Mercurial > vim
view src/vim9execute.c @ 23156:6aa8ddf7a3fa v8.2.2124
patch 8.2.2124: Vim9: a range cannot be computed at runtime
Commit: https://github.com/vim/vim/commit/08597875b2a1e7d118b0346c652a96e7527e7d8b
Author: Bram Moolenaar <Bram@vim.org>
Date: Thu Dec 10 19:43:40 2020 +0100
patch 8.2.2124: Vim9: a range cannot be computed at runtime
Problem: Vim9: a range cannot be computed at runtime.
Solution: Add the ISN_RANGE instruction.
author | Bram Moolenaar <Bram@vim.org> |
---|---|
date | Thu, 10 Dec 2020 19:45:04 +0100 |
parents | 3239b0f3c592 |
children | cc24ac009f29 |
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. */ /* * vim9execute.c: execute Vim9 script instructions */ #define USING_FLOAT_STUFF #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) #ifdef VMS # include <float.h> #endif #include "vim9.h" // Structure put on ec_trystack when ISN_TRY is encountered. typedef struct { int tcd_frame_idx; // ec_frame_idx when ISN_TRY was encountered int tcd_catch_idx; // instruction of the first catch int tcd_finally_idx; // instruction of the finally block int tcd_caught; // catch block entered int tcd_return; // when TRUE return from end of :finally } trycmd_T; // A stack is used to store: // - arguments passed to a :def function // - info about the calling function, to use when returning // - local variables // - temporary values // // In detail (FP == Frame Pointer): // arg1 first argument from caller (if present) // arg2 second argument from caller (if present) // extra_arg1 any missing optional argument default value // FP -> cur_func calling function // current previous instruction pointer // frame_ptr previous Frame Pointer // var1 space for local variable // var2 space for local variable // .... fixed space for max. number of local variables // temp temporary values // .... flexible space for temporary values (can grow big) /* * Execution context. */ typedef struct { garray_T ec_stack; // stack of typval_T values int ec_frame_idx; // index in ec_stack: context of ec_dfunc_idx garray_T *ec_outer_stack; // stack used for closures int ec_outer_frame; // stack frame in ec_outer_stack garray_T ec_trystack; // stack of trycmd_T values int ec_in_catch; // when TRUE in catch or finally block int ec_dfunc_idx; // current function index isn_T *ec_instr; // array with instructions int ec_iidx; // index in ec_instr: instruction to execute garray_T ec_funcrefs; // partials that might be a closure } ectx_T; // Get pointer to item relative to the bottom of the stack, -1 is the last one. #define STACK_TV_BOT(idx) (((typval_T *)ectx->ec_stack.ga_data) + ectx->ec_stack.ga_len + (idx)) void to_string_error(vartype_T vartype) { semsg(_(e_cannot_convert_str_to_string), vartype_name(vartype)); } /* * Return the number of arguments, including optional arguments and any vararg. */ static int ufunc_argcount(ufunc_T *ufunc) { return ufunc->uf_args.ga_len + (ufunc->uf_va_name != NULL ? 1 : 0); } /* * Set the instruction index, depending on omitted arguments, where the default * values are to be computed. If all optional arguments are present, start * with the function body. * The expression evaluation is at the start of the instructions: * 0 -> EVAL default1 * STORE arg[-2] * 1 -> EVAL default2 * STORE arg[-1] * 2 -> function body */ static void init_instr_idx(ufunc_T *ufunc, int argcount, ectx_T *ectx) { if (ufunc->uf_def_args.ga_len == 0) ectx->ec_iidx = 0; else { int defcount = ufunc->uf_args.ga_len - argcount; // If there is a varargs argument defcount can be negative, no defaults // to evaluate then. if (defcount < 0) defcount = 0; ectx->ec_iidx = ufunc->uf_def_arg_idx[ ufunc->uf_def_args.ga_len - defcount]; } } /* * Create a new list from "count" items at the bottom of the stack. * When "count" is zero an empty list is added to the stack. */ static int exe_newlist(int count, ectx_T *ectx) { list_T *list = list_alloc_with_items(count); int idx; typval_T *tv; if (list == NULL) return FAIL; for (idx = 0; idx < count; ++idx) list_set_item(list, idx, STACK_TV_BOT(idx - count)); if (count > 0) ectx->ec_stack.ga_len -= count - 1; else if (GA_GROW(&ectx->ec_stack, 1) == FAIL) return FAIL; else ++ectx->ec_stack.ga_len; tv = STACK_TV_BOT(-1); tv->v_type = VAR_LIST; tv->vval.v_list = list; ++list->lv_refcount; return OK; } /* * Call compiled function "cdf_idx" from compiled code. * * Stack has: * - current arguments (already there) * - omitted optional argument (default values) added here * - stack frame: * - pointer to calling function * - Index of next instruction in calling function * - previous frame pointer * - reserved space for local variables */ static int call_dfunc(int cdf_idx, int argcount_arg, ectx_T *ectx) { int argcount = argcount_arg; dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + cdf_idx; ufunc_T *ufunc = dfunc->df_ufunc; int arg_to_add; int vararg_count = 0; int varcount; int idx; estack_T *entry; if (dfunc->df_deleted) { emsg_funcname(e_func_deleted, ufunc->uf_name); return FAIL; } if (ufunc->uf_va_name != NULL) { // Need to make a list out of the vararg arguments. // Stack at time of call with 2 varargs: // normal_arg // optional_arg // vararg_1 // vararg_2 // After creating the list: // normal_arg // optional_arg // vararg-list // With missing optional arguments we get: // normal_arg // After creating the list // normal_arg // (space for optional_arg) // vararg-list vararg_count = argcount - ufunc->uf_args.ga_len; if (vararg_count < 0) vararg_count = 0; else argcount -= vararg_count; if (exe_newlist(vararg_count, ectx) == FAIL) return FAIL; vararg_count = 1; } arg_to_add = ufunc->uf_args.ga_len - argcount; if (arg_to_add < 0) { if (arg_to_add == -1) emsg(_(e_one_argument_too_many)); else semsg(_(e_nr_arguments_too_many), -arg_to_add); return FAIL; } // Reserve space for: // - missing arguments // - stack frame // - local variables // - if needed: a counter for number of closures created in // ectx->ec_funcrefs. varcount = dfunc->df_varcount + dfunc->df_has_closure; if (ga_grow(&ectx->ec_stack, arg_to_add + STACK_FRAME_SIZE + varcount) == FAIL) return FAIL; // If depth of calling is getting too high, don't execute the function. if (funcdepth_increment() == FAIL) return FAIL; // Move the vararg-list to below the missing optional arguments. if (vararg_count > 0 && arg_to_add > 0) *STACK_TV_BOT(arg_to_add - 1) = *STACK_TV_BOT(-1); // Reserve space for omitted optional arguments, filled in soon. for (idx = 0; idx < arg_to_add; ++idx) STACK_TV_BOT(idx - vararg_count)->v_type = VAR_UNKNOWN; ectx->ec_stack.ga_len += arg_to_add; // Store current execution state in stack frame for ISN_RETURN. STACK_TV_BOT(0)->vval.v_number = ectx->ec_dfunc_idx; STACK_TV_BOT(1)->vval.v_number = ectx->ec_iidx; STACK_TV_BOT(2)->vval.v_string = (void *)ectx->ec_outer_stack; STACK_TV_BOT(3)->vval.v_number = ectx->ec_outer_frame; STACK_TV_BOT(4)->vval.v_number = ectx->ec_frame_idx; ectx->ec_frame_idx = ectx->ec_stack.ga_len; // Initialize local variables for (idx = 0; idx < dfunc->df_varcount; ++idx) STACK_TV_BOT(STACK_FRAME_SIZE + idx)->v_type = VAR_UNKNOWN; if (dfunc->df_has_closure) { typval_T *tv = STACK_TV_BOT(STACK_FRAME_SIZE + dfunc->df_varcount); tv->v_type = VAR_NUMBER; tv->vval.v_number = 0; } ectx->ec_stack.ga_len += STACK_FRAME_SIZE + varcount; // Set execution state to the start of the called function. ectx->ec_dfunc_idx = cdf_idx; ectx->ec_instr = dfunc->df_instr; entry = estack_push_ufunc(dfunc->df_ufunc, 1); if (entry != NULL) { // Set the script context to the script where the function was defined. // TODO: save more than the SID? entry->es_save_sid = current_sctx.sc_sid; current_sctx.sc_sid = ufunc->uf_script_ctx.sc_sid; } // Decide where to start execution, handles optional arguments. init_instr_idx(ufunc, argcount, ectx); return OK; } // Get pointer to item in the stack. #define STACK_TV(idx) (((typval_T *)ectx->ec_stack.ga_data) + idx) /* * Used when returning from a function: Check if any closure is still * referenced. If so then move the arguments and variables to a separate piece * of stack to be used when the closure is called. * When "free_arguments" is TRUE the arguments are to be freed. * Returns FAIL when out of memory. */ static int handle_closure_in_use(ectx_T *ectx, int free_arguments) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ectx->ec_dfunc_idx; int argcount; int top; int idx; typval_T *tv; int closure_in_use = FALSE; garray_T *gap = &ectx->ec_funcrefs; varnumber_T closure_count; if (dfunc->df_ufunc == NULL) return OK; // function was freed if (dfunc->df_has_closure == 0) return OK; // no closures tv = STACK_TV(ectx->ec_frame_idx + STACK_FRAME_SIZE + dfunc->df_varcount); closure_count = tv->vval.v_number; if (closure_count == 0) return OK; // no funcrefs created argcount = ufunc_argcount(dfunc->df_ufunc); top = ectx->ec_frame_idx - argcount; // Check if any created closure is still in use. for (idx = 0; idx < closure_count; ++idx) { partial_T *pt; int off = gap->ga_len - closure_count + idx; if (off < 0) continue; // count is off or already done pt = ((partial_T **)gap->ga_data)[off]; if (pt->pt_refcount > 1) { int refcount = pt->pt_refcount; int i; // A Reference in a local variables doesn't count, it gets // unreferenced on return. for (i = 0; i < dfunc->df_varcount; ++i) { typval_T *stv = STACK_TV(ectx->ec_frame_idx + STACK_FRAME_SIZE + i); if (stv->v_type == VAR_PARTIAL && pt == stv->vval.v_partial) --refcount; } if (refcount > 1) { closure_in_use = TRUE; break; } } } if (closure_in_use) { funcstack_T *funcstack = ALLOC_CLEAR_ONE(funcstack_T); typval_T *stack; // A closure is using the arguments and/or local variables. // Move them to the called function. if (funcstack == NULL) return FAIL; funcstack->fs_var_offset = argcount + STACK_FRAME_SIZE; funcstack->fs_ga.ga_len = funcstack->fs_var_offset + dfunc->df_varcount; stack = ALLOC_CLEAR_MULT(typval_T, funcstack->fs_ga.ga_len); funcstack->fs_ga.ga_data = stack; if (stack == NULL) { vim_free(funcstack); return FAIL; } // Move or copy the arguments. for (idx = 0; idx < argcount; ++idx) { tv = STACK_TV(top + idx); if (free_arguments) { *(stack + idx) = *tv; tv->v_type = VAR_UNKNOWN; } else copy_tv(tv, stack + idx); } // Move the local variables. for (idx = 0; idx < dfunc->df_varcount; ++idx) { tv = STACK_TV(ectx->ec_frame_idx + STACK_FRAME_SIZE + idx); // A partial created for a local function, that is also used as a // local variable, has a reference count for the variable, thus // will never go down to zero. When all these refcounts are one // then the funcstack is unused. We need to count how many we have // so we need when to check. if (tv->v_type == VAR_PARTIAL && tv->vval.v_partial != NULL) { int i; for (i = 0; i < closure_count; ++i) if (tv->vval.v_partial == ((partial_T **)gap->ga_data)[ gap->ga_len - closure_count + i]) ++funcstack->fs_min_refcount; } *(stack + funcstack->fs_var_offset + idx) = *tv; tv->v_type = VAR_UNKNOWN; } for (idx = 0; idx < closure_count; ++idx) { partial_T *pt = ((partial_T **)gap->ga_data)[gap->ga_len - closure_count + idx]; if (pt->pt_refcount > 1) { ++funcstack->fs_refcount; pt->pt_funcstack = funcstack; pt->pt_ectx_stack = &funcstack->fs_ga; pt->pt_ectx_frame = ectx->ec_frame_idx - top; } } } for (idx = 0; idx < closure_count; ++idx) partial_unref(((partial_T **)gap->ga_data)[gap->ga_len - closure_count + idx]); gap->ga_len -= closure_count; if (gap->ga_len == 0) ga_clear(gap); return OK; } /* * Called when a partial is freed or its reference count goes down to one. The * funcstack may be the only reference to the partials in the local variables. * Go over all of them, the funcref and can be freed if all partials * referencing the funcstack have a reference count of one. */ void funcstack_check_refcount(funcstack_T *funcstack) { int i; garray_T *gap = &funcstack->fs_ga; int done = 0; if (funcstack->fs_refcount > funcstack->fs_min_refcount) return; for (i = funcstack->fs_var_offset; i < gap->ga_len; ++i) { typval_T *tv = ((typval_T *)gap->ga_data) + i; if (tv->v_type == VAR_PARTIAL && tv->vval.v_partial != NULL && tv->vval.v_partial->pt_funcstack == funcstack && tv->vval.v_partial->pt_refcount == 1) ++done; } if (done == funcstack->fs_min_refcount) { typval_T *stack = gap->ga_data; // All partials referencing the funcstack have a reference count of // one, thus the funcstack is no longer of use. for (i = 0; i < gap->ga_len; ++i) clear_tv(stack + i); vim_free(stack); vim_free(funcstack); } } /* * Return from the current function. */ static int func_return(ectx_T *ectx) { int idx; int ret_idx; dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ectx->ec_dfunc_idx; int argcount = ufunc_argcount(dfunc->df_ufunc); int top = ectx->ec_frame_idx - argcount; estack_T *entry; // execution context goes one level up entry = estack_pop(); if (entry != NULL) current_sctx.sc_sid = entry->es_save_sid; if (handle_closure_in_use(ectx, TRUE) == FAIL) return FAIL; // Clear the arguments. for (idx = top; idx < ectx->ec_frame_idx; ++idx) clear_tv(STACK_TV(idx)); // Clear local variables and temp values, but not the return value. for (idx = ectx->ec_frame_idx + STACK_FRAME_SIZE; idx < ectx->ec_stack.ga_len - 1; ++idx) clear_tv(STACK_TV(idx)); // The return value should be on top of the stack. However, when aborting // it may not be there and ec_frame_idx is the top of the stack. ret_idx = ectx->ec_stack.ga_len - 1; if (ret_idx == ectx->ec_frame_idx + 4) ret_idx = 0; // Restore the previous frame. ectx->ec_dfunc_idx = STACK_TV(ectx->ec_frame_idx)->vval.v_number; ectx->ec_iidx = STACK_TV(ectx->ec_frame_idx + 1)->vval.v_number; ectx->ec_outer_stack = (void *)STACK_TV(ectx->ec_frame_idx + 2)->vval.v_string; ectx->ec_outer_frame = STACK_TV(ectx->ec_frame_idx + 3)->vval.v_number; // restoring ec_frame_idx must be last ectx->ec_frame_idx = STACK_TV(ectx->ec_frame_idx + 4)->vval.v_number; dfunc = ((dfunc_T *)def_functions.ga_data) + ectx->ec_dfunc_idx; ectx->ec_instr = dfunc->df_instr; if (ret_idx > 0) { // Reset the stack to the position before the call, with a spot for the // return value, moved there from above the frame. ectx->ec_stack.ga_len = top + 1; *STACK_TV_BOT(-1) = *STACK_TV(ret_idx); } else // Reset the stack to the position before the call. ectx->ec_stack.ga_len = top; funcdepth_decrement(); return OK; } #undef STACK_TV /* * Prepare arguments and rettv for calling a builtin or user function. */ static int call_prepare(int argcount, typval_T *argvars, ectx_T *ectx) { int idx; typval_T *tv; // Move arguments from bottom of the stack to argvars[] and add terminator. for (idx = 0; idx < argcount; ++idx) argvars[idx] = *STACK_TV_BOT(idx - argcount); argvars[argcount].v_type = VAR_UNKNOWN; // Result replaces the arguments on the stack. if (argcount > 0) ectx->ec_stack.ga_len -= argcount - 1; else if (GA_GROW(&ectx->ec_stack, 1) == FAIL) return FAIL; else ++ectx->ec_stack.ga_len; // Default return value is zero. tv = STACK_TV_BOT(-1); tv->v_type = VAR_NUMBER; tv->vval.v_number = 0; return OK; } // Ugly global to avoid passing the execution context around through many // layers. static ectx_T *current_ectx = NULL; /* * Call a builtin function by index. */ static int call_bfunc(int func_idx, int argcount, ectx_T *ectx) { typval_T argvars[MAX_FUNC_ARGS]; int idx; int did_emsg_before = did_emsg; ectx_T *prev_ectx = current_ectx; if (call_prepare(argcount, argvars, ectx) == FAIL) return FAIL; // Call the builtin function. Set "current_ectx" so that when it // recursively invokes call_def_function() a closure context can be set. current_ectx = ectx; call_internal_func_by_idx(func_idx, argvars, STACK_TV_BOT(-1)); current_ectx = prev_ectx; // Clear the arguments. for (idx = 0; idx < argcount; ++idx) clear_tv(&argvars[idx]); if (did_emsg != did_emsg_before) return FAIL; return OK; } /* * Execute a user defined function. * "iptr" can be used to replace the instruction with a more efficient one. */ static int call_ufunc(ufunc_T *ufunc, int argcount, ectx_T *ectx, isn_T *iptr) { typval_T argvars[MAX_FUNC_ARGS]; funcexe_T funcexe; int error; int idx; int did_emsg_before = did_emsg; if (ufunc->uf_def_status == UF_TO_BE_COMPILED && compile_def_function(ufunc, FALSE, NULL) == FAIL) return FAIL; if (ufunc->uf_def_status == UF_COMPILED) { // The function has been compiled, can call it quickly. For a function // that was defined later: we can call it directly next time. if (iptr != NULL) { delete_instr(iptr); iptr->isn_type = ISN_DCALL; iptr->isn_arg.dfunc.cdf_idx = ufunc->uf_dfunc_idx; iptr->isn_arg.dfunc.cdf_argcount = argcount; } return call_dfunc(ufunc->uf_dfunc_idx, argcount, ectx); } if (call_prepare(argcount, argvars, ectx) == FAIL) return FAIL; CLEAR_FIELD(funcexe); funcexe.evaluate = TRUE; // Call the user function. Result goes in last position on the stack. // TODO: add selfdict if there is one error = call_user_func_check(ufunc, argcount, argvars, STACK_TV_BOT(-1), &funcexe, NULL); // Clear the arguments. for (idx = 0; idx < argcount; ++idx) clear_tv(&argvars[idx]); if (error != FCERR_NONE) { user_func_error(error, ufunc->uf_name); return FAIL; } if (did_emsg > did_emsg_before) // Error other than from calling the function itself. return FAIL; return OK; } /* * Return TRUE if an error was given or CTRL-C was pressed. */ static int vim9_aborting(int prev_called_emsg) { return called_emsg > prev_called_emsg || got_int || did_throw; } /* * Execute a function by "name". * This can be a builtin function or a user function. * "iptr" can be used to replace the instruction with a more efficient one. * Returns FAIL if not found without an error message. */ static int call_by_name(char_u *name, int argcount, ectx_T *ectx, isn_T *iptr) { ufunc_T *ufunc; if (builtin_function(name, -1)) { int func_idx = find_internal_func(name); if (func_idx < 0) return FAIL; if (check_internal_func(func_idx, argcount) < 0) return FAIL; return call_bfunc(func_idx, argcount, ectx); } ufunc = find_func(name, FALSE, NULL); if (ufunc == NULL) { int called_emsg_before = called_emsg; if (script_autoload(name, TRUE)) // loaded a package, search for the function again ufunc = find_func(name, FALSE, NULL); if (vim9_aborting(called_emsg_before)) return FAIL; // bail out if loading the script caused an error } if (ufunc != NULL) return call_ufunc(ufunc, argcount, ectx, iptr); return FAIL; } static int call_partial(typval_T *tv, int argcount_arg, ectx_T *ectx) { int argcount = argcount_arg; char_u *name = NULL; int called_emsg_before = called_emsg; int res; if (tv->v_type == VAR_PARTIAL) { partial_T *pt = tv->vval.v_partial; int i; if (pt->pt_argc > 0) { // Make space for arguments from the partial, shift the "argcount" // arguments up. if (ga_grow(&ectx->ec_stack, pt->pt_argc) == FAIL) return FAIL; for (i = 1; i <= argcount; ++i) *STACK_TV_BOT(-i + pt->pt_argc) = *STACK_TV_BOT(-i); ectx->ec_stack.ga_len += pt->pt_argc; argcount += pt->pt_argc; // copy the arguments from the partial onto the stack for (i = 0; i < pt->pt_argc; ++i) copy_tv(&pt->pt_argv[i], STACK_TV_BOT(-argcount + i)); } if (pt->pt_func != NULL) { int ret = call_ufunc(pt->pt_func, argcount, ectx, NULL); // closure may need the function context where it was defined ectx->ec_outer_stack = pt->pt_ectx_stack; ectx->ec_outer_frame = pt->pt_ectx_frame; return ret; } name = pt->pt_name; } else if (tv->v_type == VAR_FUNC) name = tv->vval.v_string; if (name != NULL) { char_u fname_buf[FLEN_FIXED + 1]; char_u *tofree = NULL; int error = FCERR_NONE; char_u *fname; // May need to translate <SNR>123_ to K_SNR. fname = fname_trans_sid(name, fname_buf, &tofree, &error); if (error != FCERR_NONE) res = FAIL; else res = call_by_name(fname, argcount, ectx, NULL); vim_free(tofree); } if (name == NULL || res == FAIL) { if (called_emsg == called_emsg_before) semsg(_(e_unknownfunc), name == NULL ? (char_u *)"[unknown]" : name); return FAIL; } return OK; } /* * Check if "lock" is VAR_LOCKED or VAR_FIXED. If so give an error and return * TRUE. */ static int error_if_locked(int lock, char *error) { if (lock & (VAR_LOCKED | VAR_FIXED)) { emsg(_(error)); return TRUE; } return FALSE; } /* * Store "tv" in variable "name". * This is for s: and g: variables. */ static void store_var(char_u *name, typval_T *tv) { funccal_entry_T entry; save_funccal(&entry); set_var_const(name, NULL, tv, FALSE, ASSIGN_NO_DECL); restore_funccal(); } /* * Execute a function by "name". * This can be a builtin function, user function or a funcref. * "iptr" can be used to replace the instruction with a more efficient one. */ static int call_eval_func(char_u *name, int argcount, ectx_T *ectx, isn_T *iptr) { int called_emsg_before = called_emsg; int res; res = call_by_name(name, argcount, ectx, iptr); if (res == FAIL && called_emsg == called_emsg_before) { dictitem_T *v; v = find_var(name, NULL, FALSE); if (v == NULL) { semsg(_(e_unknownfunc), name); return FAIL; } if (v->di_tv.v_type != VAR_PARTIAL && v->di_tv.v_type != VAR_FUNC) { semsg(_(e_unknownfunc), name); return FAIL; } return call_partial(&v->di_tv, argcount, ectx); } return res; } /* * Call a "def" function from old Vim script. * Return OK or FAIL. */ int call_def_function( ufunc_T *ufunc, int argc_arg, // nr of arguments typval_T *argv, // arguments partial_T *partial, // optional partial for context typval_T *rettv) // return value { ectx_T ectx; // execution context int argc = argc_arg; int initial_frame_idx; typval_T *tv; int idx; int ret = FAIL; int defcount = ufunc->uf_args.ga_len - argc; sctx_T save_current_sctx = current_sctx; int breakcheck_count = 0; int did_emsg_before = did_emsg_cumul + did_emsg; int save_suppress_errthrow = suppress_errthrow; msglist_T **saved_msg_list = NULL; msglist_T *private_msg_list = NULL; cmdmod_T save_cmdmod; int restore_cmdmod = FALSE; int save_emsg_silent_def = emsg_silent_def; int save_did_emsg_def = did_emsg_def; int trylevel_at_start = trylevel; int orig_funcdepth; // Get pointer to item in the stack. #define STACK_TV(idx) (((typval_T *)ectx.ec_stack.ga_data) + idx) // Get pointer to item at the bottom of the stack, -1 is the bottom. #undef STACK_TV_BOT #define STACK_TV_BOT(idx) (((typval_T *)ectx.ec_stack.ga_data) + ectx.ec_stack.ga_len + idx) // Get pointer to a local variable on the stack. Negative for arguments. #define STACK_TV_VAR(idx) (((typval_T *)ectx.ec_stack.ga_data) + ectx.ec_frame_idx + STACK_FRAME_SIZE + idx) // Like STACK_TV_VAR but use the outer scope #define STACK_OUT_TV_VAR(idx) (((typval_T *)ectx.ec_outer_stack->ga_data) + ectx.ec_outer_frame + STACK_FRAME_SIZE + idx) if (ufunc->uf_def_status == UF_NOT_COMPILED || (ufunc->uf_def_status == UF_TO_BE_COMPILED && compile_def_function(ufunc, FALSE, NULL) == FAIL)) { if (did_emsg_cumul + did_emsg == did_emsg_before) semsg(_(e_function_is_not_compiled_str), printable_func_name(ufunc)); return FAIL; } { // Check the function was really compiled. dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; if (dfunc->df_instr == NULL) { iemsg("using call_def_function() on not compiled function"); return FAIL; } } // If depth of calling is getting too high, don't execute the function. orig_funcdepth = funcdepth_get(); if (funcdepth_increment() == FAIL) return FAIL; CLEAR_FIELD(ectx); ectx.ec_dfunc_idx = ufunc->uf_dfunc_idx; ga_init2(&ectx.ec_stack, sizeof(typval_T), 500); if (ga_grow(&ectx.ec_stack, 20) == FAIL) { funcdepth_decrement(); return FAIL; } ga_init2(&ectx.ec_trystack, sizeof(trycmd_T), 10); ga_init2(&ectx.ec_funcrefs, sizeof(partial_T *), 10); // Put arguments on the stack. for (idx = 0; idx < argc; ++idx) { if (ufunc->uf_arg_types != NULL && idx < ufunc->uf_args.ga_len && check_typval_type(ufunc->uf_arg_types[idx], &argv[idx], idx + 1) == FAIL) goto failed_early; copy_tv(&argv[idx], STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; } // Turn varargs into a list. Empty list if no args. if (ufunc->uf_va_name != NULL) { int vararg_count = argc - ufunc->uf_args.ga_len; if (vararg_count < 0) vararg_count = 0; else argc -= vararg_count; if (exe_newlist(vararg_count, &ectx) == FAIL) goto failed_early; // Check the type of the list items. tv = STACK_TV_BOT(-1); if (ufunc->uf_va_type != NULL && ufunc->uf_va_type != &t_any && ufunc->uf_va_type->tt_member != &t_any && tv->vval.v_list != NULL) { type_T *expected = ufunc->uf_va_type->tt_member; listitem_T *li = tv->vval.v_list->lv_first; for (idx = 0; idx < vararg_count; ++idx) { if (check_typval_type(expected, &li->li_tv, argc + idx + 1) == FAIL) goto failed_early; li = li->li_next; } } if (defcount > 0) // Move varargs list to below missing default arguments. *STACK_TV_BOT(defcount - 1) = *STACK_TV_BOT(-1); --ectx.ec_stack.ga_len; } // Make space for omitted arguments, will store default value below. // Any varargs list goes after them. if (defcount > 0) for (idx = 0; idx < defcount; ++idx) { STACK_TV_BOT(0)->v_type = VAR_UNKNOWN; ++ectx.ec_stack.ga_len; } if (ufunc->uf_va_name != NULL) ++ectx.ec_stack.ga_len; // Frame pointer points to just after arguments. ectx.ec_frame_idx = ectx.ec_stack.ga_len; initial_frame_idx = ectx.ec_frame_idx; if (partial != NULL) { if (partial->pt_ectx_stack == NULL && current_ectx != NULL) { // TODO: is this always the right way? ectx.ec_outer_stack = ¤t_ectx->ec_stack; ectx.ec_outer_frame = current_ectx->ec_frame_idx; } else { ectx.ec_outer_stack = partial->pt_ectx_stack; ectx.ec_outer_frame = partial->pt_ectx_frame; } } // dummy frame entries for (idx = 0; idx < STACK_FRAME_SIZE; ++idx) { STACK_TV(ectx.ec_stack.ga_len)->v_type = VAR_UNKNOWN; ++ectx.ec_stack.ga_len; } { // Reserve space for local variables and any closure reference count. dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; for (idx = 0; idx < dfunc->df_varcount; ++idx) STACK_TV_VAR(idx)->v_type = VAR_UNKNOWN; ectx.ec_stack.ga_len += dfunc->df_varcount; if (dfunc->df_has_closure) { STACK_TV_VAR(idx)->v_type = VAR_NUMBER; STACK_TV_VAR(idx)->vval.v_number = 0; ++ectx.ec_stack.ga_len; } ectx.ec_instr = dfunc->df_instr; } // Following errors are in the function, not the caller. // Commands behave like vim9script. estack_push_ufunc(ufunc, 1); current_sctx = ufunc->uf_script_ctx; current_sctx.sc_version = SCRIPT_VERSION_VIM9; // Use a specific location for storing error messages to be converted to an // exception. saved_msg_list = msg_list; msg_list = &private_msg_list; // Do turn errors into exceptions. suppress_errthrow = FALSE; // When ":silent!" was used before calling then we still abort the // function. If ":silent!" is used in the function then we don't. emsg_silent_def = emsg_silent; did_emsg_def = 0; // Decide where to start execution, handles optional arguments. init_instr_idx(ufunc, argc, &ectx); for (;;) { isn_T *iptr; if (++breakcheck_count >= 100) { line_breakcheck(); breakcheck_count = 0; } if (got_int) { // Turn CTRL-C into an exception. got_int = FALSE; if (throw_exception("Vim:Interrupt", ET_INTERRUPT, NULL) == FAIL) goto failed; did_throw = TRUE; } if (did_emsg && msg_list != NULL && *msg_list != NULL) { // Turn an error message into an exception. did_emsg = FALSE; if (throw_exception(*msg_list, ET_ERROR, NULL) == FAIL) goto failed; did_throw = TRUE; *msg_list = NULL; } if (did_throw && !ectx.ec_in_catch) { garray_T *trystack = &ectx.ec_trystack; trycmd_T *trycmd = NULL; // An exception jumps to the first catch, finally, or returns from // the current function. if (trystack->ga_len > 0) trycmd = ((trycmd_T *)trystack->ga_data) + trystack->ga_len - 1; if (trycmd != NULL && trycmd->tcd_frame_idx == ectx.ec_frame_idx) { // jump to ":catch" or ":finally" ectx.ec_in_catch = TRUE; ectx.ec_iidx = trycmd->tcd_catch_idx; } else { // Not inside try or need to return from current functions. // Push a dummy return value. if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; tv = STACK_TV_BOT(0); tv->v_type = VAR_NUMBER; tv->vval.v_number = 0; ++ectx.ec_stack.ga_len; if (ectx.ec_frame_idx == initial_frame_idx) { // At the toplevel we are done. need_rethrow = TRUE; if (handle_closure_in_use(&ectx, FALSE) == FAIL) goto failed; goto done; } if (func_return(&ectx) == FAIL) goto failed; } continue; } iptr = &ectx.ec_instr[ectx.ec_iidx++]; switch (iptr->isn_type) { // execute Ex command line case ISN_EXEC: { SOURCING_LNUM = iptr->isn_lnum; do_cmdline_cmd(iptr->isn_arg.string); if (did_emsg) goto on_error; } break; // execute Ex command from pieces on the stack case ISN_EXECCONCAT: { int count = iptr->isn_arg.number; size_t len = 0; int pass; int i; char_u *cmd = NULL; char_u *str; for (pass = 1; pass <= 2; ++pass) { for (i = 0; i < count; ++i) { tv = STACK_TV_BOT(i - count); str = tv->vval.v_string; if (str != NULL && *str != NUL) { if (pass == 2) STRCPY(cmd + len, str); len += STRLEN(str); } if (pass == 2) clear_tv(tv); } if (pass == 1) { cmd = alloc(len + 1); if (cmd == NULL) goto failed; len = 0; } } SOURCING_LNUM = iptr->isn_lnum; do_cmdline_cmd(cmd); vim_free(cmd); } break; // execute :echo {string} ... case ISN_ECHO: { int count = iptr->isn_arg.echo.echo_count; int atstart = TRUE; int needclr = TRUE; for (idx = 0; idx < count; ++idx) { tv = STACK_TV_BOT(idx - count); echo_one(tv, iptr->isn_arg.echo.echo_with_white, &atstart, &needclr); clear_tv(tv); } if (needclr) msg_clr_eos(); ectx.ec_stack.ga_len -= count; } break; // :execute {string} ... // :echomsg {string} ... // :echoerr {string} ... case ISN_EXECUTE: case ISN_ECHOMSG: case ISN_ECHOERR: { int count = iptr->isn_arg.number; garray_T ga; char_u buf[NUMBUFLEN]; char_u *p; int len; int failed = FALSE; ga_init2(&ga, 1, 80); for (idx = 0; idx < count; ++idx) { tv = STACK_TV_BOT(idx - count); if (iptr->isn_type == ISN_EXECUTE) { if (tv->v_type == VAR_CHANNEL || tv->v_type == VAR_JOB) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_inval_string)); break; } else p = tv_get_string_buf(tv, buf); } else p = tv_stringify(tv, buf); len = (int)STRLEN(p); if (ga_grow(&ga, len + 2) == FAIL) failed = TRUE; else { if (ga.ga_len > 0) ((char_u *)(ga.ga_data))[ga.ga_len++] = ' '; STRCPY((char_u *)(ga.ga_data) + ga.ga_len, p); ga.ga_len += len; } clear_tv(tv); } ectx.ec_stack.ga_len -= count; if (failed) { ga_clear(&ga); goto on_error; } if (ga.ga_data != NULL) { if (iptr->isn_type == ISN_EXECUTE) { SOURCING_LNUM = iptr->isn_lnum; do_cmdline_cmd((char_u *)ga.ga_data); if (did_emsg) { ga_clear(&ga); goto on_error; } } else { msg_sb_eol(); if (iptr->isn_type == ISN_ECHOMSG) { msg_attr(ga.ga_data, echo_attr); out_flush(); } else { SOURCING_LNUM = iptr->isn_lnum; emsg(ga.ga_data); } } } ga_clear(&ga); } break; // load local variable or argument case ISN_LOAD: if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(STACK_TV_VAR(iptr->isn_arg.number), STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; break; // load variable or argument from outer scope case ISN_LOADOUTER: if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(STACK_OUT_TV_VAR(iptr->isn_arg.number), STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; break; // load v: variable case ISN_LOADV: if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(get_vim_var_tv(iptr->isn_arg.number), STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; break; // load s: variable in Vim9 script case ISN_LOADSCRIPT: { scriptitem_T *si = SCRIPT_ITEM(iptr->isn_arg.script.script_sid); svar_T *sv; sv = ((svar_T *)si->sn_var_vals.ga_data) + iptr->isn_arg.script.script_idx; if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(sv->sv_tv, STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; } break; // load s: variable in old script case ISN_LOADS: { hashtab_T *ht = &SCRIPT_VARS( iptr->isn_arg.loadstore.ls_sid); char_u *name = iptr->isn_arg.loadstore.ls_name; dictitem_T *di = find_var_in_ht(ht, 0, name, TRUE); if (di == NULL) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_undefined_variable_str), name); goto on_error; } else { if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(&di->di_tv, STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; } } break; // load g:/b:/w:/t: variable case ISN_LOADG: case ISN_LOADB: case ISN_LOADW: case ISN_LOADT: { dictitem_T *di = NULL; hashtab_T *ht = NULL; char namespace; switch (iptr->isn_type) { case ISN_LOADG: ht = get_globvar_ht(); namespace = 'g'; break; case ISN_LOADB: ht = &curbuf->b_vars->dv_hashtab; namespace = 'b'; break; case ISN_LOADW: ht = &curwin->w_vars->dv_hashtab; namespace = 'w'; break; case ISN_LOADT: ht = &curtab->tp_vars->dv_hashtab; namespace = 't'; break; default: // Cannot reach here goto failed; } di = find_var_in_ht(ht, 0, iptr->isn_arg.string, TRUE); if (di == NULL) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_undefined_variable_char_str), namespace, iptr->isn_arg.string); goto on_error; } else { if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; copy_tv(&di->di_tv, STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; } } break; // load g:/b:/w:/t: namespace case ISN_LOADGDICT: case ISN_LOADBDICT: case ISN_LOADWDICT: case ISN_LOADTDICT: { dict_T *d = NULL; switch (iptr->isn_type) { case ISN_LOADGDICT: d = get_globvar_dict(); break; case ISN_LOADBDICT: d = curbuf->b_vars; break; case ISN_LOADWDICT: d = curwin->w_vars; break; case ISN_LOADTDICT: d = curtab->tp_vars; break; default: // Cannot reach here goto failed; } if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; tv = STACK_TV_BOT(0); tv->v_type = VAR_DICT; tv->v_lock = 0; tv->vval.v_dict = d; ++ectx.ec_stack.ga_len; } break; // load &option case ISN_LOADOPT: { typval_T optval; char_u *name = iptr->isn_arg.string; // This is not expected to fail, name is checked during // compilation: don't set SOURCING_LNUM. if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; if (eval_option(&name, &optval, TRUE) == FAIL) goto failed; *STACK_TV_BOT(0) = optval; ++ectx.ec_stack.ga_len; } break; // load $ENV case ISN_LOADENV: { typval_T optval; char_u *name = iptr->isn_arg.string; if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; // name is always valid, checked when compiling (void)eval_env_var(&name, &optval, TRUE); *STACK_TV_BOT(0) = optval; ++ectx.ec_stack.ga_len; } break; // load @register case ISN_LOADREG: if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; tv = STACK_TV_BOT(0); tv->v_type = VAR_STRING; tv->v_lock = 0; // This may result in NULL, which should be equivalent to an // empty string. tv->vval.v_string = get_reg_contents( iptr->isn_arg.number, GREG_EXPR_SRC); ++ectx.ec_stack.ga_len; break; // store local variable case ISN_STORE: --ectx.ec_stack.ga_len; tv = STACK_TV_VAR(iptr->isn_arg.number); clear_tv(tv); *tv = *STACK_TV_BOT(0); break; // store variable or argument in outer scope case ISN_STOREOUTER: --ectx.ec_stack.ga_len; tv = STACK_OUT_TV_VAR(iptr->isn_arg.number); clear_tv(tv); *tv = *STACK_TV_BOT(0); break; // store s: variable in old script case ISN_STORES: { hashtab_T *ht = &SCRIPT_VARS( iptr->isn_arg.loadstore.ls_sid); char_u *name = iptr->isn_arg.loadstore.ls_name; dictitem_T *di = find_var_in_ht(ht, 0, name + 2, TRUE); --ectx.ec_stack.ga_len; if (di == NULL) store_var(name, STACK_TV_BOT(0)); else { clear_tv(&di->di_tv); di->di_tv = *STACK_TV_BOT(0); } } break; // store script-local variable in Vim9 script case ISN_STORESCRIPT: { scriptitem_T *si = SCRIPT_ITEM( iptr->isn_arg.script.script_sid); svar_T *sv = ((svar_T *)si->sn_var_vals.ga_data) + iptr->isn_arg.script.script_idx; --ectx.ec_stack.ga_len; clear_tv(sv->sv_tv); *sv->sv_tv = *STACK_TV_BOT(0); } break; // store option case ISN_STOREOPT: { long n = 0; char_u *s = NULL; char *msg; --ectx.ec_stack.ga_len; tv = STACK_TV_BOT(0); if (tv->v_type == VAR_STRING) { s = tv->vval.v_string; if (s == NULL) s = (char_u *)""; } else // must be VAR_NUMBER, CHECKTYPE makes sure n = tv->vval.v_number; msg = set_option_value(iptr->isn_arg.storeopt.so_name, n, s, iptr->isn_arg.storeopt.so_flags); clear_tv(tv); if (msg != NULL) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(msg)); goto on_error; } } break; // store $ENV case ISN_STOREENV: --ectx.ec_stack.ga_len; tv = STACK_TV_BOT(0); vim_setenv_ext(iptr->isn_arg.string, tv_get_string(tv)); clear_tv(tv); break; // store @r case ISN_STOREREG: { int reg = iptr->isn_arg.number; --ectx.ec_stack.ga_len; tv = STACK_TV_BOT(0); write_reg_contents(reg == '@' ? '"' : reg, tv_get_string(tv), -1, FALSE); clear_tv(tv); } break; // store v: variable case ISN_STOREV: --ectx.ec_stack.ga_len; if (set_vim_var_tv(iptr->isn_arg.number, STACK_TV_BOT(0)) == FAIL) // should not happen, type is checked when compiling goto on_error; break; // store g:/b:/w:/t: variable case ISN_STOREG: case ISN_STOREB: case ISN_STOREW: case ISN_STORET: { dictitem_T *di; hashtab_T *ht; switch (iptr->isn_type) { case ISN_STOREG: ht = get_globvar_ht(); break; case ISN_STOREB: ht = &curbuf->b_vars->dv_hashtab; break; case ISN_STOREW: ht = &curwin->w_vars->dv_hashtab; break; case ISN_STORET: ht = &curtab->tp_vars->dv_hashtab; break; default: // Cannot reach here goto failed; } --ectx.ec_stack.ga_len; di = find_var_in_ht(ht, 0, iptr->isn_arg.string + 2, TRUE); if (di == NULL) store_var(iptr->isn_arg.string, STACK_TV_BOT(0)); else { clear_tv(&di->di_tv); di->di_tv = *STACK_TV_BOT(0); } } break; // store number in local variable case ISN_STORENR: tv = STACK_TV_VAR(iptr->isn_arg.storenr.stnr_idx); clear_tv(tv); tv->v_type = VAR_NUMBER; tv->vval.v_number = iptr->isn_arg.storenr.stnr_val; break; // store value in list variable case ISN_STORELIST: { typval_T *tv_idx = STACK_TV_BOT(-2); varnumber_T lidx = tv_idx->vval.v_number; typval_T *tv_list = STACK_TV_BOT(-1); list_T *list = tv_list->vval.v_list; SOURCING_LNUM = iptr->isn_lnum; if (lidx < 0 && list->lv_len + lidx >= 0) // negative index is relative to the end lidx = list->lv_len + lidx; if (lidx < 0 || lidx > list->lv_len) { semsg(_(e_listidx), lidx); goto on_error; } tv = STACK_TV_BOT(-3); if (lidx < list->lv_len) { listitem_T *li = list_find(list, lidx); if (error_if_locked(li->li_tv.v_lock, e_cannot_change_list_item)) goto failed; // overwrite existing list item clear_tv(&li->li_tv); li->li_tv = *tv; } else { if (error_if_locked(list->lv_lock, e_cannot_change_list)) goto failed; // append to list, only fails when out of memory if (list_append_tv(list, tv) == FAIL) goto failed; clear_tv(tv); } clear_tv(tv_idx); clear_tv(tv_list); ectx.ec_stack.ga_len -= 3; } break; // store value in dict variable case ISN_STOREDICT: { typval_T *tv_key = STACK_TV_BOT(-2); char_u *key = tv_key->vval.v_string; typval_T *tv_dict = STACK_TV_BOT(-1); dict_T *dict = tv_dict->vval.v_dict; dictitem_T *di; SOURCING_LNUM = iptr->isn_lnum; if (dict == NULL) { emsg(_(e_dictionary_not_set)); goto on_error; } if (key == NULL) key = (char_u *)""; tv = STACK_TV_BOT(-3); di = dict_find(dict, key, -1); if (di != NULL) { if (error_if_locked(di->di_tv.v_lock, e_cannot_change_dict_item)) goto failed; // overwrite existing value clear_tv(&di->di_tv); di->di_tv = *tv; } else { if (error_if_locked(dict->dv_lock, e_cannot_change_dict)) goto failed; // add to dict, only fails when out of memory if (dict_add_tv(dict, (char *)key, tv) == FAIL) goto failed; clear_tv(tv); } clear_tv(tv_key); clear_tv(tv_dict); ectx.ec_stack.ga_len -= 3; } break; // push constant case ISN_PUSHNR: case ISN_PUSHBOOL: case ISN_PUSHSPEC: case ISN_PUSHF: case ISN_PUSHS: case ISN_PUSHBLOB: case ISN_PUSHFUNC: case ISN_PUSHCHANNEL: case ISN_PUSHJOB: if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; tv = STACK_TV_BOT(0); tv->v_lock = 0; ++ectx.ec_stack.ga_len; switch (iptr->isn_type) { case ISN_PUSHNR: tv->v_type = VAR_NUMBER; tv->vval.v_number = iptr->isn_arg.number; break; case ISN_PUSHBOOL: tv->v_type = VAR_BOOL; tv->vval.v_number = iptr->isn_arg.number; break; case ISN_PUSHSPEC: tv->v_type = VAR_SPECIAL; tv->vval.v_number = iptr->isn_arg.number; break; #ifdef FEAT_FLOAT case ISN_PUSHF: tv->v_type = VAR_FLOAT; tv->vval.v_float = iptr->isn_arg.fnumber; break; #endif case ISN_PUSHBLOB: blob_copy(iptr->isn_arg.blob, tv); break; case ISN_PUSHFUNC: tv->v_type = VAR_FUNC; if (iptr->isn_arg.string == NULL) tv->vval.v_string = NULL; else tv->vval.v_string = vim_strsave(iptr->isn_arg.string); break; case ISN_PUSHCHANNEL: #ifdef FEAT_JOB_CHANNEL tv->v_type = VAR_CHANNEL; tv->vval.v_channel = iptr->isn_arg.channel; if (tv->vval.v_channel != NULL) ++tv->vval.v_channel->ch_refcount; #endif break; case ISN_PUSHJOB: #ifdef FEAT_JOB_CHANNEL tv->v_type = VAR_JOB; tv->vval.v_job = iptr->isn_arg.job; if (tv->vval.v_job != NULL) ++tv->vval.v_job->jv_refcount; #endif break; default: tv->v_type = VAR_STRING; tv->vval.v_string = vim_strsave( iptr->isn_arg.string == NULL ? (char_u *)"" : iptr->isn_arg.string); } break; case ISN_UNLET: if (do_unlet(iptr->isn_arg.unlet.ul_name, iptr->isn_arg.unlet.ul_forceit) == FAIL) goto on_error; break; case ISN_UNLETENV: vim_unsetenv(iptr->isn_arg.unlet.ul_name); break; case ISN_LOCKCONST: item_lock(STACK_TV_BOT(-1), 100, TRUE, TRUE); break; // create a list from items on the stack; uses a single allocation // for the list header and the items case ISN_NEWLIST: if (exe_newlist(iptr->isn_arg.number, &ectx) == FAIL) goto failed; break; // create a dict from items on the stack case ISN_NEWDICT: { int count = iptr->isn_arg.number; dict_T *dict = dict_alloc(); dictitem_T *item; char_u *key; if (dict == NULL) goto failed; for (idx = 0; idx < count; ++idx) { // have already checked key type is VAR_STRING tv = STACK_TV_BOT(2 * (idx - count)); // check key is unique key = tv->vval.v_string == NULL ? (char_u *)"" : tv->vval.v_string; item = dict_find(dict, key, -1); if (item != NULL) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_duplicate_key), key); dict_unref(dict); goto on_error; } item = dictitem_alloc(key); clear_tv(tv); if (item == NULL) { dict_unref(dict); goto failed; } item->di_tv = *STACK_TV_BOT(2 * (idx - count) + 1); item->di_tv.v_lock = 0; if (dict_add(dict, item) == FAIL) { // can this ever happen? dict_unref(dict); goto failed; } } if (count > 0) ectx.ec_stack.ga_len -= 2 * count - 1; else if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; else ++ectx.ec_stack.ga_len; tv = STACK_TV_BOT(-1); tv->v_type = VAR_DICT; tv->v_lock = 0; tv->vval.v_dict = dict; ++dict->dv_refcount; } break; // call a :def function case ISN_DCALL: SOURCING_LNUM = iptr->isn_lnum; if (call_dfunc(iptr->isn_arg.dfunc.cdf_idx, iptr->isn_arg.dfunc.cdf_argcount, &ectx) == FAIL) goto on_error; break; // call a builtin function case ISN_BCALL: SOURCING_LNUM = iptr->isn_lnum; if (call_bfunc(iptr->isn_arg.bfunc.cbf_idx, iptr->isn_arg.bfunc.cbf_argcount, &ectx) == FAIL) goto on_error; break; // call a funcref or partial case ISN_PCALL: { cpfunc_T *pfunc = &iptr->isn_arg.pfunc; int r; typval_T partial_tv; SOURCING_LNUM = iptr->isn_lnum; if (pfunc->cpf_top) { // funcref is above the arguments tv = STACK_TV_BOT(-pfunc->cpf_argcount - 1); } else { // Get the funcref from the stack. --ectx.ec_stack.ga_len; partial_tv = *STACK_TV_BOT(0); tv = &partial_tv; } r = call_partial(tv, pfunc->cpf_argcount, &ectx); if (tv == &partial_tv) clear_tv(&partial_tv); if (r == FAIL) goto on_error; } break; case ISN_PCALL_END: // PCALL finished, arguments have been consumed and replaced by // the return value. Now clear the funcref from the stack, // and move the return value in its place. --ectx.ec_stack.ga_len; clear_tv(STACK_TV_BOT(-1)); *STACK_TV_BOT(-1) = *STACK_TV_BOT(0); break; // call a user defined function or funcref/partial case ISN_UCALL: { cufunc_T *cufunc = &iptr->isn_arg.ufunc; SOURCING_LNUM = iptr->isn_lnum; if (call_eval_func(cufunc->cuf_name, cufunc->cuf_argcount, &ectx, iptr) == FAIL) goto on_error; } break; // return from a :def function call case ISN_RETURN: { garray_T *trystack = &ectx.ec_trystack; trycmd_T *trycmd = NULL; if (trystack->ga_len > 0) trycmd = ((trycmd_T *)trystack->ga_data) + trystack->ga_len - 1; if (trycmd != NULL && trycmd->tcd_frame_idx == ectx.ec_frame_idx && trycmd->tcd_finally_idx != 0) { // jump to ":finally" ectx.ec_iidx = trycmd->tcd_finally_idx; trycmd->tcd_return = TRUE; } else goto func_return; } break; // push a function reference to a compiled function case ISN_FUNCREF: { partial_T *pt = NULL; dfunc_T *pt_dfunc; pt = ALLOC_CLEAR_ONE(partial_T); if (pt == NULL) goto failed; if (GA_GROW(&ectx.ec_stack, 1) == FAIL) { vim_free(pt); goto failed; } pt_dfunc = ((dfunc_T *)def_functions.ga_data) + iptr->isn_arg.funcref.fr_func; pt->pt_func = pt_dfunc->df_ufunc; pt->pt_refcount = 1; if (pt_dfunc->df_ufunc->uf_flags & FC_CLOSURE) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ectx.ec_dfunc_idx; // The closure needs to find arguments and local // variables in the current stack. pt->pt_ectx_stack = &ectx.ec_stack; pt->pt_ectx_frame = ectx.ec_frame_idx; // If this function returns and the closure is still // being used, we need to make a copy of the context // (arguments and local variables). Store a reference // to the partial so we can handle that. if (ga_grow(&ectx.ec_funcrefs, 1) == FAIL) { vim_free(pt); goto failed; } // Extra variable keeps the count of closures created // in the current function call. tv = STACK_TV_VAR(dfunc->df_varcount); ++tv->vval.v_number; ((partial_T **)ectx.ec_funcrefs.ga_data) [ectx.ec_funcrefs.ga_len] = pt; ++pt->pt_refcount; ++ectx.ec_funcrefs.ga_len; } ++pt_dfunc->df_ufunc->uf_refcount; tv = STACK_TV_BOT(0); ++ectx.ec_stack.ga_len; tv->vval.v_partial = pt; tv->v_type = VAR_PARTIAL; tv->v_lock = 0; } break; // Create a global function from a lambda. case ISN_NEWFUNC: { newfunc_T *newfunc = &iptr->isn_arg.newfunc; copy_func(newfunc->nf_lambda, newfunc->nf_global); } break; // List functions case ISN_DEF: if (iptr->isn_arg.string == NULL) list_functions(NULL); else { exarg_T ea; CLEAR_FIELD(ea); ea.cmd = ea.arg = iptr->isn_arg.string; define_function(&ea, NULL); } break; // jump if a condition is met case ISN_JUMP: { jumpwhen_T when = iptr->isn_arg.jump.jump_when; int error = FALSE; int jump = TRUE; if (when != JUMP_ALWAYS) { tv = STACK_TV_BOT(-1); if (when == JUMP_IF_COND_FALSE || when == JUMP_IF_FALSE || when == JUMP_IF_COND_TRUE) { SOURCING_LNUM = iptr->isn_lnum; jump = tv_get_bool_chk(tv, &error); if (error) goto on_error; } else jump = tv2bool(tv); if (when == JUMP_IF_FALSE || when == JUMP_AND_KEEP_IF_FALSE || when == JUMP_IF_COND_FALSE) jump = !jump; if (when == JUMP_IF_FALSE || !jump) { // drop the value from the stack clear_tv(tv); --ectx.ec_stack.ga_len; } } if (jump) ectx.ec_iidx = iptr->isn_arg.jump.jump_where; } break; // top of a for loop case ISN_FOR: { list_T *list = STACK_TV_BOT(-1)->vval.v_list; typval_T *idxtv = STACK_TV_VAR(iptr->isn_arg.forloop.for_idx); // push the next item from the list if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; ++idxtv->vval.v_number; if (list == NULL || idxtv->vval.v_number >= list->lv_len) // past the end of the list, jump to "endfor" ectx.ec_iidx = iptr->isn_arg.forloop.for_end; else if (list->lv_first == &range_list_item) { // non-materialized range() list tv = STACK_TV_BOT(0); tv->v_type = VAR_NUMBER; tv->v_lock = 0; tv->vval.v_number = list_find_nr( list, idxtv->vval.v_number, NULL); ++ectx.ec_stack.ga_len; } else { listitem_T *li = list_find(list, idxtv->vval.v_number); copy_tv(&li->li_tv, STACK_TV_BOT(0)); ++ectx.ec_stack.ga_len; } } break; // start of ":try" block case ISN_TRY: { trycmd_T *trycmd = NULL; if (GA_GROW(&ectx.ec_trystack, 1) == FAIL) goto failed; trycmd = ((trycmd_T *)ectx.ec_trystack.ga_data) + ectx.ec_trystack.ga_len; ++ectx.ec_trystack.ga_len; ++trylevel; trycmd->tcd_frame_idx = ectx.ec_frame_idx; trycmd->tcd_catch_idx = iptr->isn_arg.try.try_catch; trycmd->tcd_finally_idx = iptr->isn_arg.try.try_finally; trycmd->tcd_caught = FALSE; trycmd->tcd_return = FALSE; } break; case ISN_PUSHEXC: if (current_exception == NULL) { SOURCING_LNUM = iptr->isn_lnum; iemsg("Evaluating catch while current_exception is NULL"); goto failed; } if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; tv = STACK_TV_BOT(0); ++ectx.ec_stack.ga_len; tv->v_type = VAR_STRING; tv->v_lock = 0; tv->vval.v_string = vim_strsave( (char_u *)current_exception->value); break; case ISN_CATCH: { garray_T *trystack = &ectx.ec_trystack; if (trystack->ga_len > 0) { trycmd_T *trycmd = ((trycmd_T *)trystack->ga_data) + trystack->ga_len - 1; trycmd->tcd_caught = TRUE; } did_emsg = got_int = did_throw = FALSE; catch_exception(current_exception); } break; // end of ":try" block case ISN_ENDTRY: { garray_T *trystack = &ectx.ec_trystack; if (trystack->ga_len > 0) { trycmd_T *trycmd = NULL; --trystack->ga_len; --trylevel; ectx.ec_in_catch = FALSE; trycmd = ((trycmd_T *)trystack->ga_data) + trystack->ga_len; if (trycmd->tcd_caught && current_exception != NULL) { // discard the exception if (caught_stack == current_exception) caught_stack = caught_stack->caught; discard_current_exception(); } if (trycmd->tcd_return) goto func_return; } } break; case ISN_THROW: --ectx.ec_stack.ga_len; tv = STACK_TV_BOT(0); if (tv->vval.v_string == NULL || *skipwhite(tv->vval.v_string) == NUL) { vim_free(tv->vval.v_string); SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_throw_with_empty_string)); goto failed; } if (throw_exception(tv->vval.v_string, ET_USER, NULL) == FAIL) { vim_free(tv->vval.v_string); goto failed; } did_throw = TRUE; break; // compare with special values case ISN_COMPAREBOOL: case ISN_COMPARESPECIAL: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); varnumber_T arg1 = tv1->vval.v_number; varnumber_T arg2 = tv2->vval.v_number; int res; switch (iptr->isn_arg.op.op_type) { case EXPR_EQUAL: res = arg1 == arg2; break; case EXPR_NEQUAL: res = arg1 != arg2; break; default: res = 0; break; } --ectx.ec_stack.ga_len; tv1->v_type = VAR_BOOL; tv1->vval.v_number = res ? VVAL_TRUE : VVAL_FALSE; } break; // Operation with two number arguments case ISN_OPNR: case ISN_COMPARENR: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); varnumber_T arg1 = tv1->vval.v_number; varnumber_T arg2 = tv2->vval.v_number; varnumber_T res; switch (iptr->isn_arg.op.op_type) { case EXPR_MULT: res = arg1 * arg2; break; case EXPR_DIV: res = arg1 / arg2; break; case EXPR_REM: res = arg1 % arg2; break; case EXPR_SUB: res = arg1 - arg2; break; case EXPR_ADD: res = arg1 + arg2; break; case EXPR_EQUAL: res = arg1 == arg2; break; case EXPR_NEQUAL: res = arg1 != arg2; break; case EXPR_GREATER: res = arg1 > arg2; break; case EXPR_GEQUAL: res = arg1 >= arg2; break; case EXPR_SMALLER: res = arg1 < arg2; break; case EXPR_SEQUAL: res = arg1 <= arg2; break; default: res = 0; break; } --ectx.ec_stack.ga_len; if (iptr->isn_type == ISN_COMPARENR) { tv1->v_type = VAR_BOOL; tv1->vval.v_number = res ? VVAL_TRUE : VVAL_FALSE; } else tv1->vval.v_number = res; } break; // Computation with two float arguments case ISN_OPFLOAT: case ISN_COMPAREFLOAT: #ifdef FEAT_FLOAT { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); float_T arg1 = tv1->vval.v_float; float_T arg2 = tv2->vval.v_float; float_T res = 0; int cmp = FALSE; switch (iptr->isn_arg.op.op_type) { case EXPR_MULT: res = arg1 * arg2; break; case EXPR_DIV: res = arg1 / arg2; break; case EXPR_SUB: res = arg1 - arg2; break; case EXPR_ADD: res = arg1 + arg2; break; case EXPR_EQUAL: cmp = arg1 == arg2; break; case EXPR_NEQUAL: cmp = arg1 != arg2; break; case EXPR_GREATER: cmp = arg1 > arg2; break; case EXPR_GEQUAL: cmp = arg1 >= arg2; break; case EXPR_SMALLER: cmp = arg1 < arg2; break; case EXPR_SEQUAL: cmp = arg1 <= arg2; break; default: cmp = 0; break; } --ectx.ec_stack.ga_len; if (iptr->isn_type == ISN_COMPAREFLOAT) { tv1->v_type = VAR_BOOL; tv1->vval.v_number = cmp ? VVAL_TRUE : VVAL_FALSE; } else tv1->vval.v_float = res; } #endif break; case ISN_COMPARELIST: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); list_T *arg1 = tv1->vval.v_list; list_T *arg2 = tv2->vval.v_list; int cmp = FALSE; int ic = iptr->isn_arg.op.op_ic; switch (iptr->isn_arg.op.op_type) { case EXPR_EQUAL: cmp = list_equal(arg1, arg2, ic, FALSE); break; case EXPR_NEQUAL: cmp = !list_equal(arg1, arg2, ic, FALSE); break; case EXPR_IS: cmp = arg1 == arg2; break; case EXPR_ISNOT: cmp = arg1 != arg2; break; default: cmp = 0; break; } --ectx.ec_stack.ga_len; clear_tv(tv1); clear_tv(tv2); tv1->v_type = VAR_BOOL; tv1->vval.v_number = cmp ? VVAL_TRUE : VVAL_FALSE; } break; case ISN_COMPAREBLOB: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); blob_T *arg1 = tv1->vval.v_blob; blob_T *arg2 = tv2->vval.v_blob; int cmp = FALSE; switch (iptr->isn_arg.op.op_type) { case EXPR_EQUAL: cmp = blob_equal(arg1, arg2); break; case EXPR_NEQUAL: cmp = !blob_equal(arg1, arg2); break; case EXPR_IS: cmp = arg1 == arg2; break; case EXPR_ISNOT: cmp = arg1 != arg2; break; default: cmp = 0; break; } --ectx.ec_stack.ga_len; clear_tv(tv1); clear_tv(tv2); tv1->v_type = VAR_BOOL; tv1->vval.v_number = cmp ? VVAL_TRUE : VVAL_FALSE; } break; // TODO: handle separately case ISN_COMPARESTRING: case ISN_COMPAREDICT: case ISN_COMPAREFUNC: case ISN_COMPAREANY: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); exptype_T exptype = iptr->isn_arg.op.op_type; int ic = iptr->isn_arg.op.op_ic; SOURCING_LNUM = iptr->isn_lnum; typval_compare(tv1, tv2, exptype, ic); clear_tv(tv2); --ectx.ec_stack.ga_len; } break; case ISN_ADDLIST: case ISN_ADDBLOB: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); // add two lists or blobs if (iptr->isn_type == ISN_ADDLIST) eval_addlist(tv1, tv2); else eval_addblob(tv1, tv2); clear_tv(tv2); --ectx.ec_stack.ga_len; } break; case ISN_LISTAPPEND: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); list_T *l = tv1->vval.v_list; // add an item to a list if (l == NULL) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_cannot_add_to_null_list)); goto on_error; } if (list_append_tv(l, tv2) == FAIL) goto failed; clear_tv(tv2); --ectx.ec_stack.ga_len; } break; case ISN_BLOBAPPEND: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); blob_T *b = tv1->vval.v_blob; int error = FALSE; varnumber_T n; // add a number to a blob if (b == NULL) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_cannot_add_to_null_blob)); goto on_error; } n = tv_get_number_chk(tv2, &error); if (error) goto on_error; ga_append(&b->bv_ga, (int)n); --ectx.ec_stack.ga_len; } break; // Computation with two arguments of unknown type case ISN_OPANY: { typval_T *tv1 = STACK_TV_BOT(-2); typval_T *tv2 = STACK_TV_BOT(-1); varnumber_T n1, n2; #ifdef FEAT_FLOAT float_T f1 = 0, f2 = 0; #endif int error = FALSE; if (iptr->isn_arg.op.op_type == EXPR_ADD) { if (tv1->v_type == VAR_LIST && tv2->v_type == VAR_LIST) { eval_addlist(tv1, tv2); clear_tv(tv2); --ectx.ec_stack.ga_len; break; } else if (tv1->v_type == VAR_BLOB && tv2->v_type == VAR_BLOB) { eval_addblob(tv1, tv2); clear_tv(tv2); --ectx.ec_stack.ga_len; break; } } #ifdef FEAT_FLOAT if (tv1->v_type == VAR_FLOAT) { f1 = tv1->vval.v_float; n1 = 0; } else #endif { SOURCING_LNUM = iptr->isn_lnum; n1 = tv_get_number_chk(tv1, &error); if (error) goto on_error; #ifdef FEAT_FLOAT if (tv2->v_type == VAR_FLOAT) f1 = n1; #endif } #ifdef FEAT_FLOAT if (tv2->v_type == VAR_FLOAT) { f2 = tv2->vval.v_float; n2 = 0; } else #endif { n2 = tv_get_number_chk(tv2, &error); if (error) goto on_error; #ifdef FEAT_FLOAT if (tv1->v_type == VAR_FLOAT) f2 = n2; #endif } #ifdef FEAT_FLOAT // if there is a float on either side the result is a float if (tv1->v_type == VAR_FLOAT || tv2->v_type == VAR_FLOAT) { switch (iptr->isn_arg.op.op_type) { case EXPR_MULT: f1 = f1 * f2; break; case EXPR_DIV: f1 = f1 / f2; break; case EXPR_SUB: f1 = f1 - f2; break; case EXPR_ADD: f1 = f1 + f2; break; default: SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_modulus)); goto on_error; } clear_tv(tv1); clear_tv(tv2); tv1->v_type = VAR_FLOAT; tv1->vval.v_float = f1; --ectx.ec_stack.ga_len; } else #endif { switch (iptr->isn_arg.op.op_type) { case EXPR_MULT: n1 = n1 * n2; break; case EXPR_DIV: n1 = num_divide(n1, n2); break; case EXPR_SUB: n1 = n1 - n2; break; case EXPR_ADD: n1 = n1 + n2; break; default: n1 = num_modulus(n1, n2); break; } clear_tv(tv1); clear_tv(tv2); tv1->v_type = VAR_NUMBER; tv1->vval.v_number = n1; --ectx.ec_stack.ga_len; } } break; case ISN_CONCAT: { char_u *str1 = STACK_TV_BOT(-2)->vval.v_string; char_u *str2 = STACK_TV_BOT(-1)->vval.v_string; char_u *res; res = concat_str(str1, str2); clear_tv(STACK_TV_BOT(-2)); clear_tv(STACK_TV_BOT(-1)); --ectx.ec_stack.ga_len; STACK_TV_BOT(-1)->vval.v_string = res; } break; case ISN_STRINDEX: case ISN_STRSLICE: { int is_slice = iptr->isn_type == ISN_STRSLICE; varnumber_T n1 = 0, n2; char_u *res; // string index: string is at stack-2, index at stack-1 // string slice: string is at stack-3, first index at // stack-2, second index at stack-1 if (is_slice) { tv = STACK_TV_BOT(-2); n1 = tv->vval.v_number; } tv = STACK_TV_BOT(-1); n2 = tv->vval.v_number; ectx.ec_stack.ga_len -= is_slice ? 2 : 1; tv = STACK_TV_BOT(-1); if (is_slice) // Slice: Select the characters from the string res = string_slice(tv->vval.v_string, n1, n2); else // Index: The resulting variable is a string of a // single character. If the index is too big or // negative the result is empty. res = char_from_string(tv->vval.v_string, n2); vim_free(tv->vval.v_string); tv->vval.v_string = res; } break; case ISN_LISTINDEX: case ISN_LISTSLICE: { int is_slice = iptr->isn_type == ISN_LISTSLICE; list_T *list; varnumber_T n1, n2; // list index: list is at stack-2, index at stack-1 // list slice: list is at stack-3, indexes at stack-2 and // stack-1 tv = is_slice ? STACK_TV_BOT(-3) : STACK_TV_BOT(-2); list = tv->vval.v_list; tv = STACK_TV_BOT(-1); n1 = n2 = tv->vval.v_number; clear_tv(tv); if (is_slice) { tv = STACK_TV_BOT(-2); n1 = tv->vval.v_number; clear_tv(tv); } ectx.ec_stack.ga_len -= is_slice ? 2 : 1; tv = STACK_TV_BOT(-1); SOURCING_LNUM = iptr->isn_lnum; if (list_slice_or_index(list, is_slice, n1, n2, tv, TRUE) == FAIL) goto on_error; } break; case ISN_ANYINDEX: case ISN_ANYSLICE: { int is_slice = iptr->isn_type == ISN_ANYSLICE; typval_T *var1, *var2; int res; // index: composite is at stack-2, index at stack-1 // slice: composite is at stack-3, indexes at stack-2 and // stack-1 tv = is_slice ? STACK_TV_BOT(-3) : STACK_TV_BOT(-2); SOURCING_LNUM = iptr->isn_lnum; if (check_can_index(tv, TRUE, TRUE) == FAIL) goto on_error; var1 = is_slice ? STACK_TV_BOT(-2) : STACK_TV_BOT(-1); var2 = is_slice ? STACK_TV_BOT(-1) : NULL; res = eval_index_inner(tv, is_slice, var1, var2, NULL, -1, TRUE); clear_tv(var1); if (is_slice) clear_tv(var2); ectx.ec_stack.ga_len -= is_slice ? 2 : 1; if (res == FAIL) goto on_error; } break; case ISN_SLICE: { list_T *list; int count = iptr->isn_arg.number; // type will have been checked to be a list tv = STACK_TV_BOT(-1); list = tv->vval.v_list; // no error for short list, expect it to be checked earlier if (list != NULL && list->lv_len >= count) { list_T *newlist = list_slice(list, count, list->lv_len - 1); if (newlist != NULL) { list_unref(list); tv->vval.v_list = newlist; ++newlist->lv_refcount; } } } break; case ISN_GETITEM: { listitem_T *li; int index = iptr->isn_arg.number; // Get list item: list is at stack-1, push item. // List type and length is checked for when compiling. tv = STACK_TV_BOT(-1); li = list_find(tv->vval.v_list, index); if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; ++ectx.ec_stack.ga_len; copy_tv(&li->li_tv, STACK_TV_BOT(-1)); } break; case ISN_MEMBER: { dict_T *dict; char_u *key; dictitem_T *di; typval_T temp_tv; // dict member: dict is at stack-2, key at stack-1 tv = STACK_TV_BOT(-2); // no need to check for VAR_DICT, CHECKTYPE will check. dict = tv->vval.v_dict; tv = STACK_TV_BOT(-1); // no need to check for VAR_STRING, 2STRING will check. key = tv->vval.v_string; if (key == NULL) key = (char_u *)""; if ((di = dict_find(dict, key, -1)) == NULL) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_dictkey), key); // If :silent! is used we will continue, make sure the // stack contents makes sense. clear_tv(tv); --ectx.ec_stack.ga_len; tv = STACK_TV_BOT(-1); clear_tv(tv); tv->v_type = VAR_NUMBER; tv->vval.v_number = 0; goto on_fatal_error; } clear_tv(tv); --ectx.ec_stack.ga_len; // Clear the dict only after getting the item, to avoid // that it makes the item invalid. tv = STACK_TV_BOT(-1); temp_tv = *tv; copy_tv(&di->di_tv, tv); clear_tv(&temp_tv); } break; // dict member with string key case ISN_STRINGMEMBER: { dict_T *dict; dictitem_T *di; typval_T temp_tv; tv = STACK_TV_BOT(-1); if (tv->v_type != VAR_DICT || tv->vval.v_dict == NULL) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_dictreq)); goto on_error; } dict = tv->vval.v_dict; if ((di = dict_find(dict, iptr->isn_arg.string, -1)) == NULL) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_dictkey), iptr->isn_arg.string); goto on_error; } // Clear the dict after getting the item, to avoid that it // make the item invalid. temp_tv = *tv; copy_tv(&di->di_tv, tv); clear_tv(&temp_tv); } break; case ISN_NEGATENR: tv = STACK_TV_BOT(-1); if (tv->v_type != VAR_NUMBER #ifdef FEAT_FLOAT && tv->v_type != VAR_FLOAT #endif ) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_number_exp)); goto on_error; } #ifdef FEAT_FLOAT if (tv->v_type == VAR_FLOAT) tv->vval.v_float = -tv->vval.v_float; else #endif tv->vval.v_number = -tv->vval.v_number; break; case ISN_CHECKNR: { int error = FALSE; tv = STACK_TV_BOT(-1); SOURCING_LNUM = iptr->isn_lnum; if (check_not_string(tv) == FAIL) goto on_error; (void)tv_get_number_chk(tv, &error); if (error) goto on_error; } break; case ISN_CHECKTYPE: { checktype_T *ct = &iptr->isn_arg.type; tv = STACK_TV_BOT(ct->ct_off); SOURCING_LNUM = iptr->isn_lnum; if (check_typval_type(ct->ct_type, tv, 0) == FAIL) goto on_error; // number 0 is FALSE, number 1 is TRUE if (tv->v_type == VAR_NUMBER && ct->ct_type->tt_type == VAR_BOOL && (tv->vval.v_number == 0 || tv->vval.v_number == 1)) { tv->v_type = VAR_BOOL; tv->vval.v_number = tv->vval.v_number ? VVAL_TRUE : VVAL_FALSE; } } break; case ISN_CHECKLEN: { int min_len = iptr->isn_arg.checklen.cl_min_len; list_T *list = NULL; tv = STACK_TV_BOT(-1); if (tv->v_type == VAR_LIST) list = tv->vval.v_list; if (list == NULL || list->lv_len < min_len || (list->lv_len > min_len && !iptr->isn_arg.checklen.cl_more_OK)) { SOURCING_LNUM = iptr->isn_lnum; semsg(_(e_expected_nr_items_but_got_nr), min_len, list == NULL ? 0 : list->lv_len); goto on_error; } } break; case ISN_2BOOL: case ISN_COND2BOOL: { int n; int error = FALSE; tv = STACK_TV_BOT(-1); if (iptr->isn_type == ISN_2BOOL) { n = tv2bool(tv); if (iptr->isn_arg.number) // invert n = !n; } else { SOURCING_LNUM = iptr->isn_lnum; n = tv_get_bool_chk(tv, &error); if (error) goto on_error; } clear_tv(tv); tv->v_type = VAR_BOOL; tv->vval.v_number = n ? VVAL_TRUE : VVAL_FALSE; } break; case ISN_2STRING: case ISN_2STRING_ANY: { char_u *str; tv = STACK_TV_BOT(iptr->isn_arg.number); if (tv->v_type != VAR_STRING) { if (iptr->isn_type == ISN_2STRING_ANY) { switch (tv->v_type) { case VAR_SPECIAL: case VAR_BOOL: case VAR_NUMBER: case VAR_FLOAT: case VAR_BLOB: break; default: to_string_error(tv->v_type); goto on_error; } } str = typval_tostring(tv); clear_tv(tv); tv->v_type = VAR_STRING; tv->vval.v_string = str; } } break; case ISN_RANGE: { exarg_T ea; char *errormsg; if (GA_GROW(&ectx.ec_stack, 1) == FAIL) goto failed; ++ectx.ec_stack.ga_len; tv = STACK_TV_BOT(-1); ea.addr_type = ADDR_LINES; ea.cmd = iptr->isn_arg.string; if (parse_cmd_address(&ea, &errormsg, FALSE) == FAIL) goto failed; if (ea.addr_count == 0) tv->vval.v_number = curwin->w_cursor.lnum; else tv->vval.v_number = ea.line2; } break; case ISN_PUT: { int regname = iptr->isn_arg.put.put_regname; linenr_T lnum = iptr->isn_arg.put.put_lnum; char_u *expr = NULL; int dir = FORWARD; if (regname == '=') { tv = STACK_TV_BOT(-1); if (tv->v_type == VAR_STRING) expr = tv->vval.v_string; else { expr = typval_tostring(tv); // allocates value clear_tv(tv); } --ectx.ec_stack.ga_len; } if (lnum < -2) { // line number was put on the stack by ISN_RANGE tv = STACK_TV_BOT(-1); curwin->w_cursor.lnum = tv->vval.v_number; if (lnum == LNUM_VARIABLE_RANGE_ABOVE) dir = BACKWARD; --ectx.ec_stack.ga_len; } else if (lnum == -2) // :put! above cursor dir = BACKWARD; else if (lnum >= 0) curwin->w_cursor.lnum = iptr->isn_arg.put.put_lnum; check_cursor(); do_put(regname, expr, dir, 1L, PUT_LINE|PUT_CURSLINE); vim_free(expr); } break; case ISN_CMDMOD: save_cmdmod = cmdmod; restore_cmdmod = TRUE; cmdmod = *iptr->isn_arg.cmdmod.cf_cmdmod; apply_cmdmod(&cmdmod); break; case ISN_CMDMOD_REV: // filter regprog is owned by the instruction, don't free it cmdmod.cmod_filter_regmatch.regprog = NULL; undo_cmdmod(&cmdmod); cmdmod = save_cmdmod; restore_cmdmod = FALSE; break; case ISN_UNPACK: { int count = iptr->isn_arg.unpack.unp_count; int semicolon = iptr->isn_arg.unpack.unp_semicolon; list_T *l; listitem_T *li; int i; // Check there is a valid list to unpack. tv = STACK_TV_BOT(-1); if (tv->v_type != VAR_LIST) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_for_argument_must_be_sequence_of_lists)); goto on_error; } l = tv->vval.v_list; if (l == NULL || l->lv_len < (semicolon ? count - 1 : count)) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_list_value_does_not_have_enough_items)); goto on_error; } else if (!semicolon && l->lv_len > count) { SOURCING_LNUM = iptr->isn_lnum; emsg(_(e_list_value_has_more_items_than_targets)); goto on_error; } CHECK_LIST_MATERIALIZE(l); if (GA_GROW(&ectx.ec_stack, count - 1) == FAIL) goto failed; ectx.ec_stack.ga_len += count - 1; // Variable after semicolon gets a list with the remaining // items. if (semicolon) { list_T *rem_list = list_alloc_with_items(l->lv_len - count + 1); if (rem_list == NULL) goto failed; tv = STACK_TV_BOT(-count); tv->vval.v_list = rem_list; ++rem_list->lv_refcount; tv->v_lock = 0; li = l->lv_first; for (i = 0; i < count - 1; ++i) li = li->li_next; for (i = 0; li != NULL; ++i) { list_set_item(rem_list, i, &li->li_tv); li = li->li_next; } --count; } // Produce the values in reverse order, first item last. li = l->lv_first; for (i = 0; i < count; ++i) { tv = STACK_TV_BOT(-i - 1); copy_tv(&li->li_tv, tv); li = li->li_next; } list_unref(l); } break; case ISN_SHUFFLE: { typval_T tmp_tv; int item = iptr->isn_arg.shuffle.shfl_item; int up = iptr->isn_arg.shuffle.shfl_up; tmp_tv = *STACK_TV_BOT(-item); for ( ; up > 0 && item > 1; --up) { *STACK_TV_BOT(-item) = *STACK_TV_BOT(-item + 1); --item; } *STACK_TV_BOT(-item) = tmp_tv; } break; case ISN_DROP: --ectx.ec_stack.ga_len; clear_tv(STACK_TV_BOT(0)); break; } continue; func_return: // Restore previous function. If the frame pointer is where we started // then there is none and we are done. if (ectx.ec_frame_idx == initial_frame_idx) goto done; if (func_return(&ectx) == FAIL) // only fails when out of memory goto failed; continue; on_error: // Jump here for an error that does not require aborting execution. // If "emsg_silent" is set then ignore the error, unless it was set // when calling the function. if (did_emsg_cumul + did_emsg == did_emsg_before && emsg_silent && did_emsg_def == 0) continue; on_fatal_error: // Jump here for an error that messes up the stack. // If we are not inside a try-catch started here, abort execution. if (trylevel <= trylevel_at_start) goto failed; } done: // function finished, get result from the stack. tv = STACK_TV_BOT(-1); *rettv = *tv; tv->v_type = VAR_UNKNOWN; ret = OK; failed: // When failed need to unwind the call stack. while (ectx.ec_frame_idx != initial_frame_idx) func_return(&ectx); // Deal with any remaining closures, they may be in use somewhere. if (ectx.ec_funcrefs.ga_len > 0) handle_closure_in_use(&ectx, FALSE); estack_pop(); current_sctx = save_current_sctx; if (*msg_list != NULL && saved_msg_list != NULL) { msglist_T **plist = saved_msg_list; // Append entries from the current msg_list (uncaught exceptions) to // the saved msg_list. while (*plist != NULL) plist = &(*plist)->next; *plist = *msg_list; } msg_list = saved_msg_list; if (restore_cmdmod) { cmdmod.cmod_filter_regmatch.regprog = NULL; undo_cmdmod(&cmdmod); cmdmod = save_cmdmod; } emsg_silent_def = save_emsg_silent_def; did_emsg_def += save_did_emsg_def; failed_early: // Free all local variables, but not arguments. for (idx = 0; idx < ectx.ec_stack.ga_len; ++idx) clear_tv(STACK_TV(idx)); vim_free(ectx.ec_stack.ga_data); vim_free(ectx.ec_trystack.ga_data); // Not sure if this is necessary. suppress_errthrow = save_suppress_errthrow; if (ret != OK && did_emsg_cumul + did_emsg == did_emsg_before) semsg(_(e_unknown_error_while_executing_str), printable_func_name(ufunc)); funcdepth_restore(orig_funcdepth); return ret; } /* * ":dissassemble". * We don't really need this at runtime, but we do have tests that require it, * so always include this. */ void ex_disassemble(exarg_T *eap) { char_u *arg = eap->arg; char_u *fname; ufunc_T *ufunc; dfunc_T *dfunc; isn_T *instr; int current; int line_idx = 0; int prev_current = 0; int is_global = FALSE; if (STRNCMP(arg, "<lambda>", 8) == 0) { arg += 8; (void)getdigits(&arg); fname = vim_strnsave(eap->arg, arg - eap->arg); } else fname = trans_function_name(&arg, &is_global, FALSE, TFN_INT | TFN_QUIET | TFN_NO_AUTOLOAD, NULL, NULL); if (fname == NULL) { semsg(_(e_invarg2), eap->arg); return; } ufunc = find_func(fname, is_global, NULL); if (ufunc == NULL) { char_u *p = untrans_function_name(fname); if (p != NULL) // Try again without making it script-local. ufunc = find_func(p, FALSE, NULL); } vim_free(fname); if (ufunc == NULL) { semsg(_(e_cannot_find_function_str), eap->arg); return; } if (ufunc->uf_def_status == UF_TO_BE_COMPILED && compile_def_function(ufunc, FALSE, NULL) == FAIL) return; if (ufunc->uf_def_status != UF_COMPILED) { semsg(_(e_function_is_not_compiled_str), eap->arg); return; } if (ufunc->uf_name_exp != NULL) msg((char *)ufunc->uf_name_exp); else msg((char *)ufunc->uf_name); dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; instr = dfunc->df_instr; for (current = 0; current < dfunc->df_instr_count; ++current) { isn_T *iptr = &instr[current]; char *line; while (line_idx < iptr->isn_lnum && line_idx < ufunc->uf_lines.ga_len) { if (current > prev_current) { msg_puts("\n\n"); prev_current = current; } line = ((char **)ufunc->uf_lines.ga_data)[line_idx++]; if (line != NULL) msg(line); } switch (iptr->isn_type) { case ISN_EXEC: smsg("%4d EXEC %s", current, iptr->isn_arg.string); break; case ISN_EXECCONCAT: smsg("%4d EXECCONCAT %lld", current, (long long)iptr->isn_arg.number); break; case ISN_ECHO: { echo_T *echo = &iptr->isn_arg.echo; smsg("%4d %s %d", current, echo->echo_with_white ? "ECHO" : "ECHON", echo->echo_count); } break; case ISN_EXECUTE: smsg("%4d EXECUTE %lld", current, (long long)(iptr->isn_arg.number)); break; case ISN_ECHOMSG: smsg("%4d ECHOMSG %lld", current, (long long)(iptr->isn_arg.number)); break; case ISN_ECHOERR: smsg("%4d ECHOERR %lld", current, (long long)(iptr->isn_arg.number)); break; case ISN_LOAD: case ISN_LOADOUTER: { char *add = iptr->isn_type == ISN_LOAD ? "" : "OUTER"; if (iptr->isn_arg.number < 0) smsg("%4d LOAD%s arg[%lld]", current, add, (long long)(iptr->isn_arg.number + STACK_FRAME_SIZE)); else smsg("%4d LOAD%s $%lld", current, add, (long long)(iptr->isn_arg.number)); } break; case ISN_LOADV: smsg("%4d LOADV v:%s", current, get_vim_var_name(iptr->isn_arg.number)); break; case ISN_LOADSCRIPT: { scriptitem_T *si = SCRIPT_ITEM(iptr->isn_arg.script.script_sid); svar_T *sv = ((svar_T *)si->sn_var_vals.ga_data) + iptr->isn_arg.script.script_idx; smsg("%4d LOADSCRIPT %s-%d from %s", current, sv->sv_name, iptr->isn_arg.script.script_idx, si->sn_name); } break; case ISN_LOADS: { scriptitem_T *si = SCRIPT_ITEM( iptr->isn_arg.loadstore.ls_sid); smsg("%4d LOADS s:%s from %s", current, iptr->isn_arg.loadstore.ls_name, si->sn_name); } break; case ISN_LOADG: smsg("%4d LOADG g:%s", current, iptr->isn_arg.string); break; case ISN_LOADB: smsg("%4d LOADB b:%s", current, iptr->isn_arg.string); break; case ISN_LOADW: smsg("%4d LOADW w:%s", current, iptr->isn_arg.string); break; case ISN_LOADT: smsg("%4d LOADT t:%s", current, iptr->isn_arg.string); break; case ISN_LOADGDICT: smsg("%4d LOAD g:", current); break; case ISN_LOADBDICT: smsg("%4d LOAD b:", current); break; case ISN_LOADWDICT: smsg("%4d LOAD w:", current); break; case ISN_LOADTDICT: smsg("%4d LOAD t:", current); break; case ISN_LOADOPT: smsg("%4d LOADOPT %s", current, iptr->isn_arg.string); break; case ISN_LOADENV: smsg("%4d LOADENV %s", current, iptr->isn_arg.string); break; case ISN_LOADREG: smsg("%4d LOADREG @%c", current, (int)(iptr->isn_arg.number)); break; case ISN_STORE: case ISN_STOREOUTER: { char *add = iptr->isn_type == ISN_STORE ? "" : "OUTER"; if (iptr->isn_arg.number < 0) smsg("%4d STORE%s arg[%lld]", current, add, (long long)(iptr->isn_arg.number + STACK_FRAME_SIZE)); else smsg("%4d STORE%s $%lld", current, add, (long long)(iptr->isn_arg.number)); } break; case ISN_STOREV: smsg("%4d STOREV v:%s", current, get_vim_var_name(iptr->isn_arg.number)); break; case ISN_STOREG: smsg("%4d STOREG %s", current, iptr->isn_arg.string); break; case ISN_STOREB: smsg("%4d STOREB %s", current, iptr->isn_arg.string); break; case ISN_STOREW: smsg("%4d STOREW %s", current, iptr->isn_arg.string); break; case ISN_STORET: smsg("%4d STORET %s", current, iptr->isn_arg.string); break; case ISN_STORES: { scriptitem_T *si = SCRIPT_ITEM( iptr->isn_arg.loadstore.ls_sid); smsg("%4d STORES %s in %s", current, iptr->isn_arg.loadstore.ls_name, si->sn_name); } break; case ISN_STORESCRIPT: { scriptitem_T *si = SCRIPT_ITEM(iptr->isn_arg.script.script_sid); svar_T *sv = ((svar_T *)si->sn_var_vals.ga_data) + iptr->isn_arg.script.script_idx; smsg("%4d STORESCRIPT %s-%d in %s", current, sv->sv_name, iptr->isn_arg.script.script_idx, si->sn_name); } break; case ISN_STOREOPT: smsg("%4d STOREOPT &%s", current, iptr->isn_arg.storeopt.so_name); break; case ISN_STOREENV: smsg("%4d STOREENV $%s", current, iptr->isn_arg.string); break; case ISN_STOREREG: smsg("%4d STOREREG @%c", current, (int)iptr->isn_arg.number); break; case ISN_STORENR: smsg("%4d STORE %lld in $%d", current, iptr->isn_arg.storenr.stnr_val, iptr->isn_arg.storenr.stnr_idx); break; case ISN_STORELIST: smsg("%4d STORELIST", current); break; case ISN_STOREDICT: smsg("%4d STOREDICT", current); break; // constants case ISN_PUSHNR: smsg("%4d PUSHNR %lld", current, (long long)(iptr->isn_arg.number)); break; case ISN_PUSHBOOL: case ISN_PUSHSPEC: smsg("%4d PUSH %s", current, get_var_special_name(iptr->isn_arg.number)); break; case ISN_PUSHF: #ifdef FEAT_FLOAT smsg("%4d PUSHF %g", current, iptr->isn_arg.fnumber); #endif break; case ISN_PUSHS: smsg("%4d PUSHS \"%s\"", current, iptr->isn_arg.string); break; case ISN_PUSHBLOB: { char_u *r; char_u numbuf[NUMBUFLEN]; char_u *tofree; r = blob2string(iptr->isn_arg.blob, &tofree, numbuf); smsg("%4d PUSHBLOB %s", current, r); vim_free(tofree); } break; case ISN_PUSHFUNC: { char *name = (char *)iptr->isn_arg.string; smsg("%4d PUSHFUNC \"%s\"", current, name == NULL ? "[none]" : name); } break; case ISN_PUSHCHANNEL: #ifdef FEAT_JOB_CHANNEL { channel_T *channel = iptr->isn_arg.channel; smsg("%4d PUSHCHANNEL %d", current, channel == NULL ? 0 : channel->ch_id); } #endif break; case ISN_PUSHJOB: #ifdef FEAT_JOB_CHANNEL { typval_T tv; char_u *name; tv.v_type = VAR_JOB; tv.vval.v_job = iptr->isn_arg.job; name = tv_get_string(&tv); smsg("%4d PUSHJOB \"%s\"", current, name); } #endif break; case ISN_PUSHEXC: smsg("%4d PUSH v:exception", current); break; case ISN_UNLET: smsg("%4d UNLET%s %s", current, iptr->isn_arg.unlet.ul_forceit ? "!" : "", iptr->isn_arg.unlet.ul_name); break; case ISN_UNLETENV: smsg("%4d UNLETENV%s $%s", current, iptr->isn_arg.unlet.ul_forceit ? "!" : "", iptr->isn_arg.unlet.ul_name); break; case ISN_LOCKCONST: smsg("%4d LOCKCONST", current); break; case ISN_NEWLIST: smsg("%4d NEWLIST size %lld", current, (long long)(iptr->isn_arg.number)); break; case ISN_NEWDICT: smsg("%4d NEWDICT size %lld", current, (long long)(iptr->isn_arg.number)); break; // function call case ISN_BCALL: { cbfunc_T *cbfunc = &iptr->isn_arg.bfunc; smsg("%4d BCALL %s(argc %d)", current, internal_func_name(cbfunc->cbf_idx), cbfunc->cbf_argcount); } break; case ISN_DCALL: { cdfunc_T *cdfunc = &iptr->isn_arg.dfunc; dfunc_T *df = ((dfunc_T *)def_functions.ga_data) + cdfunc->cdf_idx; smsg("%4d DCALL %s(argc %d)", current, df->df_ufunc->uf_name_exp != NULL ? df->df_ufunc->uf_name_exp : df->df_ufunc->uf_name, cdfunc->cdf_argcount); } break; case ISN_UCALL: { cufunc_T *cufunc = &iptr->isn_arg.ufunc; smsg("%4d UCALL %s(argc %d)", current, cufunc->cuf_name, cufunc->cuf_argcount); } break; case ISN_PCALL: { cpfunc_T *cpfunc = &iptr->isn_arg.pfunc; smsg("%4d PCALL%s (argc %d)", current, cpfunc->cpf_top ? " top" : "", cpfunc->cpf_argcount); } break; case ISN_PCALL_END: smsg("%4d PCALL end", current); break; case ISN_RETURN: smsg("%4d RETURN", current); break; case ISN_FUNCREF: { funcref_T *funcref = &iptr->isn_arg.funcref; dfunc_T *df = ((dfunc_T *)def_functions.ga_data) + funcref->fr_func; smsg("%4d FUNCREF %s", current, df->df_ufunc->uf_name); } break; case ISN_NEWFUNC: { newfunc_T *newfunc = &iptr->isn_arg.newfunc; smsg("%4d NEWFUNC %s %s", current, newfunc->nf_lambda, newfunc->nf_global); } break; case ISN_DEF: { char_u *name = iptr->isn_arg.string; smsg("%4d DEF %s", current, name == NULL ? (char_u *)"" : name); } break; case ISN_JUMP: { char *when = "?"; switch (iptr->isn_arg.jump.jump_when) { case JUMP_ALWAYS: when = "JUMP"; break; case JUMP_AND_KEEP_IF_TRUE: when = "JUMP_AND_KEEP_IF_TRUE"; break; case JUMP_IF_FALSE: when = "JUMP_IF_FALSE"; break; case JUMP_AND_KEEP_IF_FALSE: when = "JUMP_AND_KEEP_IF_FALSE"; break; case JUMP_IF_COND_FALSE: when = "JUMP_IF_COND_FALSE"; break; case JUMP_IF_COND_TRUE: when = "JUMP_IF_COND_TRUE"; break; } smsg("%4d %s -> %d", current, when, iptr->isn_arg.jump.jump_where); } break; case ISN_FOR: { forloop_T *forloop = &iptr->isn_arg.forloop; smsg("%4d FOR $%d -> %d", current, forloop->for_idx, forloop->for_end); } break; case ISN_TRY: { try_T *try = &iptr->isn_arg.try; smsg("%4d TRY catch -> %d, finally -> %d", current, try->try_catch, try->try_finally); } break; case ISN_CATCH: // TODO smsg("%4d CATCH", current); break; case ISN_ENDTRY: smsg("%4d ENDTRY", current); break; case ISN_THROW: smsg("%4d THROW", current); break; // expression operations on number case ISN_OPNR: case ISN_OPFLOAT: case ISN_OPANY: { char *what; char *ins; switch (iptr->isn_arg.op.op_type) { case EXPR_MULT: what = "*"; break; case EXPR_DIV: what = "/"; break; case EXPR_REM: what = "%"; break; case EXPR_SUB: what = "-"; break; case EXPR_ADD: what = "+"; break; default: what = "???"; break; } switch (iptr->isn_type) { case ISN_OPNR: ins = "OPNR"; break; case ISN_OPFLOAT: ins = "OPFLOAT"; break; case ISN_OPANY: ins = "OPANY"; break; default: ins = "???"; break; } smsg("%4d %s %s", current, ins, what); } break; case ISN_COMPAREBOOL: case ISN_COMPARESPECIAL: case ISN_COMPARENR: case ISN_COMPAREFLOAT: case ISN_COMPARESTRING: case ISN_COMPAREBLOB: case ISN_COMPARELIST: case ISN_COMPAREDICT: case ISN_COMPAREFUNC: case ISN_COMPAREANY: { char *p; char buf[10]; char *type; switch (iptr->isn_arg.op.op_type) { case EXPR_EQUAL: p = "=="; break; case EXPR_NEQUAL: p = "!="; break; case EXPR_GREATER: p = ">"; break; case EXPR_GEQUAL: p = ">="; break; case EXPR_SMALLER: p = "<"; break; case EXPR_SEQUAL: p = "<="; break; case EXPR_MATCH: p = "=~"; break; case EXPR_IS: p = "is"; break; case EXPR_ISNOT: p = "isnot"; break; case EXPR_NOMATCH: p = "!~"; break; default: p = "???"; break; } STRCPY(buf, p); if (iptr->isn_arg.op.op_ic == TRUE) strcat(buf, "?"); switch(iptr->isn_type) { case ISN_COMPAREBOOL: type = "COMPAREBOOL"; break; case ISN_COMPARESPECIAL: type = "COMPARESPECIAL"; break; case ISN_COMPARENR: type = "COMPARENR"; break; case ISN_COMPAREFLOAT: type = "COMPAREFLOAT"; break; case ISN_COMPARESTRING: type = "COMPARESTRING"; break; case ISN_COMPAREBLOB: type = "COMPAREBLOB"; break; case ISN_COMPARELIST: type = "COMPARELIST"; break; case ISN_COMPAREDICT: type = "COMPAREDICT"; break; case ISN_COMPAREFUNC: type = "COMPAREFUNC"; break; case ISN_COMPAREANY: type = "COMPAREANY"; break; default: type = "???"; break; } smsg("%4d %s %s", current, type, buf); } break; case ISN_ADDLIST: smsg("%4d ADDLIST", current); break; case ISN_ADDBLOB: smsg("%4d ADDBLOB", current); break; // expression operations case ISN_CONCAT: smsg("%4d CONCAT", current); break; case ISN_STRINDEX: smsg("%4d STRINDEX", current); break; case ISN_STRSLICE: smsg("%4d STRSLICE", current); break; case ISN_LISTAPPEND: smsg("%4d LISTAPPEND", current); break; case ISN_BLOBAPPEND: smsg("%4d BLOBAPPEND", current); break; case ISN_LISTINDEX: smsg("%4d LISTINDEX", current); break; case ISN_LISTSLICE: smsg("%4d LISTSLICE", current); break; case ISN_ANYINDEX: smsg("%4d ANYINDEX", current); break; case ISN_ANYSLICE: smsg("%4d ANYSLICE", current); break; case ISN_SLICE: smsg("%4d SLICE %lld", current, iptr->isn_arg.number); break; case ISN_GETITEM: smsg("%4d ITEM %lld", current, iptr->isn_arg.number); break; case ISN_MEMBER: smsg("%4d MEMBER", current); break; case ISN_STRINGMEMBER: smsg("%4d MEMBER %s", current, iptr->isn_arg.string); break; case ISN_NEGATENR: smsg("%4d NEGATENR", current); break; case ISN_CHECKNR: smsg("%4d CHECKNR", current); break; case ISN_CHECKTYPE: { char *tofree; smsg("%4d CHECKTYPE %s stack[%d]", current, type_name(iptr->isn_arg.type.ct_type, &tofree), iptr->isn_arg.type.ct_off); vim_free(tofree); break; } case ISN_CHECKLEN: smsg("%4d CHECKLEN %s%d", current, iptr->isn_arg.checklen.cl_more_OK ? ">= " : "", iptr->isn_arg.checklen.cl_min_len); break; case ISN_COND2BOOL: smsg("%4d COND2BOOL", current); break; case ISN_2BOOL: if (iptr->isn_arg.number) smsg("%4d INVERT (!val)", current); else smsg("%4d 2BOOL (!!val)", current); break; case ISN_2STRING: smsg("%4d 2STRING stack[%lld]", current, (long long)(iptr->isn_arg.number)); break; case ISN_2STRING_ANY: smsg("%4d 2STRING_ANY stack[%lld]", current, (long long)(iptr->isn_arg.number)); break; case ISN_RANGE: smsg("%4d RANGE %s", current, iptr->isn_arg.string); break; case ISN_PUT: if (iptr->isn_arg.put.put_lnum == LNUM_VARIABLE_RANGE_ABOVE) smsg("%4d PUT %c above range", current, iptr->isn_arg.put.put_regname); else if (iptr->isn_arg.put.put_lnum == LNUM_VARIABLE_RANGE) smsg("%4d PUT %c range", current, iptr->isn_arg.put.put_regname); else smsg("%4d PUT %c %ld", current, iptr->isn_arg.put.put_regname, (long)iptr->isn_arg.put.put_lnum); break; // TODO: summarize modifiers case ISN_CMDMOD: { char_u *buf; size_t len = produce_cmdmods( NULL, iptr->isn_arg.cmdmod.cf_cmdmod, FALSE); buf = alloc(len + 1); if (buf != NULL) { (void)produce_cmdmods( buf, iptr->isn_arg.cmdmod.cf_cmdmod, FALSE); smsg("%4d CMDMOD %s", current, buf); vim_free(buf); } break; } case ISN_CMDMOD_REV: smsg("%4d CMDMOD_REV", current); break; case ISN_UNPACK: smsg("%4d UNPACK %d%s", current, iptr->isn_arg.unpack.unp_count, iptr->isn_arg.unpack.unp_semicolon ? " semicolon" : ""); break; case ISN_SHUFFLE: smsg("%4d SHUFFLE %d up %d", current, iptr->isn_arg.shuffle.shfl_item, iptr->isn_arg.shuffle.shfl_up); break; case ISN_DROP: smsg("%4d DROP", current); break; } out_flush(); // output one line at a time ui_breakcheck(); if (got_int) break; } } /* * Return TRUE when "tv" is not falsy: non-zero, non-empty string, non-empty * list, etc. Mostly like what JavaScript does, except that empty list and * empty dictionary are FALSE. */ int tv2bool(typval_T *tv) { switch (tv->v_type) { case VAR_NUMBER: return tv->vval.v_number != 0; case VAR_FLOAT: #ifdef FEAT_FLOAT return tv->vval.v_float != 0.0; #else break; #endif case VAR_PARTIAL: return tv->vval.v_partial != NULL; case VAR_FUNC: case VAR_STRING: return tv->vval.v_string != NULL && *tv->vval.v_string != NUL; case VAR_LIST: return tv->vval.v_list != NULL && tv->vval.v_list->lv_len > 0; case VAR_DICT: return tv->vval.v_dict != NULL && tv->vval.v_dict->dv_hashtab.ht_used > 0; case VAR_BOOL: case VAR_SPECIAL: return tv->vval.v_number == VVAL_TRUE ? TRUE : FALSE; case VAR_JOB: #ifdef FEAT_JOB_CHANNEL return tv->vval.v_job != NULL; #else break; #endif case VAR_CHANNEL: #ifdef FEAT_JOB_CHANNEL return tv->vval.v_channel != NULL; #else break; #endif case VAR_BLOB: return tv->vval.v_blob != NULL && tv->vval.v_blob->bv_ga.ga_len > 0; case VAR_UNKNOWN: case VAR_ANY: case VAR_VOID: break; } return FALSE; } void emsg_using_string_as(typval_T *tv, int as_number) { semsg(_(as_number ? e_using_string_as_number_str : e_using_string_as_bool_str), tv->vval.v_string == NULL ? (char_u *)"" : tv->vval.v_string); } /* * If "tv" is a string give an error and return FAIL. */ int check_not_string(typval_T *tv) { if (tv->v_type == VAR_STRING) { emsg_using_string_as(tv, TRUE); clear_tv(tv); return FAIL; } return OK; } #endif // FEAT_EVAL