Mercurial > vim
view src/vim9compile.c @ 23701:c5b5e7520fe2 v8.2.2392
patch 8.2.2392: fennel filetype not recognized
Commit: https://github.com/vim/vim/commit/402115f1c2b4d0704a822206f2e6e931e721c129
Author: Bram Moolenaar <Bram@vim.org>
Date: Fri Jan 22 20:55:04 2021 +0100
patch 8.2.2392: fennel filetype not recognized
Problem: Fennel filetype not recognized.
Solution: Detect with pattern and hashbang. (Chinmay Dalal, closes https://github.com/vim/vim/issues/7729)
author | Bram Moolenaar <Bram@vim.org> |
---|---|
date | Fri, 22 Jan 2021 21:00:06 +0100 |
parents | 19073a768852 |
children | e3720756acdc |
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. */ /* * vim9compile.c: :def and dealing with instructions */ #define USING_FLOAT_STUFF #include "vim.h" #if defined(FEAT_EVAL) || defined(PROTO) #ifdef VMS # include <float.h> #endif #define DEFINE_VIM9_GLOBALS #include "vim9.h" // values for ctx_skip typedef enum { SKIP_NOT, // condition is a constant, produce code SKIP_YES, // condition is a constant, do NOT produce code SKIP_UNKNOWN // condition is not a constant, produce code } skip_T; /* * Chain of jump instructions where the end label needs to be set. */ typedef struct endlabel_S endlabel_T; struct endlabel_S { endlabel_T *el_next; // chain end_label locations int el_end_label; // instruction idx where to set end }; /* * info specific for the scope of :if / elseif / else */ typedef struct { int is_seen_else; int is_had_return; // every block ends in :return int is_if_label; // instruction idx at IF or ELSEIF endlabel_T *is_end_label; // instructions to set end label } ifscope_T; /* * info specific for the scope of :while */ typedef struct { int ws_top_label; // instruction idx at WHILE endlabel_T *ws_end_label; // instructions to set end } whilescope_T; /* * info specific for the scope of :for */ typedef struct { int fs_top_label; // instruction idx at FOR endlabel_T *fs_end_label; // break instructions } forscope_T; /* * info specific for the scope of :try */ typedef struct { int ts_try_label; // instruction idx at TRY endlabel_T *ts_end_label; // jump to :finally or :endtry int ts_catch_label; // instruction idx of last CATCH int ts_caught_all; // "catch" without argument encountered } tryscope_T; typedef enum { NO_SCOPE, IF_SCOPE, WHILE_SCOPE, FOR_SCOPE, TRY_SCOPE, BLOCK_SCOPE } scopetype_T; /* * Info for one scope, pointed to by "ctx_scope". */ typedef struct scope_S scope_T; struct scope_S { scope_T *se_outer; // scope containing this one scopetype_T se_type; int se_local_count; // ctx_locals.ga_len before scope skip_T se_skip_save; // ctx_skip before the block union { ifscope_T se_if; whilescope_T se_while; forscope_T se_for; tryscope_T se_try; } se_u; }; /* * Entry for "ctx_locals". Used for arguments and local variables. */ typedef struct { char_u *lv_name; type_T *lv_type; int lv_idx; // index of the variable on the stack int lv_from_outer; // nesting level, using ctx_outer scope int lv_const; // when TRUE cannot be assigned to int lv_arg; // when TRUE this is an argument } lvar_T; /* * Context for compiling lines of Vim script. * Stores info about the local variables and condition stack. */ struct cctx_S { ufunc_T *ctx_ufunc; // current function int ctx_lnum; // line number in current function char_u *ctx_line_start; // start of current line or NULL garray_T ctx_instr; // generated instructions garray_T ctx_locals; // currently visible local variables int ctx_locals_count; // total number of local variables int ctx_has_closure; // set to one if a closures was created in // the function garray_T ctx_imports; // imported items skip_T ctx_skip; scope_T *ctx_scope; // current scope, NULL at toplevel int ctx_had_return; // last seen statement was "return" cctx_T *ctx_outer; // outer scope for lambda or nested // function int ctx_outer_used; // var in ctx_outer was used garray_T ctx_type_stack; // type of each item on the stack garray_T *ctx_type_list; // list of pointers to allocated types int ctx_has_cmdmod; // ISN_CMDMOD was generated }; static void delete_def_function_contents(dfunc_T *dfunc, int mark_deleted); /* * Lookup variable "name" in the local scope and return it in "lvar". * "lvar->lv_from_outer" is incremented accordingly. * If "lvar" is NULL only check if the variable can be found. * Return FAIL if not found. */ static int lookup_local(char_u *name, size_t len, lvar_T *lvar, cctx_T *cctx) { int idx; lvar_T *lvp; if (len == 0) return FAIL; // Find local in current function scope. for (idx = 0; idx < cctx->ctx_locals.ga_len; ++idx) { lvp = ((lvar_T *)cctx->ctx_locals.ga_data) + idx; if (STRNCMP(name, lvp->lv_name, len) == 0 && STRLEN(lvp->lv_name) == len) { if (lvar != NULL) { *lvar = *lvp; lvar->lv_from_outer = 0; } return OK; } } // Find local in outer function scope. if (cctx->ctx_outer != NULL) { if (lookup_local(name, len, lvar, cctx->ctx_outer) == OK) { if (lvar != NULL) { cctx->ctx_outer_used = TRUE; ++lvar->lv_from_outer; } return OK; } } return FAIL; } /* * Lookup an argument in the current function and an enclosing function. * Returns the argument index in "idxp" * Returns the argument type in "type" * Sets "gen_load_outer" to TRUE if found in outer scope. * Returns OK when found, FAIL otherwise. */ static int arg_exists( char_u *name, size_t len, int *idxp, type_T **type, int *gen_load_outer, cctx_T *cctx) { int idx; char_u *va_name; if (len == 0) return FAIL; for (idx = 0; idx < cctx->ctx_ufunc->uf_args.ga_len; ++idx) { char_u *arg = FUNCARG(cctx->ctx_ufunc, idx); if (STRNCMP(name, arg, len) == 0 && arg[len] == NUL) { if (idxp != NULL) { // Arguments are located above the frame pointer. One further // if there is a vararg argument *idxp = idx - (cctx->ctx_ufunc->uf_args.ga_len + STACK_FRAME_SIZE) + (cctx->ctx_ufunc->uf_va_name != NULL ? -1 : 0); if (cctx->ctx_ufunc->uf_arg_types != NULL) *type = cctx->ctx_ufunc->uf_arg_types[idx]; else *type = &t_any; } return OK; } } va_name = cctx->ctx_ufunc->uf_va_name; if (va_name != NULL && STRNCMP(name, va_name, len) == 0 && va_name[len] == NUL) { if (idxp != NULL) { // varargs is always the last argument *idxp = -STACK_FRAME_SIZE - 1; *type = cctx->ctx_ufunc->uf_va_type; } return OK; } if (cctx->ctx_outer != NULL) { // Lookup the name for an argument of the outer function. if (arg_exists(name, len, idxp, type, gen_load_outer, cctx->ctx_outer) == OK) { ++*gen_load_outer; return OK; } } return FAIL; } /* * Lookup a script-local variable in the current script, possibly defined in a * block that contains the function "cctx->ctx_ufunc". * "cctx" is NULL at the script level. * if "len" is <= 0 "name" must be NUL terminated. * Return NULL when not found. */ static sallvar_T * find_script_var(char_u *name, size_t len, cctx_T *cctx) { scriptitem_T *si = SCRIPT_ITEM(current_sctx.sc_sid); hashitem_T *hi; int cc; sallvar_T *sav; ufunc_T *ufunc; // Find the list of all script variables with the right name. if (len > 0) { cc = name[len]; name[len] = NUL; } hi = hash_find(&si->sn_all_vars.dv_hashtab, name); if (len > 0) name[len] = cc; if (HASHITEM_EMPTY(hi)) return NULL; sav = HI2SAV(hi); if (sav->sav_block_id == 0 || cctx == NULL) // variable defined in the script scope or not in a function. return sav; // Go over the variables with this name and find one that was visible // from the function. ufunc = cctx->ctx_ufunc; while (sav != NULL) { int idx; // Go over the blocks that this function was defined in. If the // variable block ID matches it was visible to the function. for (idx = 0; idx < ufunc->uf_block_depth; ++idx) if (ufunc->uf_block_ids[idx] == sav->sav_block_id) return sav; sav = sav->sav_next; } return NULL; } /* * Return TRUE if the script context is Vim9 script. */ static int script_is_vim9() { return SCRIPT_ITEM(current_sctx.sc_sid)->sn_version == SCRIPT_VERSION_VIM9; } /* * Lookup a variable (without s: prefix) in the current script. * If "vim9script" is TRUE the script must be Vim9 script. Used for "var" * without "s:". * "cctx" is NULL at the script level. * Returns OK or FAIL. */ static int script_var_exists(char_u *name, size_t len, int vim9script, cctx_T *cctx) { int is_vim9_script; if (current_sctx.sc_sid <= 0) return FAIL; is_vim9_script = script_is_vim9(); if (vim9script && !is_vim9_script) return FAIL; if (is_vim9_script) { // Check script variables that were visible where the function was // defined. if (find_script_var(name, len, cctx) != NULL) return OK; } else { hashtab_T *ht = &SCRIPT_VARS(current_sctx.sc_sid); dictitem_T *di; int cc; // Check script variables that are currently visible cc = name[len]; name[len] = NUL; di = find_var_in_ht(ht, 0, name, TRUE); name[len] = cc; if (di != NULL) return OK; } return FAIL; } /* * Check if "p[len]" is already defined, either in script "import_sid" or in * compilation context "cctx". "cctx" is NULL at the script level. * Does not check the global namespace. * Return FAIL and give an error if it defined. */ int check_defined(char_u *p, size_t len, cctx_T *cctx) { int c = p[len]; ufunc_T *ufunc = NULL; p[len] = NUL; if (script_var_exists(p, len, FALSE, cctx) == OK || (cctx != NULL && (lookup_local(p, len, NULL, cctx) == OK || arg_exists(p, len, NULL, NULL, NULL, cctx) == OK)) || find_imported(p, len, cctx) != NULL || (ufunc = find_func_even_dead(p, FALSE, cctx)) != NULL) { // A local or script-local function can shadow a global function. if (ufunc == NULL || !func_is_global(ufunc) || (p[0] == 'g' && p[1] == ':')) { p[len] = c; semsg(_(e_name_already_defined_str), p); return FAIL; } } p[len] = c; return OK; } ///////////////////////////////////////////////////////////////////// // Following generate_ functions expect the caller to call ga_grow(). #define RETURN_NULL_IF_SKIP(cctx) if (cctx->ctx_skip == SKIP_YES) return NULL #define RETURN_OK_IF_SKIP(cctx) if (cctx->ctx_skip == SKIP_YES) return OK /* * Generate an instruction without arguments. * Returns a pointer to the new instruction, NULL if failed. */ static isn_T * generate_instr(cctx_T *cctx, isntype_T isn_type) { garray_T *instr = &cctx->ctx_instr; isn_T *isn; RETURN_NULL_IF_SKIP(cctx); if (ga_grow(instr, 1) == FAIL) return NULL; isn = ((isn_T *)instr->ga_data) + instr->ga_len; isn->isn_type = isn_type; isn->isn_lnum = cctx->ctx_lnum + 1; ++instr->ga_len; return isn; } /* * Generate an instruction without arguments. * "drop" will be removed from the stack. * Returns a pointer to the new instruction, NULL if failed. */ static isn_T * generate_instr_drop(cctx_T *cctx, isntype_T isn_type, int drop) { garray_T *stack = &cctx->ctx_type_stack; RETURN_NULL_IF_SKIP(cctx); stack->ga_len -= drop; return generate_instr(cctx, isn_type); } /* * Generate instruction "isn_type" and put "type" on the type stack. */ static isn_T * generate_instr_type(cctx_T *cctx, isntype_T isn_type, type_T *type) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; if ((isn = generate_instr(cctx, isn_type)) == NULL) return NULL; if (ga_grow(stack, 1) == FAIL) return NULL; ((type_T **)stack->ga_data)[stack->ga_len] = type == NULL ? &t_any : type; ++stack->ga_len; return isn; } /* * If type at "offset" isn't already VAR_STRING then generate ISN_2STRING. * But only for simple types. */ static int may_generate_2STRING(int offset, cctx_T *cctx) { isn_T *isn; isntype_T isntype = ISN_2STRING; garray_T *stack = &cctx->ctx_type_stack; type_T **type; RETURN_OK_IF_SKIP(cctx); type = ((type_T **)stack->ga_data) + stack->ga_len + offset; switch ((*type)->tt_type) { // nothing to be done case VAR_STRING: return OK; // conversion possible case VAR_SPECIAL: case VAR_BOOL: case VAR_NUMBER: case VAR_FLOAT: break; // conversion possible (with runtime check) case VAR_ANY: case VAR_UNKNOWN: isntype = ISN_2STRING_ANY; break; // conversion not possible case VAR_VOID: case VAR_BLOB: case VAR_FUNC: case VAR_PARTIAL: case VAR_LIST: case VAR_DICT: case VAR_JOB: case VAR_CHANNEL: to_string_error((*type)->tt_type); return FAIL; } *type = &t_string; if ((isn = generate_instr(cctx, isntype)) == NULL) return FAIL; isn->isn_arg.number = offset; return OK; } static int check_number_or_float(vartype_T type1, vartype_T type2, char_u *op) { if (!((type1 == VAR_NUMBER || type1 == VAR_FLOAT || type1 == VAR_ANY) && (type2 == VAR_NUMBER || type2 == VAR_FLOAT || type2 == VAR_ANY))) { if (*op == '+') emsg(_(e_wrong_argument_type_for_plus)); else semsg(_(e_char_requires_number_or_float_arguments), *op); return FAIL; } return OK; } static int generate_add_instr( cctx_T *cctx, vartype_T vartype, type_T *type1, type_T *type2) { garray_T *stack = &cctx->ctx_type_stack; isn_T *isn = generate_instr_drop(cctx, vartype == VAR_NUMBER ? ISN_OPNR : vartype == VAR_LIST ? ISN_ADDLIST : vartype == VAR_BLOB ? ISN_ADDBLOB #ifdef FEAT_FLOAT : vartype == VAR_FLOAT ? ISN_OPFLOAT #endif : ISN_OPANY, 1); if (vartype != VAR_LIST && vartype != VAR_BLOB && type1->tt_type != VAR_ANY && type2->tt_type != VAR_ANY && check_number_or_float( type1->tt_type, type2->tt_type, (char_u *)"+") == FAIL) return FAIL; if (isn != NULL) isn->isn_arg.op.op_type = EXPR_ADD; // When concatenating two lists with different member types the member type // becomes "any". if (vartype == VAR_LIST && type1->tt_type == VAR_LIST && type2->tt_type == VAR_LIST && type1->tt_member != type2->tt_member) (((type_T **)stack->ga_data)[stack->ga_len - 1]) = &t_list_any; return isn == NULL ? FAIL : OK; } /* * Get the type to use for an instruction for an operation on "type1" and * "type2". If they are matching use a type-specific instruction. Otherwise * fall back to runtime type checking. */ static vartype_T operator_type(type_T *type1, type_T *type2) { if (type1->tt_type == type2->tt_type && (type1->tt_type == VAR_NUMBER || type1->tt_type == VAR_LIST #ifdef FEAT_FLOAT || type1->tt_type == VAR_FLOAT #endif || type1->tt_type == VAR_BLOB)) return type1->tt_type; return VAR_ANY; } /* * Generate an instruction with two arguments. The instruction depends on the * type of the arguments. */ static int generate_two_op(cctx_T *cctx, char_u *op) { garray_T *stack = &cctx->ctx_type_stack; type_T *type1; type_T *type2; vartype_T vartype; isn_T *isn; RETURN_OK_IF_SKIP(cctx); // Get the known type of the two items on the stack. type1 = ((type_T **)stack->ga_data)[stack->ga_len - 2]; type2 = ((type_T **)stack->ga_data)[stack->ga_len - 1]; vartype = operator_type(type1, type2); switch (*op) { case '+': if (generate_add_instr(cctx, vartype, type1, type2) == FAIL) return FAIL; break; case '-': case '*': case '/': if (check_number_or_float(type1->tt_type, type2->tt_type, op) == FAIL) return FAIL; if (vartype == VAR_NUMBER) isn = generate_instr_drop(cctx, ISN_OPNR, 1); #ifdef FEAT_FLOAT else if (vartype == VAR_FLOAT) isn = generate_instr_drop(cctx, ISN_OPFLOAT, 1); #endif else isn = generate_instr_drop(cctx, ISN_OPANY, 1); if (isn != NULL) isn->isn_arg.op.op_type = *op == '*' ? EXPR_MULT : *op == '/'? EXPR_DIV : EXPR_SUB; break; case '%': if ((type1->tt_type != VAR_ANY && type1->tt_type != VAR_NUMBER) || (type2->tt_type != VAR_ANY && type2->tt_type != VAR_NUMBER)) { emsg(_(e_percent_requires_number_arguments)); return FAIL; } isn = generate_instr_drop(cctx, vartype == VAR_NUMBER ? ISN_OPNR : ISN_OPANY, 1); if (isn != NULL) isn->isn_arg.op.op_type = EXPR_REM; break; } // correct type of result if (vartype == VAR_ANY) { type_T *type = &t_any; #ifdef FEAT_FLOAT // float+number and number+float results in float if ((type1->tt_type == VAR_NUMBER || type1->tt_type == VAR_FLOAT) && (type2->tt_type == VAR_NUMBER || type2->tt_type == VAR_FLOAT)) type = &t_float; #endif ((type_T **)stack->ga_data)[stack->ga_len - 1] = type; } return OK; } /* * Get the instruction to use for comparing "type1" with "type2" * Return ISN_DROP when failed. */ static isntype_T get_compare_isn(exprtype_T exprtype, vartype_T type1, vartype_T type2) { isntype_T isntype = ISN_DROP; if (type1 == VAR_UNKNOWN) type1 = VAR_ANY; if (type2 == VAR_UNKNOWN) type2 = VAR_ANY; if (type1 == type2) { switch (type1) { case VAR_BOOL: isntype = ISN_COMPAREBOOL; break; case VAR_SPECIAL: isntype = ISN_COMPARESPECIAL; break; case VAR_NUMBER: isntype = ISN_COMPARENR; break; case VAR_FLOAT: isntype = ISN_COMPAREFLOAT; break; case VAR_STRING: isntype = ISN_COMPARESTRING; break; case VAR_BLOB: isntype = ISN_COMPAREBLOB; break; case VAR_LIST: isntype = ISN_COMPARELIST; break; case VAR_DICT: isntype = ISN_COMPAREDICT; break; case VAR_FUNC: isntype = ISN_COMPAREFUNC; break; default: isntype = ISN_COMPAREANY; break; } } else if (type1 == VAR_ANY || type2 == VAR_ANY || ((type1 == VAR_NUMBER || type1 == VAR_FLOAT) && (type2 == VAR_NUMBER || type2 ==VAR_FLOAT))) isntype = ISN_COMPAREANY; if ((exprtype == EXPR_IS || exprtype == EXPR_ISNOT) && (isntype == ISN_COMPAREBOOL || isntype == ISN_COMPARESPECIAL || isntype == ISN_COMPARENR || isntype == ISN_COMPAREFLOAT)) { semsg(_(e_cannot_use_str_with_str), exprtype == EXPR_IS ? "is" : "isnot" , vartype_name(type1)); return ISN_DROP; } if (isntype == ISN_DROP || ((exprtype != EXPR_EQUAL && exprtype != EXPR_NEQUAL && (type1 == VAR_BOOL || type1 == VAR_SPECIAL || type2 == VAR_BOOL || type2 == VAR_SPECIAL))) || ((exprtype != EXPR_EQUAL && exprtype != EXPR_NEQUAL && exprtype != EXPR_IS && exprtype != EXPR_ISNOT && (type1 == VAR_BLOB || type2 == VAR_BLOB || type1 == VAR_LIST || type2 == VAR_LIST)))) { semsg(_(e_cannot_compare_str_with_str), vartype_name(type1), vartype_name(type2)); return ISN_DROP; } return isntype; } int check_compare_types(exprtype_T type, typval_T *tv1, typval_T *tv2) { if (get_compare_isn(type, tv1->v_type, tv2->v_type) == ISN_DROP) return FAIL; return OK; } /* * Generate an ISN_COMPARE* instruction with a boolean result. */ static int generate_COMPARE(cctx_T *cctx, exprtype_T exprtype, int ic) { isntype_T isntype; isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; vartype_T type1; vartype_T type2; RETURN_OK_IF_SKIP(cctx); // Get the known type of the two items on the stack. If they are matching // use a type-specific instruction. Otherwise fall back to runtime type // checking. type1 = ((type_T **)stack->ga_data)[stack->ga_len - 2]->tt_type; type2 = ((type_T **)stack->ga_data)[stack->ga_len - 1]->tt_type; isntype = get_compare_isn(exprtype, type1, type2); if (isntype == ISN_DROP) return FAIL; if ((isn = generate_instr(cctx, isntype)) == NULL) return FAIL; isn->isn_arg.op.op_type = exprtype; isn->isn_arg.op.op_ic = ic; // takes two arguments, puts one bool back if (stack->ga_len >= 2) { --stack->ga_len; ((type_T **)stack->ga_data)[stack->ga_len - 1] = &t_bool; } return OK; } /* * Generate an ISN_2BOOL instruction. */ static int generate_2BOOL(cctx_T *cctx, int invert) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_2BOOL)) == NULL) return FAIL; isn->isn_arg.number = invert; // type becomes bool ((type_T **)stack->ga_data)[stack->ga_len - 1] = &t_bool; return OK; } /* * Generate an ISN_COND2BOOL instruction. */ static int generate_COND2BOOL(cctx_T *cctx) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_COND2BOOL)) == NULL) return FAIL; // type becomes bool ((type_T **)stack->ga_data)[stack->ga_len - 1] = &t_bool; return OK; } static int generate_TYPECHECK( cctx_T *cctx, type_T *expected, int offset, int argidx) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_CHECKTYPE)) == NULL) return FAIL; isn->isn_arg.type.ct_type = alloc_type(expected); isn->isn_arg.type.ct_off = (int8_T)offset; isn->isn_arg.type.ct_arg_idx = (int8_T)argidx; // type becomes expected ((type_T **)stack->ga_data)[stack->ga_len + offset] = expected; return OK; } static int generate_SETTYPE( cctx_T *cctx, type_T *expected) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_SETTYPE)) == NULL) return FAIL; isn->isn_arg.type.ct_type = alloc_type(expected); return OK; } /* * Return TRUE if "actual" could be "expected" and a runtime typecheck is to be * used. Return FALSE if the types will never match. */ int use_typecheck(type_T *actual, type_T *expected) { if (actual->tt_type == VAR_ANY || actual->tt_type == VAR_UNKNOWN || (actual->tt_type == VAR_FUNC && (expected->tt_type == VAR_FUNC || expected->tt_type == VAR_PARTIAL) && (actual->tt_member == &t_any || actual->tt_argcount < 0) && ((actual->tt_member == &t_void) == (expected->tt_member == &t_void)))) return TRUE; if ((actual->tt_type == VAR_LIST || actual->tt_type == VAR_DICT) && actual->tt_type == expected->tt_type) // This takes care of a nested list or dict. return use_typecheck(actual->tt_member, expected->tt_member); return FALSE; } /* * Check that * - "actual" matches "expected" type or * - "actual" is a type that can be "expected" type: add a runtime check; or * - return FAIL. * If "actual_is_const" is TRUE then the type won't change at runtime, do not * generate a TYPECHECK. */ int need_type( type_T *actual, type_T *expected, int offset, int arg_idx, cctx_T *cctx, int silent, int actual_is_const) { if (expected == &t_bool && actual != &t_bool && (actual->tt_flags & TTFLAG_BOOL_OK)) { // Using "0", "1" or the result of an expression with "&&" or "||" as a // boolean is OK but requires a conversion. generate_2BOOL(cctx, FALSE); return OK; } if (check_type(expected, actual, FALSE, arg_idx) == OK) return OK; // If the actual type can be the expected type add a runtime check. // If it's a constant a runtime check makes no sense. if (!actual_is_const && use_typecheck(actual, expected)) { generate_TYPECHECK(cctx, expected, offset, arg_idx); return OK; } if (!silent) arg_type_mismatch(expected, actual, arg_idx); return FAIL; } /* * Check that the top of the type stack has a type that can be used as a * condition. Give an error and return FAIL if not. */ static int bool_on_stack(cctx_T *cctx) { garray_T *stack = &cctx->ctx_type_stack; type_T *type; type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (type == &t_bool) return OK; if (type == &t_any || type == &t_number) // Number 0 and 1 are OK to use as a bool. "any" could also be a bool. // This requires a runtime type check. return generate_COND2BOOL(cctx); return need_type(type, &t_bool, -1, 0, cctx, FALSE, FALSE); } /* * Generate an ISN_PUSHNR instruction. */ static int generate_PUSHNR(cctx_T *cctx, varnumber_T number) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHNR, &t_number)) == NULL) return FAIL; isn->isn_arg.number = number; if (number == 0 || number == 1) // A 0 or 1 number can also be used as a bool. ((type_T **)stack->ga_data)[stack->ga_len - 1] = &t_number_bool; return OK; } /* * Generate an ISN_PUSHBOOL instruction. */ static int generate_PUSHBOOL(cctx_T *cctx, varnumber_T number) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHBOOL, &t_bool)) == NULL) return FAIL; isn->isn_arg.number = number; return OK; } /* * Generate an ISN_PUSHSPEC instruction. */ static int generate_PUSHSPEC(cctx_T *cctx, varnumber_T number) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHSPEC, &t_special)) == NULL) return FAIL; isn->isn_arg.number = number; return OK; } #ifdef FEAT_FLOAT /* * Generate an ISN_PUSHF instruction. */ static int generate_PUSHF(cctx_T *cctx, float_T fnumber) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHF, &t_float)) == NULL) return FAIL; isn->isn_arg.fnumber = fnumber; return OK; } #endif /* * Generate an ISN_PUSHS instruction. * Consumes "str". */ static int generate_PUSHS(cctx_T *cctx, char_u *str) { isn_T *isn; if (cctx->ctx_skip == SKIP_YES) { vim_free(str); return OK; } if ((isn = generate_instr_type(cctx, ISN_PUSHS, &t_string)) == NULL) return FAIL; isn->isn_arg.string = str; return OK; } /* * Generate an ISN_PUSHCHANNEL instruction. * Consumes "channel". */ static int generate_PUSHCHANNEL(cctx_T *cctx, channel_T *channel) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHCHANNEL, &t_channel)) == NULL) return FAIL; isn->isn_arg.channel = channel; return OK; } /* * Generate an ISN_PUSHJOB instruction. * Consumes "job". */ static int generate_PUSHJOB(cctx_T *cctx, job_T *job) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHJOB, &t_channel)) == NULL) return FAIL; isn->isn_arg.job = job; return OK; } /* * Generate an ISN_PUSHBLOB instruction. * Consumes "blob". */ static int generate_PUSHBLOB(cctx_T *cctx, blob_T *blob) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHBLOB, &t_blob)) == NULL) return FAIL; isn->isn_arg.blob = blob; return OK; } /* * Generate an ISN_PUSHFUNC instruction with name "name". * Consumes "name". */ static int generate_PUSHFUNC(cctx_T *cctx, char_u *name, type_T *type) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_PUSHFUNC, type)) == NULL) return FAIL; isn->isn_arg.string = name == NULL ? NULL : vim_strsave(name); return OK; } /* * Generate an ISN_GETITEM instruction with "index". */ static int generate_GETITEM(cctx_T *cctx, int index) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; type_T *type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; type_T *item_type = &t_any; RETURN_OK_IF_SKIP(cctx); if (type->tt_type != VAR_LIST) { // cannot happen, caller has checked the type emsg(_(e_listreq)); return FAIL; } item_type = type->tt_member; if ((isn = generate_instr(cctx, ISN_GETITEM)) == NULL) return FAIL; isn->isn_arg.number = index; // add the item type to the type stack if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = item_type; ++stack->ga_len; return OK; } /* * Generate an ISN_SLICE instruction with "count". */ static int generate_SLICE(cctx_T *cctx, int count) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_SLICE)) == NULL) return FAIL; isn->isn_arg.number = count; return OK; } /* * Generate an ISN_CHECKLEN instruction with "min_len". */ static int generate_CHECKLEN(cctx_T *cctx, int min_len, int more_OK) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_CHECKLEN)) == NULL) return FAIL; isn->isn_arg.checklen.cl_min_len = min_len; isn->isn_arg.checklen.cl_more_OK = more_OK; return OK; } /* * Generate an ISN_STORE instruction. */ static int generate_STORE(cctx_T *cctx, isntype_T isn_type, int idx, char_u *name) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_drop(cctx, isn_type, 1)) == NULL) return FAIL; if (name != NULL) isn->isn_arg.string = vim_strsave(name); else isn->isn_arg.number = idx; return OK; } /* * Generate an ISN_STOREOUTER instruction. */ static int generate_STOREOUTER(cctx_T *cctx, int idx, int level) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_drop(cctx, ISN_STOREOUTER, 1)) == NULL) return FAIL; isn->isn_arg.outer.outer_idx = idx; isn->isn_arg.outer.outer_depth = level; return OK; } /* * Generate an ISN_STORENR instruction (short for ISN_PUSHNR + ISN_STORE) */ static int generate_STORENR(cctx_T *cctx, int idx, varnumber_T value) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_STORENR)) == NULL) return FAIL; isn->isn_arg.storenr.stnr_idx = idx; isn->isn_arg.storenr.stnr_val = value; return OK; } /* * Generate an ISN_STOREOPT instruction */ static int generate_STOREOPT(cctx_T *cctx, char_u *name, int opt_flags) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_drop(cctx, ISN_STOREOPT, 1)) == NULL) return FAIL; isn->isn_arg.storeopt.so_name = vim_strsave(name); isn->isn_arg.storeopt.so_flags = opt_flags; return OK; } /* * Generate an ISN_LOAD or similar instruction. */ static int generate_LOAD( cctx_T *cctx, isntype_T isn_type, int idx, char_u *name, type_T *type) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, isn_type, type)) == NULL) return FAIL; if (name != NULL) isn->isn_arg.string = vim_strsave(name); else isn->isn_arg.number = idx; return OK; } /* * Generate an ISN_LOADOUTER instruction */ static int generate_LOADOUTER( cctx_T *cctx, int idx, int nesting, type_T *type) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_type(cctx, ISN_LOADOUTER, type)) == NULL) return FAIL; isn->isn_arg.outer.outer_idx = idx; isn->isn_arg.outer.outer_depth = nesting; return OK; } /* * Generate an ISN_LOADV instruction for v:var. */ static int generate_LOADV( cctx_T *cctx, char_u *name, int error) { int di_flags; int vidx = find_vim_var(name, &di_flags); type_T *type; RETURN_OK_IF_SKIP(cctx); if (vidx < 0) { if (error) semsg(_(e_variable_not_found_str), name); return FAIL; } type = typval2type_vimvar(get_vim_var_tv(vidx), cctx->ctx_type_list); return generate_LOAD(cctx, ISN_LOADV, vidx, NULL, type); } /* * Generate an ISN_UNLET instruction. */ static int generate_UNLET(cctx_T *cctx, isntype_T isn_type, char_u *name, int forceit) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, isn_type)) == NULL) return FAIL; isn->isn_arg.unlet.ul_name = vim_strsave(name); isn->isn_arg.unlet.ul_forceit = forceit; return OK; } /* * Generate an ISN_LOCKCONST instruction. */ static int generate_LOCKCONST(cctx_T *cctx) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_LOCKCONST)) == NULL) return FAIL; return OK; } /* * Generate an ISN_LOADS instruction. */ static int generate_OLDSCRIPT( cctx_T *cctx, isntype_T isn_type, char_u *name, int sid, type_T *type) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if (isn_type == ISN_LOADS) isn = generate_instr_type(cctx, isn_type, type); else isn = generate_instr_drop(cctx, isn_type, 1); if (isn == NULL) return FAIL; isn->isn_arg.loadstore.ls_name = vim_strsave(name); isn->isn_arg.loadstore.ls_sid = sid; return OK; } /* * Generate an ISN_LOADSCRIPT or ISN_STORESCRIPT instruction. */ static int generate_VIM9SCRIPT( cctx_T *cctx, isntype_T isn_type, int sid, int idx, type_T *type) { isn_T *isn; scriptref_T *sref; scriptitem_T *si = SCRIPT_ITEM(sid); RETURN_OK_IF_SKIP(cctx); if (isn_type == ISN_LOADSCRIPT) isn = generate_instr_type(cctx, isn_type, type); else isn = generate_instr_drop(cctx, isn_type, 1); if (isn == NULL) return FAIL; // This requires three arguments, which doesn't fit in an instruction, thus // we need to allocate a struct for this. sref = ALLOC_ONE(scriptref_T); if (sref == NULL) return FAIL; isn->isn_arg.script.scriptref = sref; sref->sref_sid = sid; sref->sref_idx = idx; sref->sref_seq = si->sn_script_seq; sref->sref_type = type; return OK; } /* * Generate an ISN_NEWLIST instruction. */ static int generate_NEWLIST(cctx_T *cctx, int count) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; type_T *type; type_T *member; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_NEWLIST)) == NULL) return FAIL; isn->isn_arg.number = count; // get the member type from all the items on the stack. if (count == 0) member = &t_void; else member = get_member_type_from_stack( ((type_T **)stack->ga_data) + stack->ga_len, count, 1, cctx->ctx_type_list); type = get_list_type(member, cctx->ctx_type_list); // drop the value types stack->ga_len -= count; // add the list type to the type stack if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = type; ++stack->ga_len; return OK; } /* * Generate an ISN_NEWDICT instruction. */ static int generate_NEWDICT(cctx_T *cctx, int count) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; type_T *type; type_T *member; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_NEWDICT)) == NULL) return FAIL; isn->isn_arg.number = count; if (count == 0) member = &t_void; else member = get_member_type_from_stack( ((type_T **)stack->ga_data) + stack->ga_len, count, 2, cctx->ctx_type_list); type = get_dict_type(member, cctx->ctx_type_list); // drop the key and value types stack->ga_len -= 2 * count; // add the dict type to the type stack if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = type; ++stack->ga_len; return OK; } /* * Generate an ISN_FUNCREF instruction. */ static int generate_FUNCREF(cctx_T *cctx, ufunc_T *ufunc) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_FUNCREF)) == NULL) return FAIL; isn->isn_arg.funcref.fr_func = ufunc->uf_dfunc_idx; cctx->ctx_has_closure = 1; // if the referenced function is a closure, it may use items further up in // the nested context, including this one. if (ufunc->uf_flags & FC_CLOSURE) cctx->ctx_ufunc->uf_flags |= FC_CLOSURE; if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = ufunc->uf_func_type == NULL ? &t_func_any : ufunc->uf_func_type; ++stack->ga_len; return OK; } /* * Generate an ISN_NEWFUNC instruction. * "lambda_name" and "func_name" must be in allocated memory and will be * consumed. */ static int generate_NEWFUNC(cctx_T *cctx, char_u *lambda_name, char_u *func_name) { isn_T *isn; if (cctx->ctx_skip == SKIP_YES) { vim_free(lambda_name); vim_free(func_name); return OK; } if ((isn = generate_instr(cctx, ISN_NEWFUNC)) == NULL) { vim_free(lambda_name); vim_free(func_name); return FAIL; } isn->isn_arg.newfunc.nf_lambda = lambda_name; isn->isn_arg.newfunc.nf_global = func_name; return OK; } /* * Generate an ISN_DEF instruction: list functions */ static int generate_DEF(cctx_T *cctx, char_u *name, size_t len) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_DEF)) == NULL) return FAIL; if (len > 0) { isn->isn_arg.string = vim_strnsave(name, len); if (isn->isn_arg.string == NULL) return FAIL; } return OK; } /* * Generate an ISN_JUMP instruction. */ static int generate_JUMP(cctx_T *cctx, jumpwhen_T when, int where) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_JUMP)) == NULL) return FAIL; isn->isn_arg.jump.jump_when = when; isn->isn_arg.jump.jump_where = where; if (when != JUMP_ALWAYS && stack->ga_len > 0) --stack->ga_len; return OK; } static int generate_FOR(cctx_T *cctx, int loop_idx) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_FOR)) == NULL) return FAIL; isn->isn_arg.forloop.for_idx = loop_idx; if (ga_grow(stack, 1) == FAIL) return FAIL; // type doesn't matter, will be stored next ((type_T **)stack->ga_data)[stack->ga_len] = &t_any; ++stack->ga_len; return OK; } /* * Generate an ISN_BCALL instruction. * "method_call" is TRUE for "value->method()" * Return FAIL if the number of arguments is wrong. */ static int generate_BCALL(cctx_T *cctx, int func_idx, int argcount, int method_call) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; int argoff; type_T **argtypes = NULL; type_T *maptype = NULL; RETURN_OK_IF_SKIP(cctx); argoff = check_internal_func(func_idx, argcount); if (argoff < 0) return FAIL; if (method_call && argoff > 1) { if ((isn = generate_instr(cctx, ISN_SHUFFLE)) == NULL) return FAIL; isn->isn_arg.shuffle.shfl_item = argcount; isn->isn_arg.shuffle.shfl_up = argoff - 1; } if (argcount > 0) { // Check the types of the arguments. argtypes = ((type_T **)stack->ga_data) + stack->ga_len - argcount; if (internal_func_check_arg_types(argtypes, func_idx, argcount, cctx) == FAIL) return FAIL; if (internal_func_is_map(func_idx)) maptype = *argtypes; } if ((isn = generate_instr(cctx, ISN_BCALL)) == NULL) return FAIL; isn->isn_arg.bfunc.cbf_idx = func_idx; isn->isn_arg.bfunc.cbf_argcount = argcount; // Drop the argument types and push the return type. stack->ga_len -= argcount; if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = internal_func_ret_type(func_idx, argcount, argtypes); ++stack->ga_len; if (maptype != NULL && maptype->tt_member != NULL && maptype->tt_member != &t_any) // Check that map() didn't change the item types. generate_TYPECHECK(cctx, maptype, -1, 1); return OK; } /* * Generate an ISN_LISTAPPEND instruction. Works like add(). * Argument count is already checked. */ static int generate_LISTAPPEND(cctx_T *cctx) { garray_T *stack = &cctx->ctx_type_stack; type_T *list_type; type_T *item_type; type_T *expected; // Caller already checked that list_type is a list. list_type = ((type_T **)stack->ga_data)[stack->ga_len - 2]; item_type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; expected = list_type->tt_member; if (need_type(item_type, expected, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; if (generate_instr(cctx, ISN_LISTAPPEND) == NULL) return FAIL; --stack->ga_len; // drop the argument return OK; } /* * Generate an ISN_BLOBAPPEND instruction. Works like add(). * Argument count is already checked. */ static int generate_BLOBAPPEND(cctx_T *cctx) { garray_T *stack = &cctx->ctx_type_stack; type_T *item_type; // Caller already checked that blob_type is a blob. item_type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (need_type(item_type, &t_number, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; if (generate_instr(cctx, ISN_BLOBAPPEND) == NULL) return FAIL; --stack->ga_len; // drop the argument return OK; } /* * Generate an ISN_DCALL or ISN_UCALL instruction. * Return FAIL if the number of arguments is wrong. */ static int generate_CALL(cctx_T *cctx, ufunc_T *ufunc, int pushed_argcount) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; int regular_args = ufunc->uf_args.ga_len; int argcount = pushed_argcount; RETURN_OK_IF_SKIP(cctx); if (argcount > regular_args && !has_varargs(ufunc)) { semsg(_(e_toomanyarg), printable_func_name(ufunc)); return FAIL; } if (argcount < regular_args - ufunc->uf_def_args.ga_len) { semsg(_(e_toofewarg), printable_func_name(ufunc)); return FAIL; } if (ufunc->uf_def_status != UF_NOT_COMPILED) { int i; for (i = 0; i < argcount; ++i) { type_T *expected; type_T *actual; if (i < regular_args) { if (ufunc->uf_arg_types == NULL) continue; expected = ufunc->uf_arg_types[i]; } else if (ufunc->uf_va_type == NULL || ufunc->uf_va_type == &t_any) // possibly a lambda or "...: any" expected = &t_any; else expected = ufunc->uf_va_type->tt_member; actual = ((type_T **)stack->ga_data)[stack->ga_len - argcount + i]; if (need_type(actual, expected, -argcount + i, i + 1, cctx, TRUE, FALSE) == FAIL) { arg_type_mismatch(expected, actual, i + 1); return FAIL; } } if (ufunc->uf_def_status == UF_TO_BE_COMPILED) if (compile_def_function(ufunc, ufunc->uf_ret_type == NULL, NULL) == FAIL) return FAIL; } if ((isn = generate_instr(cctx, ufunc->uf_def_status != UF_NOT_COMPILED ? ISN_DCALL : ISN_UCALL)) == NULL) return FAIL; if (isn->isn_type == ISN_DCALL) { isn->isn_arg.dfunc.cdf_idx = ufunc->uf_dfunc_idx; isn->isn_arg.dfunc.cdf_argcount = argcount; } else { // A user function may be deleted and redefined later, can't use the // ufunc pointer, need to look it up again at runtime. isn->isn_arg.ufunc.cuf_name = vim_strsave(ufunc->uf_name); isn->isn_arg.ufunc.cuf_argcount = argcount; } stack->ga_len -= argcount; // drop the arguments if (ga_grow(stack, 1) == FAIL) return FAIL; // add return value ((type_T **)stack->ga_data)[stack->ga_len] = ufunc->uf_ret_type; ++stack->ga_len; return OK; } /* * Generate an ISN_UCALL instruction when the function isn't defined yet. */ static int generate_UCALL(cctx_T *cctx, char_u *name, int argcount) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_UCALL)) == NULL) return FAIL; isn->isn_arg.ufunc.cuf_name = vim_strsave(name); isn->isn_arg.ufunc.cuf_argcount = argcount; stack->ga_len -= argcount; // drop the arguments if (ga_grow(stack, 1) == FAIL) return FAIL; // add return value ((type_T **)stack->ga_data)[stack->ga_len] = &t_any; ++stack->ga_len; return OK; } /* * Generate an ISN_PCALL instruction. * "type" is the type of the FuncRef. */ static int generate_PCALL( cctx_T *cctx, int argcount, char_u *name, type_T *type, int at_top) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; type_T *ret_type; RETURN_OK_IF_SKIP(cctx); if (type->tt_type == VAR_ANY) ret_type = &t_any; else if (type->tt_type == VAR_FUNC || type->tt_type == VAR_PARTIAL) { if (type->tt_argcount != -1) { int varargs = (type->tt_flags & TTFLAG_VARARGS) ? 1 : 0; if (argcount < type->tt_min_argcount - varargs) { semsg(_(e_toofewarg), name); return FAIL; } if (!varargs && argcount > type->tt_argcount) { semsg(_(e_toomanyarg), name); return FAIL; } if (type->tt_args != NULL) { int i; for (i = 0; i < argcount; ++i) { int offset = -argcount + i - 1; type_T *actual = ((type_T **)stack->ga_data)[ stack->ga_len + offset]; type_T *expected; if (varargs && i >= type->tt_argcount - 1) expected = type->tt_args[ type->tt_argcount - 1]->tt_member; else expected = type->tt_args[i]; if (need_type(actual, expected, offset, i + 1, cctx, TRUE, FALSE) == FAIL) { arg_type_mismatch(expected, actual, i + 1); return FAIL; } } } } ret_type = type->tt_member; } else { semsg(_(e_not_callable_type_str), name); return FAIL; } if ((isn = generate_instr(cctx, ISN_PCALL)) == NULL) return FAIL; isn->isn_arg.pfunc.cpf_top = at_top; isn->isn_arg.pfunc.cpf_argcount = argcount; stack->ga_len -= argcount; // drop the arguments // drop the funcref/partial, get back the return value ((type_T **)stack->ga_data)[stack->ga_len - 1] = ret_type; // If partial is above the arguments it must be cleared and replaced with // the return value. if (at_top && generate_instr(cctx, ISN_PCALL_END) == NULL) return FAIL; return OK; } /* * Generate an ISN_STRINGMEMBER instruction. */ static int generate_STRINGMEMBER(cctx_T *cctx, char_u *name, size_t len) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; type_T *type; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_STRINGMEMBER)) == NULL) return FAIL; isn->isn_arg.string = vim_strnsave(name, len); // check for dict type type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (type->tt_type != VAR_DICT && type != &t_any) { emsg(_(e_dictreq)); return FAIL; } // change dict type to dict member type if (type->tt_type == VAR_DICT) { ((type_T **)stack->ga_data)[stack->ga_len - 1] = type->tt_member == &t_unknown ? &t_any : type->tt_member; } return OK; } /* * Generate an ISN_ECHO instruction. */ static int generate_ECHO(cctx_T *cctx, int with_white, int count) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr_drop(cctx, ISN_ECHO, count)) == NULL) return FAIL; isn->isn_arg.echo.echo_with_white = with_white; isn->isn_arg.echo.echo_count = count; return OK; } /* * Generate an ISN_EXECUTE/ISN_ECHOMSG/ISN_ECHOERR instruction. */ static int generate_MULT_EXPR(cctx_T *cctx, isntype_T isn_type, int count) { isn_T *isn; if ((isn = generate_instr_drop(cctx, isn_type, count)) == NULL) return FAIL; isn->isn_arg.number = count; return OK; } /* * Generate an ISN_PUT instruction. */ static int generate_PUT(cctx_T *cctx, int regname, linenr_T lnum) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_PUT)) == NULL) return FAIL; isn->isn_arg.put.put_regname = regname; isn->isn_arg.put.put_lnum = lnum; return OK; } static int generate_EXEC(cctx_T *cctx, char_u *line) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_EXEC)) == NULL) return FAIL; isn->isn_arg.string = vim_strsave(line); return OK; } static int generate_EXECCONCAT(cctx_T *cctx, int count) { isn_T *isn; if ((isn = generate_instr_drop(cctx, ISN_EXECCONCAT, count)) == NULL) return FAIL; isn->isn_arg.number = count; return OK; } /* * Generate ISN_RANGE. Consumes "range". Return OK/FAIL. */ static int generate_RANGE(cctx_T *cctx, char_u *range) { isn_T *isn; garray_T *stack = &cctx->ctx_type_stack; if ((isn = generate_instr(cctx, ISN_RANGE)) == NULL) return FAIL; isn->isn_arg.string = range; if (ga_grow(stack, 1) == FAIL) return FAIL; ((type_T **)stack->ga_data)[stack->ga_len] = &t_number; ++stack->ga_len; return OK; } static int generate_UNPACK(cctx_T *cctx, int var_count, int semicolon) { isn_T *isn; RETURN_OK_IF_SKIP(cctx); if ((isn = generate_instr(cctx, ISN_UNPACK)) == NULL) return FAIL; isn->isn_arg.unpack.unp_count = var_count; isn->isn_arg.unpack.unp_semicolon = semicolon; return OK; } /* * Generate an instruction for any command modifiers. */ static int generate_cmdmods(cctx_T *cctx, cmdmod_T *cmod) { isn_T *isn; if (cmod->cmod_flags != 0 || cmod->cmod_split != 0 || cmod->cmod_verbose != 0 || cmod->cmod_tab != 0 || cmod->cmod_filter_regmatch.regprog != NULL) { cctx->ctx_has_cmdmod = TRUE; if ((isn = generate_instr(cctx, ISN_CMDMOD)) == NULL) return FAIL; isn->isn_arg.cmdmod.cf_cmdmod = ALLOC_ONE(cmdmod_T); if (isn->isn_arg.cmdmod.cf_cmdmod == NULL) return FAIL; mch_memmove(isn->isn_arg.cmdmod.cf_cmdmod, cmod, sizeof(cmdmod_T)); // filter program now belongs to the instruction cmod->cmod_filter_regmatch.regprog = NULL; } return OK; } static int generate_undo_cmdmods(cctx_T *cctx) { if (cctx->ctx_has_cmdmod && generate_instr(cctx, ISN_CMDMOD_REV) == NULL) return FAIL; cctx->ctx_has_cmdmod = FALSE; return OK; } /* * Reserve space for a local variable. * Return the variable or NULL if it failed. */ static lvar_T * reserve_local( cctx_T *cctx, char_u *name, size_t len, int isConst, type_T *type) { lvar_T *lvar; if (arg_exists(name, len, NULL, NULL, NULL, cctx) == OK) { emsg_namelen(_(e_str_is_used_as_argument), name, (int)len); return NULL; } if (ga_grow(&cctx->ctx_locals, 1) == FAIL) return NULL; lvar = ((lvar_T *)cctx->ctx_locals.ga_data) + cctx->ctx_locals.ga_len++; CLEAR_POINTER(lvar); // Every local variable uses the next entry on the stack. We could re-use // the last ones when leaving a scope, but then variables used in a closure // might get overwritten. To keep things simple do not re-use stack // entries. This is less efficient, but memory is cheap these days. lvar->lv_idx = cctx->ctx_locals_count++; lvar->lv_name = vim_strnsave(name, len == 0 ? STRLEN(name) : len); lvar->lv_const = isConst; lvar->lv_type = type; return lvar; } /* * Remove local variables above "new_top". */ static void unwind_locals(cctx_T *cctx, int new_top) { if (cctx->ctx_locals.ga_len > new_top) { int idx; lvar_T *lvar; for (idx = new_top; idx < cctx->ctx_locals.ga_len; ++idx) { lvar = ((lvar_T *)cctx->ctx_locals.ga_data) + idx; vim_free(lvar->lv_name); } } cctx->ctx_locals.ga_len = new_top; } /* * Free all local variables. */ static void free_locals(cctx_T *cctx) { unwind_locals(cctx, 0); ga_clear(&cctx->ctx_locals); } /* * If "check_writable" is ASSIGN_CONST give an error if the variable was * defined with :final or :const, if "check_writable" is ASSIGN_FINAL give an * error if the variable was defined with :const. */ static int check_item_writable(svar_T *sv, int check_writable, char_u *name) { if ((check_writable == ASSIGN_CONST && sv->sv_const != 0) || (check_writable == ASSIGN_FINAL && sv->sv_const == ASSIGN_CONST)) { semsg(_(e_readonlyvar), name); return FAIL; } return OK; } /* * Find "name" in script-local items of script "sid". * Pass "check_writable" to check_item_writable(). * Returns the index in "sn_var_vals" if found. * If found but not in "sn_var_vals" returns -1. * If not found or the variable is not writable returns -2. */ int get_script_item_idx(int sid, char_u *name, int check_writable, cctx_T *cctx) { hashtab_T *ht; dictitem_T *di; scriptitem_T *si = SCRIPT_ITEM(sid); svar_T *sv; int idx; if (!SCRIPT_ID_VALID(sid)) return -1; if (sid == current_sctx.sc_sid) { sallvar_T *sav = find_script_var(name, 0, cctx); if (sav == NULL) return -2; idx = sav->sav_var_vals_idx; sv = ((svar_T *)si->sn_var_vals.ga_data) + idx; if (check_item_writable(sv, check_writable, name) == FAIL) return -2; return idx; } // First look the name up in the hashtable. ht = &SCRIPT_VARS(sid); di = find_var_in_ht(ht, 0, name, TRUE); if (di == NULL) return -2; // Now find the svar_T index in sn_var_vals. for (idx = 0; idx < si->sn_var_vals.ga_len; ++idx) { sv = ((svar_T *)si->sn_var_vals.ga_data) + idx; if (sv->sv_tv == &di->di_tv) { if (check_item_writable(sv, check_writable, name) == FAIL) return -2; return idx; } } return -1; } /* * Find "name" in imported items of the current script or in "cctx" if not * NULL. */ imported_T * find_imported(char_u *name, size_t len, cctx_T *cctx) { int idx; if (!SCRIPT_ID_VALID(current_sctx.sc_sid)) return NULL; if (cctx != NULL) for (idx = 0; idx < cctx->ctx_imports.ga_len; ++idx) { imported_T *import = ((imported_T *)cctx->ctx_imports.ga_data) + idx; if (len == 0 ? STRCMP(name, import->imp_name) == 0 : STRLEN(import->imp_name) == len && STRNCMP(name, import->imp_name, len) == 0) return import; } return find_imported_in_script(name, len, current_sctx.sc_sid); } imported_T * find_imported_in_script(char_u *name, size_t len, int sid) { scriptitem_T *si; int idx; if (!SCRIPT_ID_VALID(sid)) return NULL; si = SCRIPT_ITEM(sid); for (idx = 0; idx < si->sn_imports.ga_len; ++idx) { imported_T *import = ((imported_T *)si->sn_imports.ga_data) + idx; if (len == 0 ? STRCMP(name, import->imp_name) == 0 : STRLEN(import->imp_name) == len && STRNCMP(name, import->imp_name, len) == 0) return import; } return NULL; } /* * Free all imported variables. */ static void free_imported(cctx_T *cctx) { int idx; for (idx = 0; idx < cctx->ctx_imports.ga_len; ++idx) { imported_T *import = ((imported_T *)cctx->ctx_imports.ga_data) + idx; vim_free(import->imp_name); } ga_clear(&cctx->ctx_imports); } /* * Return a pointer to the next line that isn't empty or only contains a * comment. Skips over white space. * Returns NULL if there is none. */ char_u * peek_next_line_from_context(cctx_T *cctx) { int lnum = cctx->ctx_lnum; while (++lnum < cctx->ctx_ufunc->uf_lines.ga_len) { char_u *line = ((char_u **)cctx->ctx_ufunc->uf_lines.ga_data)[lnum]; char_u *p; // ignore NULLs inserted for continuation lines if (line != NULL) { p = skipwhite(line); if (*p != NUL && !vim9_comment_start(p)) return p; } } return NULL; } /* * Called when checking for a following operator at "arg". When the rest of * the line is empty or only a comment, peek the next line. If there is a next * line return a pointer to it and set "nextp". * Otherwise skip over white space. */ static char_u * may_peek_next_line(cctx_T *cctx, char_u *arg, char_u **nextp) { char_u *p = skipwhite(arg); *nextp = NULL; if (*p == NUL || (VIM_ISWHITE(*arg) && vim9_comment_start(p))) { *nextp = peek_next_line_from_context(cctx); if (*nextp != NULL) return *nextp; } return p; } /* * Get the next line of the function from "cctx". * Skips over empty lines. Skips over comment lines if "skip_comment" is TRUE. * Returns NULL when at the end. */ char_u * next_line_from_context(cctx_T *cctx, int skip_comment) { char_u *line; do { ++cctx->ctx_lnum; if (cctx->ctx_lnum >= cctx->ctx_ufunc->uf_lines.ga_len) { line = NULL; break; } line = ((char_u **)cctx->ctx_ufunc->uf_lines.ga_data)[cctx->ctx_lnum]; cctx->ctx_line_start = line; SOURCING_LNUM = cctx->ctx_lnum + 1; } while (line == NULL || *skipwhite(line) == NUL || (skip_comment && vim9_comment_start(skipwhite(line)))); return line; } /* * Skip over white space at "whitep" and assign to "*arg". * If "*arg" is at the end of the line, advance to the next line. * Also when "whitep" points to white space and "*arg" is on a "#". * Return FAIL if beyond the last line, "*arg" is unmodified then. */ static int may_get_next_line(char_u *whitep, char_u **arg, cctx_T *cctx) { *arg = skipwhite(whitep); if (**arg == NUL || (VIM_ISWHITE(*whitep) && vim9_comment_start(*arg))) { char_u *next = next_line_from_context(cctx, TRUE); if (next == NULL) return FAIL; *arg = skipwhite(next); } return OK; } /* * Idem, and give an error when failed. */ static int may_get_next_line_error(char_u *whitep, char_u **arg, cctx_T *cctx) { if (may_get_next_line(whitep, arg, cctx) == FAIL) { SOURCING_LNUM = cctx->ctx_lnum + 1; emsg(_(e_line_incomplete)); return FAIL; } return OK; } // Structure passed between the compile_expr* functions to keep track of // constants that have been parsed but for which no code was produced yet. If // possible expressions on these constants are applied at compile time. If // that is not possible, the code to push the constants needs to be generated // before other instructions. // Using 50 should be more than enough of 5 levels of (). #define PPSIZE 50 typedef struct { typval_T pp_tv[PPSIZE]; // stack of ppconst constants int pp_used; // active entries in pp_tv[] int pp_is_const; // all generated code was constants, used for a // list or dict with constant members } ppconst_T; static int compile_expr0_ext(char_u **arg, cctx_T *cctx, int *is_const); static int compile_expr0(char_u **arg, cctx_T *cctx); static int compile_expr1(char_u **arg, cctx_T *cctx, ppconst_T *ppconst); /* * Generate a PUSH instruction for "tv". * "tv" will be consumed or cleared. * Nothing happens if "tv" is NULL or of type VAR_UNKNOWN; */ static int generate_tv_PUSH(cctx_T *cctx, typval_T *tv) { if (tv != NULL) { switch (tv->v_type) { case VAR_UNKNOWN: break; case VAR_BOOL: generate_PUSHBOOL(cctx, tv->vval.v_number); break; case VAR_SPECIAL: generate_PUSHSPEC(cctx, tv->vval.v_number); break; case VAR_NUMBER: generate_PUSHNR(cctx, tv->vval.v_number); break; #ifdef FEAT_FLOAT case VAR_FLOAT: generate_PUSHF(cctx, tv->vval.v_float); break; #endif case VAR_BLOB: generate_PUSHBLOB(cctx, tv->vval.v_blob); tv->vval.v_blob = NULL; break; case VAR_STRING: generate_PUSHS(cctx, tv->vval.v_string); tv->vval.v_string = NULL; break; default: iemsg("constant type not supported"); clear_tv(tv); return FAIL; } tv->v_type = VAR_UNKNOWN; } return OK; } /* * Generate code for any ppconst entries. */ static int generate_ppconst(cctx_T *cctx, ppconst_T *ppconst) { int i; int ret = OK; int save_skip = cctx->ctx_skip; cctx->ctx_skip = SKIP_NOT; for (i = 0; i < ppconst->pp_used; ++i) if (generate_tv_PUSH(cctx, &ppconst->pp_tv[i]) == FAIL) ret = FAIL; ppconst->pp_used = 0; cctx->ctx_skip = save_skip; return ret; } /* * Clear ppconst constants. Used when failing. */ static void clear_ppconst(ppconst_T *ppconst) { int i; for (i = 0; i < ppconst->pp_used; ++i) clear_tv(&ppconst->pp_tv[i]); ppconst->pp_used = 0; } /* * Generate an instruction to load script-local variable "name", without the * leading "s:". * Also finds imported variables. */ static int compile_load_scriptvar( cctx_T *cctx, char_u *name, // variable NUL terminated char_u *start, // start of variable char_u **end, // end of variable int error) // when TRUE may give error { scriptitem_T *si; int idx; imported_T *import; if (!SCRIPT_ID_VALID(current_sctx.sc_sid)) return FAIL; si = SCRIPT_ITEM(current_sctx.sc_sid); idx = get_script_item_idx(current_sctx.sc_sid, name, 0, cctx); if (idx == -1 || si->sn_version != SCRIPT_VERSION_VIM9) { // variable is not in sn_var_vals: old style script. return generate_OLDSCRIPT(cctx, ISN_LOADS, name, current_sctx.sc_sid, &t_any); } if (idx >= 0) { svar_T *sv = ((svar_T *)si->sn_var_vals.ga_data) + idx; generate_VIM9SCRIPT(cctx, ISN_LOADSCRIPT, current_sctx.sc_sid, idx, sv->sv_type); return OK; } import = find_imported(name, 0, cctx); if (import != NULL) { if (import->imp_flags & IMP_FLAGS_STAR) { char_u *p = skipwhite(*end); char_u *exp_name; int cc; ufunc_T *ufunc; type_T *type; // Used "import * as Name", need to lookup the member. if (*p != '.') { semsg(_(e_expected_dot_after_name_str), start); return FAIL; } ++p; if (VIM_ISWHITE(*p)) { emsg(_(e_no_white_space_allowed_after_dot)); return FAIL; } // isolate one name exp_name = p; while (eval_isnamec(*p)) ++p; cc = *p; *p = NUL; idx = find_exported(import->imp_sid, exp_name, &ufunc, &type, cctx); *p = cc; p = skipwhite(p); // TODO: what if it is a function? if (idx < 0) return FAIL; *end = p; generate_VIM9SCRIPT(cctx, ISN_LOADSCRIPT, import->imp_sid, idx, type); } else if (import->imp_funcname != NULL) generate_PUSHFUNC(cctx, import->imp_funcname, import->imp_type); else generate_VIM9SCRIPT(cctx, ISN_LOADSCRIPT, import->imp_sid, import->imp_var_vals_idx, import->imp_type); return OK; } if (error) semsg(_(e_item_not_found_str), name); return FAIL; } static int generate_funcref(cctx_T *cctx, char_u *name) { ufunc_T *ufunc = find_func(name, FALSE, cctx); if (ufunc == NULL) return FAIL; // Need to compile any default values to get the argument types. if (ufunc->uf_def_status == UF_TO_BE_COMPILED) if (compile_def_function(ufunc, TRUE, NULL) == FAIL) return FAIL; return generate_PUSHFUNC(cctx, ufunc->uf_name, ufunc->uf_func_type); } /* * Compile a variable name into a load instruction. * "end" points to just after the name. * "is_expr" is TRUE when evaluating an expression, might be a funcref. * When "error" is FALSE do not give an error when not found. */ static int compile_load( char_u **arg, char_u *end_arg, cctx_T *cctx, int is_expr, int error) { type_T *type; char_u *name = NULL; char_u *end = end_arg; int res = FAIL; int prev_called_emsg = called_emsg; if (*(*arg + 1) == ':') { // load namespaced variable if (end <= *arg + 2) { isntype_T isn_type; switch (**arg) { case 'g': isn_type = ISN_LOADGDICT; break; case 'w': isn_type = ISN_LOADWDICT; break; case 't': isn_type = ISN_LOADTDICT; break; case 'b': isn_type = ISN_LOADBDICT; break; default: semsg(_(e_namespace_not_supported_str), *arg); goto theend; } if (generate_instr_type(cctx, isn_type, &t_dict_any) == NULL) goto theend; res = OK; } else { isntype_T isn_type = ISN_DROP; name = vim_strnsave(*arg + 2, end - (*arg + 2)); if (name == NULL) return FAIL; switch (**arg) { case 'v': res = generate_LOADV(cctx, name, error); break; case 's': res = compile_load_scriptvar(cctx, name, NULL, NULL, error); break; case 'g': if (vim_strchr(name, AUTOLOAD_CHAR) == NULL) isn_type = ISN_LOADG; else { isn_type = ISN_LOADAUTO; vim_free(name); name = vim_strnsave(*arg, end - *arg); if (name == NULL) return FAIL; } break; case 'w': isn_type = ISN_LOADW; break; case 't': isn_type = ISN_LOADT; break; case 'b': isn_type = ISN_LOADB; break; default: // cannot happen, just in case semsg(_(e_namespace_not_supported_str), *arg); goto theend; } if (isn_type != ISN_DROP) { // Global, Buffer-local, Window-local and Tabpage-local // variables can be defined later, thus we don't check if it // exists, give error at runtime. res = generate_LOAD(cctx, isn_type, 0, name, &t_any); } } } else { size_t len = end - *arg; int idx; int gen_load = FALSE; int gen_load_outer = 0; name = vim_strnsave(*arg, end - *arg); if (name == NULL) return FAIL; if (arg_exists(*arg, len, &idx, &type, &gen_load_outer, cctx) == OK) { if (gen_load_outer == 0) gen_load = TRUE; } else { lvar_T lvar; if (lookup_local(*arg, len, &lvar, cctx) == OK) { type = lvar.lv_type; idx = lvar.lv_idx; if (lvar.lv_from_outer != 0) gen_load_outer = lvar.lv_from_outer; else gen_load = TRUE; } else { // "var" can be script-local even without using "s:" if it // already exists in a Vim9 script or when it's imported. if (script_var_exists(*arg, len, TRUE, cctx) == OK || find_imported(name, 0, cctx) != NULL) res = compile_load_scriptvar(cctx, name, *arg, &end, FALSE); // When evaluating an expression and the name starts with an // uppercase letter or "x:" it can be a user defined function. // TODO: this is just guessing if (res == FAIL && is_expr && (ASCII_ISUPPER(*name) || name[1] == ':')) res = generate_funcref(cctx, name); } } if (gen_load) res = generate_LOAD(cctx, ISN_LOAD, idx, NULL, type); if (gen_load_outer > 0) { res = generate_LOADOUTER(cctx, idx, gen_load_outer, type); cctx->ctx_outer_used = TRUE; } } *arg = end; theend: if (res == FAIL && error && called_emsg == prev_called_emsg) semsg(_(e_variable_not_found_str), name); vim_free(name); return res; } /* * Compile the argument expressions. * "arg" points to just after the "(" and is advanced to after the ")" */ static int compile_arguments(char_u **arg, cctx_T *cctx, int *argcount) { char_u *p = *arg; char_u *whitep = *arg; int must_end = FALSE; for (;;) { if (may_get_next_line(whitep, &p, cctx) == FAIL) goto failret; if (*p == ')') { *arg = p + 1; return OK; } if (must_end) { semsg(_(e_missing_comma_before_argument_str), p); return FAIL; } if (compile_expr0(&p, cctx) == FAIL) return FAIL; ++*argcount; if (*p != ',' && *skipwhite(p) == ',') { semsg(_(e_no_white_space_allowed_before_str), ","); p = skipwhite(p); } if (*p == ',') { ++p; if (*p != NUL && !VIM_ISWHITE(*p)) semsg(_(e_white_space_required_after_str), ","); } else must_end = TRUE; whitep = p; p = skipwhite(p); } failret: emsg(_(e_missing_close)); return FAIL; } /* * Compile a function call: name(arg1, arg2) * "arg" points to "name", "arg + varlen" to the "(". * "argcount_init" is 1 for "value->method()" * Instructions: * EVAL arg1 * EVAL arg2 * BCALL / DCALL / UCALL */ static int compile_call( char_u **arg, size_t varlen, cctx_T *cctx, ppconst_T *ppconst, int argcount_init) { char_u *name = *arg; char_u *p; int argcount = argcount_init; char_u namebuf[100]; char_u fname_buf[FLEN_FIXED + 1]; char_u *tofree = NULL; int error = FCERR_NONE; ufunc_T *ufunc = NULL; int res = FAIL; int is_autoload; // we can evaluate "has('name')" at compile time if (varlen == 3 && STRNCMP(*arg, "has", 3) == 0) { char_u *s = skipwhite(*arg + varlen + 1); typval_T argvars[2]; argvars[0].v_type = VAR_UNKNOWN; if (*s == '"') (void)eval_string(&s, &argvars[0], TRUE); else if (*s == '\'') (void)eval_lit_string(&s, &argvars[0], TRUE); s = skipwhite(s); if (*s == ')' && argvars[0].v_type == VAR_STRING && !dynamic_feature(argvars[0].vval.v_string)) { typval_T *tv = &ppconst->pp_tv[ppconst->pp_used]; *arg = s + 1; argvars[1].v_type = VAR_UNKNOWN; tv->v_type = VAR_NUMBER; tv->vval.v_number = 0; f_has(argvars, tv); clear_tv(&argvars[0]); ++ppconst->pp_used; return OK; } clear_tv(&argvars[0]); } if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; if (varlen >= sizeof(namebuf)) { semsg(_(e_name_too_long_str), name); return FAIL; } vim_strncpy(namebuf, *arg, varlen); name = fname_trans_sid(namebuf, fname_buf, &tofree, &error); *arg = skipwhite(*arg + varlen + 1); if (compile_arguments(arg, cctx, &argcount) == FAIL) goto theend; is_autoload = vim_strchr(name, AUTOLOAD_CHAR) != NULL; if (ASCII_ISLOWER(*name) && name[1] != ':' && !is_autoload) { int idx; // builtin function idx = find_internal_func(name); if (idx >= 0) { if (STRCMP(name, "add") == 0 && argcount == 2) { garray_T *stack = &cctx->ctx_type_stack; type_T *type = ((type_T **)stack->ga_data)[ stack->ga_len - 2]; // add() can be compiled to instructions if we know the type if (type->tt_type == VAR_LIST) { // inline "add(list, item)" so that the type can be checked res = generate_LISTAPPEND(cctx); idx = -1; } else if (type->tt_type == VAR_BLOB) { // inline "add(blob, nr)" so that the type can be checked res = generate_BLOBAPPEND(cctx); idx = -1; } } if (idx >= 0) res = generate_BCALL(cctx, idx, argcount, argcount_init == 1); } else semsg(_(e_unknownfunc), namebuf); goto theend; } // An argument or local variable can be a function reference, this // overrules a function name. if (lookup_local(namebuf, varlen, NULL, cctx) == FAIL && arg_exists(namebuf, varlen, NULL, NULL, NULL, cctx) != OK) { // If we can find the function by name generate the right call. // Skip global functions here, a local funcref takes precedence. ufunc = find_func(name, FALSE, cctx); if (ufunc != NULL && !func_is_global(ufunc)) { res = generate_CALL(cctx, ufunc, argcount); goto theend; } } // If the name is a variable, load it and use PCALL. // Not for g:Func(), we don't know if it is a variable or not. // Not for eome#Func(), it will be loaded later. p = namebuf; if (STRNCMP(namebuf, "g:", 2) != 0 && !is_autoload && compile_load(&p, namebuf + varlen, cctx, FALSE, FALSE) == OK) { garray_T *stack = &cctx->ctx_type_stack; type_T *type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; res = generate_PCALL(cctx, argcount, namebuf, type, FALSE); goto theend; } // If we can find a global function by name generate the right call. if (ufunc != NULL) { res = generate_CALL(cctx, ufunc, argcount); goto theend; } // A global function may be defined only later. Need to figure out at // runtime. Also handles a FuncRef at runtime. if (STRNCMP(namebuf, "g:", 2) == 0 || is_autoload) res = generate_UCALL(cctx, name, argcount); else semsg(_(e_unknownfunc), namebuf); theend: vim_free(tofree); return res; } // like NAMESPACE_CHAR but with 'a' and 'l'. #define VIM9_NAMESPACE_CHAR (char_u *)"bgstvw" /* * Find the end of a variable or function name. Unlike find_name_end() this * does not recognize magic braces. * When "use_namespace" is TRUE recognize "b:", "s:", etc. * Return a pointer to just after the name. Equal to "arg" if there is no * valid name. */ char_u * to_name_end(char_u *arg, int use_namespace) { char_u *p; // Quick check for valid starting character. if (!eval_isnamec1(*arg)) return arg; for (p = arg + 1; *p != NUL && eval_isnamec(*p); MB_PTR_ADV(p)) // Include a namespace such as "s:var" and "v:var". But "n:" is not // and can be used in slice "[n:]". if (*p == ':' && (p != arg + 1 || !use_namespace || vim_strchr(VIM9_NAMESPACE_CHAR, *arg) == NULL)) break; return p; } /* * Like to_name_end() but also skip over a list or dict constant. * This intentionally does not handle line continuation. */ char_u * to_name_const_end(char_u *arg) { char_u *p = to_name_end(arg, TRUE); typval_T rettv; if (p == arg && *arg == '[') { // Can be "[1, 2, 3]->Func()". if (eval_list(&p, &rettv, NULL, FALSE) == FAIL) p = arg; } return p; } /* * parse a list: [expr, expr] * "*arg" points to the '['. * ppconst->pp_is_const is set if all items are a constant. */ static int compile_list(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { char_u *p = skipwhite(*arg + 1); char_u *whitep = *arg + 1; int count = 0; int is_const; int is_all_const = TRUE; // reset when non-const encountered for (;;) { if (may_get_next_line(whitep, &p, cctx) == FAIL) { semsg(_(e_list_end), *arg); return FAIL; } if (*p == ',') { semsg(_(e_no_white_space_allowed_before_str), ","); return FAIL; } if (*p == ']') { ++p; break; } if (compile_expr0_ext(&p, cctx, &is_const) == FAIL) return FAIL; if (!is_const) is_all_const = FALSE; ++count; if (*p == ',') { ++p; if (*p != ']' && !IS_WHITE_OR_NUL(*p)) { semsg(_(e_white_space_required_after_str), ","); return FAIL; } } whitep = p; p = skipwhite(p); } *arg = p; ppconst->pp_is_const = is_all_const; return generate_NEWLIST(cctx, count); } /* * Parse a lambda: "(arg, arg) => expr" * "*arg" points to the '{'. * Returns OK/FAIL when a lambda is recognized, NOTDONE if it's not a lambda. */ static int compile_lambda(char_u **arg, cctx_T *cctx) { int r; typval_T rettv; ufunc_T *ufunc; evalarg_T evalarg; CLEAR_FIELD(evalarg); evalarg.eval_flags = EVAL_EVALUATE; evalarg.eval_cctx = cctx; // Get the funcref in "rettv". r = get_lambda_tv(arg, &rettv, TRUE, &evalarg); if (r != OK) { clear_evalarg(&evalarg, NULL); return r; } // "rettv" will now be a partial referencing the function. ufunc = rettv.vval.v_partial->pt_func; ++ufunc->uf_refcount; clear_tv(&rettv); // Compile the function into instructions. compile_def_function(ufunc, TRUE, cctx); clear_evalarg(&evalarg, NULL); if (ufunc->uf_def_status == UF_COMPILED) { // The return type will now be known. set_function_type(ufunc); // The function reference count will be 1. When the ISN_FUNCREF // instruction is deleted the reference count is decremented and the // function is freed. return generate_FUNCREF(cctx, ufunc); } func_ptr_unref(ufunc); return FAIL; } /* * parse a dict: {key: val, [key]: val} * "*arg" points to the '{'. * ppconst->pp_is_const is set if all item values are a constant. */ static int compile_dict(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { garray_T *instr = &cctx->ctx_instr; garray_T *stack = &cctx->ctx_type_stack; int count = 0; dict_T *d = dict_alloc(); dictitem_T *item; char_u *whitep = *arg + 1; char_u *p; int is_const; int is_all_const = TRUE; // reset when non-const encountered if (d == NULL) return FAIL; if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; for (;;) { char_u *key = NULL; if (may_get_next_line(whitep, arg, cctx) == FAIL) { *arg = NULL; goto failret; } if (**arg == '}') break; if (**arg == '[') { isn_T *isn; // {[expr]: value} uses an evaluated key. *arg = skipwhite(*arg + 1); if (compile_expr0(arg, cctx) == FAIL) return FAIL; isn = ((isn_T *)instr->ga_data) + instr->ga_len - 1; if (isn->isn_type == ISN_PUSHS) key = isn->isn_arg.string; else { type_T *keytype = ((type_T **)stack->ga_data) [stack->ga_len - 1]; if (need_type(keytype, &t_string, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; } *arg = skipwhite(*arg); if (**arg != ']') { emsg(_(e_missing_matching_bracket_after_dict_key)); return FAIL; } ++*arg; } else { // {"name": value}, // {'name': value}, // {name: value} use "name" as a literal key key = get_literal_key(arg); if (key == NULL) return FAIL; if (generate_PUSHS(cctx, key) == FAIL) return FAIL; } // Check for duplicate keys, if using string keys. if (key != NULL) { item = dict_find(d, key, -1); if (item != NULL) { semsg(_(e_duplicate_key), key); goto failret; } item = dictitem_alloc(key); if (item != NULL) { item->di_tv.v_type = VAR_UNKNOWN; item->di_tv.v_lock = 0; if (dict_add(d, item) == FAIL) dictitem_free(item); } } if (**arg != ':') { if (*skipwhite(*arg) == ':') semsg(_(e_no_white_space_allowed_before_str), ":"); else semsg(_(e_missing_dict_colon), *arg); return FAIL; } whitep = *arg + 1; if (!IS_WHITE_OR_NUL(*whitep)) { semsg(_(e_white_space_required_after_str), ":"); return FAIL; } if (may_get_next_line(whitep, arg, cctx) == FAIL) { *arg = NULL; goto failret; } if (compile_expr0_ext(arg, cctx, &is_const) == FAIL) return FAIL; if (!is_const) is_all_const = FALSE; ++count; whitep = *arg; if (may_get_next_line(whitep, arg, cctx) == FAIL) { *arg = NULL; goto failret; } if (**arg == '}') break; if (**arg != ',') { semsg(_(e_missing_dict_comma), *arg); goto failret; } if (IS_WHITE_OR_NUL(*whitep)) { semsg(_(e_no_white_space_allowed_before_str), ","); return FAIL; } whitep = *arg + 1; if (!IS_WHITE_OR_NUL(*whitep)) { semsg(_(e_white_space_required_after_str), ","); return FAIL; } *arg = skipwhite(*arg + 1); } *arg = *arg + 1; // Allow for following comment, after at least one space. p = skipwhite(*arg); if (VIM_ISWHITE(**arg) && vim9_comment_start(p)) *arg += STRLEN(*arg); dict_unref(d); ppconst->pp_is_const = is_all_const; return generate_NEWDICT(cctx, count); failret: if (*arg == NULL) { semsg(_(e_missing_dict_end), _("[end of lines]")); *arg = (char_u *)""; } dict_unref(d); return FAIL; } /* * Compile "&option". */ static int compile_get_option(char_u **arg, cctx_T *cctx) { typval_T rettv; char_u *start = *arg; int ret; // parse the option and get the current value to get the type. rettv.v_type = VAR_UNKNOWN; ret = eval_option(arg, &rettv, TRUE); if (ret == OK) { // include the '&' in the name, eval_option() expects it. char_u *name = vim_strnsave(start, *arg - start); type_T *type = rettv.v_type == VAR_BOOL ? &t_bool : rettv.v_type == VAR_NUMBER ? &t_number : &t_string; ret = generate_LOAD(cctx, ISN_LOADOPT, 0, name, type); vim_free(name); } clear_tv(&rettv); return ret; } /* * Compile "$VAR". */ static int compile_get_env(char_u **arg, cctx_T *cctx) { char_u *start = *arg; int len; int ret; char_u *name; ++*arg; len = get_env_len(arg); if (len == 0) { semsg(_(e_syntax_error_at_str), start - 1); return FAIL; } // include the '$' in the name, eval_env_var() expects it. name = vim_strnsave(start, len + 1); ret = generate_LOAD(cctx, ISN_LOADENV, 0, name, &t_string); vim_free(name); return ret; } /* * Compile "@r". */ static int compile_get_register(char_u **arg, cctx_T *cctx) { int ret; ++*arg; if (**arg == NUL) { semsg(_(e_syntax_error_at_str), *arg - 1); return FAIL; } if (!valid_yank_reg(**arg, FALSE)) { emsg_invreg(**arg); return FAIL; } ret = generate_LOAD(cctx, ISN_LOADREG, **arg, NULL, &t_string); ++*arg; return ret; } /* * Apply leading '!', '-' and '+' to constant "rettv". * When "numeric_only" is TRUE do not apply '!'. */ static int apply_leader(typval_T *rettv, int numeric_only, char_u *start, char_u **end) { char_u *p = *end; // this works from end to start while (p > start) { --p; if (*p == '-' || *p == '+') { // only '-' has an effect, for '+' we only check the type #ifdef FEAT_FLOAT if (rettv->v_type == VAR_FLOAT) { if (*p == '-') rettv->vval.v_float = -rettv->vval.v_float; } else #endif { varnumber_T val; int error = FALSE; // tv_get_number_chk() accepts a string, but we don't want that // here if (check_not_string(rettv) == FAIL) return FAIL; val = tv_get_number_chk(rettv, &error); clear_tv(rettv); if (error) return FAIL; if (*p == '-') val = -val; rettv->v_type = VAR_NUMBER; rettv->vval.v_number = val; } } else if (numeric_only) { ++p; break; } else if (*p == '!') { int v = tv2bool(rettv); // '!' is permissive in the type. clear_tv(rettv); rettv->v_type = VAR_BOOL; rettv->vval.v_number = v ? VVAL_FALSE : VVAL_TRUE; } } *end = p; return OK; } /* * Recognize v: variables that are constants and set "rettv". */ static void get_vim_constant(char_u **arg, typval_T *rettv) { if (STRNCMP(*arg, "v:true", 6) == 0) { rettv->v_type = VAR_BOOL; rettv->vval.v_number = VVAL_TRUE; *arg += 6; } else if (STRNCMP(*arg, "v:false", 7) == 0) { rettv->v_type = VAR_BOOL; rettv->vval.v_number = VVAL_FALSE; *arg += 7; } else if (STRNCMP(*arg, "v:null", 6) == 0) { rettv->v_type = VAR_SPECIAL; rettv->vval.v_number = VVAL_NULL; *arg += 6; } else if (STRNCMP(*arg, "v:none", 6) == 0) { rettv->v_type = VAR_SPECIAL; rettv->vval.v_number = VVAL_NONE; *arg += 6; } } exprtype_T get_compare_type(char_u *p, int *len, int *type_is) { exprtype_T type = EXPR_UNKNOWN; int i; switch (p[0]) { case '=': if (p[1] == '=') type = EXPR_EQUAL; else if (p[1] == '~') type = EXPR_MATCH; break; case '!': if (p[1] == '=') type = EXPR_NEQUAL; else if (p[1] == '~') type = EXPR_NOMATCH; break; case '>': if (p[1] != '=') { type = EXPR_GREATER; *len = 1; } else type = EXPR_GEQUAL; break; case '<': if (p[1] != '=') { type = EXPR_SMALLER; *len = 1; } else type = EXPR_SEQUAL; break; case 'i': if (p[1] == 's') { // "is" and "isnot"; but not a prefix of a name if (p[2] == 'n' && p[3] == 'o' && p[4] == 't') *len = 5; i = p[*len]; if (!isalnum(i) && i != '_') { type = *len == 2 ? EXPR_IS : EXPR_ISNOT; *type_is = TRUE; } } break; } return type; } /* * Skip over an expression, ignoring most errors. */ static void skip_expr_cctx(char_u **arg, cctx_T *cctx) { evalarg_T evalarg; CLEAR_FIELD(evalarg); evalarg.eval_cctx = cctx; skip_expr(arg, &evalarg); } /* * Compile code to apply '-', '+' and '!'. * When "numeric_only" is TRUE do not apply '!'. */ static int compile_leader(cctx_T *cctx, int numeric_only, char_u *start, char_u **end) { char_u *p = *end; // this works from end to start while (p > start) { --p; while (VIM_ISWHITE(*p)) --p; if (*p == '-' || *p == '+') { int negate = *p == '-'; isn_T *isn; // TODO: check type while (p > start && (p[-1] == '-' || p[-1] == '+')) { --p; if (*p == '-') negate = !negate; } // only '-' has an effect, for '+' we only check the type if (negate) isn = generate_instr(cctx, ISN_NEGATENR); else isn = generate_instr(cctx, ISN_CHECKNR); if (isn == NULL) return FAIL; } else if (numeric_only) { ++p; break; } else { int invert = *p == '!'; while (p > start && (p[-1] == '!' || VIM_ISWHITE(p[-1]))) { if (p[-1] == '!') invert = !invert; --p; } if (generate_2BOOL(cctx, invert) == FAIL) return FAIL; } } *end = p; return OK; } /* * Compile "(expression)": recursive! * Return FAIL/OK. */ static int compile_parenthesis(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { int ret; char_u *p = *arg + 1; if (may_get_next_line_error(p, arg, cctx) == FAIL) return FAIL; if (ppconst->pp_used <= PPSIZE - 10) { ret = compile_expr1(arg, cctx, ppconst); } else { // Not enough space in ppconst, flush constants. if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ret = compile_expr0(arg, cctx); } if (may_get_next_line_error(*arg, arg, cctx) == FAIL) return FAIL; if (**arg == ')') ++*arg; else if (ret == OK) { emsg(_(e_missing_close)); ret = FAIL; } return ret; } /* * Compile whatever comes after "name" or "name()". * Advances "*arg" only when something was recognized. */ static int compile_subscript( char_u **arg, cctx_T *cctx, char_u *start_leader, char_u **end_leader, ppconst_T *ppconst) { char_u *name_start = *end_leader; for (;;) { char_u *p = skipwhite(*arg); if (*p == NUL || (VIM_ISWHITE(**arg) && vim9_comment_start(p))) { char_u *next = peek_next_line_from_context(cctx); // If a following line starts with "->{" or "->X" advance to that // line, so that a line break before "->" is allowed. // Also if a following line starts with ".x". if (next != NULL && ((next[0] == '-' && next[1] == '>' && (next[2] == '{' || ASCII_ISALPHA(next[2]))) || (next[0] == '.' && eval_isdictc(next[1])))) { next = next_line_from_context(cctx, TRUE); if (next == NULL) return FAIL; *arg = next; p = skipwhite(*arg); } } // Do not skip over white space to find the "(", "execute 'x' ()" is // not a function call. if (**arg == '(') { garray_T *stack = &cctx->ctx_type_stack; type_T *type; int argcount = 0; if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ppconst->pp_is_const = FALSE; // funcref(arg) type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; *arg = skipwhite(p + 1); if (compile_arguments(arg, cctx, &argcount) == FAIL) return FAIL; if (generate_PCALL(cctx, argcount, name_start, type, TRUE) == FAIL) return FAIL; } else if (*p == '-' && p[1] == '>') { char_u *pstart = p; if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ppconst->pp_is_const = FALSE; // something->method() // Apply the '!', '-' and '+' first: // -1.0->func() works like (-1.0)->func() if (compile_leader(cctx, TRUE, start_leader, end_leader) == FAIL) return FAIL; p += 2; *arg = skipwhite(p); // No line break supported right after "->". if (**arg == '(') { int argcount = 1; char_u *expr; garray_T *stack; type_T *type; // Funcref call: list->(Refs[2])(arg) // or lambda: list->((arg) => expr)(arg) // Fist compile the arguments. expr = *arg; *arg = skipwhite(*arg + 1); skip_expr_cctx(arg, cctx); *arg = skipwhite(*arg); if (**arg != ')') { semsg(_(e_missing_paren), *arg); return FAIL; } ++*arg; if (**arg != '(') { if (*skipwhite(*arg) == '(') emsg(_(e_nowhitespace)); else semsg(_(e_missing_paren), *arg); return FAIL; } *arg = skipwhite(*arg + 1); if (compile_arguments(arg, cctx, &argcount) == FAIL) return FAIL; // Compile the function expression. if (compile_parenthesis(&expr, cctx, ppconst) == FAIL) return FAIL; stack = &cctx->ctx_type_stack; type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (generate_PCALL(cctx, argcount, (char_u *)"[expression]", type, FALSE) == FAIL) return FAIL; } else { // method call: list->method() p = *arg; if (!eval_isnamec1(*p)) { semsg(_(e_trailing_arg), pstart); return FAIL; } if (ASCII_ISALPHA(*p) && p[1] == ':') p += 2; for ( ; eval_isnamec(*p); ++p) ; if (*p != '(') { semsg(_(e_missing_paren), *arg); return FAIL; } // TODO: base value may not be the first argument if (compile_call(arg, p - *arg, cctx, ppconst, 1) == FAIL) return FAIL; } } else if (**arg == '[') { garray_T *stack = &cctx->ctx_type_stack; type_T **typep; type_T *valtype; vartype_T vtype; int is_slice = FALSE; // list index: list[123] // dict member: dict[key] // string index: text[123] // TODO: blob index // TODO: more arguments // TODO: recognize list or dict at runtime if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ppconst->pp_is_const = FALSE; ++p; if (may_get_next_line_error(p, arg, cctx) == FAIL) return FAIL; if (**arg == ':') { // missing first index is equal to zero generate_PUSHNR(cctx, 0); } else { if (compile_expr0(arg, cctx) == FAIL) return FAIL; if (**arg == ':') { semsg(_(e_white_space_required_before_and_after_str_at_str), ":", *arg); return FAIL; } if (may_get_next_line_error(*arg, arg, cctx) == FAIL) return FAIL; *arg = skipwhite(*arg); } if (**arg == ':') { is_slice = TRUE; ++*arg; if (!IS_WHITE_OR_NUL(**arg) && **arg != ']') { semsg(_(e_white_space_required_before_and_after_str_at_str), ":", *arg); return FAIL; } if (may_get_next_line_error(*arg, arg, cctx) == FAIL) return FAIL; if (**arg == ']') // missing second index is equal to end of string generate_PUSHNR(cctx, -1); else { if (compile_expr0(arg, cctx) == FAIL) return FAIL; if (may_get_next_line_error(*arg, arg, cctx) == FAIL) return FAIL; *arg = skipwhite(*arg); } } if (**arg != ']') { emsg(_(e_missbrac)); return FAIL; } *arg = *arg + 1; // We can index a list and a dict. If we don't know the type // we can use the index value type. // TODO: If we don't know use an instruction to figure it out at // runtime. typep = ((type_T **)stack->ga_data) + stack->ga_len - (is_slice ? 3 : 2); vtype = (*typep)->tt_type; valtype = ((type_T **)stack->ga_data)[stack->ga_len - 1]; // If the index is a string, the variable must be a Dict. if (*typep == &t_any && valtype == &t_string) vtype = VAR_DICT; if (vtype == VAR_STRING || vtype == VAR_LIST || vtype == VAR_BLOB) { if (need_type(valtype, &t_number, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; if (is_slice) { valtype = ((type_T **)stack->ga_data)[stack->ga_len - 2]; if (need_type(valtype, &t_number, -2, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; } } if (vtype == VAR_DICT) { if (is_slice) { emsg(_(e_cannot_slice_dictionary)); return FAIL; } if ((*typep)->tt_type == VAR_DICT) { *typep = (*typep)->tt_member; if (*typep == &t_unknown) // empty dict was used *typep = &t_any; } else { if (need_type(*typep, &t_dict_any, -2, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; *typep = &t_any; } if (may_generate_2STRING(-1, cctx) == FAIL) return FAIL; if (generate_instr_drop(cctx, ISN_MEMBER, 1) == FAIL) return FAIL; } else if (vtype == VAR_STRING) { *typep = &t_string; if ((is_slice ? generate_instr_drop(cctx, ISN_STRSLICE, 2) : generate_instr_drop(cctx, ISN_STRINDEX, 1)) == FAIL) return FAIL; } else if (vtype == VAR_BLOB) { emsg("Sorry, blob index and slice not implemented yet"); return FAIL; } else if (vtype == VAR_LIST || *typep == &t_any) { if (is_slice) { if (generate_instr_drop(cctx, vtype == VAR_LIST ? ISN_LISTSLICE : ISN_ANYSLICE, 2) == FAIL) return FAIL; } else { if ((*typep)->tt_type == VAR_LIST) { *typep = (*typep)->tt_member; if (*typep == &t_unknown) // empty list was used *typep = &t_any; } if (generate_instr_drop(cctx, vtype == VAR_LIST ? ISN_LISTINDEX : ISN_ANYINDEX, 1) == FAIL) return FAIL; } } else { emsg(_(e_string_list_dict_or_blob_required)); return FAIL; } } else if (*p == '.' && p[1] != '.') { // dictionary member: dict.name if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ppconst->pp_is_const = FALSE; *arg = p + 1; if (may_get_next_line(*arg, arg, cctx) == FAIL) { emsg(_(e_missing_name_after_dot)); return FAIL; } p = *arg; if (eval_isdictc(*p)) while (eval_isnamec(*p)) MB_PTR_ADV(p); if (p == *arg) { semsg(_(e_syntax_error_at_str), *arg); return FAIL; } if (generate_STRINGMEMBER(cctx, *arg, p - *arg) == FAIL) return FAIL; *arg = p; } else break; } // TODO - see handle_subscript(): // Turn "dict.Func" into a partial for "Func" bound to "dict". // Don't do this when "Func" is already a partial that was bound // explicitly (pt_auto is FALSE). return OK; } /* * Compile an expression at "*arg" and add instructions to "cctx->ctx_instr". * "arg" is advanced until after the expression, skipping white space. * * If the value is a constant "ppconst->pp_used" will be non-zero. * Before instructions are generated, any values in "ppconst" will generated. * * This is the compiling equivalent of eval1(), eval2(), etc. */ /* * number number constant * 0zFFFFFFFF Blob constant * "string" string constant * 'string' literal string constant * &option-name option value * @r register contents * identifier variable value * function() function call * $VAR environment variable * (expression) nested expression * [expr, expr] List * {key: val, [key]: val} Dictionary * * Also handle: * ! in front logical NOT * - in front unary minus * + in front unary plus (ignored) * trailing (arg) funcref/partial call * trailing [] subscript in String or List * trailing .name entry in Dictionary * trailing ->name() method call */ static int compile_expr7( char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { char_u *start_leader, *end_leader; int ret = OK; typval_T *rettv = &ppconst->pp_tv[ppconst->pp_used]; int used_before = ppconst->pp_used; ppconst->pp_is_const = FALSE; /* * Skip '!', '-' and '+' characters. They are handled later. */ start_leader = *arg; if (eval_leader(arg, TRUE) == FAIL) return FAIL; end_leader = *arg; rettv->v_type = VAR_UNKNOWN; switch (**arg) { /* * Number constant. */ case '0': // also for blob starting with 0z case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': case '.': if (eval_number(arg, rettv, TRUE, FALSE) == FAIL) return FAIL; // Apply "-" and "+" just before the number now, right to // left. Matters especially when "->" follows. Stops at // '!'. if (apply_leader(rettv, TRUE, start_leader, &end_leader) == FAIL) { clear_tv(rettv); return FAIL; } break; /* * String constant: "string". */ case '"': if (eval_string(arg, rettv, TRUE) == FAIL) return FAIL; break; /* * Literal string constant: 'str''ing'. */ case '\'': if (eval_lit_string(arg, rettv, TRUE) == FAIL) return FAIL; break; /* * Constant Vim variable. */ case 'v': get_vim_constant(arg, rettv); ret = NOTDONE; break; /* * "true" constant */ case 't': if (STRNCMP(*arg, "true", 4) == 0 && !eval_isnamec((*arg)[4])) { *arg += 4; rettv->v_type = VAR_BOOL; rettv->vval.v_number = VVAL_TRUE; } else ret = NOTDONE; break; /* * "false" constant */ case 'f': if (STRNCMP(*arg, "false", 5) == 0 && !eval_isnamec((*arg)[5])) { *arg += 5; rettv->v_type = VAR_BOOL; rettv->vval.v_number = VVAL_FALSE; } else ret = NOTDONE; break; /* * "null" constant */ case 'n': if (STRNCMP(*arg, "null", 4) == 0 && !eval_isnamec((*arg)[5])) { *arg += 4; rettv->v_type = VAR_SPECIAL; rettv->vval.v_number = VVAL_NULL; } else ret = NOTDONE; break; /* * List: [expr, expr] */ case '[': ret = compile_list(arg, cctx, ppconst); break; /* * Dictionary: {'key': val, 'key': val} */ case '{': ret = compile_dict(arg, cctx, ppconst); break; /* * Option value: &name */ case '&': if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ret = compile_get_option(arg, cctx); break; /* * Environment variable: $VAR. */ case '$': if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ret = compile_get_env(arg, cctx); break; /* * Register contents: @r. */ case '@': if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; ret = compile_get_register(arg, cctx); break; /* * nested expression: (expression). * lambda: (arg, arg) => expr * funcref: (arg, arg) => { statement } */ case '(': // if compile_lambda returns NOTDONE then it must be (expr) ret = compile_lambda(arg, cctx); if (ret == NOTDONE) ret = compile_parenthesis(arg, cctx, ppconst); break; default: ret = NOTDONE; break; } if (ret == FAIL) return FAIL; if (rettv->v_type != VAR_UNKNOWN && used_before == ppconst->pp_used) { if (cctx->ctx_skip == SKIP_YES) clear_tv(rettv); else // A constant expression can possibly be handled compile time, // return the value instead of generating code. ++ppconst->pp_used; } else if (ret == NOTDONE) { char_u *p; int r; if (!eval_isnamec1(**arg)) { if (ends_excmd(*skipwhite(*arg))) semsg(_(e_empty_expression_str), *arg); else semsg(_(e_name_expected_str), *arg); return FAIL; } // "name" or "name()" p = to_name_end(*arg, TRUE); if (*p == '(') { r = compile_call(arg, p - *arg, cctx, ppconst, 0); } else { if (generate_ppconst(cctx, ppconst) == FAIL) return FAIL; r = compile_load(arg, p, cctx, TRUE, TRUE); } if (r == FAIL) return FAIL; } // Handle following "[]", ".member", etc. // Then deal with prefixed '-', '+' and '!', if not done already. if (compile_subscript(arg, cctx, start_leader, &end_leader, ppconst) == FAIL) return FAIL; if (ppconst->pp_used > 0) { // apply the '!', '-' and '+' before the constant rettv = &ppconst->pp_tv[ppconst->pp_used - 1]; if (apply_leader(rettv, FALSE, start_leader, &end_leader) == FAIL) return FAIL; return OK; } if (compile_leader(cctx, FALSE, start_leader, &end_leader) == FAIL) return FAIL; return OK; } /* * Give the "white on both sides" error, taking the operator from "p[len]". */ void error_white_both(char_u *op, int len) { char_u buf[10]; vim_strncpy(buf, op, len); semsg(_(e_white_space_required_before_and_after_str_at_str), buf, op); } /* * <type>expr7: runtime type check / conversion */ static int compile_expr7t(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { type_T *want_type = NULL; // Recognize <type> if (**arg == '<' && eval_isnamec1((*arg)[1])) { ++*arg; want_type = parse_type(arg, cctx->ctx_type_list, TRUE); if (want_type == NULL) return FAIL; if (**arg != '>') { if (*skipwhite(*arg) == '>') semsg(_(e_no_white_space_allowed_before_str), ">"); else emsg(_(e_missing_gt)); return FAIL; } ++*arg; if (may_get_next_line_error(*arg, arg, cctx) == FAIL) return FAIL; } if (compile_expr7(arg, cctx, ppconst) == FAIL) return FAIL; if (want_type != NULL) { garray_T *stack = &cctx->ctx_type_stack; type_T *actual; generate_ppconst(cctx, ppconst); actual = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (check_type(want_type, actual, FALSE, 0) == FAIL) { if (need_type(actual, want_type, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; } } return OK; } /* * * number multiplication * / number division * % number modulo */ static int compile_expr6(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { char_u *op; char_u *next; int ppconst_used = ppconst->pp_used; // get the first expression if (compile_expr7t(arg, cctx, ppconst) == FAIL) return FAIL; /* * Repeat computing, until no "*", "/" or "%" is following. */ for (;;) { op = may_peek_next_line(cctx, *arg, &next); if (*op != '*' && *op != '/' && *op != '%') break; if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); op = skipwhite(*arg); } if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(op[1])) { error_white_both(op, 1); return FAIL; } if (may_get_next_line_error(op + 1, arg, cctx) == FAIL) return FAIL; // get the second expression if (compile_expr7t(arg, cctx, ppconst) == FAIL) return FAIL; if (ppconst->pp_used == ppconst_used + 2 && ppconst->pp_tv[ppconst_used].v_type == VAR_NUMBER && ppconst->pp_tv[ppconst_used + 1].v_type == VAR_NUMBER) { typval_T *tv1 = &ppconst->pp_tv[ppconst_used]; typval_T *tv2 = &ppconst->pp_tv[ppconst_used + 1]; varnumber_T res = 0; int failed = FALSE; // both are numbers: compute the result switch (*op) { case '*': res = tv1->vval.v_number * tv2->vval.v_number; break; case '/': res = num_divide(tv1->vval.v_number, tv2->vval.v_number, &failed); break; case '%': res = num_modulus(tv1->vval.v_number, tv2->vval.v_number, &failed); break; } if (failed) return FAIL; tv1->vval.v_number = res; --ppconst->pp_used; } else { generate_ppconst(cctx, ppconst); generate_two_op(cctx, op); } } return OK; } /* * + number addition * - number subtraction * .. string concatenation */ static int compile_expr5(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { char_u *op; char_u *next; int oplen; int ppconst_used = ppconst->pp_used; // get the first variable if (compile_expr6(arg, cctx, ppconst) == FAIL) return FAIL; /* * Repeat computing, until no "+", "-" or ".." is following. */ for (;;) { op = may_peek_next_line(cctx, *arg, &next); if (*op != '+' && *op != '-' && !(*op == '.' && *(op + 1) == '.')) break; oplen = (*op == '.' ? 2 : 1); if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); op = skipwhite(*arg); } if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(op[oplen])) { error_white_both(op, oplen); return FAIL; } if (may_get_next_line_error(op + oplen, arg, cctx) == FAIL) return FAIL; // get the second expression if (compile_expr6(arg, cctx, ppconst) == FAIL) return FAIL; if (ppconst->pp_used == ppconst_used + 2 && (*op == '.' ? (ppconst->pp_tv[ppconst_used].v_type == VAR_STRING && ppconst->pp_tv[ppconst_used + 1].v_type == VAR_STRING) : (ppconst->pp_tv[ppconst_used].v_type == VAR_NUMBER && ppconst->pp_tv[ppconst_used + 1].v_type == VAR_NUMBER))) { typval_T *tv1 = &ppconst->pp_tv[ppconst_used]; typval_T *tv2 = &ppconst->pp_tv[ppconst_used + 1]; // concat/subtract/add constant numbers if (*op == '+') tv1->vval.v_number = tv1->vval.v_number + tv2->vval.v_number; else if (*op == '-') tv1->vval.v_number = tv1->vval.v_number - tv2->vval.v_number; else { // concatenate constant strings char_u *s1 = tv1->vval.v_string; char_u *s2 = tv2->vval.v_string; size_t len1 = STRLEN(s1); tv1->vval.v_string = alloc((int)(len1 + STRLEN(s2) + 1)); if (tv1->vval.v_string == NULL) { clear_ppconst(ppconst); return FAIL; } mch_memmove(tv1->vval.v_string, s1, len1); STRCPY(tv1->vval.v_string + len1, s2); vim_free(s1); vim_free(s2); } --ppconst->pp_used; } else { generate_ppconst(cctx, ppconst); if (*op == '.') { if (may_generate_2STRING(-2, cctx) == FAIL || may_generate_2STRING(-1, cctx) == FAIL) return FAIL; generate_instr_drop(cctx, ISN_CONCAT, 1); } else generate_two_op(cctx, op); } } return OK; } /* * expr5a == expr5b * expr5a =~ expr5b * expr5a != expr5b * expr5a !~ expr5b * expr5a > expr5b * expr5a >= expr5b * expr5a < expr5b * expr5a <= expr5b * expr5a is expr5b * expr5a isnot expr5b * * Produces instructions: * EVAL expr5a Push result of "expr5a" * EVAL expr5b Push result of "expr5b" * COMPARE one of the compare instructions */ static int compile_expr4(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { exprtype_T type = EXPR_UNKNOWN; char_u *p; char_u *next; int len = 2; int type_is = FALSE; int ppconst_used = ppconst->pp_used; // get the first variable if (compile_expr5(arg, cctx, ppconst) == FAIL) return FAIL; p = may_peek_next_line(cctx, *arg, &next); type = get_compare_type(p, &len, &type_is); /* * If there is a comparative operator, use it. */ if (type != EXPR_UNKNOWN) { int ic = FALSE; // Default: do not ignore case if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); p = skipwhite(*arg); } if (type_is && (p[len] == '?' || p[len] == '#')) { semsg(_(e_invexpr2), *arg); return FAIL; } // extra question mark appended: ignore case if (p[len] == '?') { ic = TRUE; ++len; } // extra '#' appended: match case (ignored) else if (p[len] == '#') ++len; // nothing appended: match case if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(p[len])) { error_white_both(p, len); return FAIL; } // get the second variable if (may_get_next_line_error(p + len, arg, cctx) == FAIL) return FAIL; if (compile_expr5(arg, cctx, ppconst) == FAIL) return FAIL; if (ppconst->pp_used == ppconst_used + 2) { typval_T * tv1 = &ppconst->pp_tv[ppconst->pp_used - 2]; typval_T *tv2 = &ppconst->pp_tv[ppconst->pp_used - 1]; int ret; // Both sides are a constant, compute the result now. // First check for a valid combination of types, this is more // strict than typval_compare(). if (check_compare_types(type, tv1, tv2) == FAIL) ret = FAIL; else { ret = typval_compare(tv1, tv2, type, ic); tv1->v_type = VAR_BOOL; tv1->vval.v_number = tv1->vval.v_number ? VVAL_TRUE : VVAL_FALSE; clear_tv(tv2); --ppconst->pp_used; } return ret; } generate_ppconst(cctx, ppconst); return generate_COMPARE(cctx, type, ic); } return OK; } static int compile_expr3(char_u **arg, cctx_T *cctx, ppconst_T *ppconst); /* * Compile || or &&. */ static int compile_and_or( char_u **arg, cctx_T *cctx, char *op, ppconst_T *ppconst, int ppconst_used UNUSED) { char_u *next; char_u *p = may_peek_next_line(cctx, *arg, &next); int opchar = *op; if (p[0] == opchar && p[1] == opchar) { garray_T *instr = &cctx->ctx_instr; garray_T end_ga; /* * Repeat until there is no following "||" or "&&" */ ga_init2(&end_ga, sizeof(int), 10); while (p[0] == opchar && p[1] == opchar) { if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); p = skipwhite(*arg); } if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(p[2])) { semsg(_(e_white_space_required_before_and_after_str_at_str), op, *arg); return FAIL; } // TODO: use ppconst if the value is a constant and check // evaluating to bool generate_ppconst(cctx, ppconst); // Every part must evaluate to a bool. if (bool_on_stack(cctx) == FAIL) { ga_clear(&end_ga); return FAIL; } if (ga_grow(&end_ga, 1) == FAIL) { ga_clear(&end_ga); return FAIL; } *(((int *)end_ga.ga_data) + end_ga.ga_len) = instr->ga_len; ++end_ga.ga_len; generate_JUMP(cctx, opchar == '|' ? JUMP_IF_COND_TRUE : JUMP_IF_COND_FALSE, 0); // eval the next expression if (may_get_next_line_error(p + 2, arg, cctx) == FAIL) { ga_clear(&end_ga); return FAIL; } if ((opchar == '|' ? compile_expr3(arg, cctx, ppconst) : compile_expr4(arg, cctx, ppconst)) == FAIL) { ga_clear(&end_ga); return FAIL; } p = may_peek_next_line(cctx, *arg, &next); } generate_ppconst(cctx, ppconst); // Every part must evaluate to a bool. if (bool_on_stack(cctx) == FAIL) { ga_clear(&end_ga); return FAIL; } // Fill in the end label in all jumps. while (end_ga.ga_len > 0) { isn_T *isn; --end_ga.ga_len; isn = ((isn_T *)instr->ga_data) + *(((int *)end_ga.ga_data) + end_ga.ga_len); isn->isn_arg.jump.jump_where = instr->ga_len; } ga_clear(&end_ga); } return OK; } /* * expr4a && expr4a && expr4a logical AND * * Produces instructions: * EVAL expr4a Push result of "expr4a" * COND2BOOL convert to bool if needed * JUMP_IF_COND_FALSE end * EVAL expr4b Push result of "expr4b" * JUMP_IF_COND_FALSE end * EVAL expr4c Push result of "expr4c" * end: */ static int compile_expr3(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { int ppconst_used = ppconst->pp_used; // get the first variable if (compile_expr4(arg, cctx, ppconst) == FAIL) return FAIL; // || and && work almost the same return compile_and_or(arg, cctx, "&&", ppconst, ppconst_used); } /* * expr3a || expr3b || expr3c logical OR * * Produces instructions: * EVAL expr3a Push result of "expr3a" * COND2BOOL convert to bool if needed * JUMP_IF_COND_TRUE end * EVAL expr3b Push result of "expr3b" * JUMP_IF_COND_TRUE end * EVAL expr3c Push result of "expr3c" * end: */ static int compile_expr2(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { int ppconst_used = ppconst->pp_used; // eval the first expression if (compile_expr3(arg, cctx, ppconst) == FAIL) return FAIL; // || and && work almost the same return compile_and_or(arg, cctx, "||", ppconst, ppconst_used); } /* * Toplevel expression: expr2 ? expr1a : expr1b * Produces instructions: * EVAL expr2 Push result of "expr2" * JUMP_IF_FALSE alt jump if false * EVAL expr1a * JUMP_ALWAYS end * alt: EVAL expr1b * end: * * Toplevel expression: expr2 ?? expr1 * Produces instructions: * EVAL expr2 Push result of "expr2" * JUMP_AND_KEEP_IF_TRUE end jump if true * EVAL expr1 * end: */ static int compile_expr1(char_u **arg, cctx_T *cctx, ppconst_T *ppconst) { char_u *p; int ppconst_used = ppconst->pp_used; char_u *next; // Ignore all kinds of errors when not producing code. if (cctx->ctx_skip == SKIP_YES) { skip_expr_cctx(arg, cctx); return OK; } // Evaluate the first expression. if (compile_expr2(arg, cctx, ppconst) == FAIL) return FAIL; p = may_peek_next_line(cctx, *arg, &next); if (*p == '?') { int op_falsy = p[1] == '?'; garray_T *instr = &cctx->ctx_instr; garray_T *stack = &cctx->ctx_type_stack; int alt_idx = instr->ga_len; int end_idx = 0; isn_T *isn; type_T *type1 = NULL; int has_const_expr = FALSE; int const_value = FALSE; int save_skip = cctx->ctx_skip; if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); p = skipwhite(*arg); } if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(p[1 + op_falsy])) { semsg(_(e_white_space_required_before_and_after_str_at_str), op_falsy ? "??" : "?", *arg); return FAIL; } if (ppconst->pp_used == ppconst_used + 1) { // the condition is a constant, we know whether the ? or the : // expression is to be evaluated. has_const_expr = TRUE; if (op_falsy) const_value = tv2bool(&ppconst->pp_tv[ppconst_used]); else { int error = FALSE; const_value = tv_get_bool_chk(&ppconst->pp_tv[ppconst_used], &error); if (error) return FAIL; } cctx->ctx_skip = save_skip == SKIP_YES || (op_falsy ? const_value : !const_value) ? SKIP_YES : SKIP_NOT; if (op_falsy && cctx->ctx_skip == SKIP_YES) // "left ?? right" and "left" is truthy: produce "left" generate_ppconst(cctx, ppconst); else { clear_tv(&ppconst->pp_tv[ppconst_used]); --ppconst->pp_used; } } else { generate_ppconst(cctx, ppconst); if (op_falsy) end_idx = instr->ga_len; generate_JUMP(cctx, op_falsy ? JUMP_AND_KEEP_IF_TRUE : JUMP_IF_FALSE, 0); if (op_falsy) type1 = ((type_T **)stack->ga_data)[stack->ga_len]; } // evaluate the second expression; any type is accepted if (may_get_next_line_error(p + 1 + op_falsy, arg, cctx) == FAIL) return FAIL; if (compile_expr1(arg, cctx, ppconst) == FAIL) return FAIL; if (!has_const_expr) { generate_ppconst(cctx, ppconst); if (!op_falsy) { // remember the type and drop it --stack->ga_len; type1 = ((type_T **)stack->ga_data)[stack->ga_len]; end_idx = instr->ga_len; generate_JUMP(cctx, JUMP_ALWAYS, 0); // jump here from JUMP_IF_FALSE isn = ((isn_T *)instr->ga_data) + alt_idx; isn->isn_arg.jump.jump_where = instr->ga_len; } } if (!op_falsy) { // Check for the ":". p = may_peek_next_line(cctx, *arg, &next); if (*p != ':') { emsg(_(e_missing_colon)); return FAIL; } if (next != NULL) { *arg = next_line_from_context(cctx, TRUE); p = skipwhite(*arg); } if (!IS_WHITE_OR_NUL(**arg) || !IS_WHITE_OR_NUL(p[1])) { semsg(_(e_white_space_required_before_and_after_str_at_str), ":", p); return FAIL; } // evaluate the third expression if (has_const_expr) cctx->ctx_skip = save_skip == SKIP_YES || const_value ? SKIP_YES : SKIP_NOT; if (may_get_next_line_error(p + 1, arg, cctx) == FAIL) return FAIL; if (compile_expr1(arg, cctx, ppconst) == FAIL) return FAIL; } if (!has_const_expr) { type_T **typep; generate_ppconst(cctx, ppconst); // If the types differ, the result has a more generic type. typep = ((type_T **)stack->ga_data) + stack->ga_len - 1; common_type(type1, *typep, typep, cctx->ctx_type_list); // jump here from JUMP_ALWAYS or JUMP_AND_KEEP_IF_TRUE isn = ((isn_T *)instr->ga_data) + end_idx; isn->isn_arg.jump.jump_where = instr->ga_len; } cctx->ctx_skip = save_skip; } return OK; } /* * Toplevel expression. * Sets "is_const" (if not NULL) to indicate the value is a constant. * Returns OK or FAIL. */ static int compile_expr0_ext(char_u **arg, cctx_T *cctx, int *is_const) { ppconst_T ppconst; CLEAR_FIELD(ppconst); if (compile_expr1(arg, cctx, &ppconst) == FAIL) { clear_ppconst(&ppconst); return FAIL; } if (is_const != NULL) *is_const = ppconst.pp_used > 0 || ppconst.pp_is_const; if (generate_ppconst(cctx, &ppconst) == FAIL) return FAIL; return OK; } /* * Toplevel expression. */ static int compile_expr0(char_u **arg, cctx_T *cctx) { return compile_expr0_ext(arg, cctx, NULL); } /* * compile "return [expr]" */ static char_u * compile_return(char_u *arg, int check_return_type, cctx_T *cctx) { char_u *p = arg; garray_T *stack = &cctx->ctx_type_stack; type_T *stack_type; if (*p != NUL && *p != '|' && *p != '\n') { // compile return argument into instructions if (compile_expr0(&p, cctx) == FAIL) return NULL; if (cctx->ctx_skip != SKIP_YES) { stack_type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (check_return_type && (cctx->ctx_ufunc->uf_ret_type == NULL || cctx->ctx_ufunc->uf_ret_type == &t_unknown || cctx->ctx_ufunc->uf_ret_type == &t_any)) { cctx->ctx_ufunc->uf_ret_type = stack_type; } else { if (cctx->ctx_ufunc->uf_ret_type->tt_type == VAR_VOID && stack_type->tt_type != VAR_VOID && stack_type->tt_type != VAR_UNKNOWN) { emsg(_(e_returning_value_in_function_without_return_type)); return NULL; } if (need_type(stack_type, cctx->ctx_ufunc->uf_ret_type, -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; } // No argument, return zero. generate_PUSHNR(cctx, 0); } // 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); } /* * Get a line from the compilation context, compatible with exarg_T getline(). * Return a pointer to the line in allocated memory. * Return NULL for end-of-file or some error. */ static char_u * exarg_getline( int c UNUSED, void *cookie, int indent UNUSED, getline_opt_T options UNUSED) { cctx_T *cctx = (cctx_T *)cookie; char_u *p; for (;;) { if (cctx->ctx_lnum >= cctx->ctx_ufunc->uf_lines.ga_len - 1) return NULL; ++cctx->ctx_lnum; p = ((char_u **)cctx->ctx_ufunc->uf_lines.ga_data)[cctx->ctx_lnum]; // Comment lines result in NULL pointers, skip them. if (p != NULL) return vim_strsave(p); } } /* * Compile a nested :def command. */ static char_u * compile_nested_function(exarg_T *eap, cctx_T *cctx) { int is_global = *eap->arg == 'g' && eap->arg[1] == ':'; char_u *name_start = eap->arg; char_u *name_end = to_name_end(eap->arg, TRUE); char_u *lambda_name; ufunc_T *ufunc; int r = FAIL; if (eap->forceit) { emsg(_(e_cannot_use_bang_with_nested_def)); return NULL; } if (*name_start == '/') { name_end = skip_regexp(name_start + 1, '/', TRUE); if (*name_end == '/') ++name_end; eap->nextcmd = check_nextcmd(name_end); } if (name_end == name_start || *skipwhite(name_end) != '(') { if (!ends_excmd2(name_start, name_end)) { semsg(_(e_invalid_command_str), eap->cmd); return NULL; } // "def" or "def Name": list functions if (generate_DEF(cctx, name_start, name_end - name_start) == FAIL) return NULL; return eap->nextcmd == NULL ? (char_u *)"" : eap->nextcmd; } // Only g:Func() can use a namespace. if (name_start[1] == ':' && !is_global) { semsg(_(e_namespace_not_supported_str), name_start); return NULL; } if (check_defined(name_start, name_end - name_start, cctx) == FAIL) return NULL; eap->arg = name_end; eap->getline = exarg_getline; eap->cookie = cctx; eap->skip = cctx->ctx_skip == SKIP_YES; eap->forceit = FALSE; lambda_name = vim_strsave(get_lambda_name()); if (lambda_name == NULL) return NULL; ufunc = define_function(eap, lambda_name); if (ufunc == NULL) { r = eap->skip ? OK : FAIL; goto theend; } if (ufunc->uf_def_status == UF_TO_BE_COMPILED && compile_def_function(ufunc, TRUE, cctx) == FAIL) { func_ptr_unref(ufunc); goto theend; } if (is_global) { char_u *func_name = vim_strnsave(name_start + 2, name_end - name_start - 2); if (func_name == NULL) r = FAIL; else { r = generate_NEWFUNC(cctx, lambda_name, func_name); lambda_name = NULL; } } else { // Define a local variable for the function reference. lvar_T *lvar = reserve_local(cctx, name_start, name_end - name_start, TRUE, ufunc->uf_func_type); int block_depth = cctx->ctx_ufunc->uf_block_depth; if (lvar == NULL) goto theend; if (generate_FUNCREF(cctx, ufunc) == FAIL) goto theend; r = generate_STORE(cctx, ISN_STORE, lvar->lv_idx, NULL); // copy over the block scope IDs if (block_depth > 0) { ufunc->uf_block_ids = ALLOC_MULT(int, block_depth); if (ufunc->uf_block_ids != NULL) { mch_memmove(ufunc->uf_block_ids, cctx->ctx_ufunc->uf_block_ids, sizeof(int) * block_depth); ufunc->uf_block_depth = block_depth; } } } // TODO: warning for trailing text? r = OK; theend: vim_free(lambda_name); return r == FAIL ? NULL : (char_u *)""; } /* * Return the length of an assignment operator, or zero if there isn't one. */ int assignment_len(char_u *p, int *heredoc) { if (*p == '=') { if (p[1] == '<' && p[2] == '<') { *heredoc = TRUE; return 3; } return 1; } if (vim_strchr((char_u *)"+-*/%", *p) != NULL && p[1] == '=') return 2; if (STRNCMP(p, "..=", 3) == 0) return 3; return 0; } // words that cannot be used as a variable static char *reserved[] = { "true", "false", "null", NULL }; // Destination for an assignment or ":unlet" with an index. typedef enum { dest_local, dest_option, dest_env, dest_global, dest_buffer, dest_window, dest_tab, dest_vimvar, dest_script, dest_reg, dest_expr, } assign_dest_T; // Used by compile_lhs() to store information about the LHS of an assignment // and one argument of ":unlet" with an index. typedef struct { assign_dest_T lhs_dest; // type of destination char_u *lhs_name; // allocated name including // "[expr]" or ".name". size_t lhs_varlen; // length of the variable without // "[expr]" or ".name" char_u *lhs_dest_end; // end of the destination, including // "[expr]" or ".name". int lhs_has_index; // has "[expr]" or ".name" int lhs_new_local; // create new local variable int lhs_opt_flags; // for when destination is an option int lhs_vimvaridx; // for when destination is a v:var lvar_T lhs_local_lvar; // used for existing local destination lvar_T lhs_arg_lvar; // used for argument destination lvar_T *lhs_lvar; // points to destination lvar int lhs_scriptvar_sid; int lhs_scriptvar_idx; int lhs_has_type; // type was specified type_T *lhs_type; type_T *lhs_member_type; } lhs_T; /* * Generate the load instruction for "name". */ static void generate_loadvar( cctx_T *cctx, assign_dest_T dest, char_u *name, lvar_T *lvar, type_T *type) { switch (dest) { case dest_option: // TODO: check the option exists generate_LOAD(cctx, ISN_LOADOPT, 0, name, type); break; case dest_global: if (vim_strchr(name, AUTOLOAD_CHAR) == NULL) generate_LOAD(cctx, ISN_LOADG, 0, name + 2, type); else generate_LOAD(cctx, ISN_LOADAUTO, 0, name, type); break; case dest_buffer: generate_LOAD(cctx, ISN_LOADB, 0, name + 2, type); break; case dest_window: generate_LOAD(cctx, ISN_LOADW, 0, name + 2, type); break; case dest_tab: generate_LOAD(cctx, ISN_LOADT, 0, name + 2, type); break; case dest_script: compile_load_scriptvar(cctx, name + (name[1] == ':' ? 2 : 0), NULL, NULL, TRUE); break; case dest_env: // Include $ in the name here generate_LOAD(cctx, ISN_LOADENV, 0, name, type); break; case dest_reg: generate_LOAD(cctx, ISN_LOADREG, name[1], NULL, &t_string); break; case dest_vimvar: generate_LOADV(cctx, name + 2, TRUE); break; case dest_local: if (lvar->lv_from_outer > 0) generate_LOADOUTER(cctx, lvar->lv_idx, lvar->lv_from_outer, type); else generate_LOAD(cctx, ISN_LOAD, lvar->lv_idx, NULL, type); break; case dest_expr: // list or dict value should already be on the stack. break; } } /* * Skip over "[expr]" or ".member". * Does not check for any errors. */ static char_u * skip_index(char_u *start) { char_u *p = start; if (*p == '[') { p = skipwhite(p + 1); (void)skip_expr(&p, NULL); p = skipwhite(p); if (*p == ']') return p + 1; return p; } // if (*p == '.') return to_name_end(p + 1, TRUE); } void vim9_declare_error(char_u *name) { char *scope = ""; switch (*name) { case 'g': scope = _("global"); break; case 'b': scope = _("buffer"); break; case 'w': scope = _("window"); break; case 't': scope = _("tab"); break; case 'v': scope = "v:"; break; case '$': semsg(_(e_cannot_declare_an_environment_variable), name); return; case '&': semsg(_(e_cannot_declare_an_option), name); return; case '@': semsg(_(e_cannot_declare_a_register_str), name); return; default: return; } semsg(_(e_cannot_declare_a_scope_variable), scope, name); } /* * For one assignment figure out the type of destination. Return it in "dest". * When not recognized "dest" is not set. * For an option "opt_flags" is set. * For a v:var "vimvaridx" is set. * "type" is set to the destination type if known, unchanted otherwise. * Return FAIL if an error message was given. */ static int get_var_dest( char_u *name, assign_dest_T *dest, int cmdidx, int *opt_flags, int *vimvaridx, type_T **type, cctx_T *cctx) { char_u *p; if (*name == '&') { int cc; long numval; getoption_T opt_type; *dest = dest_option; if (cmdidx == CMD_final || cmdidx == CMD_const) { emsg(_(e_const_option)); return FAIL; } p = name; p = find_option_end(&p, opt_flags); if (p == NULL) { // cannot happen? emsg(_(e_letunexp)); return FAIL; } cc = *p; *p = NUL; opt_type = get_option_value(skip_option_env_lead(name), &numval, NULL, *opt_flags); *p = cc; switch (opt_type) { case gov_unknown: semsg(_(e_unknown_option), name); return FAIL; case gov_string: case gov_hidden_string: *type = &t_string; break; case gov_bool: case gov_hidden_bool: *type = &t_bool; break; case gov_number: case gov_hidden_number: *type = &t_number; break; } } else if (*name == '$') { *dest = dest_env; *type = &t_string; } else if (*name == '@') { if (!valid_yank_reg(name[1], FALSE) || name[1] == '.') { emsg_invreg(name[1]); return FAIL; } *dest = dest_reg; *type = &t_string; } else if (STRNCMP(name, "g:", 2) == 0) { *dest = dest_global; } else if (STRNCMP(name, "b:", 2) == 0) { *dest = dest_buffer; } else if (STRNCMP(name, "w:", 2) == 0) { *dest = dest_window; } else if (STRNCMP(name, "t:", 2) == 0) { *dest = dest_tab; } else if (STRNCMP(name, "v:", 2) == 0) { typval_T *vtv; int di_flags; *vimvaridx = find_vim_var(name + 2, &di_flags); if (*vimvaridx < 0) { semsg(_(e_variable_not_found_str), name); return FAIL; } // We use the current value of "sandbox" here, is that OK? if (var_check_ro(di_flags, name, FALSE)) return FAIL; *dest = dest_vimvar; vtv = get_vim_var_tv(*vimvaridx); *type = typval2type_vimvar(vtv, cctx->ctx_type_list); } return OK; } /* * Generate a STORE instruction for "dest", not being "dest_local". * Return FAIL when out of memory. */ static int generate_store_var( cctx_T *cctx, assign_dest_T dest, int opt_flags, int vimvaridx, int scriptvar_idx, int scriptvar_sid, type_T *type, char_u *name) { switch (dest) { case dest_option: return generate_STOREOPT(cctx, skip_option_env_lead(name), opt_flags); case dest_global: // include g: with the name, easier to execute that way return generate_STORE(cctx, vim_strchr(name, AUTOLOAD_CHAR) == NULL ? ISN_STOREG : ISN_STOREAUTO, 0, name); case dest_buffer: // include b: with the name, easier to execute that way return generate_STORE(cctx, ISN_STOREB, 0, name); case dest_window: // include w: with the name, easier to execute that way return generate_STORE(cctx, ISN_STOREW, 0, name); case dest_tab: // include t: with the name, easier to execute that way return generate_STORE(cctx, ISN_STORET, 0, name); case dest_env: return generate_STORE(cctx, ISN_STOREENV, 0, name + 1); case dest_reg: return generate_STORE(cctx, ISN_STOREREG, name[1], NULL); case dest_vimvar: return generate_STORE(cctx, ISN_STOREV, vimvaridx, NULL); case dest_script: if (scriptvar_idx < 0) { char_u *name_s = name; int r; // "s:" is included in the name. r = generate_OLDSCRIPT(cctx, ISN_STORES, name_s, scriptvar_sid, type); if (name_s != name) vim_free(name_s); return r; } return generate_VIM9SCRIPT(cctx, ISN_STORESCRIPT, scriptvar_sid, scriptvar_idx, type); case dest_local: case dest_expr: // cannot happen break; } return FAIL; } static int is_decl_command(int cmdidx) { return cmdidx == CMD_let || cmdidx == CMD_var || cmdidx == CMD_final || cmdidx == CMD_const; } /* * Figure out the LHS type and other properties for an assignment or one item * of ":unlet" with an index. * Returns OK or FAIL. */ static int compile_lhs( char_u *var_start, lhs_T *lhs, int cmdidx, int heredoc, int oplen, cctx_T *cctx) { char_u *var_end; int is_decl = is_decl_command(cmdidx); CLEAR_POINTER(lhs); lhs->lhs_dest = dest_local; lhs->lhs_vimvaridx = -1; lhs->lhs_scriptvar_idx = -1; // "dest_end" is the end of the destination, including "[expr]" or // ".name". // "var_end" is the end of the variable/option/etc. name. lhs->lhs_dest_end = skip_var_one(var_start, FALSE); if (*var_start == '@') var_end = var_start + 2; else { // skip over the leading "&", "&l:", "&g:" and "$" var_end = skip_option_env_lead(var_start); var_end = to_name_end(var_end, TRUE); } // "a: type" is declaring variable "a" with a type, not dict "a:". if (is_decl && lhs->lhs_dest_end == var_start + 2 && lhs->lhs_dest_end[-1] == ':') --lhs->lhs_dest_end; if (is_decl && var_end == var_start + 2 && var_end[-1] == ':') --var_end; // compute the length of the destination without "[expr]" or ".name" lhs->lhs_varlen = var_end - var_start; lhs->lhs_name = vim_strnsave(var_start, lhs->lhs_varlen); if (lhs->lhs_name == NULL) return FAIL; if (lhs->lhs_dest_end > var_start + lhs->lhs_varlen) // Something follows after the variable: "var[idx]" or "var.key". lhs->lhs_has_index = TRUE; if (heredoc) lhs->lhs_type = &t_list_string; else lhs->lhs_type = &t_any; if (cctx->ctx_skip != SKIP_YES) { int declare_error = FALSE; if (get_var_dest(lhs->lhs_name, &lhs->lhs_dest, cmdidx, &lhs->lhs_opt_flags, &lhs->lhs_vimvaridx, &lhs->lhs_type, cctx) == FAIL) return FAIL; if (lhs->lhs_dest != dest_local) { // Specific kind of variable recognized. declare_error = is_decl; } else { int idx; // No specific kind of variable recognized, just a name. for (idx = 0; reserved[idx] != NULL; ++idx) if (STRCMP(reserved[idx], lhs->lhs_name) == 0) { semsg(_(e_cannot_use_reserved_name), lhs->lhs_name); return FAIL; } if (lookup_local(var_start, lhs->lhs_varlen, &lhs->lhs_local_lvar, cctx) == OK) lhs->lhs_lvar = &lhs->lhs_local_lvar; else { CLEAR_FIELD(lhs->lhs_arg_lvar); if (arg_exists(var_start, lhs->lhs_varlen, &lhs->lhs_arg_lvar.lv_idx, &lhs->lhs_arg_lvar.lv_type, &lhs->lhs_arg_lvar.lv_from_outer, cctx) == OK) { if (is_decl) { semsg(_(e_str_is_used_as_argument), lhs->lhs_name); return FAIL; } lhs->lhs_lvar = &lhs->lhs_arg_lvar; } } if (lhs->lhs_lvar != NULL) { if (is_decl) { semsg(_(e_variable_already_declared), lhs->lhs_name); return FAIL; } } else { int script_namespace = lhs->lhs_varlen > 1 && STRNCMP(var_start, "s:", 2) == 0; int script_var = (script_namespace ? script_var_exists(var_start + 2, lhs->lhs_varlen - 2, FALSE, cctx) : script_var_exists(var_start, lhs->lhs_varlen, TRUE, cctx)) == OK; imported_T *import = find_imported(var_start, lhs->lhs_varlen, cctx); if (script_namespace || script_var || import != NULL) { char_u *rawname = lhs->lhs_name + (lhs->lhs_name[1] == ':' ? 2 : 0); if (is_decl) { if (script_namespace) semsg(_(e_cannot_declare_script_variable_in_function), lhs->lhs_name); else semsg(_(e_variable_already_declared_in_script), lhs->lhs_name); return FAIL; } else if (cctx->ctx_ufunc->uf_script_ctx_version == SCRIPT_VERSION_VIM9 && script_namespace && !script_var && import == NULL) { semsg(_(e_unknown_variable_str), lhs->lhs_name); return FAIL; } lhs->lhs_dest = dest_script; // existing script-local variables should have a type lhs->lhs_scriptvar_sid = current_sctx.sc_sid; if (import != NULL) lhs->lhs_scriptvar_sid = import->imp_sid; if (SCRIPT_ID_VALID(lhs->lhs_scriptvar_sid)) { // Check writable only when no index follows. lhs->lhs_scriptvar_idx = get_script_item_idx( lhs->lhs_scriptvar_sid, rawname, lhs->lhs_has_index ? ASSIGN_FINAL : ASSIGN_CONST, cctx); if (lhs->lhs_scriptvar_idx >= 0) { scriptitem_T *si = SCRIPT_ITEM( lhs->lhs_scriptvar_sid); svar_T *sv = ((svar_T *)si->sn_var_vals.ga_data) + lhs->lhs_scriptvar_idx; lhs->lhs_type = sv->sv_type; } } } else if (check_defined(var_start, lhs->lhs_varlen, cctx) == FAIL) return FAIL; } } if (declare_error) { vim9_declare_error(lhs->lhs_name); return FAIL; } } // handle "a:name" as a name, not index "name" on "a" if (lhs->lhs_varlen > 1 || var_start[lhs->lhs_varlen] != ':') var_end = lhs->lhs_dest_end; if (lhs->lhs_dest != dest_option) { if (is_decl && *var_end == ':') { char_u *p; // parse optional type: "let var: type = expr" if (!VIM_ISWHITE(var_end[1])) { semsg(_(e_white_space_required_after_str), ":"); return FAIL; } p = skipwhite(var_end + 1); lhs->lhs_type = parse_type(&p, cctx->ctx_type_list, TRUE); if (lhs->lhs_type == NULL) return FAIL; lhs->lhs_has_type = TRUE; } else if (lhs->lhs_lvar != NULL) lhs->lhs_type = lhs->lhs_lvar->lv_type; } if (oplen == 3 && !heredoc && lhs->lhs_dest != dest_global && lhs->lhs_type->tt_type != VAR_STRING && lhs->lhs_type->tt_type != VAR_ANY) { emsg(_(e_can_only_concatenate_to_string)); return FAIL; } if (lhs->lhs_lvar == NULL && lhs->lhs_dest == dest_local && cctx->ctx_skip != SKIP_YES) { if (oplen > 1 && !heredoc) { // +=, /=, etc. require an existing variable semsg(_(e_cannot_use_operator_on_new_variable), lhs->lhs_name); return FAIL; } if (!is_decl) { semsg(_(e_unknown_variable_str), lhs->lhs_name); return FAIL; } // new local variable if ((lhs->lhs_type->tt_type == VAR_FUNC || lhs->lhs_type->tt_type == VAR_PARTIAL) && var_wrong_func_name(lhs->lhs_name, TRUE)) return FAIL; lhs->lhs_lvar = reserve_local(cctx, var_start, lhs->lhs_varlen, cmdidx == CMD_final || cmdidx == CMD_const, lhs->lhs_type); if (lhs->lhs_lvar == NULL) return FAIL; lhs->lhs_new_local = TRUE; } lhs->lhs_member_type = lhs->lhs_type; if (lhs->lhs_has_index) { // Something follows after the variable: "var[idx]" or "var.key". // TODO: should we also handle "->func()" here? if (is_decl) { emsg(_(e_cannot_use_index_when_declaring_variable)); return FAIL; } if (var_start[lhs->lhs_varlen] == '[' || var_start[lhs->lhs_varlen] == '.') { char_u *after = var_start + lhs->lhs_varlen; char_u *p; // Only the last index is used below, if there are others // before it generate code for the expression. Thus for // "ll[1][2]" the expression is "ll[1]" and "[2]" is the index. for (;;) { p = skip_index(after); if (*p != '[' && *p != '.') break; after = p; } if (after > var_start + lhs->lhs_varlen) { lhs->lhs_varlen = after - var_start; lhs->lhs_dest = dest_expr; // We don't know the type before evaluating the expression, // use "any" until then. lhs->lhs_type = &t_any; } if (lhs->lhs_type->tt_member == NULL) lhs->lhs_member_type = &t_any; else lhs->lhs_member_type = lhs->lhs_type->tt_member; } else { semsg("Not supported yet: %s", var_start); return FAIL; } } return OK; } /* * Assignment to a list or dict member, or ":unlet" for the item, using the * information in "lhs". * Returns OK or FAIL. */ static int compile_assign_unlet( char_u *var_start, lhs_T *lhs, int is_assign, type_T *rhs_type, cctx_T *cctx) { char_u *p; int r; vartype_T dest_type; size_t varlen = lhs->lhs_varlen; garray_T *stack = &cctx->ctx_type_stack; // Compile the "idx" in "var[idx]" or "key" in "var.key". p = var_start + varlen; if (*p == '[') { p = skipwhite(p + 1); r = compile_expr0(&p, cctx); if (r == OK && *skipwhite(p) != ']') { // this should not happen emsg(_(e_missbrac)); r = FAIL; } } else // if (*p == '.') { char_u *key_end = to_name_end(p + 1, TRUE); char_u *key = vim_strnsave(p + 1, key_end - p - 1); r = generate_PUSHS(cctx, key); } if (r == FAIL) return FAIL; if (lhs->lhs_type == &t_any) { // Index on variable of unknown type: check at runtime. dest_type = VAR_ANY; } else { dest_type = lhs->lhs_type->tt_type; if (dest_type == VAR_DICT && may_generate_2STRING(-1, cctx) == FAIL) return FAIL; if (dest_type == VAR_LIST && need_type(((type_T **)stack->ga_data)[stack->ga_len - 1], &t_number, -1, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; } // Load the dict or list. On the stack we then have: // - value (for assignment, not for :unlet) // - index // - variable if (lhs->lhs_dest == dest_expr) { int c = var_start[varlen]; // Evaluate "ll[expr]" of "ll[expr][idx]" p = var_start; var_start[varlen] = NUL; if (compile_expr0(&p, cctx) == OK && p != var_start + varlen) { // this should not happen emsg(_(e_missbrac)); return FAIL; } var_start[varlen] = c; lhs->lhs_type = stack->ga_len == 0 ? &t_void : ((type_T **)stack->ga_data)[stack->ga_len - 1]; // now we can properly check the type if (lhs->lhs_type->tt_member != NULL && rhs_type != &t_void && need_type(rhs_type, lhs->lhs_type->tt_member, -2, 0, cctx, FALSE, FALSE) == FAIL) return FAIL; } else generate_loadvar(cctx, lhs->lhs_dest, lhs->lhs_name, lhs->lhs_lvar, lhs->lhs_type); if (dest_type == VAR_LIST || dest_type == VAR_DICT || dest_type == VAR_ANY) { if (is_assign) { isn_T *isn = generate_instr_drop(cctx, ISN_STOREINDEX, 3); if (isn == NULL) return FAIL; isn->isn_arg.vartype = dest_type; } else { if (generate_instr_drop(cctx, ISN_UNLETINDEX, 2) == NULL) return FAIL; } } else { emsg(_(e_indexable_type_required)); return FAIL; } return OK; } /* * Compile declaration and assignment: * "let name" * "var name = expr" * "final name = expr" * "const name = expr" * "name = expr" * "arg" points to "name". * Return NULL for an error. * Return "arg" if it does not look like a variable list. */ static char_u * compile_assignment(char_u *arg, exarg_T *eap, cmdidx_T cmdidx, cctx_T *cctx) { char_u *var_start; char_u *p; char_u *end = arg; char_u *ret = NULL; int var_count = 0; int var_idx; int semicolon = 0; garray_T *instr = &cctx->ctx_instr; garray_T *stack = &cctx->ctx_type_stack; char_u *op; int oplen = 0; int heredoc = FALSE; type_T *rhs_type = &t_any; char_u *sp; int is_decl = is_decl_command(cmdidx); lhs_T lhs; // Skip over the "var" or "[var, var]" to get to any "=". p = skip_var_list(arg, TRUE, &var_count, &semicolon, TRUE); if (p == NULL) return *arg == '[' ? arg : NULL; if (var_count > 0 && is_decl) { // TODO: should we allow this, and figure out type inference from list // members? emsg(_(e_cannot_use_list_for_declaration)); return NULL; } lhs.lhs_name = NULL; sp = p; p = skipwhite(p); op = p; oplen = assignment_len(p, &heredoc); if (var_count > 0 && oplen == 0) // can be something like "[1, 2]->func()" return arg; if (oplen > 0 && (!VIM_ISWHITE(*sp) || !IS_WHITE_OR_NUL(op[oplen]))) { error_white_both(op, oplen); return NULL; } if (heredoc) { list_T *l; listitem_T *li; // [let] varname =<< [trim] {end} eap->getline = exarg_getline; eap->cookie = cctx; l = heredoc_get(eap, op + 3, FALSE); if (l == NULL) return NULL; if (cctx->ctx_skip != SKIP_YES) { // Push each line and the create the list. FOR_ALL_LIST_ITEMS(l, li) { generate_PUSHS(cctx, li->li_tv.vval.v_string); li->li_tv.vval.v_string = NULL; } generate_NEWLIST(cctx, l->lv_len); } list_free(l); p += STRLEN(p); end = p; } else if (var_count > 0) { char_u *wp; // for "[var, var] = expr" evaluate the expression here, loop over the // list of variables below. // A line break may follow the "=". wp = op + oplen; if (may_get_next_line_error(wp, &p, cctx) == FAIL) return FAIL; if (compile_expr0(&p, cctx) == FAIL) return NULL; end = p; if (cctx->ctx_skip != SKIP_YES) { type_T *stacktype; stacktype = stack->ga_len == 0 ? &t_void : ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (stacktype->tt_type == VAR_VOID) { emsg(_(e_cannot_use_void_value)); goto theend; } if (need_type(stacktype, &t_list_any, -1, 0, cctx, FALSE, FALSE) == FAIL) goto theend; // TODO: check the length of a constant list here generate_CHECKLEN(cctx, semicolon ? var_count - 1 : var_count, semicolon); if (stacktype->tt_member != NULL) rhs_type = stacktype->tt_member; } } /* * Loop over variables in "[var, var] = expr". * For "var = expr" and "let var: type" this is done only once. */ if (var_count > 0) var_start = skipwhite(arg + 1); // skip over the "[" else var_start = arg; for (var_idx = 0; var_idx == 0 || var_idx < var_count; var_idx++) { int instr_count = -1; vim_free(lhs.lhs_name); /* * Figure out the LHS type and other properties. */ if (compile_lhs(var_start, &lhs, cmdidx, heredoc, oplen, cctx) == FAIL) goto theend; if (!lhs.lhs_has_index && lhs.lhs_lvar == &lhs.lhs_arg_lvar) { semsg(_(e_cannot_assign_to_argument), lhs.lhs_name); goto theend; } if (!is_decl && lhs.lhs_lvar != NULL && lhs.lhs_lvar->lv_const && !lhs.lhs_has_index) { semsg(_(e_cannot_assign_to_constant), lhs.lhs_name); goto theend; } if (!heredoc) { if (cctx->ctx_skip == SKIP_YES) { if (oplen > 0 && var_count == 0) { // skip over the "=" and the expression p = skipwhite(op + oplen); compile_expr0(&p, cctx); } } else if (oplen > 0) { int is_const = FALSE; char_u *wp; // For "var = expr" evaluate the expression. if (var_count == 0) { int r; // for "+=", "*=", "..=" etc. first load the current value if (*op != '=') { generate_loadvar(cctx, lhs.lhs_dest, lhs.lhs_name, lhs.lhs_lvar, lhs.lhs_type); if (lhs.lhs_has_index) { // TODO: get member from list or dict emsg("Index with operation not supported yet"); goto theend; } } // Compile the expression. Temporarily hide the new local // variable here, it is not available to this expression. if (lhs.lhs_new_local) --cctx->ctx_locals.ga_len; instr_count = instr->ga_len; wp = op + oplen; if (may_get_next_line_error(wp, &p, cctx) == FAIL) { if (lhs.lhs_new_local) ++cctx->ctx_locals.ga_len; goto theend; } r = compile_expr0_ext(&p, cctx, &is_const); if (lhs.lhs_new_local) ++cctx->ctx_locals.ga_len; if (r == FAIL) goto theend; } else if (semicolon && var_idx == var_count - 1) { // For "[var; var] = expr" get the rest of the list if (generate_SLICE(cctx, var_count - 1) == FAIL) goto theend; } else { // For "[var, var] = expr" get the "var_idx" item from the // list. if (generate_GETITEM(cctx, var_idx) == FAIL) goto theend; } rhs_type = stack->ga_len == 0 ? &t_void : ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (lhs.lhs_lvar != NULL && (is_decl || !lhs.lhs_has_type)) { if ((rhs_type->tt_type == VAR_FUNC || rhs_type->tt_type == VAR_PARTIAL) && var_wrong_func_name(lhs.lhs_name, TRUE)) goto theend; if (lhs.lhs_new_local && !lhs.lhs_has_type) { if (rhs_type->tt_type == VAR_VOID) { emsg(_(e_cannot_use_void_value)); goto theend; } else { // An empty list or dict has a &t_unknown member, // for a variable that implies &t_any. if (rhs_type == &t_list_empty) lhs.lhs_lvar->lv_type = &t_list_any; else if (rhs_type == &t_dict_empty) lhs.lhs_lvar->lv_type = &t_dict_any; else if (rhs_type == &t_unknown) lhs.lhs_lvar->lv_type = &t_any; else lhs.lhs_lvar->lv_type = rhs_type; } } else if (*op == '=') { type_T *use_type = lhs.lhs_lvar->lv_type; // without operator check type here, otherwise below if (lhs.lhs_has_index) use_type = lhs.lhs_member_type; if (need_type(rhs_type, use_type, -1, 0, cctx, FALSE, is_const) == FAIL) goto theend; } } else if (*p != '=' && need_type(rhs_type, lhs.lhs_member_type, -1, 0, cctx, FALSE, FALSE) == FAIL) goto theend; } else if (cmdidx == CMD_final) { emsg(_(e_final_requires_a_value)); goto theend; } else if (cmdidx == CMD_const) { emsg(_(e_const_requires_a_value)); goto theend; } else if (!lhs.lhs_has_type || lhs.lhs_dest == dest_option) { emsg(_(e_type_or_initialization_required)); goto theend; } else { // variables are always initialized if (ga_grow(instr, 1) == FAIL) goto theend; switch (lhs.lhs_member_type->tt_type) { case VAR_BOOL: generate_PUSHBOOL(cctx, VVAL_FALSE); break; case VAR_FLOAT: #ifdef FEAT_FLOAT generate_PUSHF(cctx, 0.0); #endif break; case VAR_STRING: generate_PUSHS(cctx, NULL); break; case VAR_BLOB: generate_PUSHBLOB(cctx, blob_alloc()); break; case VAR_FUNC: generate_PUSHFUNC(cctx, NULL, &t_func_void); break; case VAR_LIST: generate_NEWLIST(cctx, 0); break; case VAR_DICT: generate_NEWDICT(cctx, 0); break; case VAR_JOB: generate_PUSHJOB(cctx, NULL); break; case VAR_CHANNEL: generate_PUSHCHANNEL(cctx, NULL); break; case VAR_NUMBER: case VAR_UNKNOWN: case VAR_ANY: case VAR_PARTIAL: case VAR_VOID: case VAR_SPECIAL: // cannot happen generate_PUSHNR(cctx, 0); break; } } if (var_count == 0) end = p; } // no need to parse more when skipping if (cctx->ctx_skip == SKIP_YES) break; if (oplen > 0 && *op != '=') { type_T *expected; type_T *stacktype; if (*op == '.') expected = &t_string; else expected = lhs.lhs_member_type; stacktype = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if ( #ifdef FEAT_FLOAT // If variable is float operation with number is OK. !(expected == &t_float && stacktype == &t_number) && #endif need_type(stacktype, expected, -1, 0, cctx, FALSE, FALSE) == FAIL) goto theend; if (*op == '.') { if (generate_instr_drop(cctx, ISN_CONCAT, 1) == NULL) goto theend; } else if (*op == '+') { if (generate_add_instr(cctx, operator_type(lhs.lhs_member_type, stacktype), lhs.lhs_member_type, stacktype) == FAIL) goto theend; } else if (generate_two_op(cctx, op) == FAIL) goto theend; } 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(var_start, &lhs, TRUE, rhs_type, cctx) == FAIL) goto theend; } else { if (is_decl && cmdidx == CMD_const && (lhs.lhs_dest == dest_script || lhs.lhs_dest == dest_local)) // ":const var": lock the value, but not referenced variables generate_LOCKCONST(cctx); if (is_decl && (lhs.lhs_type->tt_type == VAR_DICT || lhs.lhs_type->tt_type == VAR_LIST) && lhs.lhs_type->tt_member != NULL && lhs.lhs_type->tt_member != &t_any && lhs.lhs_type->tt_member != &t_unknown) // Set the type in the list or dict, so that it can be checked, // also in legacy script. generate_SETTYPE(cctx, lhs.lhs_type); if (lhs.lhs_dest != dest_local) { if (generate_store_var(cctx, lhs.lhs_dest, lhs.lhs_opt_flags, lhs.lhs_vimvaridx, lhs.lhs_scriptvar_idx, lhs.lhs_scriptvar_sid, lhs.lhs_type, lhs.lhs_name) == FAIL) goto theend; } else if (lhs.lhs_lvar != NULL) { isn_T *isn = ((isn_T *)instr->ga_data) + instr->ga_len - 1; // optimization: turn "var = 123" from ISN_PUSHNR + // ISN_STORE into ISN_STORENR if (lhs.lhs_lvar->lv_from_outer == 0 && instr->ga_len == instr_count + 1 && isn->isn_type == ISN_PUSHNR) { varnumber_T val = isn->isn_arg.number; isn->isn_type = ISN_STORENR; isn->isn_arg.storenr.stnr_idx = lhs.lhs_lvar->lv_idx; isn->isn_arg.storenr.stnr_val = val; if (stack->ga_len > 0) --stack->ga_len; } else if (lhs.lhs_lvar->lv_from_outer > 0) generate_STOREOUTER(cctx, lhs.lhs_lvar->lv_idx, lhs.lhs_lvar->lv_from_outer); else generate_STORE(cctx, ISN_STORE, lhs.lhs_lvar->lv_idx, NULL); } } if (var_idx + 1 < var_count) var_start = skipwhite(lhs.lhs_dest_end + 1); } // for "[var, var] = expr" drop the "expr" value if (var_count > 0 && !semicolon) { if (generate_instr_drop(cctx, ISN_DROP, 1) == NULL) goto theend; } ret = skipwhite(end); theend: vim_free(lhs.lhs_name); return ret; } /* * Check for an assignment at "eap->cmd", compile it if found. * Return NOTDONE if there is none, FAIL for failure, OK if done. */ static int may_compile_assignment(exarg_T *eap, char_u **line, cctx_T *cctx) { char_u *pskip; char_u *p; // Assuming the command starts with a variable or function name, // find what follows. // Skip over "var.member", "var[idx]" and the like. // Also "&opt = val", "$ENV = val" and "@r = val". pskip = (*eap->cmd == '&' || *eap->cmd == '$' || *eap->cmd == '@') ? eap->cmd + 1 : eap->cmd; p = to_name_end(pskip, TRUE); if (p > eap->cmd && *p != NUL) { char_u *var_end; int oplen; int heredoc; if (eap->cmd[0] == '@') var_end = eap->cmd + 2; else var_end = find_name_end(pskip, NULL, NULL, FNE_CHECK_START | FNE_INCL_BR); oplen = assignment_len(skipwhite(var_end), &heredoc); if (oplen > 0) { size_t len = p - eap->cmd; // Recognize an assignment if we recognize the variable // name: // "g:var = expr" // "local = expr" where "local" is a local var. // "script = expr" where "script" is a script-local var. // "import = expr" where "import" is an imported var // "&opt = expr" // "$ENV = expr" // "@r = expr" if (*eap->cmd == '&' || *eap->cmd == '$' || *eap->cmd == '@' || ((len) > 2 && eap->cmd[1] == ':') || lookup_local(eap->cmd, len, NULL, cctx) == OK || arg_exists(eap->cmd, len, NULL, NULL, NULL, cctx) == OK || script_var_exists(eap->cmd, len, FALSE, cctx) == OK || find_imported(eap->cmd, len, cctx) != NULL) { *line = compile_assignment(eap->cmd, eap, CMD_SIZE, cctx); if (*line == NULL || *line == eap->cmd) return FAIL; return OK; } } } if (*eap->cmd == '[') { // [var, var] = expr *line = compile_assignment(eap->cmd, eap, CMD_SIZE, cctx); if (*line == NULL) return FAIL; if (*line != eap->cmd) return OK; } return NOTDONE; } /* * Check if "name" can be "unlet". */ int check_vim9_unlet(char_u *name) { if (name[1] != ':' || vim_strchr((char_u *)"gwtb", *name) == NULL) { // "unlet s:var" is allowed in legacy script. if (*name == 's' && !script_is_vim9()) return OK; semsg(_(e_cannot_unlet_str), name); return FAIL; } return OK; } /* * Callback passed to ex_unletlock(). */ static int compile_unlet( lval_T *lvp, char_u *name_end, exarg_T *eap, int deep UNUSED, void *coookie) { cctx_T *cctx = coookie; char_u *p = lvp->ll_name; int cc = *name_end; int ret = OK; if (cctx->ctx_skip == SKIP_YES) return OK; *name_end = NUL; if (*p == '$') { // :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, 0, cctx); // : unlet an indexed item if (!lhs.lhs_has_index) { iemsg("called compile_lhs() without an index"); ret = FAIL; } else { // Use the info in "lhs" to unlet the item at the index in the // list or dict. 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; } /* * compile "unlet var", "lock var" and "unlock var" * "arg" points to "var". */ static char_u * compile_unletlock(char_u *arg, exarg_T *eap, cctx_T *cctx) { char_u *p = arg; if (eap->cmdidx != CMD_unlet) { emsg("Sorry, :lock and unlock not implemented yet"); return NULL; } ex_unletlock(eap, p, 0, GLV_NO_AUTOLOAD | GLV_COMPILING, compile_unlet, cctx); return eap->nextcmd == NULL ? (char_u *)"" : eap->nextcmd; } /* * Compile an :import command. */ static char_u * compile_import(char_u *arg, cctx_T *cctx) { return handle_import(arg, &cctx->ctx_imports, 0, NULL, cctx); } /* * generate a jump to the ":endif"/":endfor"/":endwhile"/":finally"/":endtry". */ static int compile_jump_to_end(endlabel_T **el, jumpwhen_T when, 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; generate_JUMP(cctx, when, 0); return OK; } static void compile_fill_jump_to_end(endlabel_T **el, 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 = instr->ga_len; *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; return scope; } /* * Free the current scope and go back to the outer scope. */ static 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); } /* * 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: */ static 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 (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; } 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; return p; } static char_u * compile_elseif(char_u *arg, cctx_T *cctx) { char_u *p = arg; garray_T *instr = &cctx->ctx_instr; int instr_count = instr->ga_len; 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); if (!cctx->ctx_had_return) scope->se_u.se_if.is_had_return = FALSE; if (cctx->ctx_skip == SKIP_UNKNOWN) { if (compile_jump_to_end(&scope->se_u.se_if.is_end_label, JUMP_ALWAYS, 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; } // 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; if (compile_expr1(&p, cctx, &ppconst) == FAIL) { clear_ppconst(&ppconst); return NULL; } cctx->ctx_skip = save_skip; 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 results in a constant. // TODO: how about nesting? v = tv_get_bool_chk(&ppconst.pp_tv[0], &error); if (error) 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; // "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; } static 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); if (!cctx->ctx_had_return) scope->se_u.se_if.is_had_return = FALSE; scope->se_u.se_if.is_seen_else = TRUE; if (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, 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; } static 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 (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); 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, cctx); 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; } /* * Compile "for var in expr": * * Produces instructions: * PUSHNR -1 * STORE 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 var Store item in "var" * ... body ... * 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" */ static 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 semicolon = FALSE; size_t varlen; garray_T *instr = &cctx->ctx_instr; garray_T *stack = &cctx->ctx_type_stack; scope_T *scope; lvar_T *loop_lvar; // loop iteration variable lvar_T *var_lvar; // variable for "var" type_T *vartype; type_T *item_type = &t_any; int idx; p = skip_var_list(arg_start, TRUE, &var_count, &semicolon, FALSE); if (p == NULL) return NULL; if (var_count == 0) var_count = 1; // 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])) { emsg(_(e_missing_in)); return NULL; } wp = p + 2; if (may_get_next_line_error(wp, &p, cctx) == FAIL) return NULL; scope = new_scope(cctx, FOR_SCOPE); if (scope == NULL) return NULL; // Reserve a variable to store the loop iteration counter and initialize it // to -1. loop_lvar = reserve_local(cctx, (char_u *)"", 0, FALSE, &t_number); if (loop_lvar == NULL) { // out of memory drop_scope(cctx); return NULL; } generate_STORENR(cctx, loop_lvar->lv_idx, -1); // 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; // Now that we know the type of "var", check that it is a list, now or at // runtime. vartype = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (need_type(vartype, &t_list_any, -1, 0, cctx, FALSE, FALSE) == FAIL) { drop_scope(cctx); return NULL; } if (vartype->tt_type == VAR_LIST && vartype->tt_member->tt_type != VAR_ANY) { if (var_count == 1) 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; } // "for_end" is set when ":endfor" is found scope->se_u.se_for.fs_top_label = instr->ga_len; generate_FOR(cctx, loop_lvar->lv_idx); arg = arg_start; if (var_count > 1) { generate_UNPACK(cctx, var_count, semicolon); arg = skipwhite(arg + 1); // skip white after '[' // the list item is replaced by a number of items if (ga_grow(stack, var_count - 1) == FAIL) { drop_scope(cctx); return NULL; } --stack->ga_len; for (idx = 0; idx < var_count; ++idx) { ((type_T **)stack->ga_data)[stack->ga_len] = (semicolon && idx == 0) ? vartype : item_type; ++stack->ga_len; } } 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; p = skip_var_one(arg, FALSE); varlen = p - arg; name = vim_strnsave(arg, varlen); if (name == NULL) goto failed; // TODO: script var not supported? 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, 0, 0, type, name) == FAIL) goto failed; } else { if (lookup_local(arg, varlen, NULL, cctx) == OK) { semsg(_(e_variable_already_declared), arg); goto failed; } if (STRNCMP(name, "s:", 2) == 0) { semsg(_(e_cannot_declare_script_variable_in_function), name); goto failed; } // Reserve a variable to store "var". // TODO: check for type var_lvar = reserve_local(cctx, arg, varlen, FALSE, &t_any); 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; else var_lvar->lv_type = item_type; generate_STORE(cctx, ISN_STORE, var_lvar->lv_idx, NULL); } if (*p == ':') p = skip_type(skipwhite(p + 1), FALSE); if (*p == ',' || *p == ';') ++p; arg = skipwhite(p); vim_free(name); } return arg_end; failed: vim_free(name); drop_scope(cctx); return NULL; } /* * compile "endfor" */ static 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 (scope == NULL || scope->se_type != FOR_SCOPE) { emsg(_(e_for)); return NULL; } forscope = &scope->se_u.se_for; cctx->ctx_scope = scope->se_outer; unwind_locals(cctx, scope->se_local_count); // 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 isn = ((isn_T *)instr->ga_data) + forscope->fs_top_label; 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, 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" * JUMP_IF_FALSE end jump if false * ... body ... * JUMP top Jump back to repeat * end: * */ static char_u * compile_while(char_u *arg, cctx_T *cctx) { char_u *p = arg; garray_T *instr = &cctx->ctx_instr; scope_T *scope; scope = new_scope(cctx, WHILE_SCOPE); if (scope == NULL) return NULL; scope->se_u.se_while.ws_top_label = instr->ga_len; // compile "expr" if (compile_expr0(&p, cctx) == FAIL) return NULL; if (bool_on_stack(cctx) == FAIL) return FAIL; // "while_end" is set when ":endwhile" is found if (compile_jump_to_end(&scope->se_u.se_while.ws_end_label, JUMP_IF_FALSE, cctx) == FAIL) return FAIL; return p; } /* * compile "endwhile" */ static char_u * compile_endwhile(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; if (scope == NULL || scope->se_type != WHILE_SCOPE) { emsg(_(e_while)); return NULL; } cctx->ctx_scope = scope->se_outer; unwind_locals(cctx, scope->se_local_count); // 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, cctx); vim_free(scope); return arg; } /* * compile "continue" */ static char_u * compile_continue(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; for (;;) { if (scope == NULL) { emsg(_(e_continue)); return NULL; } if (scope->se_type == FOR_SCOPE || scope->se_type == WHILE_SCOPE) break; scope = scope->se_outer; } // Jump back to the FOR or WHILE instruction. generate_JUMP(cctx, JUMP_ALWAYS, scope->se_type == FOR_SCOPE ? scope->se_u.se_for.fs_top_label : scope->se_u.se_while.ws_top_label); return arg; } /* * compile "break" */ static char_u * compile_break(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; endlabel_T **el; for (;;) { if (scope == NULL) { emsg(_(e_break)); return NULL; } if (scope->se_type == FOR_SCOPE || scope->se_type == WHILE_SCOPE) break; scope = scope->se_outer; } // Jump to the end of the FOR or WHILE loop. if (scope->se_type == FOR_SCOPE) el = &scope->se_u.se_for.fs_end_label; else el = &scope->se_u.se_while.ws_end_label; if (compile_jump_to_end(el, JUMP_ALWAYS, cctx) == FAIL) return FAIL; return arg; } /* * compile "{" start of block */ static 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 */ static 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); 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 */ static char_u * compile_try(char_u *arg, cctx_T *cctx) { garray_T *instr = &cctx->ctx_instr; scope_T *try_scope; scope_T *scope; // 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) { // "catch" is set when the first ":catch" is found. // "finally" is set when ":finally" or ":endtry" is found try_scope->se_u.se_try.ts_try_label = instr->ga_len; if (generate_instr(cctx, ISN_TRY) == 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}" */ static 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; // 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)); return NULL; } if (scope->se_u.se_try.ts_caught_all) { emsg(_(e_catch_unreachable_after_catch_all)); return NULL; } if (cctx->ctx_skip != SKIP_YES) { // 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, 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.try.try_catch == 0) isn->isn_arg.try.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; } } 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 FAIL; } 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 FAIL; if (generate_PUSHS(cctx, pat) == FAIL) return FAIL; 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; } static 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; // 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)); return NULL; } // 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.try.try_finally != 0) { emsg(_(e_finally_dup)); return NULL; } // 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, cctx); isn->isn_arg.try.try_finally = 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; scope->se_u.se_try.ts_catch_label = 0; } // TODO: set index in ts_finally_label jumps return arg; } static char_u * compile_endtry(char_u *arg, cctx_T *cctx) { scope_T *scope = cctx->ctx_scope; garray_T *instr = &cctx->ctx_instr; isn_T *isn; // 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_no_endtry)); else if (scope->se_type == WHILE_SCOPE) emsg(_(e_endwhile)); else if (scope->se_type == FOR_SCOPE) emsg(_(e_endfor)); else emsg(_(e_endif)); return NULL; } if (cctx->ctx_skip != SKIP_YES) { isn = ((isn_T *)instr->ga_data) + scope->se_u.se_try.ts_try_label; if (isn->isn_arg.try.try_catch == 0 && isn->isn_arg.try.try_finally == 0) { emsg(_(e_missing_catch_or_finally)); return NULL; } // 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, cctx); // End :catch or :finally scope: set value in ISN_TRY instruction if (isn->isn_arg.try.try_catch == 0) isn->isn_arg.try.try_catch = instr->ga_len; if (isn->isn_arg.try.try_finally == 0) isn->isn_arg.try.try_finally = instr->ga_len; if (scope->se_u.se_try.ts_catch_label != 0) { // Last 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; } } compile_endblock(cctx); if (cctx->ctx_skip != SKIP_YES && generate_instr(cctx, ISN_ENDTRY) == NULL) return NULL; return arg; } /* * compile "throw {expr}" */ static 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, cctx) == FAIL) return NULL; if (generate_instr_drop(cctx, ISN_THROW, 1) == NULL) return NULL; return p; } /* * compile "echo expr" * compile "echomsg expr" * compile "echoerr expr" * compile "execute expr" */ static char_u * compile_mult_expr(char_u *arg, int cmdidx, cctx_T *cctx) { char_u *p = arg; char_u *prev = arg; int count = 0; for (;;) { if (ends_excmd2(prev, p)) break; if (compile_expr0(&p, cctx) == FAIL) return NULL; ++count; prev = p; p = skipwhite(p); } if (count > 0) { if (cmdidx == CMD_echo || cmdidx == CMD_echon) generate_ECHO(cctx, cmdidx == CMD_echo, count); else if (cmdidx == CMD_execute) generate_MULT_EXPR(cctx, ISN_EXECUTE, count); else if (cmdidx == CMD_echomsg) generate_MULT_EXPR(cctx, ISN_ECHOMSG, count); else generate_MULT_EXPR(cctx, ISN_ECHOERR, count); } return p; } /* * 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} */ static 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 = 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. */ static char_u * compile_exec(char_u *line, exarg_T *eap, cctx_T *cctx) { char_u *p; int has_expr = FALSE; char_u *nextcmd = (char_u *)""; if (cctx->ctx_skip == SKIP_YES) goto theend; 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); 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; } } } 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) { eap->arg = p + 1; has_expr = TRUE; } } if (eap->cmdidx == CMD_folddoopen || eap->cmdidx == CMD_folddoclosed) { // TODO: should only expand when appropriate for the command eap->arg = skiptowhite(eap->arg); has_expr = TRUE; } 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) { generate_PUSHS(cctx, vim_strnsave(start, p - start)); ++count; } p += 2; if (compile_expr0(&p, cctx) == FAIL) return NULL; may_generate_2STRING(-1, 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) { generate_PUSHS(cctx, vim_strsave(start)); ++count; } break; } } generate_EXECCONCAT(cctx, count); } else generate_EXEC(cctx, line); theend: if (*nextcmd != NUL) { // the parser expects a pointer to the bar, put it back --nextcmd; *nextcmd = '|'; } return nextcmd; } /* * Add a function to the list of :def functions. * This sets "ufunc->uf_dfunc_idx" but the function isn't compiled yet. */ static int add_def_function(ufunc_T *ufunc) { dfunc_T *dfunc; if (def_functions.ga_len == 0) { // The first position is not used, so that a zero uf_dfunc_idx means it // wasn't set. if (ga_grow(&def_functions, 1) == FAIL) return FAIL; ++def_functions.ga_len; } // Add the function to "def_functions". if (ga_grow(&def_functions, 1) == FAIL) return FAIL; dfunc = ((dfunc_T *)def_functions.ga_data) + def_functions.ga_len; CLEAR_POINTER(dfunc); dfunc->df_idx = def_functions.ga_len; ufunc->uf_dfunc_idx = dfunc->df_idx; dfunc->df_ufunc = ufunc; dfunc->df_name = vim_strsave(ufunc->uf_name); ++dfunc->df_refcount; ++def_functions.ga_len; return OK; } /* * After ex_function() has collected all the function lines: parse and compile * the lines into instructions. * Adds the function to "def_functions". * When "check_return_type" is set then set ufunc->uf_ret_type to the type of * the return statement (used for lambda). When uf_ret_type is already set * then check that it matches. * "outer_cctx" is set for a nested function. * This can be used recursively through compile_lambda(), which may reallocate * "def_functions". * Returns OK or FAIL. */ int compile_def_function(ufunc_T *ufunc, int check_return_type, cctx_T *outer_cctx) { char_u *line = NULL; char_u *p; char *errormsg = NULL; // error message cctx_T cctx; garray_T *instr; int did_emsg_before = did_emsg; int ret = FAIL; sctx_T save_current_sctx = current_sctx; int save_estack_compiling = estack_compiling; int do_estack_push; int new_def_function = FALSE; // When using a function that was compiled before: Free old instructions. // The index is reused. Otherwise add a new entry in "def_functions". if (ufunc->uf_dfunc_idx > 0) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; delete_def_function_contents(dfunc, FALSE); } else { if (add_def_function(ufunc) == FAIL) return FAIL; new_def_function = TRUE; } ufunc->uf_def_status = UF_COMPILING; CLEAR_FIELD(cctx); cctx.ctx_ufunc = ufunc; cctx.ctx_lnum = -1; cctx.ctx_outer = outer_cctx; ga_init2(&cctx.ctx_locals, sizeof(lvar_T), 10); ga_init2(&cctx.ctx_type_stack, sizeof(type_T *), 50); ga_init2(&cctx.ctx_imports, sizeof(imported_T), 10); cctx.ctx_type_list = &ufunc->uf_type_list; ga_init2(&cctx.ctx_instr, sizeof(isn_T), 50); instr = &cctx.ctx_instr; // Set the context to the function, it may be compiled when called from // another script. Set the script version to the most modern one. // The line number will be set in next_line_from_context(). current_sctx = ufunc->uf_script_ctx; current_sctx.sc_version = SCRIPT_VERSION_VIM9; // Make sure error messages are OK. do_estack_push = !estack_top_is_ufunc(ufunc, 1); if (do_estack_push) estack_push_ufunc(ufunc, 1); estack_compiling = TRUE; if (ufunc->uf_def_args.ga_len > 0) { int count = ufunc->uf_def_args.ga_len; int first_def_arg = ufunc->uf_args.ga_len - count; int i; char_u *arg; int off = STACK_FRAME_SIZE + (ufunc->uf_va_name != NULL ? 1 : 0); int did_set_arg_type = FALSE; // Produce instructions for the default values of optional arguments. // Store the instruction index in uf_def_arg_idx[] so that we know // where to start when the function is called, depending on the number // of arguments. ufunc->uf_def_arg_idx = ALLOC_CLEAR_MULT(int, count + 1); if (ufunc->uf_def_arg_idx == NULL) goto erret; for (i = 0; i < count; ++i) { garray_T *stack = &cctx.ctx_type_stack; type_T *val_type; int arg_idx = first_def_arg + i; ufunc->uf_def_arg_idx[i] = instr->ga_len; arg = ((char_u **)(ufunc->uf_def_args.ga_data))[i]; if (compile_expr0(&arg, &cctx) == FAIL) goto erret; // If no type specified use the type of the default value. // Otherwise check that the default value type matches the // specified type. val_type = ((type_T **)stack->ga_data)[stack->ga_len - 1]; if (ufunc->uf_arg_types[arg_idx] == &t_unknown) { did_set_arg_type = TRUE; ufunc->uf_arg_types[arg_idx] = val_type; } else if (check_type(ufunc->uf_arg_types[arg_idx], val_type, TRUE, arg_idx + 1) == FAIL) goto erret; if (generate_STORE(&cctx, ISN_STORE, i - count - off, NULL) == FAIL) goto erret; } ufunc->uf_def_arg_idx[count] = instr->ga_len; if (did_set_arg_type) set_function_type(ufunc); } /* * Loop over all the lines of the function and generate instructions. */ for (;;) { exarg_T ea; int starts_with_colon = FALSE; char_u *cmd; cmdmod_T local_cmdmod; // Bail out on the first error to avoid a flood of errors and report // the right line number when inside try/catch. if (did_emsg_before != did_emsg) goto erret; if (line != NULL && *line == '|') // the line continues after a '|' ++line; else if (line != NULL && *skipwhite(line) != NUL && !(*line == '#' && (line == cctx.ctx_line_start || VIM_ISWHITE(line[-1])))) { semsg(_(e_trailing_arg), line); goto erret; } else { line = next_line_from_context(&cctx, FALSE); if (cctx.ctx_lnum >= ufunc->uf_lines.ga_len) // beyond the last line break; } CLEAR_FIELD(ea); ea.cmdlinep = &line; ea.cmd = skipwhite(line); // Some things can be recognized by the first character. switch (*ea.cmd) { case '#': // "#" starts a comment line = (char_u *)""; continue; case '}': { // "}" ends a block scope scopetype_T stype = cctx.ctx_scope == NULL ? NO_SCOPE : cctx.ctx_scope->se_type; if (stype == BLOCK_SCOPE) { compile_endblock(&cctx); line = ea.cmd; } else { emsg(_(e_using_rcurly_outside_if_block_scope)); goto erret; } if (line != NULL) line = skipwhite(ea.cmd + 1); continue; } case '{': // "{" starts a block scope // "{'a': 1}->func() is something else if (ends_excmd(*skipwhite(ea.cmd + 1))) { line = compile_block(ea.cmd, &cctx); continue; } break; } /* * COMMAND MODIFIERS */ cctx.ctx_has_cmdmod = FALSE; if (parse_command_modifiers(&ea, &errormsg, &local_cmdmod, FALSE) == FAIL) { if (errormsg != NULL) goto erret; // empty line or comment line = (char_u *)""; continue; } generate_cmdmods(&cctx, &local_cmdmod); undo_cmdmod(&local_cmdmod); // Check if there was a colon after the last command modifier or before // the current position. for (p = ea.cmd; p >= line; --p) { if (*p == ':') starts_with_colon = TRUE; if (p < ea.cmd && !VIM_ISWHITE(*p)) break; } // Skip ":call" to get to the function name. p = ea.cmd; if (checkforcmd(&ea.cmd, "call", 3)) { if (*ea.cmd == '(') // not for "call()" ea.cmd = p; else ea.cmd = skipwhite(ea.cmd); } if (!starts_with_colon) { int assign; // Check for assignment after command modifiers. assign = may_compile_assignment(&ea, &line, &cctx); if (assign == OK) goto nextline; if (assign == FAIL) goto erret; } /* * COMMAND after range * 'text'->func() should not be confused with 'a mark */ cmd = ea.cmd; if (*cmd != '\'' || starts_with_colon) { ea.cmd = skip_range(ea.cmd, TRUE, NULL); if (ea.cmd > cmd) { if (!starts_with_colon) { semsg(_(e_colon_required_before_range_str), cmd); goto erret; } if (ends_excmd2(line, ea.cmd)) { // A range without a command: jump to the line. // TODO: compile to a more efficient command, possibly // calling parse_cmd_address(). ea.cmdidx = CMD_SIZE; line = compile_exec(line, &ea, &cctx); goto nextline; } } } p = find_ex_command(&ea, NULL, starts_with_colon ? NULL : (int (*)(char_u *, size_t, void *, cctx_T *))lookup_local, &cctx); if (p == NULL) { if (cctx.ctx_skip != SKIP_YES) emsg(_(e_ambiguous_use_of_user_defined_command)); goto erret; } if (p == ea.cmd && ea.cmdidx != CMD_SIZE) { if (cctx.ctx_skip == SKIP_YES) { line += STRLEN(line); goto nextline; } // Expression or function call. if (ea.cmdidx != CMD_eval) { // CMD_var cannot happen, compile_assignment() above would be // used. Most likely an assignment to a non-existing variable. semsg(_(e_command_not_recognized_str), ea.cmd); goto erret; } } if (cctx.ctx_had_return && ea.cmdidx != CMD_elseif && ea.cmdidx != CMD_else && ea.cmdidx != CMD_endif && ea.cmdidx != CMD_endfor && ea.cmdidx != CMD_endwhile && ea.cmdidx != CMD_catch && ea.cmdidx != CMD_finally && ea.cmdidx != CMD_endtry) { emsg(_(e_unreachable_code_after_return)); goto erret; } p = skipwhite(p); if (ea.cmdidx != CMD_SIZE && ea.cmdidx != CMD_write && ea.cmdidx != CMD_read) { if (ea.cmdidx >= 0) ea.argt = excmd_get_argt(ea.cmdidx); if ((ea.argt & EX_BANG) && *p == '!') { ea.forceit = TRUE; p = skipwhite(p + 1); } } switch (ea.cmdidx) { case CMD_def: ea.arg = p; line = compile_nested_function(&ea, &cctx); break; case CMD_function: // TODO: should we allow this, e.g. to declare a global // function? emsg(_(e_cannot_use_function_inside_def)); goto erret; case CMD_return: line = compile_return(p, check_return_type, &cctx); cctx.ctx_had_return = TRUE; break; case CMD_let: emsg(_(e_cannot_use_let_in_vim9_script)); break; case CMD_var: case CMD_final: case CMD_const: line = compile_assignment(p, &ea, ea.cmdidx, &cctx); if (line == p) line = NULL; break; case CMD_unlet: case CMD_unlockvar: case CMD_lockvar: line = compile_unletlock(p, &ea, &cctx); break; case CMD_import: line = compile_import(p, &cctx); break; case CMD_if: line = compile_if(p, &cctx); break; case CMD_elseif: line = compile_elseif(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_else: line = compile_else(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_endif: line = compile_endif(p, &cctx); break; case CMD_while: line = compile_while(p, &cctx); break; case CMD_endwhile: line = compile_endwhile(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_for: line = compile_for(p, &cctx); break; case CMD_endfor: line = compile_endfor(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_continue: line = compile_continue(p, &cctx); break; case CMD_break: line = compile_break(p, &cctx); break; case CMD_try: line = compile_try(p, &cctx); break; case CMD_catch: line = compile_catch(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_finally: line = compile_finally(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_endtry: line = compile_endtry(p, &cctx); cctx.ctx_had_return = FALSE; break; case CMD_throw: line = compile_throw(p, &cctx); break; case CMD_eval: if (compile_expr0(&p, &cctx) == FAIL) goto erret; // drop the result generate_instr_drop(&cctx, ISN_DROP, 1); line = skipwhite(p); break; case CMD_echo: case CMD_echon: case CMD_execute: case CMD_echomsg: case CMD_echoerr: line = compile_mult_expr(p, ea.cmdidx, &cctx); break; case CMD_put: ea.cmd = cmd; line = compile_put(p, &ea, &cctx); break; // TODO: any other commands with an expression argument? case CMD_append: case CMD_change: case CMD_insert: case CMD_t: case CMD_xit: not_in_vim9(&ea); goto erret; case CMD_SIZE: if (cctx.ctx_skip != SKIP_YES) { semsg(_(e_invalid_command_str), ea.cmd); goto erret; } // We don't check for a next command here. line = (char_u *)""; break; default: if (cctx.ctx_skip == SKIP_YES) { // We don't check for a next command here. line = (char_u *)""; } else { // Not recognized, execute with do_cmdline_cmd(). ea.arg = p; line = compile_exec(line, &ea, &cctx); } break; } nextline: if (line == NULL) goto erret; line = skipwhite(line); // Undo any command modifiers. generate_undo_cmdmods(&cctx); if (cctx.ctx_type_stack.ga_len < 0) { iemsg("Type stack underflow"); goto erret; } } if (cctx.ctx_scope != NULL) { if (cctx.ctx_scope->se_type == IF_SCOPE) emsg(_(e_endif)); else if (cctx.ctx_scope->se_type == WHILE_SCOPE) emsg(_(e_endwhile)); else if (cctx.ctx_scope->se_type == FOR_SCOPE) emsg(_(e_endfor)); else emsg(_(e_missing_rcurly)); goto erret; } if (!cctx.ctx_had_return) { if (ufunc->uf_ret_type->tt_type != VAR_VOID) { emsg(_(e_missing_return_statement)); goto erret; } // Return zero if there is no return at the end. generate_instr(&cctx, ISN_RETURN_ZERO); } { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; dfunc->df_deleted = FALSE; dfunc->df_script_seq = current_sctx.sc_seq; dfunc->df_instr = instr->ga_data; dfunc->df_instr_count = instr->ga_len; dfunc->df_varcount = cctx.ctx_locals_count; dfunc->df_has_closure = cctx.ctx_has_closure; if (cctx.ctx_outer_used) ufunc->uf_flags |= FC_CLOSURE; ufunc->uf_def_status = UF_COMPILED; } ret = OK; erret: if (ret == FAIL) { int idx; dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; for (idx = 0; idx < instr->ga_len; ++idx) delete_instr(((isn_T *)instr->ga_data) + idx); ga_clear(instr); VIM_CLEAR(dfunc->df_name); // If using the last entry in the table and it was added above, we // might as well remove it. if (!dfunc->df_deleted && new_def_function && ufunc->uf_dfunc_idx == def_functions.ga_len - 1) { --def_functions.ga_len; ufunc->uf_dfunc_idx = 0; } ufunc->uf_def_status = UF_NOT_COMPILED; while (cctx.ctx_scope != NULL) drop_scope(&cctx); // Don't execute this function body. ga_clear_strings(&ufunc->uf_lines); if (errormsg != NULL) emsg(errormsg); else if (did_emsg == did_emsg_before) emsg(_(e_compiling_def_function_failed)); } current_sctx = save_current_sctx; estack_compiling = save_estack_compiling; if (do_estack_push) estack_pop(); free_imported(&cctx); free_locals(&cctx); ga_clear(&cctx.ctx_type_stack); return ret; } void set_function_type(ufunc_T *ufunc) { int varargs = ufunc->uf_va_name != NULL; int argcount = ufunc->uf_args.ga_len; // Create a type for the function, with the return type and any // argument types. // A vararg is included in uf_args.ga_len but not in uf_arg_types. // The type is included in "tt_args". if (argcount > 0 || varargs) { ufunc->uf_func_type = alloc_func_type(ufunc->uf_ret_type, argcount, &ufunc->uf_type_list); // Add argument types to the function type. if (func_type_add_arg_types(ufunc->uf_func_type, argcount + varargs, &ufunc->uf_type_list) == FAIL) return; ufunc->uf_func_type->tt_argcount = argcount + varargs; ufunc->uf_func_type->tt_min_argcount = argcount - ufunc->uf_def_args.ga_len; if (ufunc->uf_arg_types == NULL) { int i; // lambda does not have argument types. for (i = 0; i < argcount; ++i) ufunc->uf_func_type->tt_args[i] = &t_any; } else mch_memmove(ufunc->uf_func_type->tt_args, ufunc->uf_arg_types, sizeof(type_T *) * argcount); if (varargs) { ufunc->uf_func_type->tt_args[argcount] = ufunc->uf_va_type == NULL ? &t_any : ufunc->uf_va_type; ufunc->uf_func_type->tt_flags = TTFLAG_VARARGS; } } else // No arguments, can use a predefined type. ufunc->uf_func_type = get_func_type(ufunc->uf_ret_type, argcount, &ufunc->uf_type_list); } /* * Delete an instruction, free what it contains. */ void delete_instr(isn_T *isn) { switch (isn->isn_type) { case ISN_DEF: case ISN_EXEC: case ISN_LOADAUTO: case ISN_LOADB: case ISN_LOADENV: case ISN_LOADG: case ISN_LOADOPT: case ISN_LOADT: case ISN_LOADW: case ISN_PUSHEXC: case ISN_PUSHFUNC: case ISN_PUSHS: case ISN_RANGE: case ISN_STOREAUTO: case ISN_STOREB: case ISN_STOREENV: case ISN_STOREG: case ISN_STORET: case ISN_STOREW: case ISN_STRINGMEMBER: vim_free(isn->isn_arg.string); break; case ISN_LOADS: case ISN_STORES: vim_free(isn->isn_arg.loadstore.ls_name); break; case ISN_UNLET: case ISN_UNLETENV: vim_free(isn->isn_arg.unlet.ul_name); break; case ISN_STOREOPT: vim_free(isn->isn_arg.storeopt.so_name); break; case ISN_PUSHBLOB: // push blob isn_arg.blob blob_unref(isn->isn_arg.blob); break; case ISN_PUSHJOB: #ifdef FEAT_JOB_CHANNEL job_unref(isn->isn_arg.job); #endif break; case ISN_PUSHCHANNEL: #ifdef FEAT_JOB_CHANNEL channel_unref(isn->isn_arg.channel); #endif break; case ISN_UCALL: vim_free(isn->isn_arg.ufunc.cuf_name); break; case ISN_FUNCREF: { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + isn->isn_arg.funcref.fr_func; ufunc_T *ufunc = dfunc->df_ufunc; if (ufunc != NULL && func_name_refcount(ufunc->uf_name)) func_ptr_unref(ufunc); } break; case ISN_DCALL: { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + isn->isn_arg.dfunc.cdf_idx; if (dfunc->df_ufunc != NULL && func_name_refcount(dfunc->df_ufunc->uf_name)) func_ptr_unref(dfunc->df_ufunc); } break; case ISN_NEWFUNC: { char_u *lambda = isn->isn_arg.newfunc.nf_lambda; ufunc_T *ufunc = find_func_even_dead(lambda, TRUE, NULL); if (ufunc != NULL) { unlink_def_function(ufunc); func_ptr_unref(ufunc); } vim_free(lambda); vim_free(isn->isn_arg.newfunc.nf_global); } break; case ISN_CHECKTYPE: case ISN_SETTYPE: free_type(isn->isn_arg.type.ct_type); break; case ISN_CMDMOD: vim_regfree(isn->isn_arg.cmdmod.cf_cmdmod ->cmod_filter_regmatch.regprog); vim_free(isn->isn_arg.cmdmod.cf_cmdmod); break; case ISN_LOADSCRIPT: case ISN_STORESCRIPT: vim_free(isn->isn_arg.script.scriptref); break; case ISN_2BOOL: case ISN_2STRING: case ISN_2STRING_ANY: case ISN_ADDBLOB: case ISN_ADDLIST: case ISN_ANYINDEX: case ISN_ANYSLICE: case ISN_BCALL: case ISN_BLOBAPPEND: case ISN_CATCH: case ISN_CHECKLEN: case ISN_CHECKNR: case ISN_CMDMOD_REV: case ISN_COMPAREANY: case ISN_COMPAREBLOB: case ISN_COMPAREBOOL: case ISN_COMPAREDICT: case ISN_COMPAREFLOAT: case ISN_COMPAREFUNC: case ISN_COMPARELIST: case ISN_COMPARENR: case ISN_COMPARESPECIAL: case ISN_COMPARESTRING: case ISN_CONCAT: case ISN_COND2BOOL: case ISN_DROP: case ISN_ECHO: case ISN_ECHOERR: case ISN_ECHOMSG: case ISN_ENDTRY: case ISN_EXECCONCAT: case ISN_EXECUTE: case ISN_FOR: case ISN_GETITEM: case ISN_JUMP: case ISN_LISTAPPEND: case ISN_LISTINDEX: case ISN_LISTSLICE: case ISN_LOAD: case ISN_LOADBDICT: case ISN_LOADGDICT: case ISN_LOADOUTER: case ISN_LOADREG: case ISN_LOADTDICT: case ISN_LOADV: case ISN_LOADWDICT: case ISN_LOCKCONST: case ISN_MEMBER: case ISN_NEGATENR: case ISN_NEWDICT: case ISN_NEWLIST: case ISN_OPANY: case ISN_OPFLOAT: case ISN_OPNR: case ISN_PCALL: case ISN_PCALL_END: case ISN_PUSHBOOL: case ISN_PUSHF: case ISN_PUSHNR: case ISN_PUSHSPEC: case ISN_PUT: case ISN_RETURN: case ISN_RETURN_ZERO: case ISN_SHUFFLE: case ISN_SLICE: case ISN_STORE: case ISN_STOREINDEX: case ISN_STORENR: case ISN_STOREOUTER: case ISN_STOREREG: case ISN_STOREV: case ISN_STRINDEX: case ISN_STRSLICE: case ISN_THROW: case ISN_TRY: case ISN_UNLETINDEX: case ISN_UNPACK: // nothing allocated break; } } /* * Free all instructions for "dfunc" except df_name. */ static void delete_def_function_contents(dfunc_T *dfunc, int mark_deleted) { int idx; ga_clear(&dfunc->df_def_args_isn); if (dfunc->df_instr != NULL) { for (idx = 0; idx < dfunc->df_instr_count; ++idx) delete_instr(dfunc->df_instr + idx); VIM_CLEAR(dfunc->df_instr); dfunc->df_instr = NULL; } if (mark_deleted) dfunc->df_deleted = TRUE; if (dfunc->df_ufunc != NULL) dfunc->df_ufunc->uf_def_status = UF_NOT_COMPILED; } /* * When a user function is deleted, clear the contents of any associated def * function, unless another user function still uses it. * The position in def_functions can be re-used. */ void unlink_def_function(ufunc_T *ufunc) { if (ufunc->uf_dfunc_idx > 0) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; if (--dfunc->df_refcount <= 0) delete_def_function_contents(dfunc, TRUE); ufunc->uf_def_status = UF_NOT_COMPILED; ufunc->uf_dfunc_idx = 0; if (dfunc->df_ufunc == ufunc) dfunc->df_ufunc = NULL; } } /* * Used when a user function refers to an existing dfunc. */ void link_def_function(ufunc_T *ufunc) { if (ufunc->uf_dfunc_idx > 0) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + ufunc->uf_dfunc_idx; ++dfunc->df_refcount; } } #if defined(EXITFREE) || defined(PROTO) /* * Free all functions defined with ":def". */ void free_def_functions(void) { int idx; for (idx = 0; idx < def_functions.ga_len; ++idx) { dfunc_T *dfunc = ((dfunc_T *)def_functions.ga_data) + idx; delete_def_function_contents(dfunc, TRUE); vim_free(dfunc->df_name); } ga_clear(&def_functions); } #endif #endif // FEAT_EVAL