, "%s! %s", cmd, p); else vim_snprintf((char *)buf, len, "%s %d %s", cmd, deep, p); #ifdef LOG_LOCKVAR ch_log(NULL, "LKVAR: ... buf %s", buf); #endif if (isn == ISN_LOCKUNLOCK) ret = generate_LOCKUNLOCK(cctx, buf, is_arg); else ret = generate_EXEC_copy(cctx, isn, buf); vim_free(buf); *name_end = cc; } return ret; } /* * compile "unlet var", "lock var" and "unlock var" * "arg" points to "var". */ char_u * compile_unletlock(char_u *arg, exarg_T *eap, cctx_T *cctx) { int deep = 0; char_u *p = arg; if (eap->cmdidx != CMD_unlet) { if (eap->forceit) deep = -1; else if (vim_isdigit(*p)) { deep = getdigits(&p); p = skipwhite(p); } else deep = 2; } ex_unletlock(eap, p, deep, GLV_NO_AUTOLOAD | GLV_COMPILING, eap->cmdidx == CMD_unlet ? compile_unlet : compile_lock_unlock, cctx); return eap->nextcmd == NULL ? (char_u *)"" : eap->nextcmd; } /* * Generate a jump to the ":endif"/":endfor"/":endwhile"/":finally"/":endtry". * "funcref_idx" is used for JUMP_WHILE_FALSE */ static int compile_jump_to_end( endlabel_T **el, jumpwhen_T when, int funcref_idx, cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; endlabel_T *endlabel = ALLOC_CLEAR_ONE(endlabel_T); if (endlabel == NULL) return FAIL; endlabel->el_next = *el; *el = endlabel; endlabel->el_end_label = instr->ga_len; if (when == JUMP_WHILE_FALSE) generate_WHILE(cctx, funcref_idx); else generate_JUMP(cctx, when, 0); return OK; } static void compile_fill_jump_to_end(endlabel_T **el, int jump_where, cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; while (*el != NULL) { endlabel_T *cur = (*el); isn_T *isn; isn = ((isn_T *)instr->ga_data) + cur->el_end_label; isn->isn_arg.jump.jump_where = jump_where; *el = cur->el_next; vim_free(cur); } } static void compile_free_jump_to_end(endlabel_T **el) { while (*el != NULL) { endlabel_T *cur = (*el); *el = cur->el_next; vim_free(cur); } } /* * Create a new scope and set up the generic items. */ static scope_T * new_scope(cctx_T *cctx, scopetype_T type) { scope_T *scope = ALLOC_CLEAR_ONE(scope_T); if (scope == NULL) return NULL; scope->se_outer = cctx->ctx_scope; cctx->ctx_scope = scope; scope->se_type = type; scope->se_local_count = cctx->ctx_locals.ga_len; if (scope->se_outer != NULL) scope->se_loop_depth = scope->se_outer->se_loop_depth; return scope; } /* * Free the current scope and go back to the outer scope. */ void drop_scope(cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; if (scope == NULL) { iemsg("calling drop_scope() without a scope"); return; } cctx->ctx_scope = scope->se_outer; switch (scope->se_type) { case IF_SCOPE: compile_free_jump_to_end(&scope->se_u.se_if.is_end_label); break; case FOR_SCOPE: compile_free_jump_to_end(&scope->se_u.se_for.fs_end_label); break; case WHILE_SCOPE: compile_free_jump_to_end(&scope->se_u.se_while.ws_end_label); break; case TRY_SCOPE: compile_free_jump_to_end(&scope->se_u.se_try.ts_end_label); break; case NO_SCOPE: case BLOCK_SCOPE: break; } vim_free(scope); } static int misplaced_cmdmod(cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; if (cctx->ctx_has_cmdmod && ((isn_T *)instr->ga_data)[instr->ga_len - 1].isn_type == ISN_CMDMOD) { emsg(_(e_misplaced_command_modifier)); return TRUE; } return FALSE; } /* * compile "if expr" * * "if expr" Produces instructions: * EVAL expr Push result of "expr" * JUMP_IF_FALSE end * ... body ... * end: * * "if expr | else" Produces instructions: * EVAL expr Push result of "expr" * JUMP_IF_FALSE else * ... body ... * JUMP_ALWAYS end * else: * ... body ... * end: * * "if expr1 | elseif expr2 | else" Produces instructions: * EVAL expr Push result of "expr" * JUMP_IF_FALSE elseif * ... body ... * JUMP_ALWAYS end * elseif: * EVAL expr Push result of "expr" * JUMP_IF_FALSE else * ... body ... * JUMP_ALWAYS end * else: * ... body ... * end: */ char_u * compile_if(char_u *arg, cctx_T *cctx) { char_u *p = arg; garray_T *instr = &cctx->ctx_instr; int instr_count = instr->ga_len; scope_T *scope; skip_T skip_save = cctx->ctx_skip; ppconst_T ppconst; CLEAR_FIELD(ppconst); if (compile_expr1(&p, cctx, &ppconst) == FAIL) { clear_ppconst(&ppconst); return NULL; } if (!ends_excmd2(arg, skipwhite(p))) { semsg(_(e_trailing_characters_str), p); return NULL; } if (cctx->ctx_skip == SKIP_YES) clear_ppconst(&ppconst); else if (instr->ga_len == instr_count && ppconst.pp_used == 1) { int error = FALSE; int v; // The expression results in a constant. v = tv_get_bool_chk(&ppconst.pp_tv[0], &error); clear_ppconst(&ppconst); if (error) return NULL; cctx->ctx_skip = v ? SKIP_NOT : SKIP_YES; } else { // Not a constant, generate instructions for the expression. cctx->ctx_skip = SKIP_UNKNOWN; if (generate_ppconst(cctx, &ppconst) == FAIL) return NULL; if (bool_on_stack(cctx) == FAIL) return NULL; } // CMDMOD_REV must come before the jump generate_undo_cmdmods(cctx); scope = new_scope(cctx, IF_SCOPE); if (scope == NULL) return NULL; scope->se_skip_save = skip_save; // "is_had_return" will be reset if any block does not end in :return scope->se_u.se_if.is_had_return = TRUE; if (cctx->ctx_skip == SKIP_UNKNOWN) { // "where" is set when ":elseif", "else" or ":endif" is found scope->se_u.se_if.is_if_label = instr->ga_len; generate_JUMP(cctx, JUMP_IF_FALSE, 0); } else scope->se_u.se_if.is_if_label = -1; #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE && cctx->ctx_skip == SKIP_YES && skip_save != SKIP_YES) { // generated a profile start, need to generate a profile end, since it // won't be done after returning cctx->ctx_skip = SKIP_NOT; generate_instr(cctx, ISN_PROF_END); cctx->ctx_skip = SKIP_YES; } #endif return p; } char_u * compile_elseif(char_u *arg, cctx_T *cctx) { char_u *p = arg; garray_T *instr = &cctx->ctx_instr; int instr_count; isn_T *isn; scope_T *scope = cctx->ctx_scope; ppconst_T ppconst; skip_T save_skip = cctx->ctx_skip; if (scope == NULL || scope->se_type != IF_SCOPE) { emsg(_(e_elseif_without_if)); return NULL; } unwind_locals(cctx, scope->se_local_count, TRUE); if (!cctx->ctx_had_return) scope->se_u.se_if.is_had_return = FALSE; if (cctx->ctx_skip == SKIP_NOT) { // previous block was executed, this one and following will not cctx->ctx_skip = SKIP_YES; scope->se_u.se_if.is_seen_skip_not = TRUE; } if (scope->se_u.se_if.is_seen_skip_not) { // A previous block was executed, skip over expression and bail out. // Do not count the "elseif" for profiling and cmdmod instr->ga_len = current_instr_idx(cctx); skip_expr_cctx(&p, cctx); return p; } if (cctx->ctx_skip == SKIP_UNKNOWN) { int moved_cmdmod = FALSE; int saved_debug = FALSE; isn_T debug_isn; // Move any CMDMOD instruction to after the jump if (((isn_T *)instr->ga_data)[instr->ga_len - 1].isn_type == ISN_CMDMOD) { if (GA_GROW_FAILS(instr, 1)) return NULL; ((isn_T *)instr->ga_data)[instr->ga_len] = ((isn_T *)instr->ga_data)[instr->ga_len - 1]; --instr->ga_len; moved_cmdmod = TRUE; } // Remove the already generated ISN_DEBUG, it is written below the // ISN_FOR instruction. if (cctx->ctx_compile_type == CT_DEBUG && instr->ga_len > 0 && ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_type == ISN_DEBUG) { --instr->ga_len; debug_isn = ((isn_T *)instr->ga_data)[instr->ga_len]; saved_debug = TRUE; } if (compile_jump_to_end(&scope->se_u.se_if.is_end_label, JUMP_ALWAYS, 0, cctx) == FAIL) return NULL; // previous "if" or "elseif" jumps here isn = ((isn_T *)instr->ga_data) + scope->se_u.se_if.is_if_label; isn->isn_arg.jump.jump_where = instr->ga_len; if (moved_cmdmod) ++instr->ga_len; if (saved_debug) { // move the debug instruction here if (GA_GROW_FAILS(instr, 1)) return NULL; ((isn_T *)instr->ga_data)[instr->ga_len] = debug_isn; ++instr->ga_len; } } // compile "expr"; if we know it evaluates to FALSE skip the block CLEAR_FIELD(ppconst); if (cctx->ctx_skip == SKIP_YES) { cctx->ctx_skip = SKIP_UNKNOWN; #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE) // the previous block was skipped, need to profile this line generate_instr(cctx, ISN_PROF_START); #endif if (cctx->ctx_compile_type == CT_DEBUG) // the previous block was skipped, may want to debug this line generate_instr_debug(cctx); } instr_count = instr->ga_len; if (compile_expr1(&p, cctx, &ppconst) == FAIL) { clear_ppconst(&ppconst); return NULL; } cctx->ctx_skip = save_skip; if (!ends_excmd2(arg, skipwhite(p))) { clear_ppconst(&ppconst); semsg(_(e_trailing_characters_str), p); return NULL; } if (scope->se_skip_save == SKIP_YES) clear_ppconst(&ppconst); else if (instr->ga_len == instr_count && ppconst.pp_used == 1) { int error = FALSE; int v; // The expression result is a constant. v = tv_get_bool_chk(&ppconst.pp_tv[0], &error); if (error) { clear_ppconst(&ppconst); return NULL; } cctx->ctx_skip = v ? SKIP_NOT : SKIP_YES; clear_ppconst(&ppconst); scope->se_u.se_if.is_if_label = -1; } else { // Not a constant, generate instructions for the expression. cctx->ctx_skip = SKIP_UNKNOWN; if (generate_ppconst(cctx, &ppconst) == FAIL) return NULL; if (bool_on_stack(cctx) == FAIL) return NULL; // CMDMOD_REV must come before the jump generate_undo_cmdmods(cctx); // "where" is set when ":elseif", "else" or ":endif" is found scope->se_u.se_if.is_if_label = instr->ga_len; generate_JUMP(cctx, JUMP_IF_FALSE, 0); } return p; } char_u * compile_else(char_u *arg, cctx_T *cctx) { char_u *p = arg; garray_T *instr = &cctx->ctx_instr; isn_T *isn; scope_T *scope = cctx->ctx_scope; if (scope == NULL || scope->se_type != IF_SCOPE) { emsg(_(e_else_without_if)); return NULL; } unwind_locals(cctx, scope->se_local_count, TRUE); if (!cctx->ctx_had_return) scope->se_u.se_if.is_had_return = FALSE; scope->se_u.se_if.is_seen_else = TRUE; #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE) { if (cctx->ctx_skip == SKIP_NOT && ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_type == ISN_PROF_START) // the previous block was executed, do not count "else" for // profiling --instr->ga_len; if (cctx->ctx_skip == SKIP_YES && !scope->se_u.se_if.is_seen_skip_not) { // the previous block was not executed, this one will, do count the // "else" for profiling cctx->ctx_skip = SKIP_NOT; generate_instr(cctx, ISN_PROF_END); generate_instr(cctx, ISN_PROF_START); cctx->ctx_skip = SKIP_YES; } } #endif if (!scope->se_u.se_if.is_seen_skip_not && scope->se_skip_save != SKIP_YES) { // jump from previous block to the end, unless the else block is empty if (cctx->ctx_skip == SKIP_UNKNOWN) { if (!cctx->ctx_had_return && compile_jump_to_end(&scope->se_u.se_if.is_end_label, JUMP_ALWAYS, 0, cctx) == FAIL) return NULL; } if (cctx->ctx_skip == SKIP_UNKNOWN) { if (scope->se_u.se_if.is_if_label >= 0) { // previous "if" or "elseif" jumps here isn = ((isn_T *)instr->ga_data) + scope->se_u.se_if.is_if_label; isn->isn_arg.jump.jump_where = instr->ga_len; scope->se_u.se_if.is_if_label = -1; } } if (cctx->ctx_skip != SKIP_UNKNOWN) cctx->ctx_skip = cctx->ctx_skip == SKIP_YES ? SKIP_NOT : SKIP_YES; } return p; } char_u * compile_endif(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; ifscope_T *ifscope; garray_T *instr = &cctx->ctx_instr; isn_T *isn; if (misplaced_cmdmod(cctx)) return NULL; if (scope == NULL || scope->se_type != IF_SCOPE) { emsg(_(e_endif_without_if)); return NULL; } ifscope = &scope->se_u.se_if; unwind_locals(cctx, scope->se_local_count, TRUE); if (!cctx->ctx_had_return) ifscope->is_had_return = FALSE; if (scope->se_u.se_if.is_if_label >= 0) { // previous "if" or "elseif" jumps here isn = ((isn_T *)instr->ga_data) + scope->se_u.se_if.is_if_label; isn->isn_arg.jump.jump_where = instr->ga_len; } // Fill in the "end" label in jumps at the end of the blocks. compile_fill_jump_to_end(&ifscope->is_end_label, instr->ga_len, cctx); #ifdef FEAT_PROFILE // even when skipping we count the endif as executed, unless the block it's // in is skipped if (cctx->ctx_compile_type == CT_PROFILE && cctx->ctx_skip == SKIP_YES && scope->se_skip_save != SKIP_YES) { cctx->ctx_skip = SKIP_NOT; generate_instr(cctx, ISN_PROF_START); } #endif cctx->ctx_skip = scope->se_skip_save; // If all the blocks end in :return and there is an :else then the // had_return flag is set. cctx->ctx_had_return = ifscope->is_had_return && ifscope->is_seen_else; drop_scope(cctx); return arg; } /* * Save the info needed for ENDLOOP. Used by :for and :while. */ static void compile_fill_loop_info(loop_info_T *loop_info, int funcref_idx, cctx_T *cctx) { loop_info->li_funcref_idx = funcref_idx; loop_info->li_local_count = cctx->ctx_locals.ga_len; loop_info->li_closure_count = cctx->ctx_closure_count; } /* * Compile "for var in expr": * * Produces instructions: * STORE -1 in loop-idx Set index to -1 * EVAL expr Result of "expr" on top of stack * top: FOR loop-idx, end Increment index, use list on bottom of stack * - if beyond end, jump to "end" * - otherwise get item from list and push it * - store ec_funcrefs in var "loop-idx" + 1 * STORE var Store item in "var" * ... body ... * ENDLOOP funcref-idx off count Only if closure uses local var * JUMP top Jump back to repeat * end: DROP Drop the result of "expr" * * Compile "for [var1, var2] in expr" - as above, but instead of "STORE var": * UNPACK 2 Split item in 2 * STORE var1 Store item in "var1" * STORE var2 Store item in "var2" */ char_u * compile_for(char_u *arg_start, cctx_T *cctx) { char_u *arg; char_u *arg_end; char_u *name = NULL; char_u *p; char_u *wp; int var_count = 0; int var_list = FALSE; int semicolon = FALSE; size_t varlen; garray_T *instr = &cctx->ctx_instr; scope_T *scope; forscope_T *forscope; lvar_T *loop_lvar; // loop iteration variable int loop_lvar_idx; lvar_T *funcref_lvar; int funcref_lvar_idx; lvar_T *var_lvar; // variable for "var" type_T *vartype; type_T *item_type = &t_any; int idx; int prev_lnum = cctx->ctx_prev_lnum; p = skip_var_list(arg_start, TRUE, &var_count, &semicolon, FALSE); if (p == NULL) return NULL; if (var_count == 0) var_count = 1; else var_list = TRUE; // can also be a list of one variable // consume "in" wp = p; if (may_get_next_line_error(wp, &p, cctx) == FAIL) return NULL; if (STRNCMP(p, "in", 2) != 0 || !IS_WHITE_OR_NUL(p[2])) { if (*p == ':' && wp != p) semsg(_(e_no_white_space_allowed_before_colon_str), p); else emsg(_(e_missing_in_after_for)); return NULL; } wp = p + 2; if (may_get_next_line_error(wp, &p, cctx) == FAIL) return NULL; // Find the already generated ISN_DEBUG to get the line number for the // instruction written below the ISN_FOR instruction. if (cctx->ctx_compile_type == CT_DEBUG && instr->ga_len > 0 && ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_type == ISN_DEBUG) { prev_lnum = ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_arg.debug.dbg_break_lnum; } scope = new_scope(cctx, FOR_SCOPE); if (scope == NULL) return NULL; if (scope->se_loop_depth == MAX_LOOP_DEPTH) { emsg(_(e_loop_nesting_too_deep)); return NULL; } ++scope->se_loop_depth; forscope = &scope->se_u.se_for; // Reserve a variable to store the loop iteration counter and initialize it // to -1. loop_lvar = reserve_local(cctx, (char_u *)"", 0, ASSIGN_VAR, &t_number); if (loop_lvar == NULL) { drop_scope(cctx); return NULL; // out of memory } // get the index before a following reserve_local() makes the lval invalid loop_lvar_idx = loop_lvar->lv_idx; generate_STORENR(cctx, loop_lvar_idx, -1); // Reserve a variable to store ec_funcrefs.ga_len, used in ISN_ENDLOOP. // The variable index is always the loop var index plus one. // It is not used when no closures are encountered, we don't know yet. funcref_lvar = reserve_local(cctx, (char_u *)"", 0, ASSIGN_VAR, &t_number); if (funcref_lvar == NULL) { drop_scope(cctx); return NULL; // out of memory } // get the index before a following reserve_local() makes the lval invalid funcref_lvar_idx = funcref_lvar->lv_idx; // compile "expr", it remains on the stack until "endfor" arg = p; if (compile_expr0(&arg, cctx) == FAIL) { drop_scope(cctx); return NULL; } arg_end = arg; if (cctx->ctx_skip != SKIP_YES) { // If we know the type of "var" and it is not a supported type we can // give an error now. vartype = get_type_on_stack(cctx, 0); if (vartype->tt_type != VAR_LIST && vartype->tt_type != VAR_STRING && vartype->tt_type != VAR_BLOB && vartype->tt_type != VAR_ANY && vartype->tt_type != VAR_UNKNOWN) { semsg(_(e_for_loop_on_str_not_supported), vartype_name(vartype->tt_type)); drop_scope(cctx); return NULL; } if (vartype->tt_type == VAR_STRING) item_type = &t_string; else if (vartype->tt_type == VAR_BLOB) item_type = &t_number; else if (vartype->tt_type == VAR_LIST && vartype->tt_member->tt_type != VAR_ANY) { if (!var_list) item_type = vartype->tt_member; else if (vartype->tt_member->tt_type == VAR_LIST && vartype->tt_member->tt_member->tt_type != VAR_ANY) item_type = vartype->tt_member->tt_member; } // CMDMOD_REV must come before the FOR instruction. generate_undo_cmdmods(cctx); // "for_end" is set when ":endfor" is found forscope->fs_top_label = current_instr_idx(cctx); if (cctx->ctx_compile_type == CT_DEBUG) { int save_prev_lnum = cctx->ctx_prev_lnum; isn_T *isn; // Add ISN_DEBUG here, before deciding to end the loop. There will // be another ISN_DEBUG before the next instruction. // Use the prev_lnum from the ISN_DEBUG instruction removed above. // Increment the variable count so that the loop variable can be // inspected. cctx->ctx_prev_lnum = prev_lnum; isn = generate_instr_debug(cctx); ++isn->isn_arg.debug.dbg_var_names_len; cctx->ctx_prev_lnum = save_prev_lnum; } generate_FOR(cctx, loop_lvar_idx); arg = arg_start; if (var_list) { generate_UNPACK(cctx, var_count, semicolon); arg = skipwhite(arg + 1); // skip white after '[' // drop the list item --cctx->ctx_type_stack.ga_len; // add type of the items for (idx = 0; idx < var_count; ++idx) { type_T *type = (semicolon && idx == 0) ? vartype : item_type; if (push_type_stack(cctx, type) == FAIL) { drop_scope(cctx); return NULL; } } } for (idx = 0; idx < var_count; ++idx) { assign_dest_T dest = dest_local; int opt_flags = 0; int vimvaridx = -1; type_T *type = &t_any; type_T *lhs_type = &t_any; where_T where = WHERE_INIT; p = skip_var_one(arg, FALSE); varlen = p - arg; name = vim_strnsave(arg, varlen); if (name == NULL) goto failed; if (*skipwhite(p) == ':') { if (VIM_ISWHITE(*p)) { semsg(_(e_no_white_space_allowed_before_colon_str), p); goto failed; } p = skipwhite(p + 1); lhs_type = parse_type(&p, cctx->ctx_type_list, TRUE); } if (get_var_dest(name, &dest, CMD_for, &opt_flags, &vimvaridx, &type, cctx) == FAIL) goto failed; if (dest != dest_local) { if (generate_store_var(cctx, dest, opt_flags, vimvaridx, type, name, NULL) == FAIL) goto failed; } else if (varlen == 1 && *arg == '_') { // Assigning to "_": drop the value. if (generate_instr_drop(cctx, ISN_DROP, 1) == NULL) goto failed; } else { // Script var is not supported. if (STRNCMP(name, "s:", 2) == 0) { emsg(_(e_cannot_use_script_variable_in_for_loop)); goto failed; } if (!valid_varname(arg, (int)varlen, FALSE)) goto failed; if (lookup_local(arg, varlen, NULL, cctx) == OK) { semsg(_(e_variable_already_declared_str), arg); goto failed; } // Reserve a variable to store "var". if (var_list) { where.wt_index = idx + 1; where.wt_kind = WT_VARIABLE; } if (lhs_type == &t_any) lhs_type = item_type; else if (item_type != &t_unknown && need_type_where(item_type, lhs_type, FALSE, -1, where, cctx, FALSE, FALSE) == FAIL) goto failed; var_lvar = reserve_local(cctx, arg, varlen, ASSIGN_FINAL, lhs_type); if (var_lvar == NULL) // out of memory or used as an argument goto failed; if (semicolon && idx == var_count - 1) var_lvar->lv_type = vartype; generate_STORE(cctx, ISN_STORE, var_lvar->lv_idx, NULL); } if (*p == ',' || *p == ';') ++p; arg = skipwhite(p); vim_free(name); } // remember the number of variables and closures, used for ENDLOOP compile_fill_loop_info(&forscope->fs_loop_info, funcref_lvar_idx, cctx); forscope->fs_loop_info.li_depth = scope->se_loop_depth - 1; } return arg_end; failed: vim_free(name); drop_scope(cctx); return NULL; } /* * Used when ending a loop of :for and :while: Generate an ISN_ENDLOOP * instruction if any variable was declared that could be used by a new * closure. */ static int compile_loop_end(loop_info_T *loop_info, cctx_T *cctx) { if (cctx->ctx_locals.ga_len > loop_info->li_local_count && cctx->ctx_closure_count > loop_info->li_closure_count) return generate_ENDLOOP(cctx, loop_info); return OK; } /* * compile "endfor" */ char_u * compile_endfor(char_u *arg, cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; scope_T *scope = cctx->ctx_scope; forscope_T *forscope; isn_T *isn; if (misplaced_cmdmod(cctx)) return NULL; if (scope == NULL || scope->se_type != FOR_SCOPE) { emsg(_(e_endfor_without_for)); return NULL; } forscope = &scope->se_u.se_for; cctx->ctx_scope = scope->se_outer; if (cctx->ctx_skip != SKIP_YES) { // Handle the case that any local variables were declared that might be // used in a closure. if (compile_loop_end(&forscope->fs_loop_info, cctx) == FAIL) return NULL; unwind_locals(cctx, scope->se_local_count, FALSE); // At end of ":for" scope jump back to the FOR instruction. generate_JUMP(cctx, JUMP_ALWAYS, forscope->fs_top_label); // Fill in the "end" label in the FOR statement so it can jump here. // In debug mode an ISN_DEBUG was inserted. isn = ((isn_T *)instr->ga_data) + forscope->fs_top_label + (cctx->ctx_compile_type == CT_DEBUG ? 1 : 0); isn->isn_arg.forloop.for_end = instr->ga_len; // Fill in the "end" label any BREAK statements compile_fill_jump_to_end(&forscope->fs_end_label, instr->ga_len, cctx); // Below the ":for" scope drop the "expr" list from the stack. if (generate_instr_drop(cctx, ISN_DROP, 1) == NULL) return NULL; } vim_free(scope); return arg; } /* * compile "while expr" * * Produces instructions: * top: EVAL expr Push result of "expr" * WHILE funcref-idx end Jump if false * ... body ... * ENDLOOP funcref-idx off count only if closure uses local var * JUMP top Jump back to repeat * end: * */ char_u * compile_while(char_u *arg, cctx_T *cctx) { char_u *p = arg; scope_T *scope; whilescope_T *whilescope; lvar_T *funcref_lvar; int funcref_lvar_idx; scope = new_scope(cctx, WHILE_SCOPE); if (scope == NULL) return NULL; if (scope->se_loop_depth == MAX_LOOP_DEPTH) { emsg(_(e_loop_nesting_too_deep)); return NULL; } ++scope->se_loop_depth; whilescope = &scope->se_u.se_while; // "endwhile" jumps back here, one before when profiling or using cmdmods whilescope->ws_top_label = current_instr_idx(cctx); // Reserve a variable to store ec_funcrefs.ga_len, used in ISN_ENDLOOP. // It is not used when no closures are encountered, we don't know yet. funcref_lvar = reserve_local(cctx, (char_u *)"", 0, ASSIGN_VAR, &t_number); if (funcref_lvar == NULL) { drop_scope(cctx); return NULL; // out of memory } // get the index before a following reserve_local() makes the lval invalid funcref_lvar_idx = funcref_lvar->lv_idx; // remember the number of variables and closures, used for ENDLOOP compile_fill_loop_info(&whilescope->ws_loop_info, funcref_lvar_idx, cctx); whilescope->ws_loop_info.li_depth = scope->se_loop_depth - 1; // compile "expr" if (compile_expr0(&p, cctx) == FAIL) return NULL; if (!ends_excmd2(arg, skipwhite(p))) { semsg(_(e_trailing_characters_str), p); return NULL; } if (cctx->ctx_skip != SKIP_YES) { if (bool_on_stack(cctx) == FAIL) return FAIL; // CMDMOD_REV must come before the jump generate_undo_cmdmods(cctx); // "while_end" is set when ":endwhile" is found if (compile_jump_to_end(&whilescope->ws_end_label, JUMP_WHILE_FALSE, funcref_lvar_idx, cctx) == FAIL) return FAIL; } return p; } /* * compile "endwhile" */ char_u * compile_endwhile(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; garray_T *instr = &cctx->ctx_instr; if (misplaced_cmdmod(cctx)) return NULL; if (scope == NULL || scope->se_type != WHILE_SCOPE) { emsg(_(e_endwhile_without_while)); return NULL; } cctx->ctx_scope = scope->se_outer; if (cctx->ctx_skip != SKIP_YES) { whilescope_T *whilescope = &scope->se_u.se_while; // Handle the case that any local variables were declared that might be // used in a closure. if (compile_loop_end(&whilescope->ws_loop_info, cctx) == FAIL) return NULL; unwind_locals(cctx, scope->se_local_count, FALSE); #ifdef FEAT_PROFILE // count the endwhile before jumping may_generate_prof_end(cctx, cctx->ctx_lnum); #endif // At end of ":for" scope jump back to the FOR instruction. generate_JUMP(cctx, JUMP_ALWAYS, scope->se_u.se_while.ws_top_label); // Fill in the "end" label in the WHILE statement so it can jump here. // And in any jumps for ":break" compile_fill_jump_to_end(&scope->se_u.se_while.ws_end_label, instr->ga_len, cctx); } vim_free(scope); return arg; } /* * Get the current information about variables declared inside a loop. * Returns TRUE if there are any and fills "lvi". */ int get_loop_var_info(cctx_T *cctx, loopvarinfo_T *lvi) { scope_T *scope = cctx->ctx_scope; int prev_local_count = 0; CLEAR_POINTER(lvi); for (;;) { loop_info_T *loopinfo; int cur_local_last; int start_local_count; while (scope != NULL && scope->se_type != WHILE_SCOPE && scope->se_type != FOR_SCOPE) scope = scope->se_outer; if (scope == NULL) break; if (scope->se_type == WHILE_SCOPE) { loopinfo = &scope->se_u.se_while.ws_loop_info; // :while reserves one variable for funcref count cur_local_last = loopinfo->li_local_count - 1; } else { loopinfo = &scope->se_u.se_for.fs_loop_info; // :for reserves three variable: loop count, funcref count and loop // var cur_local_last = loopinfo->li_local_count - 3; } start_local_count = loopinfo->li_local_count; if (cctx->ctx_locals.ga_len > start_local_count) { lvi->lvi_loop[loopinfo->li_depth].var_idx = (short)start_local_count; lvi->lvi_loop[loopinfo->li_depth].var_count = (short)(cctx->ctx_locals.ga_len - start_local_count - prev_local_count); if (lvi->lvi_depth == 0) lvi->lvi_depth = loopinfo->li_depth + 1; } scope = scope->se_outer; prev_local_count = cctx->ctx_locals.ga_len - cur_local_last; } return lvi->lvi_depth > 0; } /* * Get the index of the variable "idx" in a loop, if any. */ void get_loop_var_idx(cctx_T *cctx, int idx, lvar_T *lvar) { loopvarinfo_T lvi; lvar->lv_loop_depth = -1; lvar->lv_loop_idx = -1; if (get_loop_var_info(cctx, &lvi)) { int depth; for (depth = lvi.lvi_depth - 1; depth >= 0; --depth) if (idx >= lvi.lvi_loop[depth].var_idx && idx < lvi.lvi_loop[depth].var_idx + lvi.lvi_loop[depth].var_count) { lvar->lv_loop_depth = depth; lvar->lv_loop_idx = lvi.lvi_loop[depth].var_idx; return; } } } /* * Common for :break, :continue and :return */ static int compile_find_scope( int *loop_label, // where to jump to or NULL endlabel_T ***el, // end label or NULL int *try_scopes, // :try scopes encountered or NULL char *error, // error to use when no scope found cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; for (;;) { if (scope == NULL) { if (error != NULL) emsg(_(error)); return FAIL; } if (scope->se_type == FOR_SCOPE) { if (compile_loop_end(&scope->se_u.se_for.fs_loop_info, cctx) == FAIL) return FAIL; if (loop_label != NULL) *loop_label = scope->se_u.se_for.fs_top_label; if (el != NULL) *el = &scope->se_u.se_for.fs_end_label; break; } if (scope->se_type == WHILE_SCOPE) { if (compile_loop_end(&scope->se_u.se_while.ws_loop_info, cctx) == FAIL) return FAIL; if (loop_label != NULL) *loop_label = scope->se_u.se_while.ws_top_label; if (el != NULL) *el = &scope->se_u.se_while.ws_end_label; break; } if (try_scopes != NULL && scope->se_type == TRY_SCOPE) ++*try_scopes; scope = scope->se_outer; } return OK; } /* * compile "continue" */ char_u * compile_continue(char_u *arg, cctx_T *cctx) { int try_scopes = 0; int loop_label; if (compile_find_scope(&loop_label, NULL, &try_scopes, e_continue_without_while_or_for, cctx) == FAIL) return NULL; if (try_scopes > 0) // Inside one or more try/catch blocks we first need to jump to the // "finally" or "endtry" to cleanup. generate_TRYCONT(cctx, try_scopes, loop_label); else // Jump back to the FOR or WHILE instruction. generate_JUMP(cctx, JUMP_ALWAYS, loop_label); return arg; } /* * compile "break" */ char_u * compile_break(char_u *arg, cctx_T *cctx) { int try_scopes = 0; endlabel_T **el; if (compile_find_scope(NULL, &el, &try_scopes, e_break_without_while_or_for, cctx) == FAIL) return NULL; if (cctx->ctx_skip == SKIP_YES) return arg; if (try_scopes > 0) // Inside one or more try/catch blocks we first need to jump to the // "finally" or "endtry" to cleanup. Then come to the next JUMP // instruction, which we don't know the index of yet. generate_TRYCONT(cctx, try_scopes, cctx->ctx_instr.ga_len + 1); // Jump to the end of the FOR or WHILE loop. The instruction index will be // filled in later. if (compile_jump_to_end(el, JUMP_ALWAYS, 0, cctx) == FAIL) return NULL; return arg; } /* * compile "{" start of block */ char_u * compile_block(char_u *arg, cctx_T *cctx) { if (new_scope(cctx, BLOCK_SCOPE) == NULL) return NULL; return skipwhite(arg + 1); } /* * compile end of block: drop one scope */ void compile_endblock(cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; cctx->ctx_scope = scope->se_outer; unwind_locals(cctx, scope->se_local_count, TRUE); vim_free(scope); } /* * Compile "try". * Creates a new scope for the try-endtry, pointing to the first catch and * finally. * Creates another scope for the "try" block itself. * TRY instruction sets up exception handling at runtime. * * "try" * TRY -> catch1, -> finally push trystack entry * ... try block * "throw {exception}" * EVAL {exception} * THROW create exception * ... try block * " catch {expr}" * JUMP -> finally * catch1: PUSH exception * EVAL {expr} * MATCH * JUMP nomatch -> catch2 * CATCH remove exception * ... catch block * " catch" * JUMP -> finally * catch2: CATCH remove exception * ... catch block * " finally" * finally: * ... finally block * " endtry" * ENDTRY pop trystack entry, may rethrow */ char_u * compile_try(char_u *arg, cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; scope_T *try_scope; scope_T *scope; if (misplaced_cmdmod(cctx)) return NULL; // scope that holds the jumps that go to catch/finally/endtry try_scope = new_scope(cctx, TRY_SCOPE); if (try_scope == NULL) return NULL; if (cctx->ctx_skip != SKIP_YES) { isn_T *isn; // "try_catch" is set when the first ":catch" is found or when no catch // is found and ":finally" is found. // "try_finally" is set when ":finally" is found // "try_endtry" is set when ":endtry" is found try_scope->se_u.se_try.ts_try_label = instr->ga_len; if ((isn = generate_instr(cctx, ISN_TRY)) == NULL) return NULL; isn->isn_arg.tryref.try_ref = ALLOC_CLEAR_ONE(tryref_T); if (isn->isn_arg.tryref.try_ref == NULL) return NULL; } // scope for the try block itself scope = new_scope(cctx, BLOCK_SCOPE); if (scope == NULL) return NULL; return arg; } /* * Compile "catch {expr}". */ char_u * compile_catch(char_u *arg, cctx_T *cctx UNUSED) { scope_T *scope = cctx->ctx_scope; garray_T *instr = &cctx->ctx_instr; char_u *p; isn_T *isn; if (misplaced_cmdmod(cctx)) return NULL; // end block scope from :try or :catch if (scope != NULL && scope->se_type == BLOCK_SCOPE) compile_endblock(cctx); scope = cctx->ctx_scope; // Error if not in a :try scope if (scope == NULL || scope->se_type != TRY_SCOPE) { emsg(_(e_catch_without_try)); return NULL; } if (scope->se_u.se_try.ts_caught_all && !ignore_unreachable_code_for_testing) { emsg(_(e_catch_unreachable_after_catch_all)); return NULL; } if (!cctx->ctx_had_return) scope->se_u.se_try.ts_no_return = TRUE; if (cctx->ctx_skip != SKIP_YES) { #ifdef FEAT_PROFILE // the profile-start should be after the jump if (cctx->ctx_compile_type == CT_PROFILE && instr->ga_len > 0 && ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_type == ISN_PROF_START) --instr->ga_len; #endif // Jump from end of previous block to :finally or :endtry if (compile_jump_to_end(&scope->se_u.se_try.ts_end_label, JUMP_ALWAYS, 0, cctx) == FAIL) return NULL; // End :try or :catch scope: set value in ISN_TRY instruction isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_try_label; if (isn->isn_arg.tryref.try_ref->try_catch == 0) isn->isn_arg.tryref.try_ref->try_catch = instr->ga_len; if (scope->se_u.se_try.ts_catch_label != 0) { // Previous catch without match jumps here isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_catch_label; isn->isn_arg.jump.jump_where = instr->ga_len; } #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE) { // a "throw" that jumps here needs to be counted generate_instr(cctx, ISN_PROF_END); // the "catch" is also counted generate_instr(cctx, ISN_PROF_START); } #endif if (cctx->ctx_compile_type == CT_DEBUG) generate_instr_debug(cctx); } p = skipwhite(arg); if (ends_excmd2(arg, p)) { scope->se_u.se_try.ts_caught_all = TRUE; scope->se_u.se_try.ts_catch_label = 0; } else { char_u *end; char_u *pat; char_u *tofree = NULL; int dropped = 0; int len; // Push v:exception, push {expr} and MATCH generate_instr_type(cctx, ISN_PUSHEXC, &t_string); end = skip_regexp_ex(p + 1, *p, TRUE, &tofree, &dropped, NULL); if (*end != *p) { semsg(_(e_separator_mismatch_str), p); vim_free(tofree); return NULL; } if (tofree == NULL) len = (int)(end - (p + 1)); else len = (int)(end - tofree); pat = vim_strnsave(tofree == NULL ? p + 1 : tofree, len); vim_free(tofree); p += len + 2 + dropped; if (pat == NULL) return NULL; if (generate_PUSHS(cctx, &pat) == FAIL) return NULL; if (generate_COMPARE(cctx, EXPR_MATCH, FALSE) == FAIL) return NULL; scope->se_u.se_try.ts_catch_label = instr->ga_len; if (generate_JUMP(cctx, JUMP_IF_FALSE, 0) == FAIL) return NULL; } if (cctx->ctx_skip != SKIP_YES && generate_instr(cctx, ISN_CATCH) == NULL) return NULL; if (new_scope(cctx, BLOCK_SCOPE) == NULL) return NULL; return p; } char_u * compile_finally(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; garray_T *instr = &cctx->ctx_instr; isn_T *isn; int this_instr; if (misplaced_cmdmod(cctx)) return NULL; // end block scope from :try or :catch if (scope != NULL && scope->se_type == BLOCK_SCOPE) compile_endblock(cctx); scope = cctx->ctx_scope; // Error if not in a :try scope if (scope == NULL || scope->se_type != TRY_SCOPE) { emsg(_(e_finally_without_try)); return NULL; } if (cctx->ctx_skip != SKIP_YES) { // End :catch or :finally scope: set value in ISN_TRY instruction isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_try_label; if (isn->isn_arg.tryref.try_ref->try_finally != 0) { emsg(_(e_multiple_finally)); return NULL; } this_instr = instr->ga_len; #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE && ((isn_T *)instr->ga_data)[this_instr - 1] .isn_type == ISN_PROF_START) { // jump to the profile start of the "finally" --this_instr; // jump to the profile end above it if (this_instr > 0 && ((isn_T *)instr->ga_data)[this_instr - 1] .isn_type == ISN_PROF_END) --this_instr; } #endif // Fill in the "end" label in jumps at the end of the blocks. compile_fill_jump_to_end(&scope->se_u.se_try.ts_end_label, this_instr, cctx); // If there is no :catch then an exception jumps to :finally. if (isn->isn_arg.tryref.try_ref->try_catch == 0) isn->isn_arg.tryref.try_ref->try_catch = this_instr; isn->isn_arg.tryref.try_ref->try_finally = this_instr; if (scope->se_u.se_try.ts_catch_label != 0) { // Previous catch without match jumps here isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_catch_label; isn->isn_arg.jump.jump_where = this_instr; scope->se_u.se_try.ts_catch_label = 0; } scope->se_u.se_try.ts_has_finally = TRUE; if (generate_instr(cctx, ISN_FINALLY) == NULL) return NULL; } return arg; } char_u * compile_endtry(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; garray_T *instr = &cctx->ctx_instr; isn_T *try_isn; if (misplaced_cmdmod(cctx)) return NULL; // end block scope from :catch or :finally if (scope != NULL && scope->se_type == BLOCK_SCOPE) compile_endblock(cctx); scope = cctx->ctx_scope; // Error if not in a :try scope if (scope == NULL || scope->se_type != TRY_SCOPE) { if (scope == NULL) emsg(_(e_endtry_without_try)); else if (scope->se_type == WHILE_SCOPE) emsg(_(e_missing_endwhile)); else if (scope->se_type == FOR_SCOPE) emsg(_(e_missing_endfor)); else emsg(_(e_missing_endif)); return NULL; } try_isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_try_label; if (cctx->ctx_skip != SKIP_YES) { if (try_isn->isn_arg.tryref.try_ref->try_catch == 0 && try_isn->isn_arg.tryref.try_ref->try_finally == 0) { emsg(_(e_missing_catch_or_finally)); return NULL; } #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE && ((isn_T *)instr->ga_data)[instr->ga_len - 1] .isn_type == ISN_PROF_START) // move the profile start after "endtry" so that it's not counted when // the exception is rethrown. --instr->ga_len; #endif // Fill in the "end" label in jumps at the end of the blocks, if not // done by ":finally". compile_fill_jump_to_end(&scope->se_u.se_try.ts_end_label, instr->ga_len, cctx); if (scope->se_u.se_try.ts_catch_label != 0) { // Last catch without match jumps here isn_T *isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_catch_label; isn->isn_arg.jump.jump_where = instr->ga_len; } } // If there is a finally clause that ends in return then we will return. // If one of the blocks didn't end in "return" or we did not catch all // exceptions reset the had_return flag. if (!(scope->se_u.se_try.ts_has_finally && cctx->ctx_had_return) && (scope->se_u.se_try.ts_no_return || !scope->se_u.se_try.ts_caught_all)) cctx->ctx_had_return = FALSE; compile_endblock(cctx); if (cctx->ctx_skip != SKIP_YES) { // End :catch or :finally scope: set instruction index in ISN_TRY // instruction try_isn->isn_arg.tryref.try_ref->try_endtry = instr->ga_len; if (generate_instr(cctx, ISN_ENDTRY) == NULL) return NULL; #ifdef FEAT_PROFILE if (cctx->ctx_compile_type == CT_PROFILE) generate_instr(cctx, ISN_PROF_START); #endif } return arg; } /* * compile "throw {expr}" */ char_u * compile_throw(char_u *arg, cctx_T *cctx UNUSED) { char_u *p = skipwhite(arg); if (compile_expr0(&p, cctx) == FAIL) return NULL; if (cctx->ctx_skip == SKIP_YES) return p; if (may_generate_2STRING(-1, FALSE, cctx) == FAIL) return NULL; if (generate_instr_drop(cctx, ISN_THROW, 1) == NULL) return NULL; return p; } /* * Compile an expression or function call. */ char_u * compile_eval(char_u *arg, cctx_T *cctx) { char_u *p = arg; int name_only; long lnum = SOURCING_LNUM; // find_ex_command() will consider a variable name an expression, assuming // that something follows on the next line. Check that something actually // follows, otherwise it's probably a misplaced command. name_only = cmd_is_name_only(arg); if (compile_expr0(&p, cctx) == FAIL) return NULL; if (name_only && lnum == SOURCING_LNUM) { semsg(_(e_expression_without_effect_str), arg); return NULL; } // drop the result generate_instr_drop(cctx, ISN_DROP, 1); return skipwhite(p); } /* * Get the local variable index for deferred function calls. * Reserve it when not done already. * Returns zero for failure. */ int get_defer_var_idx(cctx_T *cctx) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + cctx->ctx_ufunc->uf_dfunc_idx; if (dfunc->df_defer_var_idx == 0) { lvar_T *lvar = reserve_local(cctx, (char_u *)"@defer@", 7, TRUE, &t_list_any); if (lvar == NULL) return 0; dfunc->df_defer_var_idx = lvar->lv_idx + 1; } return dfunc->df_defer_var_idx; } /* * Compile "defer func(arg)". */ char_u * compile_defer(char_u *arg_start, cctx_T *cctx) { char_u *paren; char_u *arg = arg_start; int argcount = 0; int defer_var_idx; type_T *type; int func_idx; // Get a funcref for the function name. // TODO: better way to find the "(". paren = vim_strchr(arg, '('); if (paren == NULL) { semsg(_(e_missing_parenthesis_str), arg); return NULL; } *paren = NUL; func_idx = find_internal_func(arg); if (func_idx >= 0) // TODO: better type generate_PUSHFUNC(cctx, (char_u *)internal_func_name(func_idx), &t_func_any, FALSE); else if (compile_expr0(&arg, cctx) == FAIL) return NULL; *paren = '('; // check for function type type = get_type_on_stack(cctx, 0); if (type->tt_type != VAR_FUNC) { emsg(_(e_function_name_required)); return NULL; } // compile the arguments arg = skipwhite(paren + 1); if (compile_arguments(&arg, cctx, &argcount, CA_NOT_SPECIAL) == FAIL) return NULL; if (func_idx >= 0) { type2_T *argtypes = NULL; type2_T shuffled_argtypes[MAX_FUNC_ARGS]; if (check_internal_func_args(cctx, func_idx, argcount, FALSE, &argtypes, shuffled_argtypes) == FAIL) return NULL; } else if (check_func_args_from_type(cctx, type, argcount, TRUE, arg_start) == FAIL) return NULL; defer_var_idx = get_defer_var_idx(cctx); if (defer_var_idx == 0) return NULL; if (generate_DEFER(cctx, defer_var_idx - 1, argcount) == FAIL) return NULL; return skipwhite(arg); } /* * compile "echo expr" * compile "echomsg expr" * compile "echoerr expr" * compile "echoconsole expr" * compile "echowindow expr" - may have cmd_count set * compile "execute expr" */ char_u * compile_mult_expr( char_u *arg, int cmdidx, long cmd_count UNUSED, cctx_T *cctx) { char_u *p = arg; char_u *prev = arg; char_u *expr_start; int count = 0; int start_ctx_lnum = cctx->ctx_lnum; type_T *type; int r = OK; for (;;) { if (ends_excmd2(prev, p)) break; expr_start = p; if (compile_expr0(&p, cctx) == FAIL) return NULL; if (cctx->ctx_skip != SKIP_YES) { // check for non-void type type = get_type_on_stack(cctx, 0); if (type->tt_type == VAR_VOID) { semsg(_(e_expression_does_not_result_in_value_str), expr_start); return NULL; } } ++count; prev = p; p = skipwhite(p); } if (count > 0) { long save_lnum = cctx->ctx_lnum; // Use the line number where the command started. cctx->ctx_lnum = start_ctx_lnum; if (cmdidx == CMD_echo || cmdidx == CMD_echon) r = generate_ECHO(cctx, cmdidx == CMD_echo, count); else if (cmdidx == CMD_execute) r = generate_MULT_EXPR(cctx, ISN_EXECUTE, count); else if (cmdidx == CMD_echomsg) r = generate_MULT_EXPR(cctx, ISN_ECHOMSG, count); #ifdef HAS_MESSAGE_WINDOW else if (cmdidx == CMD_echowindow) r = generate_ECHOWINDOW(cctx, count, cmd_count); #endif else if (cmdidx == CMD_echoconsole) r = generate_MULT_EXPR(cctx, ISN_ECHOCONSOLE, count); else r = generate_MULT_EXPR(cctx, ISN_ECHOERR, count); cctx->ctx_lnum = save_lnum; } return r == OK ? p : NULL; } /* * If "eap" has a range that is not a constant generate an ISN_RANGE * instruction to compute it and return OK. * Otherwise return FAIL, the caller must deal with any range. */ static int compile_variable_range(exarg_T *eap, cctx_T *cctx) { char_u *range_end = skip_range(eap->cmd, TRUE, NULL); char_u *p = skipdigits(eap->cmd); if (p == range_end) return FAIL; return generate_RANGE(cctx, vim_strnsave(eap->cmd, range_end - eap->cmd)); } /* * :put r * :put ={expr} */ char_u * compile_put(char_u *arg, exarg_T *eap, cctx_T *cctx) { char_u *line = arg; linenr_T lnum; char *errormsg; int above = eap->forceit; eap->regname = *line; if (eap->regname == '=') { char_u *p = skipwhite(line + 1); if (compile_expr0(&p, cctx) == FAIL) return NULL; line = p; } else if (eap->regname != NUL) ++line; if (compile_variable_range(eap, cctx) == OK) { lnum = above ? LNUM_VARIABLE_RANGE_ABOVE : LNUM_VARIABLE_RANGE; } else { // Either no range or a number. // "errormsg" will not be set because the range is ADDR_LINES. if (parse_cmd_address(eap, &errormsg, FALSE) == FAIL) // cannot happen return NULL; if (eap->addr_count == 0) lnum = -1; else lnum = eap->line2; if (above) --lnum; } generate_PUT(cctx, eap->regname, lnum); return line; } /* * A command that is not compiled, execute with legacy code. */ char_u * compile_exec(char_u *line_arg, exarg_T *eap, cctx_T *cctx) { char_u *line = line_arg; char_u *p; int has_expr = FALSE; char_u *nextcmd = (char_u *)""; char_u *tofree = NULL; char_u *cmd_arg = NULL; if (cctx->ctx_skip == SKIP_YES) goto theend; // If there was a prececing command modifier, drop it and include it in the // EXEC command. if (cctx->ctx_has_cmdmod) { garray_T *instr = &cctx->ctx_instr; isn_T *isn = ((isn_T *)instr->ga_data) + instr->ga_len - 1; if (isn->isn_type == ISN_CMDMOD) { vim_regfree(isn->isn_arg.cmdmod.cf_cmdmod ->cmod_filter_regmatch.regprog); vim_free(isn->isn_arg.cmdmod.cf_cmdmod); --instr->ga_len; cctx->ctx_has_cmdmod = FALSE; } } if (eap->cmdidx >= 0 && eap->cmdidx < CMD_SIZE) { long argt = eap->argt; int usefilter = FALSE; has_expr = argt & (EX_XFILE | EX_EXPAND); // If the command can be followed by a bar, find the bar and truncate // it, so that the following command can be compiled. // The '|' is overwritten with a NUL, it is put back below. if ((eap->cmdidx == CMD_write || eap->cmdidx == CMD_read) && *eap->arg == '!') // :w !filter or :r !filter or :r! filter usefilter = TRUE; if ((argt & EX_TRLBAR) && !usefilter) { eap->argt = argt; separate_nextcmd(eap, TRUE); if (eap->nextcmd != NULL) nextcmd = eap->nextcmd; } else if (eap->cmdidx == CMD_wincmd) { p = eap->arg; if (*p != NUL) ++p; if (*p == 'g' || *p == Ctrl_G) ++p; p = skipwhite(p); if (*p == '|') { *p = NUL; nextcmd = p + 1; } } else if (eap->cmdidx == CMD_command || eap->cmdidx == CMD_autocmd) { // If there is a trailing '{' read lines until the '}' p = eap->arg + STRLEN(eap->arg) - 1; while (p > eap->arg && VIM_ISWHITE(*p)) --p; if (*p == '{') { exarg_T ea; int flags = 0; // unused int start_lnum = SOURCING_LNUM; CLEAR_FIELD(ea); ea.arg = eap->arg; fill_exarg_from_cctx(&ea, cctx); (void)may_get_cmd_block(&ea, p, &tofree, &flags); if (tofree != NULL) { *p = NUL; line = concat_str(line, tofree); if (line == NULL) goto theend; vim_free(tofree); tofree = line; SOURCING_LNUM = start_lnum; } } } } if (eap->cmdidx == CMD_syntax && STRNCMP(eap->arg, "include ", 8) == 0) { // expand filename in "syntax include [@group] filename" has_expr = TRUE; eap->arg = skipwhite(eap->arg + 7); if (*eap->arg == '@') eap->arg = skiptowhite(eap->arg); } if ((eap->cmdidx == CMD_global || eap->cmdidx == CMD_vglobal) && STRLEN(eap->arg) > 4) { int delim = *eap->arg; p = skip_regexp_ex(eap->arg + 1, delim, TRUE, NULL, NULL, NULL); if (*p == delim) cmd_arg = p + 1; } if (eap->cmdidx == CMD_folddoopen || eap->cmdidx == CMD_folddoclosed) cmd_arg = eap->arg; if (cmd_arg != NULL) { exarg_T nea; CLEAR_FIELD(nea); nea.cmd = cmd_arg; p = find_ex_command(&nea, NULL, lookup_scriptitem, NULL); if (nea.cmdidx < CMD_SIZE) { has_expr = excmd_get_argt(nea.cmdidx) & (EX_XFILE | EX_EXPAND); if (has_expr) eap->arg = skiptowhite(eap->arg); } } if (has_expr && (p = (char_u *)strstr((char *)eap->arg, "`=")) != NULL) { int count = 0; char_u *start = skipwhite(line); // :cmd xxx`=expr1`yyy`=expr2`zzz // PUSHS ":cmd xxx" // eval expr1 // PUSHS "yyy" // eval expr2 // PUSHS "zzz" // EXECCONCAT 5 for (;;) { if (p > start) { char_u *val = vim_strnsave(start, p - start); generate_PUSHS(cctx, &val); ++count; } p += 2; if (compile_expr0(&p, cctx) == FAIL) return NULL; may_generate_2STRING(-1, TRUE, cctx); ++count; p = skipwhite(p); if (*p != '`') { emsg(_(e_missing_backtick)); return NULL; } start = p + 1; p = (char_u *)strstr((char *)start, "`="); if (p == NULL) { if (*skipwhite(start) != NUL) { char_u *val = vim_strsave(start); generate_PUSHS(cctx, &val); ++count; } break; } } generate_EXECCONCAT(cctx, count); } else generate_EXEC_copy(cctx, ISN_EXEC, line); theend: if (*nextcmd != NUL) { // the parser expects a pointer to the bar, put it back --nextcmd; *nextcmd = '|'; } vim_free(tofree); return nextcmd; } /* * A script command with heredoc, e.g. * ruby << EOF * command * EOF * Has been turned into one long line with NL characters by * get_function_body(): * ruby << EOF<NL> command<NL>EOF */ char_u * compile_script(char_u *line, cctx_T *cctx) { if (cctx->ctx_skip != SKIP_YES) { isn_T *isn; if ((isn = generate_instr(cctx, ISN_EXEC_SPLIT)) == NULL) return NULL; isn->isn_arg.string = vim_strsave(line); } return (char_u *)""; } /* * :s/pat/repl/ */ char_u * compile_substitute(char_u *arg, exarg_T *eap, cctx_T *cctx) { char_u *cmd = eap->arg; char_u *expr = (char_u *)strstr((char *)cmd, "\\="); if (expr != NULL) { int delimiter = *cmd++; // There is a \=expr, find it in the substitute part. cmd = skip_regexp_ex(cmd, delimiter, magic_isset(), NULL, NULL, NULL); if (cmd[0] == delimiter && cmd[1] == '\\' && cmd[2] == '=') { garray_T save_ga = cctx->ctx_instr; char_u *end; int expr_res; int trailing_error; int instr_count; isn_T *instr; isn_T *isn; cmd += 3; end = skip_substitute(cmd, delimiter); // Temporarily reset the list of instructions so that the jump // labels are correct. cctx->ctx_instr.ga_len = 0; cctx->ctx_instr.ga_maxlen = 0; cctx->ctx_instr.ga_data = NULL; expr_res = compile_expr0(&cmd, cctx); if (end[-1] == NUL) end[-1] = delimiter; cmd = skipwhite(cmd); trailing_error = *cmd != delimiter && *cmd != NUL; if (expr_res == FAIL || trailing_error || GA_GROW_FAILS(&cctx->ctx_instr, 1)) { if (trailing_error) semsg(_(e_trailing_characters_str), cmd); clear_instr_ga(&cctx->ctx_instr); cctx->ctx_instr = save_ga; return NULL; } // Move the generated instructions into the ISN_SUBSTITUTE // instructions, then restore the list of instructions before // adding the ISN_SUBSTITUTE instruction. instr_count = cctx->ctx_instr.ga_len; instr = cctx->ctx_instr.ga_data; instr[instr_count].isn_type = ISN_FINISH; cctx->ctx_instr = save_ga; if ((isn = generate_instr(cctx, ISN_SUBSTITUTE)) == NULL) { int idx; for (idx = 0; idx < instr_count; ++idx) delete_instr(instr + idx); vim_free(instr); return NULL; } isn->isn_arg.subs.subs_cmd = vim_strsave(arg); isn->isn_arg.subs.subs_instr = instr; // skip over flags if (*end == '&') ++end; while (ASCII_ISALPHA(*end) || *end == '#') ++end; return end; } } return compile_exec(arg, eap, cctx); } char_u * compile_redir(char_u *line, exarg_T *eap, cctx_T *cctx) { char_u *arg = eap->arg; lhs_T *lhs = &cctx->ctx_redir_lhs; if (lhs->lhs_name != NULL) { if (STRNCMP(arg, "END", 3) == 0) { if (cctx->ctx_skip != SKIP_YES) { if (lhs->lhs_append) { // First load the current variable value. if (compile_load_lhs_with_index(lhs, lhs->lhs_whole, cctx) == FAIL) return NULL; } // Gets the redirected text and put it on the stack, then store // it in the variable. generate_instr_type(cctx, ISN_REDIREND, &t_string); if (lhs->lhs_append) generate_CONCAT(cctx, 2); if (lhs->lhs_has_index) { // Use the info in "lhs" to store the value at the index in // the list or dict. if (compile_assign_unlet(lhs->lhs_whole, lhs, TRUE, &t_string, cctx) == FAIL) return NULL; } else if (generate_store_lhs(cctx, lhs, -1, FALSE) == FAIL) return NULL; VIM_CLEAR(lhs->lhs_name); VIM_CLEAR(lhs->lhs_whole); } return arg + 3; } emsg(_(e_cannot_nest_redir)); return NULL; } if (arg[0] == '=' && arg[1] == '>') { int append = FALSE; // redirect to a variable is compiled arg += 2; if (*arg == '>') { ++arg; append = TRUE; } arg = skipwhite(arg); if (compile_assign_lhs(arg, lhs, CMD_redir, FALSE, FALSE, FALSE, 1, cctx) == FAIL) return NULL; if (need_type(&t_string, lhs->lhs_member_type, FALSE, -1, 0, cctx, FALSE, FALSE) == FAIL) return NULL; if (cctx->ctx_skip == SKIP_YES) { VIM_CLEAR(lhs->lhs_name); } else { generate_instr(cctx, ISN_REDIRSTART); lhs->lhs_append = append; if (lhs->lhs_has_index) { lhs->lhs_whole = vim_strnsave(arg, lhs->lhs_varlen_total); if (lhs->lhs_whole == NULL) return NULL; } } return arg + lhs->lhs_varlen_total; } // other redirects are handled like at script level return compile_exec(line, eap, cctx); } #if defined(FEAT_QUICKFIX) || defined(PROTO) char_u * compile_cexpr(char_u *line, exarg_T *eap, cctx_T *cctx) { isn_T *isn; char_u *p; isn = generate_instr(cctx, ISN_CEXPR_AUCMD); if (isn == NULL) return NULL; isn->isn_arg.number = eap->cmdidx; p = eap->arg; if (compile_expr0(&p, cctx) == FAIL) return NULL; isn = generate_instr(cctx, ISN_CEXPR_CORE); if (isn == NULL) return NULL; isn->isn_arg.cexpr.cexpr_ref = ALLOC_ONE(cexprref_T); if (isn->isn_arg.cexpr.cexpr_ref == NULL) return NULL; isn->isn_arg.cexpr.cexpr_ref->cer_cmdidx = eap->cmdidx; isn->isn_arg.cexpr.cexpr_ref->cer_forceit = eap->forceit; isn->isn_arg.cexpr.cexpr_ref->cer_cmdline = vim_strsave(skipwhite(line)); return p; } #endif /* * Compile "return [expr]". * When "legacy" is TRUE evaluate [expr] with legacy syntax */ char_u * compile_return(char_u *arg, int check_return_type, int legacy, cctx_T *cctx) { char_u *p = arg; type_T *stack_type; if (*p != NUL && *p != '|' && *p != '\n' && (legacy || !vim9_comment_start(p))) { // For a lambda, "return expr" is always used, also when "expr" results // in a void. if (cctx->ctx_ufunc->uf_ret_type->tt_type == VAR_VOID && (cctx->ctx_ufunc->uf_flags & FC_LAMBDA) == 0) { emsg(_(e_returning_value_in_function_without_return_type)); return NULL; } if (legacy) { int save_flags = cmdmod.cmod_flags; generate_LEGACY_EVAL(cctx, p); if (need_type(&t_any, cctx->ctx_ufunc->uf_ret_type, FALSE, -1, 0, cctx, FALSE, FALSE) == FAIL) return NULL; cmdmod.cmod_flags |= CMOD_LEGACY; (void)skip_expr(&p, NULL); cmdmod.cmod_flags = save_flags; } else { // compile return argument into instructions if (compile_expr0(&p, cctx) == FAIL) return NULL; } if (cctx->ctx_skip != SKIP_YES) { // "check_return_type" with uf_ret_type set to &t_unknown is used // for an inline function without a specified return type. Set the // return type here. stack_type = get_type_on_stack(cctx, 0); if ((check_return_type && (cctx->ctx_ufunc->uf_ret_type == NULL || cctx->ctx_ufunc->uf_ret_type == &t_unknown)) || (!check_return_type && cctx->ctx_ufunc->uf_ret_type == &t_unknown)) { cctx->ctx_ufunc->uf_ret_type = stack_type; } else { if (need_type(stack_type, cctx->ctx_ufunc->uf_ret_type, FALSE, -1, 0, cctx, FALSE, FALSE) == FAIL) return NULL; } } } else { // "check_return_type" cannot be TRUE, only used for a lambda which // always has an argument. if (cctx->ctx_ufunc->uf_ret_type->tt_type != VAR_VOID && cctx->ctx_ufunc->uf_ret_type->tt_type != VAR_UNKNOWN) { emsg(_(e_missing_return_value)); return NULL; } if (IS_CONSTRUCTOR_METHOD(cctx->ctx_ufunc)) { // For a class new() constructor, return an object of the class. generate_instr(cctx, ISN_RETURN_OBJECT); cctx->ctx_ufunc->uf_ret_type = &cctx->ctx_ufunc->uf_class->class_object_type; } else // No argument, return zero. generate_PUSHNR(cctx, 0); } // may need ENDLOOP when inside a :for or :while loop if (compile_find_scope(NULL, NULL, NULL, NULL, cctx) == FAIL) // Undo any command modifiers. generate_undo_cmdmods(cctx); if (cctx->ctx_skip != SKIP_YES && generate_instr(cctx, ISN_RETURN) == NULL) return NULL; // "return val | endif" is possible return skipwhite(p); } /* * Check if the separator for a :global or :substitute command is OK. */ int check_global_and_subst(char_u *cmd, char_u *arg) { if (arg == cmd + 1 && vim_strchr((char_u *)":-.", *arg) != NULL) { semsg(_(e_separator_not_supported_str), arg); return FAIL; } if (VIM_ISWHITE(cmd[1])) { semsg(_(e_no_white_space_allowed_before_separator_str), cmd); return FAIL; } return OK; } #endif // defined(FEAT_EVAL)