1 /* PSPP - a program for statistical analysis.
2 Copyright (C) 1997-9, 2000, 2006, 2010, 2011, 2012, 2014 Free Software Foundation, Inc.
4 This program is free software: you can redistribute it and/or modify
5 it under the terms of the GNU General Public License as published by
6 the Free Software Foundation, either version 3 of the License, or
7 (at your option) any later version.
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program. If not, see <http://www.gnu.org/licenses/>. */
26 #include "data/case.h"
27 #include "data/dictionary.h"
28 #include "data/settings.h"
29 #include "data/variable.h"
30 #include "language/expressions/helpers.h"
31 #include "language/lexer/format-parser.h"
32 #include "language/lexer/lexer.h"
33 #include "language/lexer/variable-parser.h"
34 #include "libpspp/array.h"
35 #include "libpspp/assertion.h"
36 #include "libpspp/i18n.h"
37 #include "libpspp/message.h"
38 #include "libpspp/misc.h"
39 #include "libpspp/pool.h"
40 #include "libpspp/str.h"
42 #include "gl/c-strcase.h"
43 #include "gl/minmax.h"
44 #include "gl/xalloc.h"
48 /* Recursive descent parser in order of increasing precedence. */
49 typedef struct expr_node *parse_recursively_func (struct lexer *, struct expression *);
50 static parse_recursively_func parse_or, parse_and, parse_not;
51 static parse_recursively_func parse_rel, parse_add, parse_mul;
52 static parse_recursively_func parse_neg, parse_exp;
53 static parse_recursively_func parse_primary;
54 static parse_recursively_func parse_vector_element, parse_function;
56 /* Utility functions. */
57 static struct expression *expr_create (struct dataset *ds);
58 atom_type expr_node_returns (const struct expr_node *);
60 static const char *atom_type_name (atom_type);
61 static struct expression *finish_expression (struct expr_node *,
63 static bool type_check (const struct expression *, const struct expr_node *,
64 enum val_type expected_type);
65 static struct expr_node *allocate_unary_variable (struct expression *,
66 const struct variable *);
68 /* Public functions. */
70 /* Parses an expression of the given TYPE. If DS is nonnull then variables and
71 vectors within it may be referenced within the expression; otherwise, the
72 expression must not reference any variables or vectors. Returns the new
73 expression if successful or a null pointer otherwise. */
75 expr_parse (struct lexer *lexer, struct dataset *ds, enum val_type type)
77 assert (val_type_is_valid (type));
79 struct expression *e = expr_create (ds);
80 struct expr_node *n = parse_or (lexer, e);
81 if (!n || !type_check (e, n, type))
87 return finish_expression (expr_optimize (n, e), e);
90 /* Parses a boolean expression, otherwise similar to expr_parse(). */
92 expr_parse_bool (struct lexer *lexer, struct dataset *ds)
94 struct expression *e = expr_create (ds);
95 struct expr_node *n = parse_or (lexer, e);
102 atom_type actual_type = expr_node_returns (n);
103 if (actual_type == OP_number)
104 n = expr_allocate_binary (e, OP_EXPR_TO_BOOLEAN, n,
105 expr_allocate_expr_node (e, n));
106 else if (actual_type != OP_boolean)
108 msg_at (SE, expr_location (e, n),
109 _("Type mismatch: expression has %s type, "
110 "but a boolean value is required here."),
111 atom_type_name (actual_type));
116 return finish_expression (expr_optimize (n, e), e);
119 /* Parses a numeric expression that is intended to be assigned to newly created
120 variable NEW_VAR_NAME. (This allows for a better error message if the
121 expression is not numeric.) Otherwise similar to expr_parse(). */
123 expr_parse_new_variable (struct lexer *lexer, struct dataset *ds,
124 const char *new_var_name)
126 struct expression *e = expr_create (ds);
127 struct expr_node *n = parse_or (lexer, e);
134 atom_type actual_type = expr_node_returns (n);
135 if (actual_type != OP_number && actual_type != OP_boolean)
137 msg (SE, _("This command tries to create a new variable %s by assigning a "
138 "string value to it, but this is not supported. Use "
139 "the STRING command to create the new variable with the "
140 "correct width before assigning to it, e.g. STRING %s(A20)."),
141 new_var_name, new_var_name);
146 return finish_expression (expr_optimize (n, e), e);
149 /* Free expression E. */
151 expr_free (struct expression *e)
154 pool_destroy (e->expr_pool);
158 expr_parse_any (struct lexer *lexer, struct dataset *ds, bool optimize)
161 struct expression *e;
163 e = expr_create (ds);
164 n = parse_or (lexer, e);
172 n = expr_optimize (n, e);
173 return finish_expression (n, e);
176 /* Finishing up expression building. */
178 /* Height of an expression's stacks. */
181 int number_height; /* Height of number stack. */
182 int string_height; /* Height of string stack. */
185 /* Stack heights used by different kinds of arguments. */
186 static const struct stack_heights on_number_stack = {1, 0};
187 static const struct stack_heights on_string_stack = {0, 1};
188 static const struct stack_heights not_on_stack = {0, 0};
190 /* Returns the stack heights used by an atom of the given
192 static const struct stack_heights *
193 atom_type_stack (atom_type type)
195 assert (is_atom (type));
201 return &on_number_stack;
204 return &on_string_stack;
215 return ¬_on_stack;
222 /* Measures the stack height needed for node N, supposing that
223 the stack height is initially *HEIGHT and updating *HEIGHT to
224 the final stack height. Updates *MAX, if necessary, to
225 reflect the maximum intermediate or final height. */
227 measure_stack (const struct expr_node *n,
228 struct stack_heights *height, struct stack_heights *max)
230 const struct stack_heights *return_height;
232 if (is_composite (n->type))
234 struct stack_heights args;
238 for (i = 0; i < n->n_args; i++)
239 measure_stack (n->args[i], &args, max);
241 return_height = atom_type_stack (operations[n->type].returns);
244 return_height = atom_type_stack (n->type);
246 height->number_height += return_height->number_height;
247 height->string_height += return_height->string_height;
249 if (height->number_height > max->number_height)
250 max->number_height = height->number_height;
251 if (height->string_height > max->string_height)
252 max->string_height = height->string_height;
255 /* Allocates stacks within E sufficient for evaluating node N. */
257 allocate_stacks (struct expr_node *n, struct expression *e)
259 struct stack_heights initial = {0, 0};
260 struct stack_heights max = {0, 0};
262 measure_stack (n, &initial, &max);
263 e->number_stack = pool_alloc (e->expr_pool,
264 sizeof *e->number_stack * max.number_height);
265 e->string_stack = pool_alloc (e->expr_pool,
266 sizeof *e->string_stack * max.string_height);
269 /* Finalizes expression E for evaluating node N. */
270 static struct expression *
271 finish_expression (struct expr_node *n, struct expression *e)
273 /* Allocate stacks. */
274 allocate_stacks (n, e);
276 /* Output postfix representation. */
279 /* The eval_pool might have been used for allocating strings
280 during optimization. We need to keep those strings around
281 for all subsequent evaluations, so start a new eval_pool. */
282 e->eval_pool = pool_create_subpool (e->expr_pool);
287 /* Verifies that expression E, whose root node is *N, can be
288 converted to type EXPECTED_TYPE, inserting a conversion at *N
289 if necessary. Returns true if successful, false on failure. */
291 type_check (const struct expression *e, const struct expr_node *n,
292 enum val_type expected_type)
294 atom_type actual_type = expr_node_returns (n);
296 switch (expected_type)
299 if (actual_type != OP_number && actual_type != OP_boolean)
301 msg_at (SE, expr_location (e, n),
302 _("Type mismatch: expression has type '%s', "
303 "but a numeric value is required."),
304 atom_type_name (actual_type));
310 if (actual_type != OP_string)
312 msg_at (SE, expr_location (e, n),
313 _("Type mismatch: expression has type '%s', "
314 "but a string value is required."),
315 atom_type_name (actual_type));
327 /* Recursive-descent expression parser. */
330 free_msg_location (void *loc_)
332 struct msg_location *loc = loc_;
333 msg_location_destroy (loc);
337 expr_location__ (struct expression *e,
338 const struct expr_node *node,
339 const struct msg_location **minp,
340 const struct msg_location **maxp)
342 struct msg_location *loc = node->location;
345 const struct msg_location *min = *minp;
348 || loc->start.line < min->start.line
349 || (loc->start.line == min->start.line
350 && loc->start.column < min->start.column)))
353 const struct msg_location *max = *maxp;
356 || loc->end.line > max->end.line
357 || (loc->end.line == max->end.line
358 && loc->end.column > max->end.column)))
364 if (is_composite (node->type))
365 for (size_t i = 0; i < node->n_args; i++)
366 expr_location__ (e, node->args[i], minp, maxp);
369 /* Returns the source code location corresponding to expression NODE, computing
370 it lazily if needed. */
371 const struct msg_location *
372 expr_location (const struct expression *e_, const struct expr_node *node_)
374 struct expr_node *node = CONST_CAST (struct expr_node *, node_);
380 struct expression *e = CONST_CAST (struct expression *, e_);
381 const struct msg_location *min = NULL;
382 const struct msg_location *max = NULL;
383 expr_location__ (e, node, &min, &max);
386 node->location = msg_location_dup (min);
387 node->location->end = max->end;
388 pool_register (e->expr_pool, free_msg_location, node->location);
391 return node->location;
394 /* Sets e->location to the tokens in S's lexer from offset START_OFS to the
395 token before the current one. Has no effect if E already has a location or
398 expr_add_location (struct lexer *lexer, struct expression *e,
399 int start_ofs, struct expr_node *node)
401 if (node && !node->location)
403 node->location = lex_ofs_location (lexer, start_ofs, lex_ofs (lexer) - 1);
404 pool_register (e->expr_pool, free_msg_location, node->location);
409 type_coercion__ (struct expression *e, struct expr_node *node, size_t arg_idx,
412 assert (!!do_coercion == (e != NULL));
417 struct expr_node **argp = &node->args[arg_idx];
418 struct expr_node *arg = *argp;
422 const struct operation *op = &operations[node->type];
423 atom_type required_type = op->args[MIN (arg_idx, op->n_args - 1)];
424 atom_type actual_type = expr_node_returns (arg);
425 if (actual_type == required_type)
431 switch (required_type)
434 if (actual_type == OP_boolean)
436 /* To enforce strict typing rules, insert Boolean to
437 numeric "conversion". This conversion is a no-op,
438 so it will be removed later. */
440 *argp = expr_allocate_unary (e, OP_BOOLEAN_TO_NUM, arg);
446 /* No coercion to string. */
450 if (actual_type == OP_number)
452 /* Convert numeric to boolean. */
454 *argp = expr_allocate_binary (e, OP_OPERAND_TO_BOOLEAN, arg,
455 expr_allocate_expr_node (e, node));
461 if (actual_type == OP_number)
463 /* Convert number to integer. */
465 *argp = expr_allocate_unary (e, OP_NUM_TO_INTEGER, arg);
471 /* We never coerce to OP_format, only to OP_ni_format or OP_no_format. */
476 if (arg->type == OP_format
477 && fmt_check_input (&arg->format)
478 && fmt_check_type_compat (&arg->format, VAL_NUMERIC))
482 arg->type = OP_ni_format;
490 if (arg->type == OP_format
491 && fmt_check_output (&arg->format)
492 && fmt_check_type_compat (&arg->format, VAL_NUMERIC))
496 arg->type = OP_no_format;
503 if (arg->type == OP_NUM_VAR)
506 *argp = arg->args[0];
512 if (arg->type == OP_STR_VAR)
515 *argp = arg->args[0];
521 if (arg->type == OP_NUM_VAR || arg->type == OP_STR_VAR)
524 *argp = arg->args[0];
530 if (arg->type == OP_number
531 && floor (arg->number) == arg->number
532 && arg->number > 0 && arg->number < INT_MAX)
535 *argp = expr_allocate_pos_int (e, arg->number);
547 type_coercion (struct expression *e, struct expr_node *node, size_t arg_idx)
549 return type_coercion__ (e, node, arg_idx, true);
553 is_coercible (const struct expr_node *node_, size_t arg_idx)
555 struct expr_node *node = CONST_CAST (struct expr_node *, node_);
556 return type_coercion__ (NULL, node, arg_idx, false);
559 /* How to parse an operator.
561 Some operators support both numeric and string operators. For those,
562 'num_op' and 'str_op' are both nonzero. Otherwise, only one 'num_op' is
563 nonzero. (PSPP doesn't have any string-only operators.) */
566 enum token_type token; /* Operator token. */
567 operation_type num_op; /* Operation for numeric operands (or 0). */
568 operation_type str_op; /* Operation for string operands (or 0). */
571 static operation_type
572 match_operator (struct lexer *lexer, const struct operator ops[], size_t n_ops,
573 const struct expr_node *lhs)
575 bool lhs_is_numeric = operations[lhs->type].returns != OP_string;
576 for (const struct operator *op = ops; op < ops + n_ops; op++)
577 if (lex_token (lexer) == op->token)
579 if (op->token != T_NEG_NUM)
582 return op->str_op && !lhs_is_numeric ? op->str_op : op->num_op;
588 operator_name (enum token_type token)
590 return token == T_NEG_NUM ? "-" : token_type_to_string (token);
593 static struct expr_node *
594 parse_binary_operators__ (struct lexer *lexer, struct expression *e,
595 const struct operator ops[], size_t n_ops,
596 parse_recursively_func *parse_next_level,
597 const char *chain_warning, struct expr_node *lhs)
599 for (int op_count = 0; ; op_count++)
601 enum token_type token = lex_token (lexer);
602 operation_type optype = match_operator (lexer, ops, n_ops, lhs);
605 if (op_count > 1 && chain_warning)
606 msg_at (SW, expr_location (e, lhs), "%s", chain_warning);
611 struct expr_node *rhs = parse_next_level (lexer, e);
615 struct expr_node *node = expr_allocate_binary (e, optype, lhs, rhs);
616 if (!is_coercible (node, 0) || !is_coercible (node, 1))
619 for (size_t i = 0; i < n_ops; i++)
620 if (ops[i].token == token)
621 both = ops[i].num_op && ops[i].str_op;
623 const char *name = operator_name (token);
625 msg_at (SE, expr_location (e, node),
626 _("Both operands of %s must have the same type."), name);
627 else if (operations[node->type].args[0] != OP_string)
628 msg_at (SE, expr_location (e, node),
629 _("Both operands of %s must be numeric."), name);
631 msg_at (SE, expr_location (e, node),
632 _("Both operands of %s must be strings."), name);
634 msg_at (SN, expr_location (e, node->args[0]),
635 _("This operand has type '%s'."),
636 atom_type_name (expr_node_returns (node->args[0])));
637 msg_at (SN, expr_location (e, node->args[1]),
638 _("This operand has type '%s'."),
639 atom_type_name (expr_node_returns (node->args[1])));
644 if (!type_coercion (e, node, 0) || !type_coercion (e, node, 1))
651 static struct expr_node *
652 parse_binary_operators (struct lexer *lexer, struct expression *e,
653 const struct operator ops[], size_t n_ops,
654 parse_recursively_func *parse_next_level,
655 const char *chain_warning)
657 struct expr_node *lhs = parse_next_level (lexer, e);
661 return parse_binary_operators__ (lexer, e, ops, n_ops, parse_next_level,
665 static struct expr_node *
666 parse_inverting_unary_operator (struct lexer *lexer, struct expression *e,
667 const struct operator *op,
668 parse_recursively_func *parse_next_level)
670 int start_ofs = lex_ofs (lexer);
671 unsigned int op_count = 0;
672 while (lex_match (lexer, op->token))
675 struct expr_node *inner = parse_next_level (lexer, e);
676 if (!inner || !op_count)
679 struct expr_node *outer = expr_allocate_unary (e, op->num_op, inner);
680 expr_add_location (lexer, e, start_ofs, outer);
682 if (!type_coercion (e, outer, 0))
684 assert (operations[outer->type].args[0] != OP_string);
686 const char *name = operator_name (op->token);
687 msg_at (SE, expr_location (e, outer),
688 _("The unary %s operator requires a numeric operand."), name);
690 msg_at (SN, expr_location (e, outer->args[0]),
691 _("The operand of %s has type '%s'."),
692 name, atom_type_name (expr_node_returns (outer->args[0])));
697 return op_count % 2 ? outer : outer->args[0];
700 /* Parses the OR level. */
701 static struct expr_node *
702 parse_or (struct lexer *lexer, struct expression *e)
704 static const struct operator op = { .token = T_OR, .num_op = OP_OR };
705 return parse_binary_operators (lexer, e, &op, 1, parse_and, NULL);
708 /* Parses the AND level. */
709 static struct expr_node *
710 parse_and (struct lexer *lexer, struct expression *e)
712 static const struct operator op = { .token = T_AND, .num_op = OP_AND };
714 return parse_binary_operators (lexer, e, &op, 1, parse_not, NULL);
717 /* Parses the NOT level. */
718 static struct expr_node *
719 parse_not (struct lexer *lexer, struct expression *e)
721 static const struct operator op = { .token = T_NOT, .num_op = OP_NOT };
722 return parse_inverting_unary_operator (lexer, e, &op, parse_rel);
725 /* Parse relational operators. */
726 static struct expr_node *
727 parse_rel (struct lexer *lexer, struct expression *e)
729 const char *chain_warning =
730 _("Chaining relational operators (e.g. `a < b < c') will "
731 "not produce the mathematically expected result. "
732 "Use the AND logical operator to fix the problem "
733 "(e.g. `a < b AND b < c'). "
734 "To disable this warning, insert parentheses.");
736 static const struct operator ops[] =
738 { .token = T_EQUALS, .num_op = OP_EQ, .str_op = OP_EQ_STRING },
739 { .token = T_EQ, .num_op = OP_EQ, .str_op = OP_EQ_STRING },
740 { .token = T_GE, .num_op = OP_GE, .str_op = OP_GE_STRING },
741 { .token = T_GT, .num_op = OP_GT, .str_op = OP_GT_STRING },
742 { .token = T_LE, .num_op = OP_LE, .str_op = OP_LE_STRING },
743 { .token = T_LT, .num_op = OP_LT, .str_op = OP_LT_STRING },
744 { .token = T_NE, .num_op = OP_NE, .str_op = OP_NE_STRING },
747 return parse_binary_operators (lexer, e, ops, sizeof ops / sizeof *ops,
748 parse_add, chain_warning);
751 /* Parses the addition and subtraction level. */
752 static struct expr_node *
753 parse_add (struct lexer *lexer, struct expression *e)
755 static const struct operator ops[] =
757 { .token = T_PLUS, .num_op = OP_ADD },
758 { .token = T_DASH, .num_op = OP_SUB },
759 { .token = T_NEG_NUM, .num_op = OP_ADD },
762 return parse_binary_operators (lexer, e, ops, sizeof ops / sizeof *ops,
766 /* Parses the multiplication and division level. */
767 static struct expr_node *
768 parse_mul (struct lexer *lexer, struct expression *e)
770 static const struct operator ops[] =
772 { .token = T_ASTERISK, .num_op = OP_MUL },
773 { .token = T_SLASH, .num_op = OP_DIV },
776 return parse_binary_operators (lexer, e, ops, sizeof ops / sizeof *ops,
780 /* Parses the unary minus level. */
781 static struct expr_node *
782 parse_neg (struct lexer *lexer, struct expression *e)
784 static const struct operator op = { .token = T_DASH, .num_op = OP_NEG };
785 return parse_inverting_unary_operator (lexer, e, &op, parse_exp);
788 static struct expr_node *
789 parse_exp (struct lexer *lexer, struct expression *e)
791 static const struct operator op = { .token = T_EXP, .num_op = OP_POW };
793 const char *chain_warning =
794 _("The exponentiation operator (`**') is left-associative: "
795 "`a**b**c' equals `(a**b)**c', not `a**(b**c)'. "
796 "To disable this warning, insert parentheses.");
798 if (lex_token (lexer) != T_NEG_NUM || lex_next_token (lexer, 1) != T_EXP)
799 return parse_binary_operators (lexer, e, &op, 1,
800 parse_primary, chain_warning);
802 /* Special case for situations like "-5**6", which must be parsed as
805 int start_ofs = lex_ofs (lexer);
806 struct expr_node *lhs = expr_allocate_number (e, -lex_tokval (lexer));
808 expr_add_location (lexer, e, start_ofs, lhs);
810 struct expr_node *node = parse_binary_operators__ (
811 lexer, e, &op, 1, parse_primary, chain_warning, lhs);
815 node = expr_allocate_unary (e, OP_NEG, node);
816 expr_add_location (lexer, e, start_ofs, node);
821 ymd_to_offset (int y, int m, int d)
824 double retval = calendar_gregorian_to_offset (
825 y, m, d, settings_get_fmt_settings (), &error);
828 msg (SE, "%s", error);
834 static struct expr_node *
835 expr_date (struct expression *e, int year_digits)
837 static const char *months[12] =
839 "JAN", "FEB", "MAR", "APR", "MAY", "JUN",
840 "JUL", "AUG", "SEP", "OCT", "NOV", "DEC",
843 time_t last_proc_time = time_of_last_procedure (e->ds);
844 struct tm *time = localtime (&last_proc_time);
846 char *tmp = (year_digits == 2
847 ? xasprintf ("%02d-%s-%02d", time->tm_mday, months[time->tm_mon],
849 : xasprintf ("%02d-%s-%04d", time->tm_mday, months[time->tm_mon],
850 time->tm_year + 1900));
853 ss_alloc_substring_pool (&s, ss_cstr (tmp), e->expr_pool);
857 return expr_allocate_string (e, s);
860 /* Parses system variables. */
861 static struct expr_node *
862 parse_sysvar (struct lexer *lexer, struct expression *e)
864 if (lex_match_id (lexer, "$CASENUM"))
865 return expr_allocate_nullary (e, OP_CASENUM);
866 else if (lex_match_id (lexer, "$DATE"))
867 return expr_date (e, 2);
868 else if (lex_match_id (lexer, "$DATE11"))
869 return expr_date (e, 4);
870 else if (lex_match_id (lexer, "$TRUE"))
871 return expr_allocate_boolean (e, 1.0);
872 else if (lex_match_id (lexer, "$FALSE"))
873 return expr_allocate_boolean (e, 0.0);
874 else if (lex_match_id (lexer, "$SYSMIS"))
875 return expr_allocate_number (e, SYSMIS);
876 else if (lex_match_id (lexer, "$JDATE"))
878 time_t time = time_of_last_procedure (e->ds);
879 struct tm *tm = localtime (&time);
880 return expr_allocate_number (e, ymd_to_offset (tm->tm_year + 1900,
884 else if (lex_match_id (lexer, "$TIME"))
886 time_t time = time_of_last_procedure (e->ds);
887 struct tm *tm = localtime (&time);
888 return expr_allocate_number (e, ymd_to_offset (tm->tm_year + 1900,
891 + tm->tm_hour * 60 * 60.
895 else if (lex_match_id (lexer, "$LENGTH"))
896 return expr_allocate_number (e, settings_get_viewlength ());
897 else if (lex_match_id (lexer, "$WIDTH"))
898 return expr_allocate_number (e, settings_get_viewwidth ());
901 msg (SE, _("Unknown system variable %s."), lex_tokcstr (lexer));
906 /* Parses numbers, varnames, etc. */
907 static struct expr_node *
908 parse_primary__ (struct lexer *lexer, struct expression *e)
910 switch (lex_token (lexer))
913 if (lex_next_token (lexer, 1) == T_LPAREN)
915 /* An identifier followed by a left parenthesis may be
916 a vector element reference. If not, it's a function
918 if (e->ds != NULL && dict_lookup_vector (dataset_dict (e->ds), lex_tokcstr (lexer)) != NULL)
919 return parse_vector_element (lexer, e);
921 return parse_function (lexer, e);
923 else if (lex_tokcstr (lexer)[0] == '$')
925 /* $ at the beginning indicates a system variable. */
926 return parse_sysvar (lexer, e);
928 else if (e->ds != NULL && dict_lookup_var (dataset_dict (e->ds), lex_tokcstr (lexer)))
930 /* It looks like a user variable.
931 (It could be a format specifier, but we'll assume
932 it's a variable unless proven otherwise. */
933 return allocate_unary_variable (e, parse_variable (lexer, dataset_dict (e->ds)));
937 /* Try to parse it as a format specifier. */
942 ok = parse_format_specifier (lexer, &fmt);
946 return expr_allocate_format (e, &fmt);
948 /* All attempts failed. */
949 msg (SE, _("Unknown identifier %s."), lex_tokcstr (lexer));
957 struct expr_node *node = expr_allocate_number (e, lex_tokval (lexer));
964 const char *dict_encoding;
965 struct expr_node *node;
968 dict_encoding = (e->ds != NULL
969 ? dict_get_encoding (dataset_dict (e->ds))
971 s = recode_string_pool (dict_encoding, "UTF-8", lex_tokcstr (lexer),
972 ss_length (lex_tokss (lexer)), e->expr_pool);
973 node = expr_allocate_string (e, ss_cstr (s));
982 struct expr_node *node = parse_or (lexer, e);
983 return !node || !lex_force_match (lexer, T_RPAREN) ? NULL : node;
987 lex_error (lexer, NULL);
992 static struct expr_node *
993 parse_primary (struct lexer *lexer, struct expression *e)
995 int start_ofs = lex_ofs (lexer);
996 struct expr_node *node = parse_primary__ (lexer, e);
997 expr_add_location (lexer, e, start_ofs, node);
1001 static struct expr_node *
1002 parse_vector_element (struct lexer *lexer, struct expression *e)
1004 int vector_start_ofs = lex_ofs (lexer);
1006 /* Find vector, skip token.
1007 The caller must already have verified that the current token
1008 is the name of a vector. */
1009 const struct vector *vector = dict_lookup_vector (dataset_dict (e->ds),
1010 lex_tokcstr (lexer));
1011 assert (vector != NULL);
1014 /* Skip left parenthesis token.
1015 The caller must have verified that the lookahead is a left
1017 assert (lex_token (lexer) == T_LPAREN);
1020 int element_start_ofs = lex_ofs (lexer);
1021 struct expr_node *element = parse_or (lexer, e);
1024 expr_add_location (lexer, e, element_start_ofs, element);
1026 if (!lex_match (lexer, T_RPAREN))
1029 operation_type type = (vector_get_type (vector) == VAL_NUMERIC
1030 ? OP_VEC_ELEM_NUM : OP_VEC_ELEM_STR);
1031 struct expr_node *node = expr_allocate_binary (
1032 e, type, element, expr_allocate_vector (e, vector));
1033 expr_add_location (lexer, e, vector_start_ofs, node);
1035 if (!type_coercion (e, node, 0))
1037 msg_at (SE, expr_location (e, node),
1038 _("A vector index must be numeric."));
1040 msg_at (SN, expr_location (e, node->args[0]),
1041 _("This vector index has type '%s'."),
1042 atom_type_name (expr_node_returns (node->args[0])));
1050 /* Individual function parsing. */
1052 const struct operation operations[OP_first + n_OP] = {
1053 #include "parse.inc"
1057 word_matches (const char **test, const char **name)
1059 size_t test_len = strcspn (*test, ".");
1060 size_t name_len = strcspn (*name, ".");
1061 if (test_len == name_len)
1063 if (buf_compare_case (*test, *name, test_len))
1066 else if (test_len < 3 || test_len > name_len)
1070 if (buf_compare_case (*test, *name, test_len))
1076 if (**test != **name)
1087 /* Returns 0 if TOKEN and FUNC do not match,
1088 1 if TOKEN is an acceptable abbreviation for FUNC,
1089 2 if TOKEN equals FUNC. */
1091 compare_function_names (const char *token_, const char *func_)
1093 const char *token = token_;
1094 const char *func = func_;
1095 while (*token || *func)
1096 if (!word_matches (&token, &func))
1098 return !c_strcasecmp (token_, func_) ? 2 : 1;
1102 lookup_function (const char *token,
1103 const struct operation **first,
1104 const struct operation **last)
1106 *first = *last = NULL;
1107 const struct operation *best = NULL;
1109 for (const struct operation *f = operations + OP_function_first;
1110 f <= operations + OP_function_last; f++)
1112 int score = compare_function_names (token, f->name);
1118 else if (score == 1 && !(f->flags & OPF_NO_ABBREV) && !best)
1127 const struct operation *f = best;
1128 while (f <= operations + OP_function_last
1129 && !c_strcasecmp (f->name, best->name))
1137 extract_min_valid (const char *s)
1139 char *p = strrchr (s, '.');
1141 || p[1] < '0' || p[1] > '9'
1142 || strspn (p + 1, "0123456789") != strlen (p + 1))
1145 return atoi (p + 1);
1149 match_function__ (struct expr_node *node, const struct operation *f)
1151 if (node->n_args < f->n_args
1152 || (node->n_args > f->n_args && (f->flags & OPF_ARRAY_OPERAND) == 0)
1153 || node->n_args - (f->n_args - 1) < f->array_min_elems)
1156 node->type = f - operations;
1157 for (size_t i = 0; i < node->n_args; i++)
1158 if (!is_coercible (node, i))
1164 static const struct operation *
1165 match_function (struct expr_node *node,
1166 const struct operation *first, const struct operation *last)
1168 for (const struct operation *f = first; f < last; f++)
1169 if (match_function__ (node, f))
1175 validate_function_args (const struct expression *e, const struct expr_node *n,
1176 const struct operation *f, int n_args, int min_valid)
1178 /* Count the function arguments that go into the trailing array (if any). We
1179 know that there must be at least the minimum number because
1180 match_function() already checked. */
1181 int array_n_args = n_args - (f->n_args - 1);
1182 assert (array_n_args >= f->array_min_elems);
1184 if ((f->flags & OPF_ARRAY_OPERAND)
1185 && array_n_args % f->array_granularity != 0)
1187 /* RANGE is the only case we have so far. It has paired arguments with
1188 one initial argument, and that's the only special case we deal with
1190 assert (f->array_granularity == 2);
1191 assert (n_args % 2 == 0);
1192 msg_at (SE, expr_location (e, n),
1193 _("%s must have an odd number of arguments."), f->prototype);
1197 if (min_valid != -1)
1199 if (f->array_min_elems == 0)
1201 assert ((f->flags & OPF_MIN_VALID) == 0);
1202 msg_at (SE, expr_location (e, n),
1203 _("%s function cannot accept suffix .%d to specify the "
1204 "minimum number of valid arguments."),
1205 f->prototype, min_valid);
1210 assert (f->flags & OPF_MIN_VALID);
1211 if (min_valid > array_n_args)
1213 msg_at (SE, expr_location (e, n),
1214 _("For %s with %d arguments, at most %d (not %d) may be "
1215 "required to be valid."),
1216 f->prototype, n_args, array_n_args, min_valid);
1226 add_arg (struct expr_node ***args, size_t *n_args, size_t *allocated_args,
1227 struct expr_node *arg,
1228 struct expression *e, struct lexer *lexer, int arg_start_ofs)
1230 if (*n_args >= *allocated_args)
1231 *args = x2nrealloc (*args, allocated_args, sizeof **args);
1233 expr_add_location (lexer, e, arg_start_ofs, arg);
1234 (*args)[(*n_args)++] = arg;
1238 put_invocation (struct string *s,
1239 const char *func_name, struct expr_node *node)
1243 ds_put_format (s, "%s(", func_name);
1244 for (i = 0; i < node->n_args; i++)
1247 ds_put_cstr (s, ", ");
1248 ds_put_cstr (s, operations[expr_node_returns (node->args[i])].prototype);
1250 ds_put_byte (s, ')');
1254 no_match (struct expression *e, const char *func_name, struct expr_node *node,
1255 const struct operation *first, const struct operation *last)
1258 const struct operation *f;
1262 if (last - first == 1)
1264 ds_put_format (&s, _("Type mismatch invoking %s as "), first->prototype);
1265 put_invocation (&s, func_name, node);
1269 ds_put_cstr (&s, _("Function invocation "));
1270 put_invocation (&s, func_name, node);
1271 ds_put_cstr (&s, _(" does not match any known function. Candidates are:"));
1273 for (f = first; f < last; f++)
1274 ds_put_format (&s, "\n%s", f->prototype);
1276 ds_put_byte (&s, '.');
1278 msg_at (SE, expr_location (e, node), "%s", ds_cstr (&s));
1283 static struct expr_node *
1284 parse_function (struct lexer *lexer, struct expression *e)
1286 struct string func_name;
1287 ds_init_substring (&func_name, lex_tokss (lexer));
1289 int min_valid = extract_min_valid (lex_tokcstr (lexer));
1291 const struct operation *first, *last;
1292 if (!lookup_function (lex_tokcstr (lexer), &first, &last))
1294 msg (SE, _("No function or vector named %s."), lex_tokcstr (lexer));
1295 ds_destroy (&func_name);
1299 int func_start_ofs = lex_ofs (lexer);
1301 if (!lex_force_match (lexer, T_LPAREN))
1303 ds_destroy (&func_name);
1307 struct expr_node **args = NULL;
1309 size_t allocated_args = 0;
1310 if (lex_token (lexer) != T_RPAREN)
1313 int arg_start_ofs = lex_ofs (lexer);
1314 if (lex_token (lexer) == T_ID
1315 && lex_next_token (lexer, 1) == T_TO)
1317 const struct variable **vars;
1320 if (!parse_variables_const (lexer, dataset_dict (e->ds),
1321 &vars, &n_vars, PV_SINGLE))
1323 for (size_t i = 0; i < n_vars; i++)
1324 add_arg (&args, &n_args, &allocated_args,
1325 allocate_unary_variable (e, vars[i]),
1326 e, lexer, arg_start_ofs);
1331 struct expr_node *arg = parse_or (lexer, e);
1335 add_arg (&args, &n_args, &allocated_args, arg,
1336 e, lexer, arg_start_ofs);
1338 if (lex_match (lexer, T_RPAREN))
1340 else if (!lex_match (lexer, T_COMMA))
1342 lex_error_expecting (lexer, "`,'", "`)'");
1347 struct expr_node *n = expr_allocate_composite (e, first - operations,
1349 expr_add_location (lexer, e, func_start_ofs, n);
1350 const struct operation *f = match_function (n, first, last);
1353 no_match (e, ds_cstr (&func_name), n, first, last);
1356 n->type = f - operations;
1357 n->min_valid = min_valid != -1 ? min_valid : f->array_min_elems;
1359 for (size_t i = 0; i < n_args; i++)
1360 if (!type_coercion (e, n, i))
1362 /* Unreachable because match_function already checked that the
1363 arguments were coercible. */
1366 if (!validate_function_args (e, n, f, n_args, min_valid))
1369 if ((f->flags & OPF_EXTENSION) && settings_get_syntax () == COMPATIBLE)
1370 msg_at (SW, expr_location (e, n),
1371 _("%s is a PSPP extension."), f->prototype);
1372 if (f->flags & OPF_UNIMPLEMENTED)
1374 msg_at (SE, expr_location (e, n),
1375 _("%s is not available in this version of PSPP."), f->prototype);
1378 if ((f->flags & OPF_PERM_ONLY) &&
1379 proc_in_temporary_transformations (e->ds))
1381 msg_at (SE, expr_location (e, n),
1382 _("%s may not appear after %s."), f->prototype, "TEMPORARY");
1386 if (n->type == OP_LAG_Vn || n->type == OP_LAG_Vs)
1387 dataset_need_lag (e->ds, 1);
1388 else if (n->type == OP_LAG_Vnn || n->type == OP_LAG_Vsn)
1390 assert (n->n_args == 2);
1391 assert (n->args[1]->type == OP_pos_int);
1392 dataset_need_lag (e->ds, n->args[1]->integer);
1396 ds_destroy (&func_name);
1401 ds_destroy (&func_name);
1405 /* Utility functions. */
1407 static struct expression *
1408 expr_create (struct dataset *ds)
1410 struct pool *pool = pool_create ();
1411 struct expression *e = pool_alloc (pool, sizeof *e);
1412 *e = (struct expression) {
1415 .eval_pool = pool_create_subpool (pool),
1421 expr_node_returns (const struct expr_node *n)
1424 assert (is_operation (n->type));
1425 if (is_atom (n->type))
1427 else if (is_composite (n->type))
1428 return operations[n->type].returns;
1434 atom_type_name (atom_type type)
1436 assert (is_atom (type));
1438 /* The Boolean type is purely an internal concept that the documentation
1439 doesn't mention, so it might confuse users if we talked about them in
1441 return type == OP_boolean ? "number" : operations[type].name;
1445 expr_allocate_nullary (struct expression *e, operation_type op)
1447 return expr_allocate_composite (e, op, NULL, 0);
1451 expr_allocate_unary (struct expression *e, operation_type op,
1452 struct expr_node *arg0)
1454 return expr_allocate_composite (e, op, &arg0, 1);
1458 expr_allocate_binary (struct expression *e, operation_type op,
1459 struct expr_node *arg0, struct expr_node *arg1)
1461 struct expr_node *args[2];
1464 return expr_allocate_composite (e, op, args, 2);
1468 expr_allocate_composite (struct expression *e, operation_type op,
1469 struct expr_node **args, size_t n_args)
1471 for (size_t i = 0; i < n_args; i++)
1475 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1476 *n = (struct expr_node) {
1479 .args = pool_clone (e->expr_pool, args, sizeof *n->args * n_args),
1485 expr_allocate_number (struct expression *e, double d)
1487 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1488 *n = (struct expr_node) { .type = OP_number, .number = d };
1493 expr_allocate_boolean (struct expression *e, double b)
1495 assert (b == 0.0 || b == 1.0 || b == SYSMIS);
1497 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1498 *n = (struct expr_node) { .type = OP_boolean, .number = b };
1503 expr_allocate_integer (struct expression *e, int i)
1505 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1506 *n = (struct expr_node) { .type = OP_integer, .integer = i };
1511 expr_allocate_pos_int (struct expression *e, int i)
1515 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1516 *n = (struct expr_node) { .type = OP_pos_int, .integer = i };
1521 expr_allocate_vector (struct expression *e, const struct vector *vector)
1523 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1524 *n = (struct expr_node) { .type = OP_vector, .vector = vector };
1529 expr_allocate_string (struct expression *e, struct substring s)
1531 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1532 *n = (struct expr_node) { .type = OP_string, .string = s };
1537 expr_allocate_variable (struct expression *e, const struct variable *v)
1539 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1540 *n = (struct expr_node) {
1541 .type = var_is_numeric (v) ? OP_num_var : OP_str_var,
1548 expr_allocate_format (struct expression *e, const struct fmt_spec *format)
1550 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1551 *n = (struct expr_node) { .type = OP_format, .format = *format };
1556 expr_allocate_expr_node (struct expression *e,
1557 const struct expr_node *expr_node)
1559 struct expr_node *n = pool_alloc (e->expr_pool, sizeof *n);
1560 *n = (struct expr_node) { .type = OP_expr_node, .expr_node = expr_node };
1564 /* Allocates a unary composite node that represents the value of
1565 variable V in expression E. */
1566 static struct expr_node *
1567 allocate_unary_variable (struct expression *e, const struct variable *v)
1570 return expr_allocate_unary (e, var_is_numeric (v) ? OP_NUM_VAR : OP_STR_VAR,
1571 expr_allocate_variable (e, v));
1574 /* Export function details to other modules. */
1576 /* Returns the operation structure for the function with the
1578 const struct operation *
1579 expr_get_function (size_t idx)
1581 assert (idx < n_OP_function);
1582 return &operations[OP_function_first + idx];
1585 /* Returns the number of expression functions. */
1587 expr_get_n_functions (void)
1589 return n_OP_function;
1592 /* Returns the name of operation OP. */
1594 expr_operation_get_name (const struct operation *op)
1599 /* Returns the human-readable prototype for operation OP. */
1601 expr_operation_get_prototype (const struct operation *op)
1603 return op->prototype;
1606 /* Returns the number of arguments for operation OP. */
1608 expr_operation_get_n_args (const struct operation *op)