int i;
args = *height;
- for (i = 0; i < n->composite.arg_cnt; i++)
+ for (i = 0; i < n->composite.n_args; i++)
measure_stack (n->composite.args[i], &args, max);
return_height = atom_type_stack (operations[n->type].returns);
On failure, returns false and, if OPERATOR is non-null, sets
*OPERATOR to a null pointer. */
static bool
-match_operator (struct lexer *lexer, const struct operator ops[], size_t op_cnt,
+match_operator (struct lexer *lexer, const struct operator ops[], size_t n_ops,
const struct operator **operator)
{
const struct operator *op;
- for (op = ops; op < ops + op_cnt; op++)
+ for (op = ops; op < ops + n_ops; op++)
if (lex_token (lexer) == op->token)
{
if (op->token != T_NEG_NUM)
}
static bool
-check_operator (const struct operator *op, int arg_cnt, atom_type arg_type)
+check_operator (const struct operator *op, int n_args, atom_type arg_type)
{
const struct operation *o;
size_t i;
assert (op != NULL);
o = &operations[op->type];
- assert (o->arg_cnt == arg_cnt);
+ assert (o->n_args == n_args);
assert ((o->flags & OPF_ARRAY_OPERAND) == 0);
- for (i = 0; i < arg_cnt; i++)
+ for (i = 0; i < n_args; i++)
assert (is_compatible (arg_type, o->args[i]));
return true;
}
static bool
-check_binary_operators (const struct operator ops[], size_t op_cnt,
+check_binary_operators (const struct operator ops[], size_t n_ops,
atom_type arg_type)
{
size_t i;
- for (i = 0; i < op_cnt; i++)
+ for (i = 0; i < n_ops; i++)
check_operator (&ops[i], 2, arg_type);
return true;
}
one operator/operand pair is parsed. */
static union any_node *
parse_binary_operators (struct lexer *lexer, struct expression *e, union any_node *node,
- const struct operator ops[], size_t op_cnt,
+ const struct operator ops[], size_t n_ops,
parse_recursively_func *parse_next_level,
const char *chain_warning)
{
int op_count;
const struct operator *operator;
- assert (check_binary_operators (ops, op_cnt, operand_type));
+ assert (check_binary_operators (ops, n_ops, operand_type));
if (node == NULL)
return node;
- for (op_count = 0; match_operator (lexer, ops, op_cnt, &operator); op_count++)
+ for (op_count = 0; match_operator (lexer, ops, n_ops, &operator); op_count++)
{
union any_node *rhs;
\f
/* Individual function parsing. */
-const struct operation operations[OP_first + OP_cnt] = {
+const struct operation operations[OP_first + n_OP] = {
#include "parse.inc"
};
static atom_type
function_arg_type (const struct operation *f, size_t arg_idx)
{
- assert (arg_idx < f->arg_cnt || (f->flags & OPF_ARRAY_OPERAND));
+ assert (arg_idx < f->n_args || (f->flags & OPF_ARRAY_OPERAND));
- return f->args[arg_idx < f->arg_cnt ? arg_idx : f->arg_cnt - 1];
+ return f->args[arg_idx < f->n_args ? arg_idx : f->n_args - 1];
}
static bool
-match_function (union any_node **args, int arg_cnt, const struct operation *f)
+match_function (union any_node **args, int n_args, const struct operation *f)
{
size_t i;
- if (arg_cnt < f->arg_cnt
- || (arg_cnt > f->arg_cnt && (f->flags & OPF_ARRAY_OPERAND) == 0)
- || arg_cnt - (f->arg_cnt - 1) < f->array_min_elems)
+ if (n_args < f->n_args
+ || (n_args > f->n_args && (f->flags & OPF_ARRAY_OPERAND) == 0)
+ || n_args - (f->n_args - 1) < f->array_min_elems)
return false;
- for (i = 0; i < arg_cnt; i++)
+ for (i = 0; i < n_args; i++)
if (!is_coercible (function_arg_type (f, i), &args[i]))
return false;
static void
coerce_function_args (struct expression *e, const struct operation *f,
- union any_node **args, size_t arg_cnt)
+ union any_node **args, size_t n_args)
{
int i;
- for (i = 0; i < arg_cnt; i++)
+ for (i = 0; i < n_args; i++)
type_coercion_assert (e, function_arg_type (f, i), &args[i]);
}
static bool
-validate_function_args (const struct operation *f, int arg_cnt, int min_valid)
+validate_function_args (const struct operation *f, int n_args, int min_valid)
{
/* Count the function arguments that go into the trailing array (if any). We
know that there must be at least the minimum number because
match_function() already checked. */
- int array_arg_cnt = arg_cnt - (f->arg_cnt - 1);
- assert (array_arg_cnt >= f->array_min_elems);
+ int array_n_args = n_args - (f->n_args - 1);
+ assert (array_n_args >= f->array_min_elems);
if ((f->flags & OPF_ARRAY_OPERAND)
- && array_arg_cnt % f->array_granularity != 0)
+ && array_n_args % f->array_granularity != 0)
{
/* RANGE is the only case we have so far. It has paired arguments with
one initial argument, and that's the only special case we deal with
here. */
assert (f->array_granularity == 2);
- assert (arg_cnt % 2 == 0);
+ assert (n_args % 2 == 0);
msg (SE, _("%s must have an odd number of arguments."), f->prototype);
return false;
}
else
{
assert (f->flags & OPF_MIN_VALID);
- if (min_valid > array_arg_cnt)
+ if (min_valid > array_n_args)
{
msg (SE, _("For %s with %d arguments, at most %d (not %d) may be "
"required to be valid."),
- f->prototype, arg_cnt, array_arg_cnt, min_valid);
+ f->prototype, n_args, array_n_args, min_valid);
return false;
}
}
}
static void
-add_arg (union any_node ***args, int *arg_cnt, int *arg_cap,
+add_arg (union any_node ***args, int *n_args, int *allocated_args,
union any_node *arg)
{
- if (*arg_cnt >= *arg_cap)
+ if (*n_args >= *allocated_args)
{
- *arg_cap += 8;
- *args = xrealloc (*args, sizeof **args * *arg_cap);
+ *allocated_args += 8;
+ *args = xrealloc (*args, sizeof **args * *allocated_args);
}
- (*args)[(*arg_cnt)++] = arg;
+ (*args)[(*n_args)++] = arg;
}
static void
put_invocation (struct string *s,
- const char *func_name, union any_node **args, size_t arg_cnt)
+ const char *func_name, union any_node **args, size_t n_args)
{
size_t i;
ds_put_format (s, "%s(", func_name);
- for (i = 0; i < arg_cnt; i++)
+ for (i = 0; i < n_args; i++)
{
if (i > 0)
ds_put_cstr (s, ", ");
static void
no_match (const char *func_name,
- union any_node **args, size_t arg_cnt,
+ union any_node **args, size_t n_args,
const struct operation *first, const struct operation *last)
{
struct string s;
if (last - first == 1)
{
ds_put_format (&s, _("Type mismatch invoking %s as "), first->prototype);
- put_invocation (&s, func_name, args, arg_cnt);
+ put_invocation (&s, func_name, args, n_args);
}
else
{
ds_put_cstr (&s, _("Function invocation "));
- put_invocation (&s, func_name, args, arg_cnt);
+ put_invocation (&s, func_name, args, n_args);
ds_put_cstr (&s, _(" does not match any known function. Candidates are:"));
for (f = first; f < last; f++)
const struct operation *f, *first, *last;
union any_node **args = NULL;
- int arg_cnt = 0;
- int arg_cap = 0;
+ int n_args = 0;
+ int allocated_args = 0;
struct string func_name;
}
args = NULL;
- arg_cnt = arg_cap = 0;
+ n_args = allocated_args = 0;
if (lex_token (lexer) != T_RPAREN)
for (;;)
{
&& lex_next_token (lexer, 1) == T_TO)
{
const struct variable **vars;
- size_t var_cnt;
+ size_t n_vars;
size_t i;
- if (!parse_variables_const (lexer, dataset_dict (e->ds), &vars, &var_cnt, PV_SINGLE))
+ if (!parse_variables_const (lexer, dataset_dict (e->ds), &vars, &n_vars, PV_SINGLE))
goto fail;
- for (i = 0; i < var_cnt; i++)
- add_arg (&args, &arg_cnt, &arg_cap,
+ for (i = 0; i < n_vars; i++)
+ add_arg (&args, &n_args, &allocated_args,
allocate_unary_variable (e, vars[i]));
free (vars);
}
if (arg == NULL)
goto fail;
- add_arg (&args, &arg_cnt, &arg_cap, arg);
+ add_arg (&args, &n_args, &allocated_args, arg);
}
if (lex_match (lexer, T_RPAREN))
break;
}
for (f = first; f < last; f++)
- if (match_function (args, arg_cnt, f))
+ if (match_function (args, n_args, f))
break;
if (f >= last)
{
- no_match (ds_cstr (&func_name), args, arg_cnt, first, last);
+ no_match (ds_cstr (&func_name), args, n_args, first, last);
goto fail;
}
- coerce_function_args (e, f, args, arg_cnt);
- if (!validate_function_args (f, arg_cnt, min_valid))
+ coerce_function_args (e, f, args, n_args);
+ if (!validate_function_args (f, n_args, min_valid))
goto fail;
if ((f->flags & OPF_EXTENSION) && settings_get_syntax () == COMPATIBLE)
goto fail;
}
- n = expr_allocate_composite (e, f - operations, args, arg_cnt);
+ n = expr_allocate_composite (e, f - operations, args, n_args);
n->composite.min_valid = min_valid != -1 ? min_valid : f->array_min_elems;
if (n->type == OP_LAG_Vn || n->type == OP_LAG_Vs)
else if (n->type == OP_LAG_Vnn || n->type == OP_LAG_Vsn)
{
int n_before;
- assert (n->composite.arg_cnt == 2);
+ assert (n->composite.n_args == 2);
assert (n->composite.args[1]->type == OP_pos_int);
n_before = n->composite.args[1]->integer.i;
dataset_need_lag (e->ds, n_before);
e->eval_pool = pool_create_subpool (e->expr_pool);
e->ops = NULL;
e->op_types = NULL;
- e->op_cnt = e->op_cap = 0;
+ e->n_ops = e->allocated_ops = 0;
return e;
}
struct composite_node *c = &n->composite;
assert (is_composite (n->type));
- assert (c->arg_cnt >= op->arg_cnt);
- for (i = 0; i < op->arg_cnt; i++)
+ assert (c->n_args >= op->n_args);
+ for (i = 0; i < op->n_args; i++)
assert (is_compatible (op->args[i], expr_node_returns (c->args[i])));
- if (c->arg_cnt > op->arg_cnt && !is_operator (n->type))
+ if (c->n_args > op->n_args && !is_operator (n->type))
{
assert (op->flags & OPF_ARRAY_OPERAND);
- for (i = 0; i < c->arg_cnt; i++)
- assert (is_compatible (op->args[op->arg_cnt - 1],
+ for (i = 0; i < c->n_args; i++)
+ assert (is_compatible (op->args[op->n_args - 1],
expr_node_returns (c->args[i])));
}
}
union any_node *
expr_allocate_composite (struct expression *e, operation_type op,
- union any_node **args, size_t arg_cnt)
+ union any_node **args, size_t n_args)
{
union any_node *n;
size_t i;
n = pool_alloc (e->expr_pool, sizeof n->composite);
n->type = op;
- n->composite.arg_cnt = arg_cnt;
+ n->composite.n_args = n_args;
n->composite.args = pool_alloc (e->expr_pool,
- sizeof *n->composite.args * arg_cnt);
- for (i = 0; i < arg_cnt; i++)
+ sizeof *n->composite.args * n_args);
+ for (i = 0; i < n_args; i++)
{
if (args[i] == NULL)
return NULL;
n->composite.args[i] = args[i];
}
- memcpy (n->composite.args, args, sizeof *n->composite.args * arg_cnt);
+ memcpy (n->composite.args, args, sizeof *n->composite.args * n_args);
n->composite.min_valid = 0;
assert (is_valid_node (n));
return n;
const struct operation *
expr_get_function (size_t idx)
{
- assert (idx < OP_function_cnt);
+ assert (idx < n_OP_function);
return &operations[OP_function_first + idx];
}
/* Returns the number of expression functions. */
size_t
-expr_get_function_cnt (void)
+expr_get_n_functions (void)
{
- return OP_function_cnt;
+ return n_OP_function;
}
/* Returns the name of operation OP. */
/* Returns the number of arguments for operation OP. */
int
-expr_operation_get_arg_cnt (const struct operation *op)
+expr_operation_get_n_args (const struct operation *op)
{
- return op->arg_cnt;
+ return op->n_args;
}