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isl_flow.c
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isl_flow.c
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/*
* Copyright 2005-2007 Universiteit Leiden
* Copyright 2008-2009 Katholieke Universiteit Leuven
* Copyright 2010 INRIA Saclay
* Copyright 2012 Universiteit Leiden
* Copyright 2014 Ecole Normale Superieure
*
* Use of this software is governed by the MIT license
*
* Written by Sven Verdoolaege, Leiden Institute of Advanced Computer Science,
* Universiteit Leiden, Niels Bohrweg 1, 2333 CA Leiden, The Netherlands
* and K.U.Leuven, Departement Computerwetenschappen, Celestijnenlaan 200A,
* B-3001 Leuven, Belgium
* and INRIA Saclay - Ile-de-France, Parc Club Orsay Universite,
* ZAC des vignes, 4 rue Jacques Monod, 91893 Orsay, France
* and Ecole Normale Superieure, 45 rue d'Ulm, 75230 Paris, France
*/
#include <isl/val.h>
#include <isl/space.h>
#include <isl/set.h>
#include <isl/map.h>
#include <isl/union_set.h>
#include <isl/union_map.h>
#include <isl/flow.h>
#include <isl/schedule_node.h>
#include <isl_sort.h>
#include <isl/stream.h>
enum isl_restriction_type {
isl_restriction_type_empty,
isl_restriction_type_none,
isl_restriction_type_input,
isl_restriction_type_output
};
struct isl_restriction {
enum isl_restriction_type type;
isl_set *source;
isl_set *sink;
};
/* Create a restriction of the given type.
*/
static __isl_give isl_restriction *isl_restriction_alloc(
__isl_take isl_map *source_map, enum isl_restriction_type type)
{
isl_ctx *ctx;
isl_restriction *restr;
if (!source_map)
return NULL;
ctx = isl_map_get_ctx(source_map);
restr = isl_calloc_type(ctx, struct isl_restriction);
if (!restr)
goto error;
restr->type = type;
isl_map_free(source_map);
return restr;
error:
isl_map_free(source_map);
return NULL;
}
/* Create a restriction that doesn't restrict anything.
*/
__isl_give isl_restriction *isl_restriction_none(__isl_take isl_map *source_map)
{
return isl_restriction_alloc(source_map, isl_restriction_type_none);
}
/* Create a restriction that removes everything.
*/
__isl_give isl_restriction *isl_restriction_empty(
__isl_take isl_map *source_map)
{
return isl_restriction_alloc(source_map, isl_restriction_type_empty);
}
/* Create a restriction on the input of the maximization problem
* based on the given source and sink restrictions.
*/
__isl_give isl_restriction *isl_restriction_input(
__isl_take isl_set *source_restr, __isl_take isl_set *sink_restr)
{
isl_ctx *ctx;
isl_restriction *restr;
if (!source_restr || !sink_restr)
goto error;
ctx = isl_set_get_ctx(source_restr);
restr = isl_calloc_type(ctx, struct isl_restriction);
if (!restr)
goto error;
restr->type = isl_restriction_type_input;
restr->source = source_restr;
restr->sink = sink_restr;
return restr;
error:
isl_set_free(source_restr);
isl_set_free(sink_restr);
return NULL;
}
/* Create a restriction on the output of the maximization problem
* based on the given source restriction.
*/
__isl_give isl_restriction *isl_restriction_output(
__isl_take isl_set *source_restr)
{
isl_ctx *ctx;
isl_restriction *restr;
if (!source_restr)
return NULL;
ctx = isl_set_get_ctx(source_restr);
restr = isl_calloc_type(ctx, struct isl_restriction);
if (!restr)
goto error;
restr->type = isl_restriction_type_output;
restr->source = source_restr;
return restr;
error:
isl_set_free(source_restr);
return NULL;
}
__isl_null isl_restriction *isl_restriction_free(
__isl_take isl_restriction *restr)
{
if (!restr)
return NULL;
isl_set_free(restr->source);
isl_set_free(restr->sink);
free(restr);
return NULL;
}
isl_ctx *isl_restriction_get_ctx(__isl_keep isl_restriction *restr)
{
return restr ? isl_set_get_ctx(restr->source) : NULL;
}
/* A private structure to keep track of a mapping together with
* a user-specified identifier and a boolean indicating whether
* the map represents a must or may access/dependence.
*/
struct isl_labeled_map {
struct isl_map *map;
void *data;
int must;
};
typedef isl_bool (*isl_access_coscheduled)(void *first, void *second);
/* A structure containing the input for dependence analysis:
* - a sink
* - n_must + n_may (<= max_source) sources
* - a function for determining the relative order of sources and sink
* - an optional function "coscheduled" for determining whether sources
* may be coscheduled. If "coscheduled" is NULL, then the sources
* are assumed not to be coscheduled.
* The must sources are placed before the may sources.
*
* domain_map is an auxiliary map that maps the sink access relation
* to the domain of this access relation.
* This field is only needed when restrict_fn is set and
* the field itself is set by isl_access_info_compute_flow.
*
* restrict_fn is a callback that (if not NULL) will be called
* right before any lexicographical maximization.
*/
struct isl_access_info {
isl_map *domain_map;
struct isl_labeled_map sink;
isl_access_level_before level_before;
isl_access_coscheduled coscheduled;
isl_access_restrict restrict_fn;
void *restrict_user;
int max_source;
int n_must;
int n_may;
struct isl_labeled_map source[1];
};
/* A structure containing the output of dependence analysis:
* - n_source dependences
* - a wrapped subset of the sink for which definitely no source could be found
* - a wrapped subset of the sink for which possibly no source could be found
*/
struct isl_flow {
isl_set *must_no_source;
isl_set *may_no_source;
int n_source;
struct isl_labeled_map *dep;
};
/* Construct an isl_access_info structure and fill it up with
* the given data. The number of sources is set to 0.
*/
__isl_give isl_access_info *isl_access_info_alloc(__isl_take isl_map *sink,
void *sink_user, isl_access_level_before fn, int max_source)
{
isl_ctx *ctx;
struct isl_access_info *acc;
if (!sink)
return NULL;
ctx = isl_map_get_ctx(sink);
isl_assert(ctx, max_source >= 0, goto error);
acc = isl_calloc(ctx, struct isl_access_info,
sizeof(struct isl_access_info) +
(max_source - 1) * sizeof(struct isl_labeled_map));
if (!acc)
goto error;
acc->sink.map = sink;
acc->sink.data = sink_user;
acc->level_before = fn;
acc->max_source = max_source;
acc->n_must = 0;
acc->n_may = 0;
return acc;
error:
isl_map_free(sink);
return NULL;
}
/* Free the given isl_access_info structure.
*/
__isl_null isl_access_info *isl_access_info_free(
__isl_take isl_access_info *acc)
{
int i;
if (!acc)
return NULL;
isl_map_free(acc->domain_map);
isl_map_free(acc->sink.map);
for (i = 0; i < acc->n_must + acc->n_may; ++i)
isl_map_free(acc->source[i].map);
free(acc);
return NULL;
}
isl_ctx *isl_access_info_get_ctx(__isl_keep isl_access_info *acc)
{
return acc ? isl_map_get_ctx(acc->sink.map) : NULL;
}
__isl_give isl_access_info *isl_access_info_set_restrict(
__isl_take isl_access_info *acc, isl_access_restrict fn, void *user)
{
if (!acc)
return NULL;
acc->restrict_fn = fn;
acc->restrict_user = user;
return acc;
}
/* Add another source to an isl_access_info structure, making
* sure the "must" sources are placed before the "may" sources.
* This function may be called at most max_source times on a
* given isl_access_info structure, with max_source as specified
* in the call to isl_access_info_alloc that constructed the structure.
*/
__isl_give isl_access_info *isl_access_info_add_source(
__isl_take isl_access_info *acc, __isl_take isl_map *source,
int must, void *source_user)
{
isl_ctx *ctx;
if (!acc)
goto error;
ctx = isl_map_get_ctx(acc->sink.map);
isl_assert(ctx, acc->n_must + acc->n_may < acc->max_source, goto error);
if (must) {
if (acc->n_may)
acc->source[acc->n_must + acc->n_may] =
acc->source[acc->n_must];
acc->source[acc->n_must].map = source;
acc->source[acc->n_must].data = source_user;
acc->source[acc->n_must].must = 1;
acc->n_must++;
} else {
acc->source[acc->n_must + acc->n_may].map = source;
acc->source[acc->n_must + acc->n_may].data = source_user;
acc->source[acc->n_must + acc->n_may].must = 0;
acc->n_may++;
}
return acc;
error:
isl_map_free(source);
isl_access_info_free(acc);
return NULL;
}
/* A helper struct carrying the isl_access_info and an error condition.
*/
struct access_sort_info {
isl_access_info *access_info;
int error;
};
/* Return -n, 0 or n (with n a positive value), depending on whether
* the source access identified by p1 should be sorted before, together
* or after that identified by p2.
*
* If p1 appears before p2, then it should be sorted first.
* For more generic initial schedules, it is possible that neither
* p1 nor p2 appears before the other, or at least not in any obvious way.
* We therefore also check if p2 appears before p1, in which case p2
* should be sorted first.
* If not, we try to order the two statements based on the description
* of the iteration domains. This results in an arbitrary, but fairly
* stable ordering.
*
* In case of an error, sort_info.error is set to true and all elements are
* reported to be equal.
*/
static int access_sort_cmp(const void *p1, const void *p2, void *user)
{
struct access_sort_info *sort_info = user;
isl_access_info *acc = sort_info->access_info;
if (sort_info->error)
return 0;
const struct isl_labeled_map *i1, *i2;
int level1, level2;
uint32_t h1, h2;
i1 = (const struct isl_labeled_map *) p1;
i2 = (const struct isl_labeled_map *) p2;
level1 = acc->level_before(i1->data, i2->data);
if (level1 < 0)
goto error;
if (level1 % 2)
return -1;
level2 = acc->level_before(i2->data, i1->data);
if (level2 < 0)
goto error;
if (level2 % 2)
return 1;
h1 = isl_map_get_hash(i1->map);
h2 = isl_map_get_hash(i2->map);
return h1 > h2 ? 1 : h1 < h2 ? -1 : 0;
error:
sort_info->error = 1;
return 0;
}
/* Sort the must source accesses in their textual order.
*/
static __isl_give isl_access_info *isl_access_info_sort_sources(
__isl_take isl_access_info *acc)
{
struct access_sort_info sort_info;
sort_info.access_info = acc;
sort_info.error = 0;
if (!acc)
return NULL;
if (acc->n_must <= 1)
return acc;
if (isl_sort(acc->source, acc->n_must, sizeof(struct isl_labeled_map),
access_sort_cmp, &sort_info) < 0)
return isl_access_info_free(acc);
if (sort_info.error)
return isl_access_info_free(acc);
return acc;
}
/* Align the parameters of the two spaces if needed and then call
* isl_space_join.
*/
static __isl_give isl_space *space_align_and_join(__isl_take isl_space *left,
__isl_take isl_space *right)
{
isl_bool equal_params;
equal_params = isl_space_has_equal_params(left, right);
if (equal_params < 0)
goto error;
if (equal_params)
return isl_space_join(left, right);
left = isl_space_align_params(left, isl_space_copy(right));
right = isl_space_align_params(right, isl_space_copy(left));
return isl_space_join(left, right);
error:
isl_space_free(left);
isl_space_free(right);
return NULL;
}
/* Initialize an empty isl_flow structure corresponding to a given
* isl_access_info structure.
* For each must access, two dependences are created (initialized
* to the empty relation), one for the resulting must dependences
* and one for the resulting may dependences. May accesses can
* only lead to may dependences, so only one dependence is created
* for each of them.
* This function is private as isl_flow structures are only supposed
* to be created by isl_access_info_compute_flow.
*/
static __isl_give isl_flow *isl_flow_alloc(__isl_keep isl_access_info *acc)
{
int i, n;
struct isl_ctx *ctx;
struct isl_flow *dep;
if (!acc)
return NULL;
ctx = isl_map_get_ctx(acc->sink.map);
dep = isl_calloc_type(ctx, struct isl_flow);
if (!dep)
return NULL;
n = 2 * acc->n_must + acc->n_may;
dep->dep = isl_calloc_array(ctx, struct isl_labeled_map, n);
if (n && !dep->dep)
goto error;
dep->n_source = n;
for (i = 0; i < acc->n_must; ++i) {
isl_space *space;
space = space_align_and_join(
isl_map_get_space(acc->source[i].map),
isl_space_reverse(isl_map_get_space(acc->sink.map)));
dep->dep[2 * i].map = isl_map_empty(space);
dep->dep[2 * i + 1].map = isl_map_copy(dep->dep[2 * i].map);
dep->dep[2 * i].data = acc->source[i].data;
dep->dep[2 * i + 1].data = acc->source[i].data;
dep->dep[2 * i].must = 1;
dep->dep[2 * i + 1].must = 0;
if (!dep->dep[2 * i].map || !dep->dep[2 * i + 1].map)
goto error;
}
for (i = acc->n_must; i < acc->n_must + acc->n_may; ++i) {
isl_space *space;
space = space_align_and_join(
isl_map_get_space(acc->source[i].map),
isl_space_reverse(isl_map_get_space(acc->sink.map)));
dep->dep[acc->n_must + i].map = isl_map_empty(space);
dep->dep[acc->n_must + i].data = acc->source[i].data;
dep->dep[acc->n_must + i].must = 0;
if (!dep->dep[acc->n_must + i].map)
goto error;
}
return dep;
error:
isl_flow_free(dep);
return NULL;
}
/* Iterate over all sources and for each resulting flow dependence
* that is not empty, call the user specfied function.
* The second argument in this function call identifies the source,
* while the third argument correspond to the final argument of
* the isl_flow_foreach call.
*/
isl_stat isl_flow_foreach(__isl_keep isl_flow *deps,
isl_stat (*fn)(__isl_take isl_map *dep, int must, void *dep_user,
void *user),
void *user)
{
int i;
if (!deps)
return isl_stat_error;
for (i = 0; i < deps->n_source; ++i) {
if (isl_map_plain_is_empty(deps->dep[i].map))
continue;
if (fn(isl_map_copy(deps->dep[i].map), deps->dep[i].must,
deps->dep[i].data, user) < 0)
return isl_stat_error;
}
return isl_stat_ok;
}
/* Return a copy of the subset of the sink for which no source could be found.
*/
__isl_give isl_map *isl_flow_get_no_source(__isl_keep isl_flow *deps, int must)
{
if (!deps)
return NULL;
if (must)
return isl_set_unwrap(isl_set_copy(deps->must_no_source));
else
return isl_set_unwrap(isl_set_copy(deps->may_no_source));
}
__isl_null isl_flow *isl_flow_free(__isl_take isl_flow *deps)
{
int i;
if (!deps)
return NULL;
isl_set_free(deps->must_no_source);
isl_set_free(deps->may_no_source);
if (deps->dep) {
for (i = 0; i < deps->n_source; ++i)
isl_map_free(deps->dep[i].map);
free(deps->dep);
}
free(deps);
return NULL;
}
isl_ctx *isl_flow_get_ctx(__isl_keep isl_flow *deps)
{
return deps ? isl_set_get_ctx(deps->must_no_source) : NULL;
}
/* Return a map that enforces that the domain iteration occurs after
* the range iteration at the given level.
* If level is odd, then the domain iteration should occur after
* the target iteration in their shared level/2 outermost loops.
* In this case we simply need to enforce that these outermost
* loop iterations are the same.
* If level is even, then the loop iterator of the domain should
* be greater than the loop iterator of the range at the last
* of the level/2 shared loops, i.e., loop level/2 - 1.
*/
static __isl_give isl_map *after_at_level(__isl_take isl_space *space,
int level)
{
struct isl_basic_map *bmap;
if (level % 2)
bmap = isl_basic_map_equal(space, level/2);
else
bmap = isl_basic_map_more_at(space, level/2 - 1);
return isl_map_from_basic_map(bmap);
}
/* Compute the partial lexicographic maximum of "dep" on domain "sink",
* but first check if the user has set acc->restrict_fn and if so
* update either the input or the output of the maximization problem
* with respect to the resulting restriction.
*
* Since the user expects a mapping from sink iterations to source iterations,
* whereas the domain of "dep" is a wrapped map, mapping sink iterations
* to accessed array elements, we first need to project out the accessed
* sink array elements by applying acc->domain_map.
* Similarly, the sink restriction specified by the user needs to be
* converted back to the wrapped map.
*/
static __isl_give isl_map *restricted_partial_lexmax(
__isl_keep isl_access_info *acc, __isl_take isl_map *dep,
int source, __isl_take isl_set *sink, __isl_give isl_set **empty)
{
isl_map *source_map;
isl_restriction *restr;
isl_set *sink_domain;
isl_set *sink_restr;
isl_map *res;
if (!acc->restrict_fn)
return isl_map_partial_lexmax(dep, sink, empty);
source_map = isl_map_copy(dep);
source_map = isl_map_apply_domain(source_map,
isl_map_copy(acc->domain_map));
sink_domain = isl_set_copy(sink);
sink_domain = isl_set_apply(sink_domain, isl_map_copy(acc->domain_map));
restr = acc->restrict_fn(source_map, sink_domain,
acc->source[source].data, acc->restrict_user);
isl_set_free(sink_domain);
isl_map_free(source_map);
if (!restr)
goto error;
if (restr->type == isl_restriction_type_input) {
dep = isl_map_intersect_range(dep, isl_set_copy(restr->source));
sink_restr = isl_set_copy(restr->sink);
sink_restr = isl_set_apply(sink_restr,
isl_map_reverse(isl_map_copy(acc->domain_map)));
sink = isl_set_intersect(sink, sink_restr);
} else if (restr->type == isl_restriction_type_empty) {
isl_space *space = isl_map_get_space(dep);
isl_map_free(dep);
dep = isl_map_empty(space);
}
res = isl_map_partial_lexmax(dep, sink, empty);
if (restr->type == isl_restriction_type_output)
res = isl_map_intersect_range(res, isl_set_copy(restr->source));
isl_restriction_free(restr);
return res;
error:
isl_map_free(dep);
isl_set_free(sink);
*empty = NULL;
return NULL;
}
/* Compute the last iteration of must source j that precedes the sink
* at the given level for sink iterations in set_C.
* The subset of set_C for which no such iteration can be found is returned
* in *empty.
*/
static struct isl_map *last_source(struct isl_access_info *acc,
struct isl_set *set_C,
int j, int level, struct isl_set **empty)
{
struct isl_map *read_map;
struct isl_map *write_map;
struct isl_map *dep_map;
struct isl_map *after;
struct isl_map *result;
read_map = isl_map_copy(acc->sink.map);
write_map = isl_map_copy(acc->source[j].map);
write_map = isl_map_reverse(write_map);
dep_map = isl_map_apply_range(read_map, write_map);
after = after_at_level(isl_map_get_space(dep_map), level);
dep_map = isl_map_intersect(dep_map, after);
result = restricted_partial_lexmax(acc, dep_map, j, set_C, empty);
result = isl_map_reverse(result);
return result;
}
/* For a given mapping between iterations of must source j and iterations
* of the sink, compute the last iteration of must source k preceding
* the sink at level before_level for any of the sink iterations,
* but following the corresponding iteration of must source j at level
* after_level.
*/
static struct isl_map *last_later_source(struct isl_access_info *acc,
struct isl_map *old_map,
int j, int before_level,
int k, int after_level,
struct isl_set **empty)
{
isl_space *space;
struct isl_set *set_C;
struct isl_map *read_map;
struct isl_map *write_map;
struct isl_map *dep_map;
struct isl_map *after_write;
struct isl_map *before_read;
struct isl_map *result;
set_C = isl_map_range(isl_map_copy(old_map));
read_map = isl_map_copy(acc->sink.map);
write_map = isl_map_copy(acc->source[k].map);
write_map = isl_map_reverse(write_map);
dep_map = isl_map_apply_range(read_map, write_map);
space = space_align_and_join(isl_map_get_space(acc->source[k].map),
isl_space_reverse(isl_map_get_space(acc->source[j].map)));
after_write = after_at_level(space, after_level);
after_write = isl_map_apply_range(after_write, old_map);
after_write = isl_map_reverse(after_write);
dep_map = isl_map_intersect(dep_map, after_write);
before_read = after_at_level(isl_map_get_space(dep_map), before_level);
dep_map = isl_map_intersect(dep_map, before_read);
result = restricted_partial_lexmax(acc, dep_map, k, set_C, empty);
result = isl_map_reverse(result);
return result;
}
/* Given a shared_level between two accesses, return 1 if the
* the first can precede the second at the requested target_level.
* If the target level is odd, i.e., refers to a statement level
* dimension, then first needs to precede second at the requested
* level, i.e., shared_level must be equal to target_level.
* If the target level is odd, then the two loops should share
* at least the requested number of outer loops.
*/
static int can_precede_at_level(int shared_level, int target_level)
{
if (shared_level < target_level)
return 0;
if ((target_level % 2) && shared_level > target_level)
return 0;
return 1;
}
/* Given a possible flow dependence temp_rel[j] between source j and the sink
* at level sink_level, remove those elements for which
* there is an iteration of another source k < j that is closer to the sink.
* The flow dependences temp_rel[k] are updated with the improved sources.
* Any improved source needs to precede the sink at the same level
* and needs to follow source j at the same or a deeper level.
* The lower this level, the later the execution date of source k.
* We therefore consider lower levels first.
*
* If temp_rel[j] is empty, then there can be no improvement and
* we return immediately.
*
* This function returns isl_stat_ok in case it was executed successfully and
* isl_stat_error in case of errors during the execution of this function.
*/
static isl_stat intermediate_sources(__isl_keep isl_access_info *acc,
struct isl_map **temp_rel, int j, int sink_level)
{
int k, level;
isl_size n_in = isl_map_dim(acc->source[j].map, isl_dim_in);
int depth = 2 * n_in + 1;
if (n_in < 0)
return isl_stat_error;
if (isl_map_plain_is_empty(temp_rel[j]))
return isl_stat_ok;
for (k = j - 1; k >= 0; --k) {
int plevel, plevel2;
plevel = acc->level_before(acc->source[k].data, acc->sink.data);
if (plevel < 0)
return isl_stat_error;
if (!can_precede_at_level(plevel, sink_level))
continue;
plevel2 = acc->level_before(acc->source[j].data,
acc->source[k].data);
if (plevel2 < 0)
return isl_stat_error;
for (level = sink_level; level <= depth; ++level) {
struct isl_map *T;
struct isl_set *trest;
struct isl_map *copy;
if (!can_precede_at_level(plevel2, level))
continue;
copy = isl_map_copy(temp_rel[j]);
T = last_later_source(acc, copy, j, sink_level, k,
level, &trest);
if (isl_map_plain_is_empty(T)) {
isl_set_free(trest);
isl_map_free(T);
continue;
}
temp_rel[j] = isl_map_intersect_range(temp_rel[j], trest);
temp_rel[k] = isl_map_union_disjoint(temp_rel[k], T);
}
}
return isl_stat_ok;
}
/* Compute all iterations of may source j that precedes the sink at the given
* level for sink iterations in set_C.
*/
static __isl_give isl_map *all_sources(__isl_keep isl_access_info *acc,
__isl_take isl_set *set_C, int j, int level)
{
isl_map *read_map;
isl_map *write_map;
isl_map *dep_map;
isl_map *after;
read_map = isl_map_copy(acc->sink.map);
read_map = isl_map_intersect_domain(read_map, set_C);
write_map = isl_map_copy(acc->source[acc->n_must + j].map);
write_map = isl_map_reverse(write_map);
dep_map = isl_map_apply_range(read_map, write_map);
after = after_at_level(isl_map_get_space(dep_map), level);
dep_map = isl_map_intersect(dep_map, after);
return isl_map_reverse(dep_map);
}
/* For a given mapping between iterations of must source k and iterations
* of the sink, compute all iterations of may source j preceding
* the sink at level before_level for any of the sink iterations,
* but following the corresponding iteration of must source k at level
* after_level.
*/
static __isl_give isl_map *all_later_sources(__isl_keep isl_access_info *acc,
__isl_take isl_map *old_map,
int j, int before_level, int k, int after_level)
{
isl_space *space;
isl_set *set_C;
isl_map *read_map;
isl_map *write_map;
isl_map *dep_map;
isl_map *after_write;
isl_map *before_read;
set_C = isl_map_range(isl_map_copy(old_map));
read_map = isl_map_copy(acc->sink.map);
read_map = isl_map_intersect_domain(read_map, set_C);
write_map = isl_map_copy(acc->source[acc->n_must + j].map);
write_map = isl_map_reverse(write_map);
dep_map = isl_map_apply_range(read_map, write_map);
space = isl_space_join(isl_map_get_space(
acc->source[acc->n_must + j].map),
isl_space_reverse(isl_map_get_space(acc->source[k].map)));
after_write = after_at_level(space, after_level);
after_write = isl_map_apply_range(after_write, old_map);
after_write = isl_map_reverse(after_write);
dep_map = isl_map_intersect(dep_map, after_write);
before_read = after_at_level(isl_map_get_space(dep_map), before_level);
dep_map = isl_map_intersect(dep_map, before_read);
return isl_map_reverse(dep_map);
}
/* Given the must and may dependence relations for the must accesses
* for level sink_level, check if there are any accesses of may access j
* that occur in between and return their union.
* If some of these accesses are intermediate with respect to
* (previously thought to be) must dependences, then these
* must dependences are turned into may dependences.
*/
static __isl_give isl_map *all_intermediate_sources(
__isl_keep isl_access_info *acc, __isl_take isl_map *map,
struct isl_map **must_rel, struct isl_map **may_rel,
int j, int sink_level)
{
int k, level;
isl_size n_in = isl_map_dim(acc->source[acc->n_must + j].map,
isl_dim_in);
int depth = 2 * n_in + 1;
if (n_in < 0)
return isl_map_free(map);
for (k = 0; k < acc->n_must; ++k) {
int plevel;
if (isl_map_plain_is_empty(may_rel[k]) &&
isl_map_plain_is_empty(must_rel[k]))
continue;
plevel = acc->level_before(acc->source[k].data,
acc->source[acc->n_must + j].data);
if (plevel < 0)
return isl_map_free(map);
for (level = sink_level; level <= depth; ++level) {
isl_map *T;
isl_map *copy;
isl_set *ran;
if (!can_precede_at_level(plevel, level))
continue;
copy = isl_map_copy(may_rel[k]);
T = all_later_sources(acc, copy, j, sink_level, k, level);
map = isl_map_union(map, T);
copy = isl_map_copy(must_rel[k]);
T = all_later_sources(acc, copy, j, sink_level, k, level);
ran = isl_map_range(isl_map_copy(T));
map = isl_map_union(map, T);
may_rel[k] = isl_map_union_disjoint(may_rel[k],
isl_map_intersect_range(isl_map_copy(must_rel[k]),
isl_set_copy(ran)));
T = isl_map_from_domain_and_range(
isl_set_universe(
isl_space_domain(isl_map_get_space(must_rel[k]))),
ran);
must_rel[k] = isl_map_subtract(must_rel[k], T);
}
}
return map;
}
/* Given a dependence relation "old_map" between a must-source and the sink,
* return a subset of the dependences, augmented with instances
* of the source at position "pos" in "acc" that are coscheduled
* with the must-source and that access the same element.
* That is, if the input lives in a space T -> K, then the output
* lives in the space [T -> S] -> K, with S the space of source "pos", and
* the domain factor of the domain product is a subset of the input.
* The sources are considered to be coscheduled if they have the same values
* for the initial "depth" coordinates.
*
* First construct a dependence relation S -> K and a mapping
* between coscheduled sources T -> S.
* The second is combined with the original dependence relation T -> K
* to form a relation in T -> [S -> K], which is subsequently
* uncurried to [T -> S] -> K.
* This result is then intersected with the dependence relation S -> K
* to form the output.
*
* In case a negative depth is given, NULL is returned to indicate an error.
*/
static __isl_give isl_map *coscheduled_source(__isl_keep isl_access_info *acc,
__isl_keep isl_map *old_map, int pos, int depth)
{
isl_space *space;
isl_set *set_C;
isl_map *read_map;
isl_map *write_map;
isl_map *dep_map;
isl_map *equal;
isl_map *map;
if (depth < 0)
return NULL;
set_C = isl_map_range(isl_map_copy(old_map));
read_map = isl_map_copy(acc->sink.map);
read_map = isl_map_intersect_domain(read_map, set_C);
write_map = isl_map_copy(acc->source[pos].map);
dep_map = isl_map_domain_product(write_map, read_map);
dep_map = isl_set_unwrap(isl_map_domain(dep_map));
space = isl_space_join(isl_map_get_space(old_map),
isl_space_reverse(isl_map_get_space(dep_map)));
equal = isl_map_from_basic_map(isl_basic_map_equal(space, depth));
map = isl_map_range_product(equal, isl_map_copy(old_map));
map = isl_map_uncurry(map);
map = isl_map_intersect_domain_factor_range(map, dep_map);
return map;
}
/* After the dependences derived from a must-source have been computed
* at a certain level, check if any of the sources of the must-dependences
* may be coscheduled with other sources.
* If they are any such sources, then there is no way of determining
* which of the sources actually comes last and the must-dependences
* need to be turned into may-dependences, while dependences from
* the other sources need to be added to the may-dependences as well.
* "acc" describes the sources and a callback for checking whether
* two sources may be coscheduled. If acc->coscheduled is NULL then
* the sources are assumed not to be coscheduled.
* "must_rel" and "may_rel" describe the must and may-dependence relations
* computed at the current level for the must-sources. Some of the dependences
* may be moved from "must_rel" to "may_rel".
* "flow" contains all dependences computed so far (apart from those
* in "must_rel" and "may_rel") and may be updated with additional
* dependences derived from may-sources.
*
* In particular, consider all the must-sources with a non-empty
* dependence relation in "must_rel". They are considered in reverse
* order because that is the order in which they are considered in the caller.
* If any of the must-sources are coscheduled, then the last one
* is the one that will have a corresponding dependence relation.
* For each must-source i, consider both all the previous must-sources
* and all the may-sources. If any of those may be coscheduled with
* must-source i, then compute the coscheduled instances that access
* the same memory elements. The result is a relation [T -> S] -> K.
* The projection onto T -> K is a subset of the must-dependence relation
* that needs to be turned into may-dependences.
* The projection onto S -> K needs to be added to the may-dependences
* of source S.
* Since a given must-source instance may be coscheduled with several
* other source instances, the dependences that need to be turned
* into may-dependences are first collected and only actually removed
* from the must-dependences after all other sources have been considered.
*/
static __isl_give isl_flow *handle_coscheduled(__isl_keep isl_access_info *acc,
__isl_keep isl_map **must_rel, __isl_keep isl_map **may_rel,
__isl_take isl_flow *flow)
{
int i, j;
if (!acc->coscheduled)
return flow;
for (i = acc->n_must - 1; i >= 0; --i) {
isl_map *move;
if (isl_map_plain_is_empty(must_rel[i]))
continue;
move = isl_map_empty(isl_map_get_space(must_rel[i]));
for (j = i - 1; j >= 0; --j) {
int depth;