[deliverable/binutils-gdb.git] / gdb / ada-operator.def

/* Ada language operator definitions for GDB, the GNU debugger.

   Copyright (C) 1992-2013 Free Software Foundation, Inc.

   This file is part of GDB.

   This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 3 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>.  */

/* X IN A'RANGE(N).  N is an immediate operand, surrounded by 
   BINOP_IN_BOUNDS before and after.  A is an array, X an index 
   value.  Evaluates to true iff X is within range of the Nth
   dimension (1-based) of A.  (A multi-dimensional array
   type is represented as array of array of ...) */
OP (BINOP_IN_BOUNDS)

/* X IN L .. U.  True iff L <= X <= U.  */
OP (TERNOP_IN_RANGE)

/* Ada attributes ('Foo). */
OP (OP_ATR_FIRST)
OP (OP_ATR_LAST)
OP (OP_ATR_LENGTH)
OP (OP_ATR_IMAGE)
OP (OP_ATR_MAX)
OP (OP_ATR_MIN)
OP (OP_ATR_MODULUS)
OP (OP_ATR_POS)
OP (OP_ATR_SIZE)
OP (OP_ATR_TAG)
OP (OP_ATR_VAL)

/* Ada type qualification.  It is encoded as for UNOP_CAST, above, 
   and denotes the TYPE'(EXPR) construct. */
OP (UNOP_QUAL)

/* X IN TYPE.  The `TYPE' argument is immediate, with 
   UNOP_IN_RANGE before and after it. True iff X is a member of 
   type TYPE (typically a subrange). */
OP (UNOP_IN_RANGE)

/* An aggregate.   A single immediate operand, N>0, gives
   the number of component specifications that follow.  The
   immediate operand is followed by a second OP_AGGREGATE.  
   Next come N component specifications.  A component
   specification is either an OP_OTHERS (others=>...), an
   OP_CHOICES (for named associations), or other expression (for
   positional aggregates only).  Aggregates currently
   occur only as the right sides of assignments. */
OP (OP_AGGREGATE)

/* An others clause.  Followed by a single expression. */
OP (OP_OTHERS)

/* An aggregate component association.  A single immediate operand, N, 
   gives the number of choices that follow.  This is followed by a second
   OP_CHOICES operator.  Next come N operands, each of which is an
   expression, an OP_DISCRETE_RANGE, or an OP_NAME---the latter 
   for a simple name that must be a record component name and does 
   not correspond to a single existing symbol.  After the N choice 
   indicators comes an expression giving the value.

   In an aggregate such as (X => E1, ...), where X is a simple
   name, X could syntactically be either a component_selector_name 
   or an expression used as a discrete_choice, depending on the
   aggregate's type context.  Since this is not known at parsing
   time, we don't attempt to disambiguate X if it has multiple
   definitions, but instead supply an OP_NAME.  If X has a single
   definition, we represent it with an OP_VAR_VALUE, even though
   it may turn out to be within a record aggregate.  Aggregate 
   evaluation can use either OP_NAMEs or OP_VAR_VALUEs to get a
   record field name, and can evaluate OP_VAR_VALUE normally to
   get its value as an expression.  Unfortunately, we lose out in
   cases where X has multiple meanings and is part of an array
   aggregate.  I hope these are not common enough to annoy users,
   who can work around the problem in any case by putting
   parentheses around X. */
OP (OP_CHOICES)

/* A positional aggregate component association.  The operator is 
   followed by a single integer indicating the position in the 
   aggregate (0-based), followed by a second OP_POSITIONAL.  Next 
   follows a single expression giving the component value.  */
OP (OP_POSITIONAL)

/* A range of values.  Followed by two expressions giving the
   upper and lower bounds of the range. */
OP (OP_DISCRETE_RANGE)
Commit	Line	Data
56c12414 JK	1	/* Ada language operator definitions for GDB, the GNU debugger.
56c12414 JK	2
28e7fd62	3	Copyright (C) 1992-2013 Free Software Foundation, Inc.
56c12414 JK	4
	5	This file is part of GDB.
	6
	7	This program is free software; you can redistribute it and/or modify
	8	it under the terms of the GNU General Public License as published by
	9	the Free Software Foundation; either version 3 of the License, or
	10	(at your option) any later version.
	11
	12	This program is distributed in the hope that it will be useful,
	13	but WITHOUT ANY WARRANTY; without even the implied warranty of
	14	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	15	GNU General Public License for more details.
	16
	17	You should have received a copy of the GNU General Public License
	18	along with this program. If not, see <http://www.gnu.org/licenses/>. */
	19
	20	/* X IN A'RANGE(N). N is an immediate operand, surrounded by
	21	BINOP_IN_BOUNDS before and after. A is an array, X an index
	22	value. Evaluates to true iff X is within range of the Nth
	23	dimension (1-based) of A. (A multi-dimensional array
	24	type is represented as array of array of ...) */
	25	OP (BINOP_IN_BOUNDS)
	26
	27	/* X IN L .. U. True iff L <= X <= U. */
	28	OP (TERNOP_IN_RANGE)
	29
	30	/* Ada attributes ('Foo). */
	31	OP (OP_ATR_FIRST)
	32	OP (OP_ATR_LAST)
	33	OP (OP_ATR_LENGTH)
	34	OP (OP_ATR_IMAGE)
	35	OP (OP_ATR_MAX)
	36	OP (OP_ATR_MIN)
	37	OP (OP_ATR_MODULUS)
	38	OP (OP_ATR_POS)
	39	OP (OP_ATR_SIZE)
	40	OP (OP_ATR_TAG)
	41	OP (OP_ATR_VAL)
	42
	43	/* Ada type qualification. It is encoded as for UNOP_CAST, above,
	44	and denotes the TYPE'(EXPR) construct. */
	45	OP (UNOP_QUAL)
	46
	47	/* X IN TYPE. The `TYPE' argument is immediate, with
	48	UNOP_IN_RANGE before and after it. True iff X is a member of
	49	type TYPE (typically a subrange). */
	50	OP (UNOP_IN_RANGE)
	51
	52	/* An aggregate. A single immediate operand, N>0, gives
	53	the number of component specifications that follow. The
	54	immediate operand is followed by a second OP_AGGREGATE.
	55	Next come N component specifications. A component
	56	specification is either an OP_OTHERS (others=>...), an
	57	OP_CHOICES (for named associations), or other expression (for
	58	positional aggregates only). Aggregates currently
	59	occur only as the right sides of assignments. */
	60	OP (OP_AGGREGATE)
	61
	62	/* An others clause. Followed by a single expression. */
	63	OP (OP_OTHERS)
	64
	65	/* An aggregate component association. A single immediate operand, N,
	66	gives the number of choices that follow. This is followed by a second
	67	OP_CHOICES operator. Next come N operands, each of which is an
68	expression, an OP_DISCRETE_RANGE, or an OP_NAME---the latter
69	for a simple name that must be a record component name and does
70	not correspond to a single existing symbol. After the N choice
71	indicators comes an expression giving the value.
72
73	In an aggregate such as (X => E1, ...), where X is a simple
74	name, X could syntactically be either a component_selector_name
75	or an expression used as a discrete_choice, depending on the
76	aggregate's type context. Since this is not known at parsing
77	time, we don't attempt to disambiguate X if it has multiple
78	definitions, but instead supply an OP_NAME. If X has a single
79	definition, we represent it with an OP_VAR_VALUE, even though
80	it may turn out to be within a record aggregate. Aggregate
81	evaluation can use either OP_NAMEs or OP_VAR_VALUEs to get a
82	record field name, and can evaluate OP_VAR_VALUE normally to
83	get its value as an expression. Unfortunately, we lose out in
84	cases where X has multiple meanings and is part of an array
85	aggregate. I hope these are not common enough to annoy users,
86	who can work around the problem in any case by putting
87	parentheses around X. */
88	OP (OP_CHOICES)
89
90	/* A positional aggregate component association. The operator is
91	followed by a single integer indicating the position in the
92	aggregate (0-based), followed by a second OP_POSITIONAL. Next
93	follows a single expression giving the component value. */
94	OP (OP_POSITIONAL)
95
96	/* A range of values. Followed by two expressions giving the
97	upper and lower bounds of the range. */
98	OP (OP_DISCRETE_RANGE)