[m-rev.] tr_array
Julien Fischer
juliensf at csse.unimelb.edu.au
Wed Jun 6 15:01:21 AEST 2007
-------------- next part --------------
%-----------------------------------------------------------------------------%
% vim: ft=mercury ts=4 sw=4 et wm=0 tw=0
%-----------------------------------------------------------------------------%
% Copyright (C) 1993-1995, 1997, 1999, 2002, 2005-2006
% The University of Melbourne.
% This file may only be copied under the terms of the GNU Library General
% Public License - see the file COPYING.LIB in the Mercury distribution.
%-----------------------------------------------------------------------------%
%
% File: tr_array.m.
% Main authors: fjh.
% Stability: medium.
%
% This module provides backtrackable destructive update operations on arrays.
%
%-----------------------------------------------------------------------------%
:- module tr_array.
:- interface.
:- import_module array, list, maybe.
%-----------------------------------------------------------------------------%
%
% Operations that perform backtrackable destructive update
%
% tr_array.set sets the nth element of an array, and returns the
% resulting array (good opportunity for destructive update ;-).
% It is an error if the index is out of bounds.
%
:- pred tr_array.set(array(T)::array_mdi, int::in, T::in,
array(T)::array_muo) is det.
% tr_array.semidet_set sets the nth element of an array,
% and returns the resulting array.
% It fails if the index is out of bounds.
%
:- pred tr_array.semidet_set(array(T)::array_mdi, int::in, T::in,
array(T)::array_muo) is semidet.
%-----------------------------------------------------------------------------%
%
% "mui" (Mostly Unique Input) versions of standard array operations.
% It is necessary to use these ones rather than the standard array
% operations when dealing with mostly-unique values, to preserve
% "mostly_unique"-ness.
%
% tr_array.min returns the lower bound of the array.
% NOTE: in this implementation, the lower bound is always zero.
%
:- pred tr_array.min(array(_T), int).
:- mode tr_array.min(array_mui, out) is det.
:- mode tr_array.min(in, out) is det.
% tr_array.max returns the upper bound of the array.
%
:- pred tr_array.max(array(_T), int).
:- mode tr_array.max(array_mui, out) is det.
:- mode tr_array.max(in, out) is det.
% tr_array.size returns the length of the array,
% i.e. upper bound - lower bound + 1.
%
:- pred tr_array.size(array(_T), int).
:- mode tr_array.size(array_mui, out) is det.
:- mode tr_array.size(in, out) is det.
% tr_array.bounds returns the upper and lower bounds of an array.
% Note: in this implementation, the lower bound is always zero.
%
:- pred tr_array.bounds(array(_T), int, int).
:- mode tr_array.bounds(array_mui, out, out) is det.
:- mode tr_array.bounds(in, out, out) is det.
% tr_array.bounds checks whether an index is in the bounds
% of an array.
%
:- pred tr_array.in_bounds(array(_T), int).
:- mode tr_array.in_bounds(array_mui, in) is semidet.
:- mode tr_array.in_bounds(in, in) is semidet.
%-----------------------------------------------------------------------------%
% tr_array.lookup returns the Nth element of an array.
% It is an error if the index is out of bounds.
%
:- pred tr_array.lookup(array(T), int, T).
:- mode tr_array.lookup(array_mui, in, out) is det.
:- mode tr_array.lookup(in, in, out) is det.
% tr_array.semidet_lookup returns the Nth element of an array.
% It fails if the index is out of bounds.
%
:- pred tr_array.semidet_lookup(array(T), int, T).
:- mode tr_array.semidet_lookup(array_mui, in, out) is semidet.
:- mode tr_array.semidet_lookup(in, in, out) is semidet.
% tr_array.slow_set sets the nth element of an array,
% and returns the resulting array. The initial array is not
% required to be unique, so the implementation may not be able to use
% destructive update.
% It is an error if the index is out of bounds.
%
:- pred tr_array.slow_set(array(T), int, T, array(T)).
:- mode tr_array.slow_set(array_mui, in, in, array_uo) is det.
:- mode tr_array.slow_set(in, in, in, array_uo) is det.
% tr_array.semidet_slow_set sets the nth element of an array,
% and returns the resulting array. The initial array is not
% required to be unique, so the implementation may not be able to use
% destructive update.
% It fails if the index is out of bounds.
%
:- pred tr_array.semidet_slow_set(array(T), int, T, array(T)).
:- mode tr_array.semidet_slow_set(array_mui, in, in, array_uo) is semidet.
:- mode tr_array.semidet_slow_set(in, in, in, array_uo) is semidet.
% tr_array.copy(Array0, Array):
% Makes a new unique copy of an array.
%
:- pred tr_array.copy(array(T), array(T)).
:- mode tr_array.copy(array_mui, array_uo) is det.
:- mode tr_array.copy(in, array_uo) is det.
% tr_array.resize(Array0, Size, Init, Array):
% The array is expanded or shrunk to make it fit
% the new size `Size'. Any new entries are filled
% with `Init'.
%
:- pred tr_array.resize(array(T), int, T, array(T)).
:- mode tr_array.resize(array_mui, in, in, array_uo) is det.
:- mode tr_array.resize(in, in, in, array_uo) is det.
% tr_array.shrink(Array0, Size, Array):
% The array is shrunk to make it fit the new size `Size'.
% It is an error if `Size' is larger than the size of `Array0'.
%
:- pred tr_array.shrink(array(T), int, array(T)).
:- mode tr_array.shrink(array_mui, in, array_uo) is det.
:- mode tr_array.shrink(in, in, array_uo) is det.
% tr_array.to_list takes an array and returns a list containing
% the elements of the array in the same order that they
% occurred in the array.
%
:- pred tr_array.to_list(array(T), list(T)).
:- mode tr_array.to_list(array_mui, out) is det.
:- mode tr_array.to_list(in, out) is det.
% tr_array.fetch_items takes an array and a lower and upper
% index, and places those items in the array between these
% indices into a list. It is an error if either index is
% out of bounds.
%
:- pred tr_array.fetch_items(array(T), int, int, list(T)).
:- mode tr_array.fetch_items(array_mui, in, in, out) is det.
:- mode tr_array.fetch_items(in, in, in, out) is det.
% tr_array.bsearch takes an array, an element to be found
% and a comparison predicate and returns the position of
% the element in the array. Assumes the array is in sorted
% order. Fails if the element is not present. If the
% element to be found appears multiple times, the index of
% the first occurrence is returned.
%
:- pred tr_array.bsearch(array(T), T, pred(T, T, comparison_result),
maybe(int)).
:- mode tr_array.bsearch(array_mui, in, pred(in, in, out) is det, out)
is det.
:- mode tr_array.bsearch(in, in, pred(in, in, out) is det, out) is det.
%-----------------------------------------------------------------------------%
%-----------------------------------------------------------------------------%
:- implementation.
:- import_module int.
/****
lower bounds other than zero are not supported
% tr_array.resize takes an array and new lower and upper bounds.
% the array is expanded or shrunk at each end to make it fit
% the new bounds.
:- pred tr_array.resize(array(T), int, int, array(T)).
:- mode tr_array.resize(in, in, in, out) is det.
****/
%-----------------------------------------------------------------------------%
% Arrays are implemented in array.m using the C interface.
% The C type which defines the representation of arrays is
% MR_ArrayType; it is defined in runtime/mercury_library_types.h.
:- pragma foreign_decl("C", "#include ""mercury_library_types.h""").
%-----------------------------------------------------------------------------%
:- pragma foreign_proc("C",
tr_array.set(Array0::array_mdi, Index::in, Item::in, Array::array_muo),
[promise_pure, will_not_call_mercury],
"
MR_ArrayType *array = (MR_ArrayType *) Array0;
if ((MR_Unsigned) Index >= (MR_Unsigned) array->size) {
MR_fatal_error(""tr_array.set: array index out of bounds"");
}
MR_trail_current_value(&array->elements[Index]);
array->elements[Index] = Item; /* destructive update! */
Array = Array0;
").
tr_array.semidet_set(Array0, Index, Item, Array) :-
tr_array.in_bounds(Array0, Index),
tr_array.set(Array0, Index, Item, Array).
%-----------------------------------------------------------------------------%
%-----------------------------------------------------------------------------%
:- pragma foreign_proc("C",
tr_array.min(Array::array_mui, Min::out),
[promise_pure, will_not_call_mercury],
"
/* Array not used */
Min = 0;
").
:- pragma foreign_proc("C",
tr_array.min(Array::in, Min::out),
[promise_pure, will_not_call_mercury],
"
/* Array not used */
Min = 0;
").
:- pragma foreign_proc("C",
tr_array.max(Array::array_mui, Max::out),
[promise_pure, will_not_call_mercury],
"
Max = ((MR_ArrayType *)Array)->size - 1;
").
:- pragma foreign_proc("C",
tr_array.max(Array::in, Max::out),
[promise_pure, will_not_call_mercury],
"
Max = ((MR_ArrayType *)Array)->size - 1;
").
tr_array.bounds(Array, Min, Max) :-
tr_array.min(Array, Min),
tr_array.max(Array, Max).
%-----------------------------------------------------------------------------%
:- pragma foreign_proc("C",
tr_array.size(Array::array_mui, Max::out),
[promise_pure, will_not_call_mercury],
"
Max = ((MR_ArrayType *)Array)->size;
").
:- pragma foreign_proc("C",
tr_array.size(Array::in, Max::out),
[promise_pure, will_not_call_mercury],
"
Max = ((MR_ArrayType *)Array)->size;
").
%-----------------------------------------------------------------------------%
tr_array.in_bounds(Array, Index) :-
tr_array.bounds(Array, Min, Max),
Min =< Index, Index =< Max.
tr_array.semidet_lookup(Array, Index, Item) :-
tr_array.in_bounds(Array, Index),
tr_array.lookup(Array, Index, Item).
tr_array.semidet_slow_set(Array0, Index, Item, Array) :-
tr_array.in_bounds(Array0, Index),
tr_array.slow_set(Array0, Index, Item, Array).
tr_array.slow_set(Array0, Index, Item, Array) :-
tr_array.copy(Array0, Array1),
array.set(Array1, Index, Item, Array).
%-----------------------------------------------------------------------------%
:- pragma foreign_proc("C",
tr_array.lookup(Array::array_mui, Index::in, Item::out),
[promise_pure, will_not_call_mercury],
"
MR_ArrayType *array = (MR_ArrayType *) Array;
if ((MR_Unsigned) Index >= (MR_Unsigned) array->size) {
MR_fatal_error(""tr_array.lookup: array index out of bounds"");
}
Item = array->elements[Index];
").
:- pragma foreign_proc("C",
tr_array.lookup(Array::in, Index::in, Item::out),
[promise_pure, will_not_call_mercury],
"
MR_ArrayType *array = (MR_ArrayType *) Array;
if ((MR_Unsigned) Index >= (MR_Unsigned) array->size) {
MR_fatal_error(""tr_array.lookup: array index out of bounds"");
}
Item = array->elements[Index];
").
%-----------------------------------------------------------------------------%
:- pragma foreign_decl("C", "
void ML_tr_resize_array(MR_ArrayType *array, const MR_ArrayType *old_array,
MR_Integer array_size, MR_Word item);
").
:- pragma foreign_code("C", "
void
ML_tr_resize_array(MR_ArrayType *array, const MR_ArrayType *old_array,
MR_Integer array_size, MR_Word item)
{
MR_Integer i;
MR_Integer elements_to_copy;
elements_to_copy = old_array->size;
if (elements_to_copy > array_size) {
elements_to_copy = array_size;
}
array->size = array_size;
for (i = 0; i < elements_to_copy; i++) {
array->elements[i] = old_array->elements[i];
}
for (; i < array_size; i++) {
array->elements[i] = item;
}
/*
** since the mode on the old array is `array_mdi', it is NOT safe to
** deallocate the storage for it
*/
}
").
:- pragma foreign_proc("C",
tr_array.resize(Array0::array_mui, Size::in, Item::in,
Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, Size + 1, MR_PROC_LABEL, ""array:array/1"");
ML_tr_resize_array((MR_ArrayType *)Array, (const MR_ArrayType *)Array0,
Size, Item);
").
:- pragma foreign_proc("C",
tr_array.resize(Array0::in, Size::in, Item::in, Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, Size + 1, MR_PROC_LABEL, ""array:array/1"");
ML_tr_resize_array((MR_ArrayType *)Array, (const MR_ArrayType *)Array0,
Size, Item);
").
%-----------------------------------------------------------------------------%
:- pragma foreign_decl("C", "
void ML_tr_shrink_array(MR_ArrayType *, const MR_ArrayType *old_array,
MR_Integer array_size);
").
:- pragma foreign_code("C", "
void
ML_tr_shrink_array(MR_ArrayType *array, const MR_ArrayType *old_array,
MR_Integer array_size)
{
MR_Integer i;
MR_Integer old_array_size;
old_array_size = old_array->size;
if (old_array_size < array_size) {
MR_fatal_error(
""tr_array.shrink: can't shrink to a larger size"");
}
array->size = array_size;
for (i = 0; i < array_size; i++) {
array->elements[i] = old_array->elements[i];
}
/*
** since the mode on the old array is `array_mdi', it is NOT safe to
** deallocate the storage for it
*/
}
").
:- pragma foreign_proc("C",
tr_array.shrink(Array0::array_mui, Size::in, Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, Size + 1, MR_PROC_LABEL, ""array:array/1"");
ML_tr_shrink_array((MR_ArrayType *) Array,
(const MR_ArrayType *) Array0, Size);
").
:- pragma foreign_proc("C",
tr_array.shrink(Array0::in, Size::in, Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, Size + 1, MR_PROC_LABEL, ""array:array/1"");
ML_tr_shrink_array((MR_ArrayType *) Array,
(const MR_ArrayType *) Array0, Size);
").
%-----------------------------------------------------------------------------%
:- pragma foreign_decl("C", "
void ML_tr_copy_array(MR_ArrayType *array, const MR_ArrayType *old_array);
").
:- pragma foreign_code("C", "
void
ML_tr_copy_array(MR_ArrayType *array, const MR_ArrayType *old_array)
{
/*
** Any changes to this function will probably also require
** changes to deepcopy() in runtime/deep_copy.c.
*/
MR_Integer i;
MR_Integer array_size;
array_size = old_array->size;
array->size = array_size;
for (i = 0; i < array_size; i++) {
array->elements[i] = old_array->elements[i];
}
}
").
:- pragma foreign_proc("C",
tr_array.copy(Array0::array_mui, Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, ((const MR_ArrayType *)Array0)->size + 1,
MR_PROC_LABEL, ""array:array/1"");
ML_tr_copy_array((MR_ArrayType *)Array, (const MR_ArrayType *)Array0);
").
:- pragma foreign_proc("C",
tr_array.copy(Array0::in, Array::array_uo),
[promise_pure, will_not_call_mercury],
"
MR_incr_hp_msg(Array, ((const MR_ArrayType *)Array0)->size + 1,
MR_PROC_LABEL, ""array:array/1"");
ML_tr_copy_array((MR_ArrayType *)Array, (const MR_ArrayType *)Array0);
").
%-----------------------------------------------------------------------------%
tr_array.to_list(Array, List) :-
tr_array.bounds(Array, Low, High),
tr_array.fetch_items(Array, Low, High, List).
%-----------------------------------------------------------------------------%
tr_array.fetch_items(Array, Low, High, List) :-
(
Low > High
->
List = []
;
Low1 = Low + 1,
tr_array.fetch_items(Array, Low1, High, List0),
tr_array.lookup(Array, Low, Item),
List = [Item | List0]
).
%-----------------------------------------------------------------------------%
tr_array.bsearch(A, El, Compare, Result) :-
tr_array.bounds(A, Lo, Hi),
tr_array.bsearch_2(A, Lo, Hi, El, Compare, Result).
:- pred tr_array.bsearch_2(array(T), int, int, T,
pred(T, T, comparison_result), maybe(int)).
:- mode tr_array.bsearch_2(in, in, in, in, pred(in, in, out) is det,
out) is det.
tr_array.bsearch_2(Array, Lo, Hi, El, Compare, Result) :-
Width = Hi - Lo,
% If Width < 0, there is no range left.
( Width < 0 ->
Result = no
;
% If Width == 0, we may just have found our element.
% Do a Compare to check.
( Width = 0 ->
tr_array.lookup(Array, Lo, X),
( Compare(El, X, (=)) ->
Result = yes(Lo)
;
Result = no
)
;
% Otherwise find the middle element of the range
% and check against that.
Mid = (Lo + Hi) >> 1, % `>> 1' is hand-optimized `div 2'.
tr_array.lookup(Array, Mid, XMid),
Compare(XMid, El, Comp),
(
Comp = (<),
Mid1 = Mid + 1,
tr_array.bsearch_2(Array, Mid1, Hi, El, Compare, Result)
;
Comp = (=),
tr_array.bsearch_2(Array, Lo, Mid, El, Compare, Result)
;
Comp = (>),
Mid1 = Mid - 1,
tr_array.bsearch_2(Array, Lo, Mid1, El, Compare, Result)
)
)
).
%-----------------------------------------------------------------------------%
:- end_module tr_array.
%-----------------------------------------------------------------------------%
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