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/*
* Copyright 2010-2011 INRIA Saclay
* Copyright 2012-2013 Ecole Normale Superieure
* Copyright 2015-2016 Sven Verdoolaege
*
* Use of this software is governed by the MIT license
*
* Written by Sven Verdoolaege, 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 <stdlib.h>
#include <string.h>
#include <isl/polynomial.h>
#include <isl/union_set.h>
#include <isl/aff.h>
#include <isl/ilp.h>
#include <isl/flow.h>
#include <isl/schedule.h>
#include <isl/schedule_node.h>
#include <isl/options.h>
#include <isl/ast_build.h>
#include "cpu.h"
#include "gpu.h"
#include "gpu_array_tile.h"
#include "gpu_group.h"
#include "gpu_hybrid.h"
#include "gpu_tree.h"
#include "hybrid.h"
#include "schedule.h"
#include "ppcg_options.h"
#include "print.h"
#include "util.h"
struct gpu_array_info;
/* Return the name of the outer array (of structs) accessed by "access".
*/
static const char *get_outer_array_name(__isl_keep isl_map *access)
{
isl_space *space;
const char *name;
space = isl_space_range(isl_map_get_space(access));
while (space && isl_space_is_wrapping(space))
space = isl_space_domain(isl_space_unwrap(space));
name = isl_space_get_tuple_name(space, isl_dim_set);
isl_space_free(space);
return name;
}
/* Collect all references to the given array and store pointers to them
* in array->refs.
*/
static isl_stat collect_references(struct gpu_prog *prog,
struct gpu_array_info *array)
{
int i;
int n;
n = 0;
for (i = 0; i < prog->n_stmts; ++i) {
struct gpu_stmt *stmt = &prog->stmts[i];
struct gpu_stmt_access *access;
for (access = stmt->accesses; access; access = access->next) {
const char *name;
name = get_outer_array_name(access->access);
if (name && !strcmp(array->name, name))
n++;
}
}
array->refs = isl_alloc_array(prog->ctx, struct gpu_stmt_access *, n);
if (!array->refs)
return isl_stat_error;
array->n_ref = n;
n = 0;
for (i = 0; i < prog->n_stmts; ++i) {
struct gpu_stmt *stmt = &prog->stmts[i];
struct gpu_stmt_access *access;
for (access = stmt->accesses; access; access = access->next) {
const char *name;
name = get_outer_array_name(access->access);
if (!name || strcmp(array->name, name))
continue;
array->refs[n++] = access;
}
}
return isl_stat_ok;
}
/* Compute and return the extent of "array", taking into account the set of
* accessed elements.
*
* In particular, the extent in the outer dimension is taken
* from "accessed", while the extents in the remaining dimensions
* are taken from array->extent.
*
* The extent in the outer dimension cannot be taken from array->extent
* because that may be unbounded. Furthermore, even if it is bounded,
* it may be larger than the piece of the array that is being accessed.
*/
static __isl_give isl_set *compute_extent(struct pet_array *array,
__isl_keep isl_set *accessed)
{
int n_index;
isl_id *id;
isl_set *outer;
isl_set *extent;
extent = isl_set_copy(array->extent);
n_index = isl_set_dim(accessed, isl_dim_set);
if (n_index == 0)
return extent;
extent = isl_set_project_out(extent, isl_dim_set, 0, 1);
outer = isl_set_copy(accessed);
outer = isl_set_project_out(outer, isl_dim_set, 1, n_index - 1);
extent = isl_set_flat_product(outer, extent);
id = isl_set_get_tuple_id(accessed);
extent = isl_set_set_tuple_id(extent, id);
return extent;
}
/* Is the array "array" being extracted a read-only scalar?
*
* That is, is "array" a scalar that is never possibly written to.
* An array containing structures is never considered to be a scalar.
*/
static int is_read_only_scalar(struct gpu_array_info *array,
struct gpu_prog *prog)
{
isl_set *space;
isl_union_map *write;
int empty;
if (array->has_compound_element)
return 0;
if (array->n_index != 0)
return 0;
write = isl_union_map_copy(prog->may_write);
space = isl_set_universe(isl_space_copy(array->space));
write = isl_union_map_intersect_range(write,
isl_union_set_from_set(space));
empty = isl_union_map_is_empty(write);
isl_union_map_free(write);
return empty;
}
/* Is "array" only accessed as individual, fixed elements?
* That is, does each access to "array" access a single, fixed element?
*/
static isl_bool only_fixed_element_accessed(struct gpu_array_info *array)
{
int i;
for (i = 0; i < array->n_ref; ++i)
if (!array->refs[i]->fixed_element)
return isl_bool_false;
return isl_bool_true;
}
/* Compute bounds on the host array "pa" based on the corresponding
* accessed elements in "arrays"
* and collect all references to the array.
* Store the results in "info".
*
* If the array is zero-dimensional and does not contain structures,
* i.e., if the array is a scalar, we check whether it is read-only.
* We also check whether the array is accessed at all.
*/
static isl_stat extract_array_info(struct gpu_prog *prog,
struct gpu_array_info *info, struct pet_array *pa,
__isl_keep isl_union_set *arrays)
{
int empty;
const char *name;
int n_index;
isl_multi_pw_aff *bounds;
isl_set *accessed, *extent;
n_index = isl_set_dim(pa->extent, isl_dim_set);
name = isl_set_get_tuple_name(pa->extent);
info->space = isl_set_get_space(pa->extent);
info->name = strdup(name);
info->n_index = n_index;
info->linearize = prog->scop->options->linearize_device_arrays;
info->type = strdup(pa->element_type);
info->size = pa->element_size;
info->local = pa->declared && !pa->exposed;
info->has_compound_element = pa->element_is_record;
info->read_only_scalar = is_read_only_scalar(info, prog);
info->declared_extent = isl_set_copy(pa->extent);
accessed = isl_union_set_extract_set(arrays,
isl_space_copy(info->space));
empty = isl_set_is_empty(accessed);
extent = compute_extent(pa, accessed);
isl_set_free(accessed);
info->extent = extent;
if (empty < 0)
return isl_stat_error;
info->accessed = !empty;
bounds = ppcg_size_from_extent(isl_set_copy(extent));
bounds = isl_multi_pw_aff_gist(bounds, isl_set_copy(prog->context));
if (!bounds)
return isl_stat_error;
if (!isl_multi_pw_aff_is_cst(bounds))
info->linearize = 1;
info->bound = bounds;
if (collect_references(prog, info) < 0)
return isl_stat_error;
info->only_fixed_element = only_fixed_element_accessed(info);
return isl_stat_ok;
}
/* Remove independence from the order constraints "order" on array "array".
* Since the pairs of iterations in the filter relation of an independence
* are guaranteed to be completely independent by the user, there is
* no need to ensure that live ranges are ordered along those pairs.
* We make an exception for local variables, though, as the independence
* guarantee does not apply to those.
*
* The order constraints are used in two places.
* Those on scalars are used in check_scalar_live_ranges to check if
* we need to force the scalar to be private. Any non-local scalar
* should not be forced scalar if it only appears in independent loops.
* Those on non-scalars are added to the coincidence constraints
* in compute_schedule because we do not support any array expansion.
* Accesses to non-local arrays should not prevent a loop from being
* considered coincident so we should indeed remove those constraints
* from the order constraints.
*/
static __isl_give isl_union_map *remove_independences(struct gpu_prog *prog,
struct gpu_array_info *array, __isl_take isl_union_map *order)
{
int i;
for (i = 0; i < prog->scop->pet->n_independence; ++i) {
struct pet_independence *pi = prog->scop->pet->independences[i];
if (isl_union_set_contains(pi->local, array->space))
continue;
order = isl_union_map_subtract(order,
isl_union_map_copy(pi->filter));
}
return order;
}
/* For each array in "prog", store the (untagged) order dependences
* derived from the array in array->dep_order.
* In particular, consider all references that access the given array
* and take the order dependences that have one of these references
* as source. (Since an order dependence relates two references to
* the same array, the target of these order dependences will also
* be one of these references.)
* Additionally, store the union of these array->dep_order relations
* for all arrays that cannot be mapped to private memory in prog->array_order.
*/
void collect_order_dependences(struct gpu_prog *prog)
{
int i;
isl_space *space;
isl_union_map *accesses;
space = isl_union_map_get_space(prog->read);
prog->array_order = isl_union_map_empty(space);
accesses = isl_union_map_copy(prog->scop->tagged_reads);
accesses = isl_union_map_union(accesses,
isl_union_map_copy(prog->scop->tagged_may_writes));
accesses = isl_union_map_universe(accesses);
accesses = isl_union_map_apply_range(accesses,
isl_union_map_copy(prog->to_outer));
for (i = 0; i < prog->n_array; ++i) {
struct gpu_array_info *array = &prog->array[i];
isl_set *set;
isl_union_set *uset;
isl_union_map *order;
set = isl_set_universe(isl_space_copy(array->space));
uset = isl_union_set_from_set(set);
uset = isl_union_map_domain(
isl_union_map_intersect_range(isl_union_map_copy(accesses),
uset));
order = isl_union_map_copy(prog->scop->tagged_dep_order);
order = isl_union_map_intersect_domain(order, uset);
order = isl_union_map_zip(order);
order = isl_union_set_unwrap(isl_union_map_domain(order));
order = remove_independences(prog, array, order);
array->dep_order = order;
if (gpu_array_can_be_private(array))
continue;
prog->array_order = isl_union_map_union(prog->array_order,
isl_union_map_copy(array->dep_order));
}
isl_union_map_free(accesses);
}
/* Construct a gpu_array_info for each array referenced by prog->scop and
* collect them in prog->array.
*
* The sizes are based on the extents and the set of possibly accessed
* elements by "prog".
* If there are any member accesses involved, then they are first mapped
* to the outer arrays of structs.
* Only extract gpu_array_info entries for these outer arrays.
*
* If we are allowing live range reordering, then also set
* the dep_order field. Otherwise leave it NULL.
*/
static isl_stat collect_array_info(struct gpu_prog *prog)
{
int i;
isl_stat r = isl_stat_ok;
isl_union_set *arrays;
prog->n_array = 0;
prog->array = isl_calloc_array(prog->ctx,
struct gpu_array_info, prog->scop->pet->n_array);
if (!prog->array)
return isl_stat_error;
arrays = isl_union_map_range(isl_union_map_copy(prog->read));
arrays = isl_union_set_union(arrays,
isl_union_map_range(isl_union_map_copy(prog->may_write)));
arrays = isl_union_set_apply(arrays,
isl_union_map_copy(prog->to_outer));
arrays = isl_union_set_coalesce(arrays);
for (i = 0; i < prog->scop->pet->n_array; ++i) {
isl_bool field;
field = isl_set_is_wrapping(prog->scop->pet->arrays[i]->extent);
if (field < 0)
break;
if (field)
continue;
if (extract_array_info(prog, &prog->array[prog->n_array++],
prog->scop->pet->arrays[i], arrays) < 0)
r = isl_stat_error;
}
if (i < prog->scop->pet->n_array)
r = isl_stat_error;
isl_union_set_free(arrays);
if (prog->scop->options->live_range_reordering)
collect_order_dependences(prog);
return r;
}
static void free_array_info(struct gpu_prog *prog)
{
int i;
for (i = 0; i < prog->n_array; ++i) {
free(prog->array[i].type);
free(prog->array[i].name);
isl_multi_pw_aff_free(prog->array[i].bound);
isl_ast_expr_free(prog->array[i].bound_expr);
isl_space_free(prog->array[i].space);
isl_set_free(prog->array[i].declared_extent);
isl_set_free(prog->array[i].extent);
isl_ast_expr_free(prog->array[i].declared_size);
free(prog->array[i].refs);
isl_union_map_free(prog->array[i].dep_order);
}
free(prog->array);
}
/* Check if a gpu array is a scalar. A scalar is a value that is not stored
* as an array or through a pointer reference, but as a single data element.
* At the moment, scalars are represented as zero-dimensional arrays.
* Note that the single data element may be an entire structure.
*/
int gpu_array_is_scalar(struct gpu_array_info *array)
{
return array->n_index == 0;
}
/* Can "array" be mapped to private memory?
* That is, is it only accessed as individual elements with
* constant index expressions?
*/
isl_bool gpu_array_can_be_private(struct gpu_array_info *array)
{
if (!array)
return isl_bool_error;
return array->only_fixed_element;
}
/* Is "array" a read-only scalar?
*/
int gpu_array_is_read_only_scalar(struct gpu_array_info *array)
{
return array->read_only_scalar;
}
/* Does "array" need to be allocated on the device?
* If it is a read-only scalar, then it will be passed as an argument
* to the kernel and therefore does not require any allocation.
* If this device memory is not accessed at all, then it does not
* need to be allocated either.
*/
int gpu_array_requires_device_allocation(struct gpu_array_info *array)
{
if (gpu_array_is_read_only_scalar(array))
return 0;
if (!array->global)
return 0;
return 1;
}
/* Return the set of parameter values for which the array has a positive
* size in all dimensions.
* If the sizes are only valid for some parameter values, then those
* constraints are also taken into account.
*/
__isl_give isl_set *gpu_array_positive_size_guard(struct gpu_array_info *array)
{
int i;
isl_space *space;
isl_set *guard;
if (!array)
return NULL;
space = isl_space_params(isl_space_copy(array->space));
guard = isl_set_universe(space);
for (i = 0; i < array->n_index; ++i) {
isl_pw_aff *bound;
isl_set *guard_i, *zero;
bound = isl_multi_pw_aff_get_pw_aff(array->bound, i);
guard_i = isl_pw_aff_nonneg_set(isl_pw_aff_copy(bound));
zero = isl_pw_aff_zero_set(bound);
guard_i = isl_set_subtract(guard_i, zero);
guard = isl_set_intersect(guard, guard_i);
}
return guard;
}
/* Internal data structure for extract_size_of_type.
* "type" specifies the name of the space that we want to extract.
* "res" is used to store the subset of that space.
*/
struct ppcg_extract_size_data {
const char *type;
isl_set *res;
};
/* This function is called for each set in a union_set.
* If the name of the set matches data->type, we store the
* set in data->res.
*/
static isl_stat extract_size_of_type(__isl_take isl_set *size, void *user)
{
struct ppcg_extract_size_data *data = user;
const char *name;
name = isl_set_get_tuple_name(size);
if (name && !strcmp(name, data->type)) {
data->res = size;
return isl_stat_error;
}
isl_set_free(size);
return isl_stat_ok;
}
/* Given a union map { kernel[i] -> *[...] },
* return the range in the space called "type" for the kernel with
* sequence number "id".
*/
static __isl_give isl_set *extract_sizes(__isl_keep isl_union_map *sizes,
const char *type, int id)
{
isl_space *space;
isl_set *dom;
isl_union_set *local_sizes;
struct ppcg_extract_size_data data = { type, NULL };
if (!sizes)
return NULL;
space = isl_union_map_get_space(sizes);
space = isl_space_set_from_params(space);
space = isl_space_add_dims(space, isl_dim_set, 1);
space = isl_space_set_tuple_name(space, isl_dim_set, "kernel");
dom = isl_set_universe(space);
dom = isl_set_fix_si(dom, isl_dim_set, 0, id);
local_sizes = isl_union_set_apply(isl_union_set_from_set(dom),
isl_union_map_copy(sizes));
isl_union_set_foreach_set(local_sizes, &extract_size_of_type, &data);
isl_union_set_free(local_sizes);
return data.res;
}
/* Given a singleton set, extract the first (at most *len) elements
* of the single integer tuple into *sizes and update *len if needed.
*
* If "set" is NULL, then the "sizes" array is not updated.
*/
static isl_stat read_sizes_from_set(__isl_take isl_set *set, int *sizes,
int *len)
{
int i;
int dim;
if (!set)
return isl_stat_ok;
dim = isl_set_dim(set, isl_dim_set);
if (dim < *len)
*len = dim;
for (i = 0; i < *len; ++i) {
isl_val *v;
v = isl_set_plain_get_val_if_fixed(set, isl_dim_set, i);
if (!v)
goto error;
sizes[i] = isl_val_get_num_si(v);
isl_val_free(v);
}
isl_set_free(set);
return isl_stat_ok;
error:
isl_set_free(set);
return isl_stat_error;
}
/* Add the map { kernel[id] -> type[sizes] } to gen->used_sizes,
* if the option debug->dump_sizes is set.
*/
static void set_used_sizes(struct gpu_gen *gen, const char *type, int id,
int *sizes, int len)
{
int i;
isl_space *space;
isl_map *map;
if (!gen->options->debug->dump_sizes)
return;
space = isl_union_map_get_space(gen->used_sizes);
space = isl_space_set_from_params(space);
space = isl_space_add_dims(space, isl_dim_set, 1);
space = isl_space_set_tuple_name(space, isl_dim_set, "kernel");
space = isl_space_from_domain(space);
space = isl_space_add_dims(space, isl_dim_out, len);
space = isl_space_set_tuple_name(space, isl_dim_out, type);
map = isl_map_universe(space);
map = isl_map_fix_si(map, isl_dim_in, 0, id);
for (i = 0; i < len; ++i)
map = isl_map_fix_si(map, isl_dim_out, i, sizes[i]);
gen->used_sizes = isl_union_map_add_map(gen->used_sizes, map);
}
/* Extract user specified "tile" sizes from the "sizes" command line option,
* defaulting to option->tile_size in each dimension.
* *tile_len contains the maximum number of tile sizes needed.
* Update *tile_len to the number of specified tile sizes, if any, and
* return a pointer to the tile sizes (or NULL on error).
* Add the effectively used sizes to gen->used_sizes.
*/
static int *read_tile_sizes(struct gpu_gen *gen, int *tile_len)
{
int n;
int *tile_size;
isl_set *size;
tile_size = isl_alloc_array(gen->ctx, int, *tile_len);
if (!tile_size)
return NULL;
for (n = 0; n < *tile_len; ++n)
tile_size[n] = gen->options->tile_size;
size = extract_sizes(gen->sizes, "tile", gen->kernel_id);
if (read_sizes_from_set(size, tile_size, tile_len) < 0)
goto error;
set_used_sizes(gen, "tile", gen->kernel_id, tile_size, *tile_len);
return tile_size;
error:
free(tile_size);
return NULL;
}
/* Extract user specified "block" sizes from the "sizes" command line option,
* after filling in some potentially useful defaults.
*/
static isl_stat read_block_sizes(struct ppcg_kernel *kernel,
__isl_keep isl_union_map *sizes)
{
isl_set *size;
if (kernel->n_block > 3)
kernel->n_block = 3;
switch (kernel->n_block) {
case 1:
kernel->block_dim[0] = 512;
break;
case 2:
kernel->block_dim[0] = 32;
kernel->block_dim[1] = 16;
break;
default:
kernel->block_dim[0] = 32;
kernel->block_dim[1] = 4;
kernel->block_dim[2] = 4;
break;
}
size = extract_sizes(sizes, "block", kernel->id);
return read_sizes_from_set(size, kernel->block_dim, &kernel->n_block);
}
/* Extract user specified "grid" sizes from the "sizes" command line option,
* after filling in some potentially useful defaults.
*/
static isl_stat read_grid_sizes(struct ppcg_kernel *kernel,
__isl_keep isl_union_map *sizes)
{
isl_set *size;
if (kernel->n_grid > 2)
kernel->n_grid = 2;
switch (kernel->n_grid) {
case 1:
kernel->grid_dim[0] = 32768;
break;
default:
kernel->grid_dim[0] = 256;
kernel->grid_dim[1] = 256;
break;
}
size = extract_sizes(sizes, "grid", kernel->id);
return read_sizes_from_set(size, kernel->grid_dim, &kernel->n_grid);
}
/* Extract user specified grid and block sizes from the gen->sizes
* command line option after filling in some potentially useful defaults.
* Store the extracted sizes in "kernel".
* Add the effectively used sizes to gen->used_sizes.
*/
static isl_stat read_grid_and_block_sizes(struct ppcg_kernel *kernel,
struct gpu_gen *gen)
{
if (read_block_sizes(kernel, gen->sizes) < 0)
return isl_stat_error;
if (read_grid_sizes(kernel, gen->sizes) < 0)
return isl_stat_error;
set_used_sizes(gen, "block", kernel->id,
kernel->block_dim, kernel->n_block);
set_used_sizes(gen, "grid", kernel->id,
kernel->grid_dim, kernel->n_grid);
return isl_stat_ok;
}
static void *free_stmts(struct gpu_stmt *stmts, int n)
{
int i;
if (!stmts)
return NULL;
for (i = 0; i < n; ++i) {
struct gpu_stmt_access *access, *next;
for (access = stmts[i].accesses; access; access = next) {
next = access->next;
isl_id_free(access->ref_id);
isl_map_free(access->access);
isl_map_free(access->tagged_access);
free(access);
}
isl_id_free(stmts[i].id);
}
free(stmts);
return NULL;
}
/* Add parameters p[i] with identifiers "ids" to "set",
* with bounds to 0 <= p[i] < size[i].
*/
__isl_give isl_set *add_bounded_parameters(__isl_take isl_set *set,
int *size, __isl_keep isl_id_list *ids)
{
int i, len;
unsigned nparam;
len = isl_id_list_n_id(ids);
nparam = isl_set_dim(set, isl_dim_param);
set = isl_set_add_dims(set, isl_dim_param, len);
for (i = 0; i < len; ++i) {
isl_id *id;
id = isl_id_list_get_id(ids, i);
set = isl_set_set_dim_id(set, isl_dim_param, nparam + i, id);
set = isl_set_lower_bound_si(set, isl_dim_param, nparam + i, 0);
set = isl_set_upper_bound_si(set, isl_dim_param,
nparam + i, size[i] - 1);
}
return set;
}
/* Add "len" parameters p[i] with identifiers "ids" and intersect "set"
* with
*
* { : 0 <= p[i] < size[i] }
*
* or an overapproximation.
*/
static __isl_give isl_set *add_bounded_parameters_dynamic(
__isl_take isl_set *set, __isl_keep isl_multi_pw_aff *size,
__isl_keep isl_id_list *ids)
{
int i, len;
unsigned nparam;
isl_space *space;
isl_local_space *ls;
len = isl_multi_pw_aff_dim(size, isl_dim_out);
nparam = isl_set_dim(set, isl_dim_param);
set = isl_set_add_dims(set, isl_dim_param, len);
for (i = 0; i < len; ++i) {
isl_id *id;
id = isl_id_list_get_id(ids, i);
set = isl_set_set_dim_id(set, isl_dim_param, nparam + i, id);
}
space = isl_space_params(isl_set_get_space(set));
ls = isl_local_space_from_space(space);
for (i = 0; i < len; ++i) {
isl_pw_aff *param, *size_i, *zero;
isl_set *bound;
param = isl_pw_aff_var_on_domain(isl_local_space_copy(ls),
isl_dim_param, nparam + i);
size_i = isl_multi_pw_aff_get_pw_aff(size, i);
bound = isl_pw_aff_lt_set(isl_pw_aff_copy(param), size_i);
bound = isl_set_from_basic_set(isl_set_simple_hull(bound));
set = isl_set_intersect_params(set, bound);
zero = isl_pw_aff_zero_on_domain(isl_local_space_copy(ls));
bound = isl_pw_aff_ge_set(param, zero);
set = isl_set_intersect_params(set, bound);
}
isl_local_space_free(ls);
return set;
}
/* Return the union of all tagged access relations in the group.
*/
static __isl_give isl_union_map *group_tagged_access_relation(
struct gpu_array_ref_group *group)
{
int i;
isl_union_map *access;
access = isl_union_map_empty(isl_map_get_space(group->access));
for (i = 0; i < group->n_ref; ++i) {
isl_map *map_i;
map_i = isl_map_copy(group->refs[i]->tagged_access);
access = isl_union_map_union(access,
isl_union_map_from_map(map_i));
}
return access;
}
/* Return the extent of "array", recomputed from the bounds.
* The recomputed extent may be simpler than the original extent.
*/
static __isl_give isl_set *array_extent(struct gpu_array_info *array)
{
int i;
isl_id *id;
isl_space *space;
isl_local_space *ls;
isl_set *extent;
id = isl_set_get_tuple_id(array->extent);
space = isl_set_get_space(array->extent);
extent = isl_set_universe(isl_space_copy(space));
ls = isl_local_space_from_space(space);
for (i = 0; i < array->n_index; ++i) {
isl_pw_aff *bound;
isl_aff *aff;
isl_pw_aff *index;
isl_set *lt;
extent = isl_set_lower_bound_si(extent, isl_dim_set, i, 0);
aff = isl_aff_var_on_domain(isl_local_space_copy(ls),
isl_dim_set, i);
index = isl_pw_aff_from_aff(aff);
bound = isl_multi_pw_aff_get_pw_aff(array->bound, i);
bound = isl_pw_aff_from_range(bound);
bound = isl_pw_aff_add_dims(bound, isl_dim_in, array->n_index);
bound = isl_pw_aff_set_tuple_id(bound, isl_dim_in,
isl_id_copy(id));
lt = isl_pw_aff_lt_set(index, bound);
extent = isl_set_intersect(extent, lt);
}
isl_local_space_free(ls);
isl_id_free(id);
return extent;
}
/* Return a map from the first group->shared_tile->depth dimensions
* of the computed schedule to the array tile in
* global memory that corresponds to the shared memory copy.
*
* In particular, return a map
*
* { D[i] -> A[a] }
*
* with constraints
*
* tile_offset(i) <= a <= tile_offset(i) + tile_size - 1 (1)
*
* and
*
* 0 <= a <= array_size - 1 (2)
*
* Note that if some stride has been detected (i.e., when
* group->shared_tile->bound[i].shift is set), then a in (1) refers
* to the shifted and scaled down version.
*
* Constraints (1) are obtained by mapping the size constraints on the
* shared/private memory tile back to the access relation.
* Constraints (2) are obtained from the (recomputed) extent.
*/
static __isl_give isl_map *group_tile(struct gpu_array_ref_group *group)
{
int i;
int n_index = group->array->n_index;
isl_map *tile;
isl_space *space;
isl_set *local;
isl_set *extent;
space = isl_multi_aff_get_space(group->shared_tile->tiling);
space = isl_space_range(space);
local = isl_set_universe(space);
for (i = 0; i < n_index; ++i) {
isl_val *bound;
local = isl_set_lower_bound_si(local, isl_dim_set, i, 0);
bound = isl_val_copy(group->shared_tile->bound[i].size);
bound = isl_val_sub_ui(bound, 1);
local = isl_set_upper_bound_val(local, isl_dim_set, i, bound);
}
local = isl_set_preimage_multi_aff(local,
isl_multi_aff_copy(group->shared_tile->tiling));
tile = isl_set_unwrap(local);
extent = array_extent(group->array);
tile = isl_map_intersect_range(tile, extent);
return tile;
}
/* Given a mapping "iterator_map" from the AST schedule to a domain,
* return the corresponding mapping from the AST schedule
* to the outer kernel->copy_schedule_dim dimensions of
* the schedule computed by PPCG for this kernel.
*
* Note that kernel->copy_schedule_dim is at least as large as
* the largest depth of any array reference group associated to the kernel.
* This is needed as the returned schedule is used to extract a mapping
* to the outer tile->depth dimensions in transform_index.
*/
static __isl_give isl_pw_multi_aff *compute_sched_to_copy(
struct ppcg_kernel *kernel, __isl_take isl_pw_multi_aff *iterator_map)
{
isl_union_pw_multi_aff *upma;
isl_pw_multi_aff *pma;
isl_space *space;
space = isl_space_range(isl_pw_multi_aff_get_space(iterator_map));
space = isl_space_from_domain(space);
space = isl_space_add_dims(space, isl_dim_out,
kernel->copy_schedule_dim);
upma = isl_union_pw_multi_aff_copy(kernel->copy_schedule);
pma = isl_union_pw_multi_aff_extract_pw_multi_aff(upma, space);
isl_union_pw_multi_aff_free(upma);
return isl_pw_multi_aff_pullback_pw_multi_aff(pma, iterator_map);
}
/* If max_shared_memory is not set to infinity (-1), then make
* sure that the total amount of shared memory required by the
* array reference groups mapped to shared memory by "kernel"
* is no larger than this maximum.
*
* We apply a greedy approach and discard (keep in global memory)
* those groups that would result in a total memory size that
* is larger than the maximum.
*
* This function should be called after any function that may
* affect the decision on whether to place a reference group
* in private, shared or global memory.
*/
static void check_shared_memory_bound(struct ppcg_kernel *kernel)
{
int i, j;
isl_val *left, *size;
if (kernel->options->max_shared_memory < 0)
return;
left = isl_val_int_from_si(kernel->ctx,
kernel->options->max_shared_memory);
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *local = &kernel->array[i];
for (j = 0; j < local->n_group; ++j) {
struct gpu_array_ref_group *group;
enum ppcg_group_access_type type;
group = local->groups[j];
type = gpu_array_ref_group_type(group);
if (type != ppcg_access_shared)
continue;
size = gpu_array_tile_size(group->shared_tile);
size = isl_val_mul_ui(size, local->array->size);
if (isl_val_le(size, left)) {
left = isl_val_sub(left, size);
continue;
}
isl_val_free(size);
group->shared_tile =
gpu_array_tile_free(group->shared_tile);
}
}
isl_val_free(left);
}
/* Mark all arrays of "kernel" that have an array reference group
* that is not mapped to private or shared memory as
* accessing the corresponding global device memory.
*/
static void mark_global_arrays(struct ppcg_kernel *kernel)
{
int i, j;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *local = &kernel->array[i];
if (local->global)
continue;
for (j = 0; j < local->n_group; ++j) {
if (gpu_array_ref_group_tile(local->groups[j]))
continue;
local->global = 1;
local->array->global = 1;
break;
}
}
}
/* Compute a tiling for all the array reference groups in "kernel".
*/
static void compute_group_tilings(struct ppcg_kernel *kernel)
{
int i, j;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j)
gpu_array_ref_group_compute_tiling(array->groups[j]);
}
}
/* Compute the effective grid size as a list of the sizes in each dimension.
*
* The grid size specified by the user or set by default
* in read_grid_sizes() and applied by the block filter,
* may be too large for the given code in the sense that
* it may contain blocks that don't need to execute anything.
* We therefore don't return this grid size, but instead the
* smallest grid size that ensures that all blocks that actually
* execute code are included in the grid.
*
* We first extract a description of the grid, i.e., the possible values
* of the block ids, from the domain elements in "domain" and
* kernel->block_filter.
* The block ids are parameters in kernel->block_filter.
* We simply need to change them into set dimensions.
*
* Then, for each block dimension, we compute the maximal value of the block id
* and add one.
*/
static __isl_give isl_multi_pw_aff *extract_grid_size(
struct ppcg_kernel *kernel, __isl_take isl_union_set *domain)
{
int i;
isl_set *grid;
isl_set *context;
isl_multi_pw_aff *size;
domain = isl_union_set_intersect(domain,
isl_union_set_copy(kernel->block_filter));
grid = isl_union_set_params(domain);
grid = isl_set_from_params(grid);
grid = isl_set_add_dims(grid, isl_dim_set, kernel->n_grid);
for (i = 0; i < kernel->n_grid; ++i) {
int pos;
isl_id *id;
if (!grid)
return NULL;
id = isl_id_list_get_id(kernel->block_ids, i);
pos = isl_set_find_dim_by_id(grid, isl_dim_param, id);
isl_id_free(id);
if (pos < 0)
isl_die(isl_set_get_ctx(grid), isl_error_internal,
"missing constraints on block identifier",
grid = isl_set_free(grid));
grid = isl_set_equate(grid, isl_dim_param, pos, isl_dim_set, i);
grid = isl_set_project_out(grid, isl_dim_param, pos, 1);
}
grid = isl_set_coalesce(grid);
size = ppcg_size_from_extent(grid);
context = isl_set_params(isl_set_copy(kernel->context));
return isl_multi_pw_aff_gist(size, context);
}
/* Compute the size of a fixed bounding box around the origin and "set",
* where "set" is assumed to contain only non-negative elements,
* and store the results in "size".
* In particular, compute the maximal value of "set" in each direction
* and add one.
*/
static void extract_fixed_size(__isl_take isl_set *set, int *size)
{
int i, n;
isl_local_space *ls;
isl_aff *obj;
n = isl_set_dim(set, isl_dim_set);
ls = isl_local_space_from_space(isl_set_get_space(set));
obj = isl_aff_zero_on_domain(ls);
for (i = 0; i < n; ++i) {
isl_val *max;
obj = isl_aff_set_coefficient_si(obj, isl_dim_in, i, 1);
max = isl_set_max_val(set, obj);
size[i] = isl_val_get_num_si(max) + 1;
isl_val_free(max);
obj = isl_aff_set_coefficient_si(obj, isl_dim_in, i, 0);
}
isl_aff_free(obj);
isl_set_free(set);
}
/* Compute the effective block size as a list of the sizes in each dimension
* and store the sizes in kernel->block_dim.
*
* The block size specified by the user or set by default
* in read_block_sizes() and applied by the thread filter,
* may be too large for the given code in the sense that
* it may contain threads that don't need to execute anything.
* We therefore update this block size in kernel->block_dim
* to the smallest block size that ensures that all threads
* that actually execute code are included in the block.
*
* The set of possible values of the thread ids is obtained from
* the domain elements "domain" and kernel->thread_filter.
* The current implementation eliminates all parameters, ensuring
* that the size is a fixed constant in each dimension.
* In principle we could also compute parametric sizes.
* We would have to make sure to project out all b%d and t%d parameters,
* however.
*/
static isl_stat extract_block_size(struct ppcg_kernel *kernel,
__isl_take isl_union_set *domain)
{
int i;
int nparam;
isl_set *block;
domain = isl_union_set_intersect(domain,
isl_union_set_copy(kernel->thread_filter));
block = isl_union_set_params(domain);
block = isl_set_from_params(block);
block = isl_set_add_dims(block, isl_dim_set, kernel->n_block);
for (i = 0; i < kernel->n_block; ++i) {
int pos;
isl_id *id;
if (!block)
return isl_stat_error;
id = isl_id_list_get_id(kernel->thread_ids, i);
pos = isl_set_find_dim_by_id(block, isl_dim_param, id);
isl_id_free(id);
if (pos < 0)
isl_die(isl_set_get_ctx(block), isl_error_internal,
"missing constraints on thread identifier",
block = isl_set_free(block));
block = isl_set_equate(block, isl_dim_param, pos,
isl_dim_set, i);
}
nparam = isl_set_dim(block, isl_dim_param);
block = isl_set_project_out(block, isl_dim_param, 0, nparam);
if (!block)
return isl_stat_error;
extract_fixed_size(block, kernel->block_dim);
return isl_stat_ok;
}
struct ppcg_kernel *ppcg_kernel_free(struct ppcg_kernel *kernel)
{
int i, j;
if (!kernel)
return NULL;
isl_id_list_free(kernel->block_ids);
isl_id_list_free(kernel->thread_ids);
isl_multi_pw_aff_free(kernel->grid_size);
isl_ast_expr_free(kernel->grid_size_expr);
isl_set_free(kernel->context);
isl_union_set_free(kernel->core);
isl_union_set_free(kernel->arrays);
isl_union_pw_multi_aff_free(kernel->contraction);
isl_union_set_free(kernel->expanded_domain);
isl_space_free(kernel->space);
isl_ast_node_free(kernel->tree);
isl_union_set_free(kernel->block_filter);
isl_union_set_free(kernel->thread_filter);
isl_union_pw_multi_aff_free(kernel->copy_schedule);
isl_union_set_free(kernel->sync_writes);
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j)
gpu_array_ref_group_free(array->groups[j]);
free(array->groups);
isl_multi_pw_aff_free(array->bound);
isl_ast_expr_free(array->bound_expr);
}
free(kernel->array);
for (i = 0; i < kernel->n_var; ++i) {
free(kernel->var[i].name);
isl_vec_free(kernel->var[i].size);
}
free(kernel->var);
free(kernel);
return NULL;
}
/* Wrapper around ppcg_kernel_free for use as a isl_id_set_free_user callback.
*/
static void ppcg_kernel_free_wrap(void *user)
{
struct ppcg_kernel *kernel = user;
ppcg_kernel_free(kernel);
}
static void create_kernel_var(isl_ctx *ctx, struct gpu_array_ref_group *group,
struct ppcg_kernel_var *var)
{
int j;
struct gpu_array_tile *tile;
isl_printer *p;
var->array = group->array;
var->type = gpu_array_ref_group_type(group);
tile = gpu_array_ref_group_tile(group);
p = isl_printer_to_str(ctx);
p = gpu_array_ref_group_print_name(group, p);
var->name = isl_printer_get_str(p);
isl_printer_free(p);
var->size = isl_vec_alloc(ctx, group->array->n_index);
for (j = 0; j < group->array->n_index; ++j)
var->size = isl_vec_set_element_val(var->size, j,
isl_val_copy(tile->bound[j].size));
}
static isl_stat create_kernel_vars(struct ppcg_kernel *kernel)
{
int i, j, n;
n = 0;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j) {
struct gpu_array_ref_group *group = array->groups[j];
enum ppcg_group_access_type type;
type = gpu_array_ref_group_type(group);
if (type != ppcg_access_global)
++n;
}
}
kernel->var = isl_calloc_array(kernel->ctx, struct ppcg_kernel_var, n);
if (!kernel->var)
return isl_stat_error;
kernel->n_var = n;
n = 0;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j) {
struct gpu_array_ref_group *group = array->groups[j];
enum ppcg_group_access_type type;
type = gpu_array_ref_group_type(group);
if (type == ppcg_access_global)
continue;
create_kernel_var(kernel->ctx, group, &kernel->var[n]);
++n;
}
}
return isl_stat_ok;
}
/* Replace "pa" by the zero function defined over the universe domain
* in the space of "pa".
*/
static __isl_give isl_pw_aff *set_universally_zero(__isl_take isl_pw_aff *pa)
{
isl_space *space;
isl_aff *zero;
space = isl_space_domain(isl_pw_aff_get_space(pa));
isl_pw_aff_free(pa);
zero = isl_aff_zero_on_domain(isl_local_space_from_space(space));
return isl_pw_aff_from_aff(zero);
}
/* The sizes of the arrays on the host that have been computed by
* extract_array_info may depend on the parameters. Use the extra
* constraints on the parameters that are valid at "host_domain"
* to simplify these expressions and store the results in kernel->array.
*
* We only need these localized bounds for arrays that are accessed
* by the current kernel. If we have found at least one reference group
* then the array is accessed by the kernel.
*
* The resulting sizes may be functions that are nowhere defined
* in case the access function cannot possibly access anything inside
* the kernel for some reason. If so, they are replaced by the zero
* function. Since the access function cannot actually access anything,
* there is no harm in printing the array sizes as zero.
*/
static void localize_bounds(struct ppcg_kernel *kernel,
__isl_keep isl_set *host_domain)
{
int i, j;
isl_set *context;
context = isl_set_copy(host_domain);
context = isl_set_params(context);
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *local = &kernel->array[i];
isl_multi_pw_aff *bound;
int n_index;
if (local->n_group == 0)
continue;
n_index = local->array->n_index;
bound = isl_multi_pw_aff_copy(local->array->bound);
for (j = 0; j < n_index; ++j) {
isl_pw_aff *pwaff;
int empty;
pwaff = isl_multi_pw_aff_get_pw_aff(bound, j);
pwaff = isl_pw_aff_gist(pwaff, isl_set_copy(context));
empty = isl_pw_aff_is_empty(pwaff);
if (empty < 0)
pwaff = isl_pw_aff_free(pwaff);
else if (empty)
pwaff = set_universally_zero(pwaff);
bound = isl_multi_pw_aff_set_pw_aff(bound, j, pwaff);
}
local->n_index = n_index;
local->bound = bound;
}
isl_set_free(context);
}
/* Create the array of gpu_local_array_info structures "array"
* inside "kernel". The number of elements in this array is
* the same as the number of arrays in "prog".
* Initialize the "array" field of each local array to point
* to the corresponding array in "prog".
*/
static struct ppcg_kernel *ppcg_kernel_create_local_arrays(
struct ppcg_kernel *kernel, struct gpu_prog *prog)
{
int i;
isl_ctx *ctx;
if (!kernel)
return NULL;
ctx = isl_set_get_ctx(prog->context);
kernel->array = isl_calloc_array(ctx,
struct gpu_local_array_info, prog->n_array);
if (!kernel->array)
return ppcg_kernel_free(kernel);
kernel->n_array = prog->n_array;
for (i = 0; i < prog->n_array; ++i)
kernel->array[i].array = &prog->array[i];
return kernel;
}
/* Does "kernel" need to be passed an argument corresponding to array "i"?
*
* The argument is only needed if the kernel accesses this device memory.
*/
int ppcg_kernel_requires_array_argument(struct ppcg_kernel *kernel, int i)
{
return kernel->array[i].global;
}
/* Find the element in gen->stmt that has the given "id".
* Return NULL if no such gpu_stmt can be found.
*/
static struct gpu_stmt *find_stmt(struct gpu_prog *prog, __isl_keep isl_id *id)
{
int i;
for (i = 0; i < prog->n_stmts; ++i) {
if (id == prog->stmts[i].id)
break;
}
return i < prog->n_stmts ? &prog->stmts[i] : NULL;
}
void ppcg_kernel_stmt_free(void *user)
{
struct ppcg_kernel_stmt *stmt = user;
if (!stmt)
return;
switch (stmt->type) {
case ppcg_kernel_copy:
isl_ast_expr_free(stmt->u.c.index);
isl_ast_expr_free(stmt->u.c.local_index);
break;
case ppcg_kernel_domain:
isl_id_to_ast_expr_free(stmt->u.d.ref2expr);
break;
case ppcg_kernel_sync:
break;
}
free(stmt);
}
/* Return the gpu_stmt_access in the list "accesses" that corresponds
* to "ref_id".
*/
static struct gpu_stmt_access *find_access(struct gpu_stmt_access *accesses,
__isl_keep isl_id *ref_id)
{
struct gpu_stmt_access *access;
for (access = accesses; access; access = access->next)
if (access->ref_id == ref_id)
return access;
return NULL;
}
/* Return the index of the array called "name" in the list of arrays.
*/
static int find_array_index(struct ppcg_kernel *kernel, const char *name)
{
int i;
for (i = 0; i < kernel->n_array; ++i)
if (!strcmp(name, kernel->array[i].array->name))
return i;
return -1;
}
/* Internal data structure for the index and AST expression transformation
* callbacks for pet_stmt_build_ast_exprs.
*
* "kernel" is the kernel for which are computing AST expressions and
* may be NULL if we are not inside a kernel.
* "accesses" is the list of gpu_stmt_access in the statement.
* "iterator_map" expresses the statement iterators in terms of
* the AST loop iterators.
* "sched2copy" expresses the outer copy_schedule_dim dimensions of
* the kernel schedule in terms of the AST loop iterators and
* may be NULL if we are not inside a kernel.
*
* The following fields are set in transform_index and used in transform_expr.
* "array" is the array that is being accessed.
* "global" is set if the global array is accessed (rather than
* shared/private memory).
* "local_array" refers to information on the array specialized
* to the current kernel.
*/
struct ppcg_transform_data {
struct ppcg_kernel *kernel;
struct gpu_stmt_access *accesses;
isl_pw_multi_aff *iterator_map;
isl_pw_multi_aff *sched2copy;
struct gpu_array_info *array;
int global;
struct gpu_local_array_info *local_array;
};
/* Return a pointer to the gpu_array_ref_group in "local"
* that contains the reference "access".
* Return NULL if no such group can be found.
*/
static struct gpu_array_ref_group *find_ref_group(
struct gpu_local_array_info *local, struct gpu_stmt_access *access)
{
int i, j;
for (i = 0; i < local->n_group; ++i) {
struct gpu_array_ref_group *group = local->groups[i];
for (j = 0; j < group->n_ref; ++j)
if (group->refs[j] == access)
return group;
}
return NULL;
}
/* Given an index expression "index" of the form
*
* L -> F(A),
*
* with F(A) either A or some subfield of A and L the AST loop iterators,
* and a tiling "tiling" of the form
*
* [L -> A] -> T
*
* apply the tiling to the outer array in the index expression to obtain
*
* L -> T(A)
*
* If F(A) is some subfield of A, then separate the member access
* into the base index expression and the field index expression,
* apply the tiling to the base index expression and combine the result
* with the field index expression.
*
* If F(A) is A, then modify index to keep track of the iterators
*
* L -> [L -> A]
*
* and combine the result with the tiling to obtain a tiled index expression
* in terms of the AST loop iterators
*
* L -> T
*/
static __isl_give isl_multi_pw_aff *tile_outer(
__isl_take isl_multi_pw_aff *index, __isl_take isl_multi_pw_aff *tiling)
{
isl_bool is_wrapping;
isl_space *space;
isl_multi_pw_aff *mpa;
is_wrapping = isl_multi_pw_aff_range_is_wrapping(index);
if (is_wrapping < 0)
goto error;
if (is_wrapping) {
isl_multi_pw_aff *field;
field = isl_multi_pw_aff_copy(index);
field = isl_multi_pw_aff_range_factor_range(field);
index = isl_multi_pw_aff_range_factor_domain(index);
index = tile_outer(index, tiling);
return isl_multi_pw_aff_range_product(index, field);
}
space = isl_space_domain(isl_multi_pw_aff_get_space(index));
space = isl_space_map_from_set(space);
mpa = isl_multi_pw_aff_identity(space);
index = isl_multi_pw_aff_range_product(mpa, index);
index = isl_multi_pw_aff_pullback_multi_pw_aff(tiling, index);
return index;
error:
isl_multi_pw_aff_free(index);
isl_multi_pw_aff_free(tiling);
return NULL;
}
/* Index transformation callback for pet_stmt_build_ast_exprs.
*
* "index" expresses the array indices in terms of statement iterators
*
* We first reformulate "index" in terms of the AST loop iterators.
* Then we check if we are accessing the global array or
* a shared/private copy. In particular, if we are not inside a kernel
* then we must be accessing a global array.
* In the former case, we simply return
* the updated index. If "index" is an affine expression rather
* than an array access, then we also return the updated index here.
*
* If no reference groups have been computed for the array,
* then we can only be accessing the global array.
*
* Otherwise, we apply the tiling to the index.
* This tiling is of the form
*
* [D -> A] -> T
*
* where D corresponds to the outer tile->depth dimensions of
* the kernel schedule.
* The index is of the form
*
* L -> A
*
* We update the tiling to refer to the AST loop iterators
*
* [L -> A] -> T
*
* and combine it with the index to obtain a tiled index expression in terms
* of the AST loop iterators
*
* L -> T
*
* Note that while the tiling applies directly to an outer array.
* the index may refer to some subfield of this outer array.
* In such cases, the result will refer to the same subfield of the tile.
* That is, an index expression of the form L -> F(A) will be transformed
* into an index expression of the form L -> F(T).
*/
static __isl_give isl_multi_pw_aff *transform_index(
__isl_take isl_multi_pw_aff *index, __isl_keep isl_id *ref_id,
void *user)
{
struct ppcg_transform_data *data = user;
struct gpu_stmt_access *access;
struct gpu_array_ref_group *group;
struct gpu_array_tile *tile;
isl_pw_multi_aff *iterator_map;
int i;
int dim;
const char *name;
isl_space *space;
isl_multi_pw_aff *tiling;
isl_pw_multi_aff *pma;
isl_pw_multi_aff *sched2depth;
data->array = NULL;
iterator_map = isl_pw_multi_aff_copy(data->iterator_map);
index = isl_multi_pw_aff_pullback_pw_multi_aff(index, iterator_map);
if (!data->kernel)
return index;
access = find_access(data->accesses, ref_id);
if (!access)
return index;
if (!isl_map_has_tuple_name(access->access, isl_dim_out))
return index;
name = get_outer_array_name(access->access);
if (!name)
return isl_multi_pw_aff_free(index);
i = find_array_index(data->kernel, name);
if (i < 0)
isl_die(isl_multi_pw_aff_get_ctx(index), isl_error_internal,
"cannot find array",
return isl_multi_pw_aff_free(index));
data->local_array = &data->kernel->array[i];
data->array = data->local_array->array;
group = find_ref_group(data->local_array, access);
if (!group) {
data->global = 1;
return index;
}
tile = gpu_array_ref_group_tile(group);
data->global = !tile;
if (!tile)
return index;
space = isl_space_domain(isl_multi_aff_get_space(tile->tiling));
space = isl_space_range(isl_space_unwrap(space));
space = isl_space_map_from_set(space);
pma = isl_pw_multi_aff_identity(space);
sched2depth = isl_pw_multi_aff_copy(data->sched2copy);
dim = isl_pw_multi_aff_dim(sched2depth, isl_dim_out);
sched2depth = isl_pw_multi_aff_drop_dims(sched2depth, isl_dim_out,
tile->depth, dim - tile->depth);
pma = isl_pw_multi_aff_product(sched2depth, pma);
tiling = isl_multi_pw_aff_from_multi_aff(
isl_multi_aff_copy(tile->tiling));
tiling = isl_multi_pw_aff_pullback_pw_multi_aff(tiling, pma);
index = tile_outer(index, tiling);
return index;
}
/* Dereference "expr" by adding an index [0].
* The original "expr" is assumed not to have any indices.
*
* If "expr" is a member access, then the dereferencing needs
* to be applied to the structure argument of this member access.
*/
static __isl_give isl_ast_expr *dereference(__isl_take isl_ast_expr *expr)
{
isl_ctx *ctx;
isl_ast_expr *arg0, *res;
isl_ast_expr_list *list;
arg0 = isl_ast_expr_get_op_arg(expr, 0);
if (!arg0)
return isl_ast_expr_free(expr);
if (isl_ast_expr_get_type(arg0) == isl_ast_expr_op &&
isl_ast_expr_get_op_type(arg0) == isl_ast_op_member) {
isl_ast_expr *arg;
arg = isl_ast_expr_get_op_arg(arg0, 0);
arg = dereference(arg);
arg0 = isl_ast_expr_set_op_arg(arg0, 0, arg);
expr = isl_ast_expr_set_op_arg(expr, 0, arg0);
return expr;
}
isl_ast_expr_free(arg0);
ctx = isl_ast_expr_get_ctx(expr);
res = isl_ast_expr_from_val(isl_val_zero(ctx));
list = isl_ast_expr_list_from_ast_expr(res);
res = isl_ast_expr_get_op_arg(expr, 0);
res = isl_ast_expr_access(res, list);
isl_ast_expr_free(expr);
return res;
}
/* Linearize the index expression "expr" based on the array bounds
* of "array".
*
* That is, transform expression
*
* A[i_0][i_1]...[i_n]
*
* to
*
* A[(..((i_0 * b_1 + i_1) ... ) * b_n + i_n]
*
* where b_0, b_1, ..., b_n are the bounds on the array.
*
* If the base of "expr" is a member access, then the linearization needs
* to be applied to the structure argument of this member access.
*
* In the base case, if "expr" has no arguments (other than the name of
* the array), then we are passing an entire array to a function.
* In this case, there is nothing to linearize.
* Note that at this point an expression with no arguments can
* only be an entire array because the scalar case and
* the case of single struct are handled by the caller.
*
* If the number of specified index expressions in "expr"
* is smaller than the dimension of the accessed array,
* then the missing i_j also do not appear in the linearized expression.
* Furthermore, since such an expression does not refer to a single
* element while the default linearized expression would refer to
* a single element, we return the expression
*
* A + (..((i_0 * b_1 + i_1) ... ) * b_l + i_l)
*
* instead. Note that because of the special case handling above,
* we can assume here that there is at least one index expression.
*/
__isl_give isl_ast_expr *gpu_local_array_info_linearize_index(
struct gpu_local_array_info *array, __isl_take isl_ast_expr *expr)
{
int i, n;
isl_ast_expr *arg0;
isl_ast_expr *res;
isl_ast_expr_list *list;
arg0 = isl_ast_expr_get_op_arg(expr, 0);
if (isl_ast_expr_get_type(arg0) == isl_ast_expr_op &&
isl_ast_expr_get_op_type(arg0) == isl_ast_op_member) {
isl_ast_expr *arg;
arg = isl_ast_expr_get_op_arg(arg0, 0);
arg = gpu_local_array_info_linearize_index(array, arg);
arg0 = isl_ast_expr_set_op_arg(arg0, 0, arg);
expr = isl_ast_expr_set_op_arg(expr, 0, arg0);
return expr;
}
isl_ast_expr_free(arg0);
if (isl_ast_expr_get_op_n_arg(expr) == 1)
return expr;
n = isl_ast_expr_get_op_n_arg(expr);
res = isl_ast_expr_get_op_arg(expr, 1);
for (i = 1; i < array->n_index; ++i) {
isl_ast_expr *expr_i;
expr_i = isl_ast_expr_get_op_arg(array->bound_expr, 1 + i);
res = isl_ast_expr_mul(res, expr_i);
if (i + 1 >= n)
continue;
expr_i = isl_ast_expr_get_op_arg(expr, i + 1);
res = isl_ast_expr_add(res, expr_i);
}
if (1 + array->n_index > n) {
res = isl_ast_expr_add(isl_ast_expr_get_op_arg(expr, 0), res);
} else {
list = isl_ast_expr_list_from_ast_expr(res);
res = isl_ast_expr_get_op_arg(expr, 0);
res = isl_ast_expr_access(res, list);
}
isl_ast_expr_free(expr);
return res;
}
/* AST expression transformation callback for pet_stmt_build_ast_exprs.
*
* If the AST expression refers to an array that is not accessed
* at all, then this means the value of the expression is not used,
* so we might as well print zero (NULL pointer) instead.
*
* If the AST expression refers to a global scalar that is not
* a read-only scalar, then its address was passed to the kernel and
* we need to dereference it.
*
* If the AST expression refers to an access to a global array,
* then we linearize the access exploiting the bounds in data->local_array.
*/
static __isl_give isl_ast_expr *transform_expr(__isl_take isl_ast_expr *expr,
__isl_keep isl_id *id, void *user)
{
struct ppcg_transform_data *data = user;
if (!data->array)
return expr;
if (!data->array->accessed) {
isl_ctx *ctx;
ctx = isl_ast_expr_get_ctx(expr);
isl_ast_expr_free(expr);
return isl_ast_expr_from_val(isl_val_zero(ctx));
}
if (gpu_array_is_read_only_scalar(data->array))
return expr;
if (!data->global)
return expr;
if (data->array->n_index == 0)
return dereference(expr);
if (!data->array->linearize)
return expr;
return gpu_local_array_info_linearize_index(data->local_array, expr);
}
/* This function is called for each instance of a user statement
* in the kernel "kernel", identified by "gpu_stmt".
* "kernel" may be NULL if we are not inside a kernel.
*
* We attach a struct ppcg_kernel_stmt to the "node", containing
* a computed AST expression for each access, through an annotation
* with name "user".
* These AST expressions are computed from iterator_map,
* which expresses the domain
* elements in terms of the generated loops, and sched2copy,
* which expresses the outer copy_schedule_dim dimensions of
* the kernel schedule computed by PPCG in terms of the generated loops.
*/
static __isl_give isl_ast_node *create_domain_leaf(
struct ppcg_kernel *kernel, __isl_take isl_ast_node *node,
__isl_keep isl_ast_build *build, struct gpu_stmt *gpu_stmt)
{
struct ppcg_transform_data data;
struct ppcg_kernel_stmt *stmt;
isl_ctx *ctx;
isl_id *id;
isl_pw_multi_aff *sched2copy;
isl_map *map;
isl_pw_multi_aff *iterator_map;
isl_union_map *schedule;
if (!node)
return NULL;
ctx = isl_ast_node_get_ctx(node);
stmt = isl_calloc_type(ctx, struct ppcg_kernel_stmt);
if (!stmt)
return isl_ast_node_free(node);
schedule = isl_ast_build_get_schedule(build);
map = isl_map_reverse(isl_map_from_union_map(schedule));
iterator_map = isl_pw_multi_aff_from_map(map);
if (kernel)
sched2copy = compute_sched_to_copy(kernel,
isl_pw_multi_aff_copy(iterator_map));
else
sched2copy = NULL;
stmt->type = ppcg_kernel_domain;
stmt->u.d.stmt = gpu_stmt;
data.kernel = kernel;
data.accesses = stmt->u.d.stmt->accesses;
data.iterator_map = iterator_map;
data.sched2copy = sched2copy;
stmt->u.d.ref2expr = pet_stmt_build_ast_exprs(stmt->u.d.stmt->stmt,
build, &transform_index, &data,
&transform_expr, &data);
isl_pw_multi_aff_free(iterator_map);
isl_pw_multi_aff_free(sched2copy);
id = isl_id_alloc(ctx, "user", stmt);
id = isl_id_set_free_user(id, &ppcg_kernel_stmt_free);
if (!id)
ppcg_kernel_stmt_free(stmt);
return isl_ast_node_set_annotation(node, id);
}
/* This function is called for each statement node in the AST
* for copying to or from shared/private memory.
* Attach a pointer to a ppcg_kernel_stmt representing the copy
* statement to the node.
* The statement name is "read" or "write", depending on whether we are
* reading from global memory or writing to global memory.
*
* The schedule is of the form
*
* type[D -> A] -> L
*
* where D corresponds to the outer tile->depth dimensions of
* the kernel schedule, A to the global array and L to the outer
* generated AST schedule.
* We compute the inverse and strip off the type, resulting in
*
* L -> [D -> A]
*
* We combine this mapping with on the one hand the projection
*
* [D -> A] -> A
*
* and on the other hand the group tiling
*
* [D -> A] -> T
*
* resulting in
*
* L -> A and L -> T
*
* and store the corresponding expressions in stmt->index and stmt->local_index,
* where stmt points to the ppcg_kernel_stmt that is attached to the node.
* stmt->index is linearized if the global memory array is linearized.
*/
static __isl_give isl_ast_node *create_access_leaf(struct ppcg_kernel *kernel,
struct gpu_array_ref_group *group, __isl_take isl_ast_node *node,
__isl_keep isl_ast_build *build)
{
struct ppcg_kernel_stmt *stmt;
struct gpu_array_tile *tile;
isl_id *id;
isl_ast_expr *expr;
isl_space *space;
isl_map *access;
isl_pw_multi_aff *pma, *pma2;
const char *type;
stmt = isl_calloc_type(kernel->ctx, struct ppcg_kernel_stmt);
if (!stmt)
return isl_ast_node_free(node);
access = isl_map_from_union_map(isl_ast_build_get_schedule(build));
type = isl_map_get_tuple_name(access, isl_dim_in);
stmt->u.c.read = type && !strcmp(type, "read");
access = isl_map_reverse(access);
pma = isl_pw_multi_aff_from_map(access);
pma = isl_pw_multi_aff_reset_tuple_id(pma, isl_dim_out);
space = isl_space_range(isl_pw_multi_aff_get_space(pma));
space = isl_space_unwrap(space);
pma2 = isl_pw_multi_aff_range_map(space);
pma2 = isl_pw_multi_aff_pullback_pw_multi_aff(pma2,
isl_pw_multi_aff_copy(pma));
expr = isl_ast_build_access_from_pw_multi_aff(build, pma2);
if (group->array->linearize)
expr = gpu_local_array_info_linearize_index(group->local_array,
expr);
stmt->u.c.index = expr;
tile = gpu_array_ref_group_tile(group);
pma2 = isl_pw_multi_aff_from_multi_aff(
isl_multi_aff_copy(tile->tiling));
pma2 = isl_pw_multi_aff_pullback_pw_multi_aff(pma2, pma);
expr = isl_ast_build_access_from_pw_multi_aff(build, pma2);
stmt->u.c.local_index = expr;
stmt->u.c.array = group->array;
stmt->u.c.local_array = group->local_array;
stmt->type = ppcg_kernel_copy;
id = isl_id_alloc(kernel->ctx, "copy", stmt);
id = isl_id_set_free_user(id, &ppcg_kernel_stmt_free);
if (!id)
ppcg_kernel_stmt_free(stmt);
return isl_ast_node_set_annotation(node, id);
}
/* Create a synchronization ppcg_kernel_stmt and
* attach it to the node "node" representing the synchronization.
*/
static __isl_give isl_ast_node *create_sync_leaf(
struct ppcg_kernel *kernel, __isl_take isl_ast_node *node,
__isl_keep isl_ast_build *build)
{
struct ppcg_kernel_stmt *stmt;
isl_id *id;
stmt = isl_calloc_type(kernel->ctx, struct ppcg_kernel_stmt);
if (!stmt)
return isl_ast_node_free(node);
stmt->type = ppcg_kernel_sync;
id = isl_id_alloc(kernel->ctx, "sync", stmt);
id = isl_id_set_free_user(id, &ppcg_kernel_stmt_free);
if (!id)
ppcg_kernel_stmt_free(stmt);
return isl_ast_node_set_annotation(node, id);
}
/* Build AST expressions for the device array sizes of all arrays in "prog"
* that require allocation on the device using "build", as well as
* for the original array sizes of all arrays that need to be declared
* on the host.
* "node" is freed in case of error.
*/
static __isl_give isl_ast_node *build_array_bounds(
__isl_take isl_ast_node *node, struct gpu_prog *prog,
__isl_keep isl_ast_build *build)
{
int i;
for (i = 0; i < prog->n_array; ++i) {
struct gpu_array_info *array = &prog->array[i];
isl_multi_pw_aff *size;
isl_ast_expr *expr;
if (!gpu_array_requires_device_allocation(array))
continue;
size = isl_multi_pw_aff_copy(array->bound);
expr = ppcg_build_size_expr(size, build);
array->bound_expr = expr;
if (!expr)
return isl_ast_node_free(node);
}
for (i = 0; i < prog->n_array; ++i) {
struct gpu_array_info *array = &prog->array[i];
isl_set *extent;
isl_multi_pw_aff *size;
isl_ast_expr *expr;
if (!array->declare_local)
continue;
extent = isl_set_copy(array->declared_extent);
size = ppcg_size_from_extent(extent);
expr = ppcg_build_size_expr(size, build);
array->declared_size = expr;
if (!expr)
return isl_ast_node_free(node);
}
return node;
}
/* Internal data structure for at_domain.
*
* "prog" represents the entire scop.
* "kernel" points to the kernel to which the current schedule node
* belongs. It is set by before_mark and reset by after_mark.
* It may be NULL if we are outside any kernel.
*/
struct ppcg_at_domain_data {
struct gpu_prog *prog;
struct ppcg_kernel *kernel;
};
/* This function is called for each instance of a user statement
* in the kernel. This may be one of the original user statements
* or a statement introduced by PPCG.
*
* We first check if the statement id corresponds to a gpu statement,
* which indicates the statement is an original user statement. Any statement
* that is not an original user statement has been introduced by PPCG and
* requires special handling.
*
* If the user statement is one of the original user statements, then we call
* create_domain_leaf. If it is "init_device", then we call
* build_array_bounds. Otherwise, we check if it is a copy or synchronization
* statement and call the appropriate functions. Statements that copy an array
* to/from the device do not need any further treatment.
* Neither does "clear_device".
*/
static __isl_give isl_ast_node *at_domain(__isl_take isl_ast_node *node,
__isl_keep isl_ast_build *build, void *user)
{
struct ppcg_at_domain_data *data = user;
struct gpu_stmt *gpu_stmt;
isl_ast_expr *expr, *arg;
isl_id *id;
int is_sync;
const char *name;
void *p;
expr = isl_ast_node_user_get_expr(node);
arg = isl_ast_expr_get_op_arg(expr, 0);
id = isl_ast_expr_get_id(arg);
name = isl_id_get_name(id);
p = isl_id_get_user(id);
isl_ast_expr_free(expr);
isl_ast_expr_free(arg);
gpu_stmt = find_stmt(data->prog, id);
is_sync = gpu_tree_id_is_sync(id, data->kernel);
isl_id_free(id);
if (gpu_stmt)
return create_domain_leaf(data->kernel, node, build, gpu_stmt);
if (!prefixcmp(name, "to_device_") || !prefixcmp(name, "from_device_"))
return node;
if (!strcmp(name, "init_device"))
return build_array_bounds(node, data->prog, build);
if (!strcmp(name, "clear_device"))
return node;
if (is_sync < 0)
return isl_ast_node_free(node);
if (!strcmp(name, "read") || !strcmp(name, "write")) {
struct gpu_array_ref_group *group = p;
return create_access_leaf(data->kernel, group, node, build);
}
if (!is_sync)
isl_die(data->prog->ctx, isl_error_internal,
"unknown statement type",
return isl_ast_node_free(node));
return create_sync_leaf(data->kernel, node, build);
}
/* Given a set of wrapped references "ref", return the corresponding
* access relations based on the tagged access relations "tagged".
*
* The elements of "ref" are of the form
*
* [D -> R]
*
* with D an iteration domains and R a reference.
* The elements of "tagged" are of the form
*
* [D -> R] -> A
*
* with A an array.
*
* Extend "tagged" to include the iteration domain in the range, i.e.,
*
* [D -> R] -> [D -> A]
*
* apply the result to "ref" and then unwrap the resulting set
* to obtain relations of the form
*
* D -> A
*/
static __isl_give isl_union_map *wrapped_reference_to_access(
__isl_take isl_union_set *ref, __isl_take isl_union_map *tagged)
{
isl_union_map *tag2access;
tag2access = isl_union_map_copy(tagged);
tag2access = isl_union_map_universe(tag2access);
tag2access = isl_union_set_unwrap(isl_union_map_domain(tag2access));
tag2access = isl_union_map_domain_map(tag2access);
tag2access = isl_union_map_range_product(tag2access, tagged);
ref = isl_union_set_coalesce(ref);
ref = isl_union_set_apply(ref, tag2access);
return isl_union_set_unwrap(ref);
}
/* Given an access relation "access" from one or more array reference groups,
* remove those reads if ("read" is 1) or writes (if "read" is 0)
* that are only needed to communicate data within
* the same iteration of "sched".
* The domain of "sched" corresponds to the original statement instances,
* i.e., those that appear in the domains of the access relations.
* "tagged" contains all tagged access relations to all
* the array reference groups accessed by "access" from statement
* instances scheduled by "sched".
*
* If the access is a read then it is either an element of
*
* live_in union (range flow)
*
* where live_in and flow may be overapproximations, or
* it reads an uninitialized value (that is not live-in because
* there is an intermediate kill) or it reads a value that was
* written within the same (compound) statement instance.
* If the access is a write then it is either an element of
*
* live_out union (domain flow)
*
* or it writes a value that is never read (and is not live-out
* because of an intermediate kill) or only
* within the same (compound) statement instance.
* In both cases, the access relation is also a subset of
* the group access relation.
*
* The cases where an uninitialized value is read or a value is written
* that is never read or where the dataflow occurs within a statement
* instance are also considered local and may also be removed.
*
* Essentially, we compute the intersection of "access" with either
*
* live_in union (range non-local-flow)
*
* or
*
* live_out union (domain non-local-flow)
*
* We first construct a relation "local"
*
* [[D -> R] -> [D' -> R']]
*
* of pairs of domain iterations accessing the reference group
* and references in the group that are coscheduled by "sched".
*
* If this relation does not intersect the dataflow dependences,
* then there is nothing we can possibly remove, unless the dataflow
* dependences themselves only relate a subset of the accesses.
* In particular, the accesses may not be involved in any dataflow
* dependences, either because they are uninitialized reads/dead writes
* or because the dataflow occurs inside a statement instance.
*
* Since the computation below may break up the access relation
* into smaller pieces, we only perform the intersection with
* the non-local dependent accesses if the local pairs
* intersect the dataflow dependences. Otherwise, we intersect
* with the universe of the non-local dependent accesses.
* This should at least remove accesses from statements that
* do not participate in any dependences.
*
* In particular, we remove the "local" dataflow dependences from
* the set of all dataflow dependences, or at least those
* that may contribute to a domain/range that intersects
* the domain of "access".
* Note that if the potential dataflow dependences are an overapproximation
* of the actual dataflow dependences, then the result remains an
* overapproximation of the non-local dataflow dependences.
* Copying to/from global memory is only needed for the references
* in the domain/range of the result or for accesses that are live out/in
* for the entire scop.
*
* We therefore map the domain/range of the "external" relation
* to the corresponding access relation and take the union with
* the live out/in relation.
*/
static __isl_give isl_union_map *remove_local_accesses(
struct gpu_prog *prog, __isl_take isl_union_map *tagged,
__isl_take isl_union_map *access, __isl_take isl_union_map *sched,
int read)
{
int empty;
isl_union_pw_multi_aff *tagger;
isl_union_set *domain, *access_domain;
isl_union_map *local, *external, *universe;
isl_union_set *tag_set;
if (isl_union_map_is_empty(access)) {
isl_union_map_free(sched);
isl_union_map_free(tagged);
return access;
}
tagger = isl_union_pw_multi_aff_copy(prog->scop->tagger);
domain = isl_union_map_domain(isl_union_map_copy(tagged));
tagger = isl_union_pw_multi_aff_intersect_domain(tagger,
isl_union_set_copy(domain));
sched = isl_union_map_preimage_domain_union_pw_multi_aff(sched, tagger);
local = isl_union_map_apply_range(sched,
isl_union_map_reverse(isl_union_map_copy(sched)));
local = isl_union_map_intersect(local,
isl_union_map_copy(prog->scop->tagged_dep_flow));
empty = isl_union_map_is_empty(local);
external = isl_union_map_copy(prog->scop->tagged_dep_flow);
universe = isl_union_map_universe(isl_union_map_copy(access));
access_domain = isl_union_map_domain(universe);
domain = isl_union_set_universe(domain);
universe = isl_union_set_unwrap(domain);
universe = isl_union_map_intersect_domain(universe, access_domain);
domain = isl_union_map_wrap(universe);
if (read)
external = isl_union_map_intersect_range(external, domain);
else
external = isl_union_map_intersect_domain(external, domain);
external = isl_union_map_intersect_params(external,
isl_set_copy(prog->scop->context));
external = isl_union_map_subtract(external, local);
if (read) {
tag_set = isl_union_map_range(external);
external = wrapped_reference_to_access(tag_set, tagged);
external = isl_union_map_union(external,
isl_union_map_copy(prog->scop->live_in));
} else {
tag_set = isl_union_map_domain(external);
external = wrapped_reference_to_access(tag_set, tagged);
external = isl_union_map_union(external,
isl_union_map_copy(prog->scop->live_out));
}
if (empty < 0)
external = isl_union_map_free(external);
else if (empty)
external = isl_union_map_universe(external);
access = isl_union_map_intersect(access, external);
return access;
}
/* Given an access relation "access" from "group", remove those reads
* if ("read" is 1) or writes (if "read" is 0) that are only needed to
* communicate data within the same iteration of the schedule "prefix"
* at the position where the copying of the group is inserted.
* That is, the output dimension of "prefix"
* is equal to tile->depth.
* The domain of "prefix" corresponds to the original statement instances,
* i.e., those that appear in the domains of the access relations.
*
* Extract the tagged access relation of "group" and
* then call remove_local_accesses.
*/
static __isl_give isl_union_map *remove_local_accesses_group(
struct ppcg_kernel *kernel, struct gpu_array_ref_group *group,
__isl_take isl_union_map *access, __isl_keep isl_union_map *prefix,
int read)
{
isl_union_map *sched, *tagged;
if (isl_union_map_is_empty(access))
return access;
tagged = group_tagged_access_relation(group);
sched = isl_union_map_copy(prefix);
return remove_local_accesses(kernel->prog, tagged, access, sched, read);
}
/* Build an access AST expression for the effective grid size using "build".
* Store the result in kernel->grid_size_expr.
*/
static isl_stat build_grid_size(struct ppcg_kernel *kernel,
__isl_keep isl_ast_build *build)
{
isl_multi_pw_aff *size;
size = isl_multi_pw_aff_copy(kernel->grid_size);
size = isl_multi_pw_aff_set_tuple_name(size, isl_dim_out, "grid");
kernel->grid_size_expr = ppcg_build_size_expr(size, build);
if (!kernel->grid_size_expr)
return isl_stat_error;
return isl_stat_ok;
}
/* Build access AST expressions for the localized array sizes using "build".
* Store the result in local->bound_expr.
* Only do this for arrays for which localized bounds have been computed.
*/
static isl_stat build_local_array_sizes(struct ppcg_kernel *kernel,
__isl_keep isl_ast_build *build)
{
int i;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *local = &kernel->array[i];
isl_multi_pw_aff *size;
if (local->n_group == 0)
continue;
size = isl_multi_pw_aff_copy(local->bound);
local->bound_expr = ppcg_build_size_expr(size, build);
if (!local->bound_expr)
return isl_stat_error;
}
return isl_stat_ok;
}
/* Build access AST expressions for the effective grid size and
* the localized array sizes using "build".
*/
static isl_stat build_grid_and_local_array_sizes(struct ppcg_kernel *kernel,
__isl_keep isl_ast_build *build)
{
if (build_grid_size(kernel, build) < 0)
return isl_stat_error;
if (build_local_array_sizes(kernel, build) < 0)
return isl_stat_error;
return isl_stat_ok;
}
/* This function is called before the AST generator starts traversing
* the schedule subtree of a node with mark "mark".
*
* If the mark is called "kernel", store the kernel pointer in data->kernel
* for use in at_domain and build AST expressions for the grid size and
* the localized array sizes.
*/
static isl_stat before_mark(__isl_keep isl_id *mark,
__isl_keep isl_ast_build *build, void *user)
{
struct ppcg_at_domain_data *data = user;
if (!mark)
return isl_stat_error;
if (!strcmp(isl_id_get_name(mark), "kernel")) {
data->kernel = isl_id_get_user(mark);
if (build_grid_and_local_array_sizes(data->kernel, build) < 0)
return isl_stat_error;
}
return isl_stat_ok;
}
/* This function is called after the AST generator has finished traversing
* the schedule subtree of a mark node. "node" points to the corresponding
* mark AST node.
*
* If the mark is called "kernel", then replace "node" by a user node
* that "calls" the kernel, representing the launch of the kernel.
* The original "node" is stored inside the kernel object so that
* it can be used to print the device code.
* Note that this assumes that a kernel is only launched once.
* Also clear data->kernel.
*/
static __isl_give isl_ast_node *after_mark(__isl_take isl_ast_node *node,
__isl_keep isl_ast_build *build, void *user)
{
isl_ctx *ctx;
isl_id *id;
isl_ast_expr *expr;
isl_ast_expr_list *list;
struct ppcg_kernel *kernel;
struct ppcg_at_domain_data *data = user;
ctx = isl_ast_node_get_ctx(node);
id = isl_ast_node_mark_get_id(node);
if (!id)
return isl_ast_node_free(node);
if (strcmp(isl_id_get_name(id), "kernel") || !data->kernel) {
isl_id_free(id);
return node;
}
kernel = data->kernel;
data->kernel = NULL;
kernel->space = isl_ast_build_get_schedule_space(build);
kernel->tree = isl_ast_node_mark_get_node(node);
isl_ast_node_free(node);
expr = isl_ast_expr_from_id(isl_id_copy(id));
list = isl_ast_expr_list_alloc(ctx, 0);
expr = isl_ast_expr_call(expr, list);
node = isl_ast_node_alloc_user(expr);
node = isl_ast_node_set_annotation(node, id);
return node;
}
static isl_bool update_depth(__isl_keep isl_schedule_node *node, void *user)
{
int *depth = user;
int node_depth;
if (isl_schedule_node_get_type(node) != isl_schedule_node_leaf)
return isl_bool_true;
node_depth = isl_schedule_node_get_schedule_depth(node);
if (node_depth > *depth)
*depth = node_depth;
return isl_bool_false;
}
/* Use isl to generate code for both the host and the device
* from "schedule".
* The device code is marked by "kernel" mark nodes in the schedule tree,
* containing a pointer to a ppcg_kernel object.
* The returned AST only contains the AST for the host code.
* The ASTs for the device code are embedded in ppcg_kernel objects
* attached to the leaf nodes that call "kernel".
*/
static __isl_give isl_ast_node *generate_code(struct gpu_gen *gen,
__isl_take isl_schedule *schedule)
{
struct ppcg_at_domain_data data;
isl_ast_build *build;
isl_ast_node *tree;
isl_id_list *iterators;
int depth;
data.prog = gen->prog;
data.kernel = NULL;
depth = 0;
if (isl_schedule_foreach_schedule_node_top_down(schedule, &update_depth,
&depth) < 0)
schedule = isl_schedule_free(schedule);
build = isl_ast_build_alloc(gen->prog->ctx);
iterators = ppcg_scop_generate_names(gen->prog->scop, depth, "c");
build = isl_ast_build_set_iterators(build, iterators);
build = isl_ast_build_set_at_each_domain(build, &at_domain, &data);
build = isl_ast_build_set_before_each_mark(build, &before_mark, &data);
build = isl_ast_build_set_after_each_mark(build, &after_mark, &data);
if (gen->prog->scop->options->debug->dump_final_schedule)
isl_schedule_dump(schedule);
tree = isl_ast_build_node_from_schedule(build, schedule);
isl_ast_build_free(build);
return tree;
}
__isl_give isl_union_map *extract_sizes_from_str(isl_ctx *ctx, const char *str)
{
if (!str)
return NULL;
return isl_union_map_read_from_str(ctx, str);
}
/* Can "node" be tiled and then mapped to block and thread identifiers?
* That is, is it permutable with at least one coincident dimension?
*/
static isl_bool is_permutable(__isl_keep isl_schedule_node *node)
{
if (!node)
return isl_bool_error;
if (isl_schedule_node_get_type(node) != isl_schedule_node_band)
return isl_bool_false;
if (!isl_schedule_node_band_get_permutable(node))
return isl_bool_false;
if (isl_schedule_node_band_n_member(node) < 1)
return isl_bool_false;
if (!isl_schedule_node_band_member_get_coincident(node, 0))
return isl_bool_false;
return isl_bool_true;
}
/* Is "node" not a suitably permutable band?
*/
static isl_bool not_permutable(__isl_keep isl_schedule_node *node, void *user)
{
return isl_bool_not(is_permutable(node));
}
/* Does the subtree rooted at "node" have any suitably permutable band nodes?
* That is, does it have any nodes that are permutable and that
* have a least one coincident dimension?
*/
static isl_bool subtree_has_permutable_bands(__isl_keep isl_schedule_node *node)
{
isl_bool all_non_permutable;
all_non_permutable = isl_schedule_node_every_descendant(node,
&not_permutable, NULL);
return isl_bool_not(all_non_permutable);
}
/* Does "schedule" contain any permutable band with at least one coincident
* member?
*/
static isl_bool has_any_permutable_node(__isl_keep isl_schedule *schedule)
{
isl_schedule_node *root;
isl_bool any_permutable;
root = isl_schedule_get_root(schedule);
any_permutable = subtree_has_permutable_bands(root);
isl_schedule_node_free(root);
return any_permutable;
}
/* Is "node" a candidate for mapping to block and thread identifiers?
* In particular, is it permutable with at least one coincident dimension?
* Alternatively, does the subtree rooted at "node" not contain
* any such permutable node? Filter nodes are skipped in this case,
* because a band node will be inserted in front of the returned
* node and this is not possible for filter nodes that are children
* of set or sequence nodes.
*/
static int is_candidate(__isl_keep isl_schedule_node *node)
{
isl_bool permutable;
if (isl_schedule_node_get_type(node) == isl_schedule_node_leaf)
return 1;
permutable = is_permutable(node);
if (permutable < 0 || permutable)
return permutable;
if (isl_schedule_node_get_type(node) == isl_schedule_node_filter)
return 0;
permutable = subtree_has_permutable_bands(node);
if (permutable < 0)
return -1;
return !permutable;
}
/* Is "node" the outermost node in its branch that can be tiled
* and then mapped to block and thread identifiers?
* If there are no such nodes in the subtree at "node" and
* if "node" is not a filter node, then it is accepted too.
*/
static int is_outer_tilable(__isl_keep isl_schedule_node *node)
{
int tilable;
isl_schedule_node *ancestor;
tilable = is_candidate(node);
if (tilable < 0)
return -1;
if (!tilable)
return 0;
tilable = 0;
ancestor = isl_schedule_node_copy(node);
while (isl_schedule_node_has_parent(ancestor)) {
ancestor = isl_schedule_node_parent(ancestor);
tilable = is_candidate(ancestor);
if (tilable < 0 || tilable)
break;
}
isl_schedule_node_free(ancestor);
return tilable < 0 ? -1 : !tilable;
}
/* Collect the references to all writes in "group".
* Each reference is represented by a universe set in a space
*
* [S[i,j] -> R[]]
*
* with S[i,j] the statement instance space and R[] the array reference.
*/
static __isl_give isl_union_set *group_tagged_writes(
struct gpu_array_ref_group *group)
{
int i;
isl_space *space;
isl_union_set *writes;
space = isl_map_get_space(group->access);
writes = isl_union_set_empty(space);
for (i = 0; i < group->n_ref; ++i) {
isl_space *space;
isl_set *writes_i;
if (!group->refs[i]->write)
continue;
space = isl_map_get_space(group->refs[i]->tagged_access);
space = isl_space_domain(space);
writes_i = isl_set_universe(space);
writes = isl_union_set_add_set(writes, writes_i);
}
return writes;
}
/* Is there any write access in "group" that requires synchronization
* on a write to global memory?
* We currently take into account all writes that would require
* synchronization at the thread level depth, but if the copying
* for this group is performed at an outer level, then we do not
* actually need to take into account dependences at intermediate levels.
*/
static int any_sync_writes_in_group(struct ppcg_kernel *kernel,
struct gpu_array_ref_group *group)
{
isl_union_set *writes;
int empty, disjoint;
empty = isl_union_set_is_empty(kernel->sync_writes);
if (empty < 0)
return -1;
if (empty)
return 0;
writes = group_tagged_writes(group);
disjoint = isl_union_set_is_disjoint(kernel->sync_writes, writes);
isl_union_set_free(writes);
return disjoint < 0 ? -1 : !disjoint;
}
/* Collect the references to all writes in "kernel" that write directly
* to global or shared memory, i.e., that are not mapped to private memory.
* Each reference is represented by a universe set in a space
*
* [S[i,j] -> R[]]
*
* with S[i,j] the statement instance space and R[] the array reference.
*/
static __isl_give isl_union_set *collect_non_private_tagged_writes(
struct ppcg_kernel *kernel)
{
isl_union_set *writes;
int i, j;
writes = isl_union_set_empty(isl_union_set_get_space(kernel->arrays));
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j) {
struct gpu_array_ref_group *group = array->groups[j];
enum ppcg_group_access_type type;
isl_union_set *writes_ij;
if (!group->write)
continue;
type = gpu_array_ref_group_type(group);
if (type == ppcg_access_private)
continue;
writes_ij = group_tagged_writes(group);
writes = isl_union_set_union(writes, writes_ij);
}
}
return writes;
}
/* Are there any direct writes to global memory that require
* synchronization?
*/
static int any_global_or_shared_sync_writes(struct ppcg_kernel *kernel)
{
isl_union_set *writes;
int empty, disjoint;
empty = isl_union_set_is_empty(kernel->sync_writes);
if (empty < 0)
return -1;
if (empty)
return 0;
writes = collect_non_private_tagged_writes(kernel);
disjoint = isl_union_set_is_disjoint(kernel->sync_writes, writes);
isl_union_set_free(writes);
return disjoint < 0 ? -1 : !disjoint;
}
/* Construct an isl_multi_val for use as tile sizes for tiling "node"
* from the elements in "tile_size".
*/
static __isl_give isl_multi_val *construct_band_tiles_sizes(
__isl_keep isl_schedule_node *node, int *tile_size)
{
isl_space *space;
if (!node)
return NULL;
space = isl_schedule_node_band_get_space(node);
return ppcg_multi_val_from_int_list(space, tile_size);
}
/* Replace the partial schedule S of the band node "node" by
*
* floor(S/f)
*
* or
*
* f * floor(S/f)
*
* if scale_tile_loops is set, with f the integers in "factor".
* The list that "factor" points to is assumed to contain at least
* as many elements as the number of members in the band.
*/
static __isl_give isl_schedule_node *snap_band_to_sizes(
__isl_take isl_schedule_node *node, int *factor,
struct ppcg_options *options)
{
isl_multi_val *mv;
mv = construct_band_tiles_sizes(node, factor);
node = isl_schedule_node_band_scale_down(node, isl_multi_val_copy(mv));
if (options->scale_tile_loops)
node = isl_schedule_node_band_scale(node,
isl_multi_val_copy(mv));
isl_multi_val_free(mv);
return node;
}
/* Tile "band" with tile size specified by "sizes".
*
* Since the tile loops will be mapped to block ids, we forcibly
* turn off tile loop scaling. We may want to enable tile loop scaling
* at some later point, but then we would have to support the detection
* of strides during the mapping to block ids.
* Similarly, since the point loops will be mapped to thread ids,
* we forcibly shift the point loops so that they start at zero.
*/
static __isl_give isl_schedule_node *tile_band(
__isl_take isl_schedule_node *node, __isl_take isl_multi_val *sizes)
{
isl_ctx *ctx = isl_schedule_node_get_ctx(node);
int scale_tile;
int shift_point;
scale_tile = isl_options_get_tile_scale_tile_loops(ctx);
isl_options_set_tile_scale_tile_loops(ctx, 0);
shift_point = isl_options_get_tile_shift_point_loops(ctx);
isl_options_set_tile_shift_point_loops(ctx, 1);
node = ppcg_tile(node, sizes);
isl_options_set_tile_scale_tile_loops(ctx, scale_tile);
isl_options_set_tile_shift_point_loops(ctx, shift_point);
return node;
}
/* Extract the set of parameter values and outer schedule dimensions
* for which any statement instance
* in the kernel inserted at "node" needs to be executed.
* Intersect the set of parameter values derived from the host schedule
* relation with the context of "prog".
*/
static __isl_give isl_set *extract_context(__isl_keep isl_schedule_node *node,
struct gpu_prog *prog)
{
isl_union_map *schedule;
isl_union_set *schedule_domain;
isl_set *context;
int empty;
schedule = isl_schedule_node_get_prefix_schedule_relation(node);
schedule_domain = isl_union_map_range(schedule);
empty = isl_union_set_is_empty(schedule_domain);
if (empty < 0) {
isl_union_set_free(schedule_domain);
return NULL;
}
if (empty) {
int depth;
isl_space *space;
space = isl_union_set_get_space(schedule_domain);
isl_union_set_free(schedule_domain);
space = isl_space_set_from_params(space);
depth = isl_schedule_node_get_schedule_depth(node);
space = isl_space_add_dims(space, isl_dim_set, depth);
context = isl_set_empty(space);
} else {
context = isl_set_from_union_set(schedule_domain);
}
context = isl_set_intersect_params(context,
isl_set_copy(prog->context));
return context;
}
/* Return the set of outer array elements accessed by
* by the statement instances in "domain" in "prog".
* The instances in "domain" are those that appear
* in the domains of the access relations in "prog".
*/
static __isl_give isl_union_set *accessed_by_domain(
__isl_take isl_union_set *domain, struct gpu_prog *prog)
{
isl_union_map *access;
isl_union_set *arrays;
access = isl_union_map_union(isl_union_map_copy(prog->read),
isl_union_map_copy(prog->may_write));
access = isl_union_map_intersect_domain(access, domain);
arrays = isl_union_map_range(access);
arrays = isl_union_set_apply(arrays,
isl_union_map_copy(prog->to_outer));
return arrays;
}
/* Return the number of outer band members of the band node "node"
* that are marked coincident.
*/
static int n_outer_coincidence(__isl_keep isl_schedule_node *node)
{
int i, n;
n = isl_schedule_node_band_n_member(node);
for (i = 0; i < n; ++i)
if (!isl_schedule_node_band_member_get_coincident(node, i))
break;
return i;
}
/* If the band node "node" has more than "n" members, then split off
* the first "n" of them.
*/
static __isl_give isl_schedule_node *split_band(
__isl_take isl_schedule_node *node, int n)
{
int dim;
dim = isl_schedule_node_band_n_member(node);
if (n < dim)
node = isl_schedule_node_band_split(node, n);
return node;
}
/* Scale a band node that may have been split by split_band.
* "sizes" are the scaling factors for the original node.
* "node" either points to the original band node, or the outer
* of the two pieces after splitting.
*
* If the number of elements in "node" is smaller than the number of
* elements in "sizes", then some splitting has occurred and we split
* "sizes" in the same way.
*/
static __isl_give isl_schedule_node *scale_band(
__isl_take isl_schedule_node *node, __isl_take isl_multi_val *sizes)
{
int n, dim;
n = isl_multi_val_dim(sizes, isl_dim_set);
dim = isl_schedule_node_band_n_member(node);
if (n > dim) {
isl_multi_val *sizes2;
sizes2 = isl_multi_val_copy(sizes);
sizes = isl_multi_val_drop_dims(sizes,
isl_dim_set, dim, n - dim);
sizes2 = isl_multi_val_drop_dims(sizes2, isl_dim_set, 0, dim);
node = isl_schedule_node_child(node, 0);
node = isl_schedule_node_band_scale(node, sizes2);
node = isl_schedule_node_parent(node);
}
return isl_schedule_node_band_scale(node, sizes);
}
/* Return an isl_multi_aff, with as elements the parameters in "space"
* that have the names specified by the elements in "names".
* If (some of) these parameters do not already appear in "space",
* then they are added first.
*/
static __isl_give isl_multi_aff *parameter_vector(__isl_take isl_space *space,
__isl_keep isl_id_list *names)
{
int i, n;
isl_local_space *ls;
isl_multi_aff *ma;
if (!names)
space = isl_space_free(space);
n = isl_id_list_n_id(names);
for (i = 0; i < n; ++i) {
int pos;
isl_id *id;
id = isl_id_list_get_id(names, i);
pos = isl_space_find_dim_by_id(space, isl_dim_param, id);
if (pos >= 0) {
isl_id_free(id);
continue;
}
pos = isl_space_dim(space, isl_dim_param);
space = isl_space_add_dims(space, isl_dim_param, 1);
space = isl_space_set_dim_id(space, isl_dim_param, pos, id);
}
ma = isl_multi_aff_zero(isl_space_copy(space));
ls = isl_local_space_from_space(isl_space_domain(space));
for (i = 0; i < n; ++i) {
int pos;
isl_id *id;
isl_aff *aff;
id = isl_id_list_get_id(names, i);
pos = isl_space_find_dim_by_id(space, isl_dim_param, id);
isl_id_free(id);
aff = isl_aff_var_on_domain(isl_local_space_copy(ls),
isl_dim_param, pos);
ma = isl_multi_aff_set_aff(ma, i, aff);
}
isl_local_space_free(ls);
return ma;
}
/* Return constraints on the domain elements that equate a sequence of
* parameters called "names", to the partial schedule
* of "node" modulo the integers in "size".
* The number of elements in the array "size" should be equal
* to the number of elements in "names".
* The number of members of the band node "node" should be smaller
* than or equal to this number. If it is smaller, then the first
* elements of "names" are equated to zero.
*/
static __isl_give isl_union_set *set_schedule_modulo(
__isl_keep isl_schedule_node *node, __isl_keep isl_id_list *names,
int *size)
{
int n, n_zero;
isl_space *space;
isl_multi_aff *ma;
isl_multi_union_pw_aff *mupa, *mupa2;
isl_multi_val *mv;
isl_union_set *domain;
if (!node)
return NULL;
n = isl_id_list_n_id(names);
if (n == 0)
return isl_schedule_node_get_universe_domain(node);
n_zero = n - isl_schedule_node_band_n_member(node);
mupa = isl_schedule_node_band_get_partial_schedule(node);
mv = construct_band_tiles_sizes(node, size + n_zero);
mupa = isl_multi_union_pw_aff_mod_multi_val(mupa, mv);
space = isl_multi_union_pw_aff_get_space(mupa);
space = isl_space_params(space);
space = isl_space_set_from_params(space);
space = isl_space_add_dims(space, isl_dim_set, n_zero);
ma = isl_multi_aff_zero(space);
domain = isl_schedule_node_get_universe_domain(node);
mupa2 = isl_multi_union_pw_aff_multi_aff_on_domain(
isl_union_set_copy(domain), ma);
mupa = isl_multi_union_pw_aff_range_product(mupa2, mupa);
space = isl_multi_union_pw_aff_get_space(mupa);
ma = parameter_vector(space, names);
mupa2 = isl_multi_union_pw_aff_multi_aff_on_domain(domain, ma);
mupa = isl_multi_union_pw_aff_sub(mupa, mupa2);
return isl_multi_union_pw_aff_zero_union_set(mupa);
}
/* Insert a context node at "node" introducing the block and thread
* identifiers along with their bounds, which are stored in kernel->grid_size
* and kernel->block_dim.
* Note that the bounds on the block identifiers may implicitly impose
* constraints on the parameters. A guard needs to be inserted
* in the schedule tree to ensure that those bounds hold at "node".
* This guard is inserted in insert_guard.
*/
static __isl_give isl_schedule_node *insert_context(struct ppcg_kernel *kernel,
__isl_take isl_schedule_node *node)
{
isl_set *context;
context = isl_set_universe(isl_set_get_space(kernel->context));
context = add_bounded_parameters_dynamic(context,
kernel->grid_size, kernel->block_ids);
context = add_bounded_parameters(context,
kernel->block_dim, kernel->thread_ids);
node = isl_schedule_node_insert_context(node, context);
return node;
}
/* Insert a guard that eliminates kernel launches where the kernel
* obviously does not have any work to do.
*
* In particular, eliminate kernel launches where there are obviously
* zero blocks.
* Use the same block size constraints that are used to create the context
* to ensure that all constraints implicit in the constructed context
* are imposed by the guard.
*
* Additionally, add other constraints that are valid
* for each executed instance ("context"), as long as this does not result
* in a disjunction.
*/
static __isl_give isl_schedule_node *insert_guard(
__isl_take isl_schedule_node *node, __isl_keep isl_set *context,
__isl_keep isl_multi_pw_aff *size, struct ppcg_scop *scop)
{
unsigned nparam, n;
isl_set *guard;
isl_id_list *ids;
guard = isl_set_copy(context);
guard = isl_set_compute_divs(guard);
guard = isl_set_from_basic_set(isl_set_simple_hull(guard));
nparam = isl_set_dim(guard, isl_dim_param);
n = isl_multi_pw_aff_dim(size, isl_dim_out);
ids = ppcg_scop_generate_names(scop, n, "__ppcg_tmp");
guard = add_bounded_parameters_dynamic(guard, size, ids);
isl_id_list_free(ids);
guard = isl_set_project_out(guard, isl_dim_param, nparam, n);
node = isl_schedule_node_insert_guard(node, guard);
return node;
}
/* Does any array reference group mapping require the band that is mapped
* to threads to be unrolled?
*/
static int kernel_requires_unroll(struct ppcg_kernel *kernel)
{
int i, j;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j) {
struct gpu_array_ref_group *group = array->groups[j];
if (gpu_array_ref_group_requires_unroll(group))
return 1;
}
}
return 0;
}
/* Mark the given band node "node" for unrolling by the AST generator and
* then sink it to the leaves of the schedule tree.
* All dimensions of "node" are assumed to be coincident, such that this
* sinking is a valid operation.
*/
static __isl_give isl_schedule_node *unroll(__isl_take isl_schedule_node *node)
{
node = ppcg_set_schedule_node_type(node, isl_ast_loop_unroll);
node = isl_schedule_node_band_sink(node);
return node;
}
/* Insert a synchronization node in the schedule tree of "node"
* after the core computation of "kernel" at the level of the band
* that is mapped to threads, except if that level is equal to
* that of the band that is mapped to blocks or if there are no writes
* to global or shared memory in the core computation that require
* synchronization.
* If there are any writes to shared memory and the shared memory
* copying is performed at the same level, then synchronization
* is needed between the core and the copying anyway, so we might
* as well add it here. If the copying is performed at a higher
* level, then different iterations of intermediate schedule dimensions
* may have a different mapping from between shared memory elements and
* threads, such that synchronization is required after the core.
* "node" is assumed to point to the kernel node.
*
* If the shared and the thread mark point to the same node, then make
* sure the synchronization is inserted outside of the shared mark.
*/
static __isl_give isl_schedule_node *add_sync(struct ppcg_kernel *kernel,
__isl_take isl_schedule_node *node)
{
int depth;
int need_sync;
need_sync = any_global_or_shared_sync_writes(kernel);
if (need_sync < 0)
return isl_schedule_node_free(node);
if (!need_sync)
return node;
node = gpu_tree_move_down_to_thread(node, kernel->core);
depth = isl_schedule_node_get_schedule_depth(node);
node = gpu_tree_move_up_to_kernel(node);
if (depth == isl_schedule_node_get_schedule_depth(node))
return node;
node = gpu_tree_move_down_to_depth(node, depth, kernel->core);
node = gpu_tree_ensure_following_sync(node, kernel);
node = gpu_tree_move_up_to_kernel(node);
return node;
}
/* Return a read ("read" is 1) or write access relation for "group"
* with those accesses removed that are only needed to communicate data
* within the subtree of the schedule rooted at "node".
* Furthermore, include the prefix schedule at "node".
* That is, return a relation of the form
*
* S -> [D -> A]
*
* with D the outer schedule dimensions at "node".
*/
static __isl_give isl_union_map *anchored_non_local_accesses(
struct ppcg_kernel *kernel, struct gpu_array_ref_group *group,
__isl_take isl_schedule_node *node, int read)
{
isl_union_map *access;
isl_union_map *prefix;
prefix = isl_schedule_node_get_prefix_schedule_relation(node);
prefix = isl_union_map_preimage_domain_union_pw_multi_aff(prefix,
isl_union_pw_multi_aff_copy(kernel->contraction));
access = gpu_array_ref_group_access_relation(group, read, !read);
access = remove_local_accesses_group(kernel, group, access, prefix,
read);
access = isl_union_map_range_product(prefix, access);
return access;
}
/* Given an array reference group "group", create a mapping
*
* read[D -> A] -> [D -> A]
*
* if "read" is set or
*
* write[D -> A] -> [D -> A]
*
* if "read" is not set.
* D corresponds to the outer tile->depth dimensions of
* the kernel schedule.
*/
static __isl_give isl_multi_aff *create_from_access(isl_ctx *ctx,
struct gpu_array_ref_group *group, int read)
{
struct gpu_array_tile *tile;
isl_space *space;
isl_id *id;
tile = gpu_array_ref_group_tile(group);
space = isl_space_copy(group->array->space);
space = isl_space_from_range(space);
space = isl_space_add_dims(space, isl_dim_in, tile->depth);
space = isl_space_wrap(space);
space = isl_space_map_from_set(space);
id = isl_id_alloc(ctx, read ? "read" : "write", group);
space = isl_space_set_tuple_id(space, isl_dim_in, id);
return isl_multi_aff_identity(space);
}
/* If any writes in "group" require synchronization, then make sure
* that there is a synchronization node for "kernel" after the node
* following "node" in a sequence.
*
* If "shared" is set and no synchronization is needed for
* the writes to global memory, then add synchronization before
* the kernel to protect shared memory from being overwritten
* by the next iteration of the core computation.
* No additional synchronization is needed to protect against
* the next copy into shared memory because each element of
* the shared memory tile is always copied by the same thread.
*/
static __isl_give isl_schedule_node *add_group_write_sync(
__isl_take isl_schedule_node *node, struct ppcg_kernel *kernel,
struct gpu_array_ref_group *group, int shared)
{
int need_sync;
need_sync = any_sync_writes_in_group(kernel, group);
if (need_sync < 0)
return isl_schedule_node_free(node);
if (need_sync) {
node = isl_schedule_node_parent(node);
node = isl_schedule_node_next_sibling(node);
node = isl_schedule_node_child(node, 0);
node = gpu_tree_ensure_following_sync(node, kernel);
} else if (shared) {
struct gpu_array_tile *tile;
tile = gpu_array_ref_group_tile(group);
node = isl_schedule_node_parent(node);
node = isl_schedule_node_parent(node);
node = gpu_tree_move_down_to_depth(node, tile->depth,
kernel->core);
node = gpu_tree_move_left_to_sync(node, kernel);
}
return node;
}
/* Add copy statements to the schedule tree of "node"
* for reading from global memory to private memory (if "read" is set) or
* for writing back from private memory to global memory
* (if "read" is not set) for the array reference group "group" that
* is mapped to private memory.
* On input, "node" points to the kernel node, and it is moved
* back there on output.
*
* The copies are performed in the order of the array elements.
* The copy statement instances include a reference to the outer
* tile->depth dimensions of the kernel schedule for ease of
* combining them with the group tiling.
*
* That is, the extra schedule is of the form
*
* type[D -> A] -> A
*
* where D corresponds to the outer tile->depth dimensions of
* the kernel schedule and A to the global array.
* This schedule is unrolled because registers are not addressable.
*
* The copying is inserted in the schedule tree through an extension
* of the form
*
* D -> type[D -> A]
*
* where the extra domain elements type[D -> A] are those accessed
* by the group.
* A filter is inserted on type[D -> A] to ensure that the element
* is read/written by the same thread that needs the element.
* This filter is obtained by applying
*
* S -> type[D -> A]
*
* to the thread filter for the core statements.
*
* The extension is inserted before the core computation in case of a read
* and after the core computation in case of a write.
* In the latter case, we also make sure that there is a synchronization
* node after the write to global memory, unless this write is performed
* at the outer level of the kernel.
* In principle, this synchronization could be inserted higher
* in the schedule tree depending on where the corresponding reads
* from global memory are performed.
*/
static __isl_give isl_schedule_node *add_copies_group_private(
struct ppcg_kernel *kernel, struct gpu_array_ref_group *group,
__isl_take isl_schedule_node *node, int read)
{
struct gpu_array_tile *tile;
isl_union_map *access;
isl_union_set *domain;
isl_space *space;
isl_multi_aff *from_access;
isl_multi_pw_aff *mpa;
isl_multi_union_pw_aff *mupa;
isl_union_pw_multi_aff *contraction;
isl_schedule_node *graft;
isl_union_set *filter;
int kernel_depth;
int empty;
kernel_depth = isl_schedule_node_get_schedule_depth(node);
tile = gpu_array_ref_group_tile(group);
node = gpu_tree_move_down_to_depth(node, tile->depth, kernel->core);
access = anchored_non_local_accesses(kernel, group, node, read);
empty = isl_union_map_is_empty(access);
if (empty < 0 || empty) {
isl_union_map_free(access);
if (empty < 0)
return isl_schedule_node_free(node);
return gpu_tree_move_up_to_kernel(node);
}
group->array->global = 1;
group->local_array->global = 1;
from_access = create_from_access(kernel->ctx, group, read);
space = isl_space_domain(isl_multi_aff_get_space(from_access));
access = isl_union_map_preimage_range_multi_aff(access, from_access);
filter = isl_union_set_copy(kernel->thread_filter);
contraction = isl_union_pw_multi_aff_copy(kernel->contraction);
filter = isl_union_set_preimage_union_pw_multi_aff(filter, contraction);
filter = isl_union_set_apply(filter, isl_union_map_copy(access));
filter = isl_union_set_detect_equalities(filter);
filter = isl_union_set_coalesce(filter);
domain = isl_union_map_range(access);
access = isl_union_set_wrapped_domain_map(domain);
access = isl_union_map_reverse(access);
access = isl_union_map_coalesce(access);
graft = isl_schedule_node_from_extension(access);
space = isl_space_map_from_set(space);
mpa = isl_multi_pw_aff_identity(space);
mpa = isl_multi_pw_aff_range_factor_range(mpa);
mupa = isl_multi_union_pw_aff_from_multi_pw_aff(mpa);
graft = isl_schedule_node_child(graft, 0);
graft = isl_schedule_node_insert_partial_schedule(graft, mupa);
graft = unroll(graft);
graft = isl_schedule_node_insert_filter(graft, filter);
graft = isl_schedule_node_parent(graft);
if (read)
node = isl_schedule_node_graft_before(node, graft);
else {
node = isl_schedule_node_graft_after(node, graft);
if (kernel_depth < tile->depth)
node = add_group_write_sync(node, kernel, group, 0);
}
node = gpu_tree_move_up_to_kernel(node);
return node;
}
/* Add copy statements to the schedule tree of "node"
* for reading from global memory to shared memory (if "read" is set) or
* for writing back from shared memory to global memory
* (if "read" is not set) for the array reference group "group" that
* is mapped to shared memory.
* On input, "node" points to the kernel node, and it is moved
* back there on output.
*
* The copies are performed in the order of the corresponding shared
* memory tile.
* The copy statement instances include a reference to the outer
* tile->depth dimensions of the kernel schedule for ease of
* combining them with the group tiling.
*
* If we are performing a read from global memory to shared memory and
* if the array involved is not a scalar, then we copy
* the entire tile to shared memory. This may result in some extra
* elements getting copied, but it should lead to simpler code
* (which means that fewer registers may be needed) and less divergence.
*
* Otherwise, we only copy the elements that will be read or have been written
* in the kernel.
*
* That is, the extra schedule is of the form
*
* type[D -> A] -> T
*
* where D corresponds to the outer tile->depth dimensions of
* the kernel schedule, A to the global array and T is the corresponding
* shared memory tile.
*
* The copying is inserted in the schedule tree through an extension
* of the form
*
* D -> type[D -> A]
*
* where the extra domain elements type[D -> A] are those accessed
* by the group. In the case of read from a non-scalar, this set
* is replaced by the entire shared memory tile.
*
* If the "unroll_copy_shared" option is set, then the AST generator
* is instructed to unroll the copying code.
*
* A filter is inserted on type[D -> A] to map the copy instances
* to the threads. In particular, the thread identifiers are
* equated to the position inside the shared memory tile (T)
* modulo the block size.
* We try to align the innermost tile dimension with the innermost
* thread identifier (x) as a heuristic to improve coalescing.
* In particular, if the dimension of the tile is greater than
* the dimension of the block, then the schedule mapping to the tile
* is broken up into two pieces and the filter is applied to the inner part.
* If, on the other hand, the dimension of the tile is smaller than
* the dimension of the block, then the initial thread identifiers
* are equated to zero and the remaining thread identifiers are
* matched to the memory tile.
*
* The extension is inserted before the core computation in case of a read
* and after the core computation in case of a write.
* In the case of a read, we first need to make sure there is some
* synchronization before the core computation such that we can put the read
* from global memory to shared memory before that synchronization.
* This ensures that all threads have finished copying into shared memory
* before the shared memory is used.
* We also need to make sure that there is a synchronization node after
* the core computation to ensure that the next load into shared memory
* only happens after all data has been used. There is no need for
* this synchronization if we are at the outer level since then there
* won't be a next load.
* In the case of a write, we need to make sure there is some synchronization
* after the core computation such that we can put the write from shared
* memory to global memory after that synchronization.
* Unless we are at the outer level, we also need a synchronization node
* after the write to ensure the data is saved to global memory
* before the next iteration writes to the same shared memory.
* It also makes sure the data has arrived in global memory before
* it is read in a subsequent iteration.
*/
static __isl_give isl_schedule_node *add_copies_group_shared(
struct ppcg_kernel *kernel, struct gpu_array_ref_group *group,
__isl_take isl_schedule_node *node, int read)
{
struct gpu_array_tile *tile;
isl_union_map *access;
isl_union_set *domain;
isl_multi_aff *ma;
isl_multi_aff *from_access;
isl_multi_pw_aff *mpa;
isl_multi_union_pw_aff *mupa;
isl_schedule_node *graft;
isl_union_set *filter;
int skip;
int kernel_depth;
int empty;
tile = gpu_array_ref_group_tile(group);
kernel_depth = isl_schedule_node_get_schedule_depth(node);
node = gpu_tree_move_down_to_depth(node, tile->depth, kernel->core);
access = anchored_non_local_accesses(kernel, group, node, read);
empty = isl_union_map_is_empty(access);
if (empty < 0 || empty) {
isl_union_map_free(access);
if (empty < 0)
return isl_schedule_node_free(node);
return gpu_tree_move_up_to_kernel(node);
}
group->array->global = 1;
group->local_array->global = 1;
from_access = create_from_access(kernel->ctx, group, read);
ma = isl_multi_aff_copy(tile->tiling);
ma = isl_multi_aff_pullback_multi_aff(ma,
isl_multi_aff_copy(from_access));
mpa = isl_multi_pw_aff_from_multi_aff(ma);
mupa = isl_multi_union_pw_aff_from_multi_pw_aff(mpa);
domain = isl_union_map_range(access);
if (read && !gpu_array_is_scalar(group->array)) {
isl_map *map;
isl_union_set_free(domain);
map = group_tile(group);
domain = isl_union_set_from_set(isl_map_wrap(map));
}
domain = isl_union_set_preimage_multi_aff(domain, from_access);
access = isl_union_set_wrapped_domain_map(domain);
access = isl_union_map_reverse(access);
access = isl_union_map_coalesce(access);
graft = isl_schedule_node_from_extension(access);
graft = isl_schedule_node_child(graft, 0);
graft = isl_schedule_node_insert_partial_schedule(graft, mupa);
if (kernel->options->unroll_copy_shared)
graft = ppcg_set_schedule_node_type(graft, isl_ast_loop_unroll);
if (tile->n > kernel->n_block && kernel->n_block > 0) {
graft = isl_schedule_node_band_split(graft,
tile->n - kernel->n_block);
graft = isl_schedule_node_child(graft, 0);
}
if (tile->n < kernel->n_block)
skip = kernel->n_block - tile->n;
else
skip = 0;
filter = set_schedule_modulo(graft, kernel->thread_ids,
kernel->block_dim);
if (!kernel->options->wrap)
graft = snap_band_to_sizes(graft, kernel->block_dim + skip,
kernel->options);
if (tile->n > kernel->n_block && kernel->n_block > 0)
graft = isl_schedule_node_parent(graft);
graft = isl_schedule_node_insert_filter(graft, filter);
while (graft && isl_schedule_node_has_parent(graft))
graft = isl_schedule_node_parent(graft);
if (read) {
if (kernel_depth < tile->depth)
node = gpu_tree_ensure_sync_after_core(node, kernel);
node = gpu_tree_move_left_to_sync(node, kernel);
node = isl_schedule_node_graft_before(node, graft);
} else {
node = gpu_tree_move_right_to_sync(node, kernel);
node = isl_schedule_node_graft_after(node, graft);
if (kernel_depth < tile->depth)
node = add_group_write_sync(node, kernel, group, 1);
}
node = gpu_tree_move_up_to_kernel(node);
return node;
}
/* Check whether the array reference group "group" is mapped to
* private or shared memory and, if so,
* add copy statements to the schedule tree of "node"
* for reading from global memory to private or shared memory
* (if "read" is set) or for writing back from private or shared memory
* to global memory (if "read" is not set) for this group.
* On input, "node" points to the kernel node, and it is moved
* back there on output.
*/
static __isl_give isl_schedule_node *add_copies_group(
struct ppcg_kernel *kernel, struct gpu_array_ref_group *group,
__isl_take isl_schedule_node *node, int read)
{
enum ppcg_group_access_type type;
type = gpu_array_ref_group_type(group);
if (type == ppcg_access_private)
return add_copies_group_private(kernel, group, node, read);
if (type == ppcg_access_shared)
return add_copies_group_shared(kernel, group, node, read);
return node;
}
/* For each array reference group that is mapped to private or shared memory,
* add copy statements to the schedule tree of "node"
* for reading from global memory to private or shared memory
* and for writing back.
* On input, "node" points to the kernel node, and it is moved
* back there on output.
*/
static __isl_give isl_schedule_node *add_copies(struct ppcg_kernel *kernel,
__isl_take isl_schedule_node *node)
{
int i, j;
for (i = 0; i < kernel->n_array; ++i) {
struct gpu_local_array_info *array = &kernel->array[i];
for (j = 0; j < array->n_group; ++j) {
struct gpu_array_ref_group *group = array->groups[j];
node = add_copies_group(kernel, group, node, 1);
if (!node)
return NULL;
node = add_copies_group(kernel, group, node, 0);
if (!node)
return NULL;
}
}
return node;
}
/* Mark all dimensions in the current band node atomic.
*/
static __isl_give isl_schedule_node *atomic(__isl_take isl_schedule_node *node)
{
return ppcg_set_schedule_node_type(node, isl_ast_loop_atomic);
}
/* Mark "node" atomic, if it is a band node.
* Do the same for all ancestors.
* Return a pointer to "node" (in the updated schedule tree).
*/
static __isl_give isl_schedule_node *atomic_ancestors(
__isl_take isl_schedule_node *node)
{
int pos;
if (!node)
return NULL;
if (!isl_schedule_node_has_parent(node))
return node;
pos = isl_schedule_node_get_child_position(node);
node = isl_schedule_node_parent(node);
if (isl_schedule_node_get_type(node) == isl_schedule_node_band)
node = atomic(node);
node = atomic_ancestors(node);
node = isl_schedule_node_child(node, pos);
return node;
}
/* Collect all write references that require synchronization.
* "node" is assumed to point to the kernel node.
* Each reference is represented by a universe set in a space
*
* [S[i,j] -> R[]]
*
* with S[i,j] the statement instance space and R[] the array reference.
*
* This function should be called before block and thread filters are added.
*
* Synchronization is needed after a write if there is a subsequent read
* within the same block that may not be performed by the same thread.
* There should not be any dependences between different blocks,
* so we start with the flow dependences within the same kernel invocation
* and we subtract from these those dependences that are mapped
* to the same iteration of the bands where synchronization is inserted.
* We do not remove pairs of instances that are known to map to
* the same thread across different iterations of the intermediate
* bands because the read may be performed by a different thread
* than the one that needs the value if shared memory is involved.
*
* We also consider all pairs of possible writes that access the same
* memory location and that may be mapped to the same block but not
* to the same iteration of the intermediate bands.
* In theory, it would be possible for one thread to still be in
* a previous iteration of a loop in these bands.
* A write to global memory in this delayed thread could then overwrite
* a write from another thread that has already moved on to
* the next iteration.
*
* After computing the above writes paired off with reads or writes
* that depend on them, we project onto the domain writes.
* Sychronization is needed after writes to global memory
* through these references.
*/
static __isl_give isl_union_set *compute_sync_writes(
struct ppcg_kernel *kernel, __isl_keep isl_schedule_node *node)
{
isl_union_map *local;
isl_union_map *may_writes, *shared_access;
isl_union_map *kernel_prefix, *thread_prefix;
isl_union_map *equal;
isl_union_set *wrap;
isl_union_set *domain;
isl_union_pw_multi_aff *contraction;
kernel_prefix = isl_schedule_node_get_prefix_schedule_union_map(node);
node = isl_schedule_node_copy(node);
node = gpu_tree_move_down_to_thread(node, kernel->core);
thread_prefix = isl_schedule_node_get_prefix_schedule_union_map(node);
isl_schedule_node_free(node);
contraction = kernel->contraction;
kernel_prefix = isl_union_map_preimage_domain_union_pw_multi_aff(
kernel_prefix, isl_union_pw_multi_aff_copy(contraction));
thread_prefix = isl_union_map_preimage_domain_union_pw_multi_aff(
thread_prefix, isl_union_pw_multi_aff_copy(contraction));
domain = isl_union_set_copy(kernel->expanded_domain);
domain = isl_union_set_universe(domain);
may_writes = isl_union_map_copy(kernel->prog->scop->tagged_may_writes);
may_writes = isl_union_map_curry(may_writes);
may_writes = isl_union_map_intersect_domain(may_writes, domain);
may_writes = isl_union_map_uncurry(may_writes);
shared_access = isl_union_map_copy(may_writes);
shared_access = isl_union_map_apply_range(shared_access,
isl_union_map_reverse(may_writes));
local = isl_union_map_copy(kernel->prog->scop->tagged_dep_flow);
local = isl_union_map_union(local, shared_access);
local = isl_union_map_zip(local);
equal = isl_union_map_apply_range(kernel_prefix,
isl_union_map_reverse(isl_union_map_copy(kernel_prefix)));
wrap = isl_union_map_wrap(equal);
local = isl_union_map_intersect_domain(local, wrap);
equal = isl_union_map_apply_range(thread_prefix,
isl_union_map_reverse(isl_union_map_copy(thread_prefix)));
wrap = isl_union_map_wrap(equal);
local = isl_union_map_subtract_domain(local, wrap);
local = isl_union_map_zip(local);
local = isl_union_map_universe(local);
return isl_union_map_domain(local);
}
/* Group the domain elements into a single space, named kernelX,
* with X the kernel sequence number "kernel_id".
*/
static __isl_give isl_schedule_node *group_statements(
__isl_take isl_schedule_node *node, int kernel_id)
{
char buffer[20];
isl_id *id;
if (!node)
return NULL;
snprintf(buffer, sizeof(buffer), "kernel%d", kernel_id);
id = isl_id_alloc(isl_schedule_node_get_ctx(node), buffer, NULL);
return isl_schedule_node_group(node, id);
}
/* Create a ppcg_kernel representing the domain instances that reach "node"
* and insert a mark node pointing to the ppcg_kernel before "node".
* The band that "node" points to is the band that needs to be mapped
* to block identifiers. The band that needs to be mapped to thread
* identifiers should be marked by a "thread" mark by the caller.
* The linear branch between the current node and the "thread" mark
* may also have a "shared" mark. If present, the mapping to shared
* memory is computed at that point.
* Both marks are removed by this function.
* If "scale" is set, then the band that "node" points to is scaled
* by "sizes".
*
* Mark all outer band nodes as atomic to ensure each kernel is only
* scheduled once.
* If the domain elements that reach "node" live in more than one space,
* then group the domain elements into a single space, named kernelX,
* with X the kernel sequence number.
*
* Insert a guard node governing the kernel node to ensure that
* no kernels with zero blocks are launched.
*
* Insert a context node describing the block and thread
* identifiers inside the kernel mark.
* The context node needs to be inserted after the effective block size
* has been determined such that the bounds on the thread identifiers
* would reflect the effective block size.
* Insert a filter node inside the context node mapping the statement
* instances to block identifiers. In particular, the block identifiers
* are equated to the partial schedule of band that was marked for mapping
* to blocks modulo the grid size.
* Insert a filter node inside the "thread" mark mapping the statement
* instances to thread identifiers. In particular, the thread identifiers
* are equated to the partial schedule of band that was marked for mapping
* to threads modulo the block size.
*
* Compute array reference groups for all arrays, set the local
* array bounds based on the set of domain instances that reach
* the kernel node, check the total amount of shared memory used
* and compute all group tilings.
* The array reference groups are computed after the block filter
* has been inserted because it affects the mapping to shared or
* private memory. This computation also requires the thread filter
* (in the ppcg_kernel object), but this thread filter should not
* have been added to the schedule tree yet since the computation
* requires the schedule of the band that needs to be mapped to
* threads before the privatization is applied.
*
* If any array reference group requires the band mapped to threads
* to be unrolled, then we perform the required unrolling.
*
* We save a copy of the schedule that may influence the mappings
* to shared or private memory in kernel->copy_schedule.
*
* Finally, we add synchronization and copy statements to the schedule tree,
* remove the "thread" mark and create representations for the local
* variables in the kernel.
*
* We keep a copy of the isl_id that points to the kernel to ensure
* that the kernel does not get destroyed if the schedule node
* is freed due to some error condition.
*/
__isl_give isl_schedule_node *gpu_create_kernel(struct gpu_gen *gen,
__isl_take isl_schedule_node *node, int scale,
__isl_keep isl_multi_val *sizes)
{
struct ppcg_kernel *kernel;
isl_id *id;
isl_schedule_node *node_thread;
isl_union_map *host_schedule;
isl_union_pw_multi_aff *contraction;
isl_set *host_domain;
isl_union_set *domain, *expanded;
int single_statement;
node = gpu_tree_insert_shared_before_thread(node);
if (!node)
return NULL;
kernel = isl_calloc_type(gen->ctx, struct ppcg_kernel);
kernel = ppcg_kernel_create_local_arrays(kernel, gen->prog);
if (!kernel)
return isl_schedule_node_free(node);
domain = isl_schedule_node_get_domain(node);
single_statement = isl_union_set_n_set(domain) == 1;
kernel->ctx = gen->ctx;
kernel->prog = gen->prog;
kernel->options = gen->options;
kernel->context = extract_context(node, gen->prog);
kernel->core = isl_union_set_universe(isl_union_set_copy(domain));
contraction = isl_schedule_node_get_subtree_contraction(node);
kernel->contraction = isl_union_pw_multi_aff_copy(contraction);
expanded = isl_union_set_copy(domain);
expanded = isl_union_set_preimage_union_pw_multi_aff(expanded,
contraction);
kernel->expanded_domain = isl_union_set_copy(expanded);
kernel->arrays = accessed_by_domain(expanded, gen->prog);
kernel->n_grid = n_outer_coincidence(node);
node_thread = isl_schedule_node_copy(node);
node_thread = gpu_tree_move_down_to_thread(node_thread, kernel->core);
node_thread = isl_schedule_node_child(node_thread, 0);
kernel->n_block = n_outer_coincidence(node_thread);
isl_schedule_node_free(node_thread);
kernel->id = gen->kernel_id++;
if (read_grid_and_block_sizes(kernel, gen) < 0)
node = isl_schedule_node_free(node);
kernel->sync_writes = compute_sync_writes(kernel, node);
host_schedule = isl_schedule_node_get_prefix_schedule_union_map(node);
host_domain = isl_set_from_union_set(isl_union_map_range(
host_schedule));
node = atomic_ancestors(node);
id = isl_id_alloc(gen->ctx, "kernel", kernel);
id = isl_id_set_free_user(id, &ppcg_kernel_free_wrap);
node = isl_schedule_node_insert_mark(node, isl_id_copy(id));
if (!single_statement)
node = group_statements(node, kernel->id);
node = isl_schedule_node_child(node, 0);
node = split_band(node, kernel->n_grid);
kernel->block_ids = ppcg_scop_generate_names(gen->prog->scop,
kernel->n_grid, "b");
kernel->block_filter = set_schedule_modulo(node, kernel->block_ids,
kernel->grid_dim);
kernel->grid_size = extract_grid_size(kernel,
isl_union_set_copy(domain));
if (!kernel->options->wrap)
node = snap_band_to_sizes(node, kernel->grid_dim,
kernel->options);
if (scale)
node = scale_band(node, isl_multi_val_copy(sizes));
node = isl_schedule_node_parent(node);
if (!single_statement)
node = isl_schedule_node_parent(node);
node = insert_guard(node, kernel->context, kernel->grid_size,
gen->prog->scop);
node = gpu_tree_move_down_to_thread(node, kernel->core);
node = isl_schedule_node_child(node, 0);
node = split_band(node, kernel->n_block);
kernel->thread_ids = ppcg_scop_generate_names(gen->prog->scop,
kernel->n_block, "t");
kernel->thread_filter = set_schedule_modulo(node, kernel->thread_ids,
kernel->block_dim);
if (extract_block_size(kernel, domain) < 0)
node = isl_schedule_node_free(node);
node = gpu_tree_move_up_to_kernel(node);
node = isl_schedule_node_child(node, 0);
node = insert_context(kernel, node);
node = isl_schedule_node_child(node, 0);
node = isl_schedule_node_insert_filter(node,
isl_union_set_copy(kernel->block_filter));
node = gpu_tree_move_up_to_kernel(node);
if (gpu_group_references(kernel, node) < 0)
node = isl_schedule_node_free(node);
localize_bounds(kernel, host_domain);
isl_set_free(host_domain);
check_shared_memory_bound(kernel);
mark_global_arrays(kernel);
compute_group_tilings(kernel);
node = gpu_tree_move_down_to_thread(node, kernel->core);
node = isl_schedule_node_child(node, 0);
if (!kernel->options->wrap)
node = snap_band_to_sizes(node, kernel->block_dim,
kernel->options);
node = isl_schedule_node_insert_filter(node,
isl_union_set_copy(kernel->thread_filter));
if (kernel_requires_unroll(kernel)) {
node = isl_schedule_node_child(node, 0);
node = unroll(node);
}
node = gpu_tree_move_up_to_thread(node);
kernel->copy_schedule_dim = isl_schedule_node_get_schedule_depth(node);
kernel->copy_schedule =
isl_schedule_node_get_prefix_schedule_union_pw_multi_aff(node);
contraction = isl_union_pw_multi_aff_copy(kernel->contraction);
kernel->copy_schedule =
isl_union_pw_multi_aff_pullback_union_pw_multi_aff(
kernel->copy_schedule, contraction);
node = gpu_tree_move_up_to_kernel(node);
node = add_sync(kernel, node);
node = add_copies(kernel, node);
node = gpu_tree_move_down_to_shared(node, kernel->core);
node = isl_schedule_node_delete(node);
node = gpu_tree_move_down_to_thread(node, kernel->core);
node = isl_schedule_node_delete(node);
node = gpu_tree_move_up_to_kernel(node);
if (create_kernel_vars(kernel) < 0)
node = isl_schedule_node_free(node);
if (!single_statement)
node = isl_schedule_node_parent(node);
node = isl_schedule_node_parent(node);
isl_id_free(id);
if (!id)
ppcg_kernel_free(kernel);
return node;
}
/* Insert a zero-dimensional permutable band at "node",
* defined over the spaces of the statements that reach this node.
*/
static __isl_give isl_schedule_node *insert_empty_permutable_band(
__isl_take isl_schedule_node *node)
{
isl_space *space;
isl_union_set *domain;
isl_multi_union_pw_aff *mupa;
domain = isl_schedule_node_get_universe_domain(node);
space = isl_union_set_get_space(domain);
space = isl_space_set_from_params(space);
mupa = isl_multi_union_pw_aff_zero(space);
mupa = isl_multi_union_pw_aff_intersect_domain(mupa, domain);
node = isl_schedule_node_insert_partial_schedule(node, mupa);
node = isl_schedule_node_band_set_permutable(node, 1);
return node;
}
/* See if hybrid tiling can be performed on "node" and its parent.
* If so, apply hybrid tiling and return the updated schedule tree.
* If not, return the original schedule tree.
* Return NULL on error.
*
* First check if "node", together with its parent, meets
* the basic requirements for hybrid tiling.
* If so, compute the relative dependence distances of "node"
* with respect to its parent and check if they are sufficiently bounded.
* If so, apply hybrid tiling using user specified tile sizes.
*
* The tile sizes are read before the dependence distance bounds are
* computed, because the user may have specified fewer dimensions
* than are available. In this case, the remaining schedule dimensions
* are split off and the dependence distances should be computed
* after these dimensions have been split off.
*/
static __isl_give isl_schedule_node *try_hybrid_tile(struct gpu_gen *gen,
__isl_take isl_schedule_node *node)
{
int tile_len;
int *tile_size;
isl_bool ok;
isl_schedule_node *orig = node;
ppcg_ht_bounds *bounds;
ok = ppcg_ht_parent_has_input_pattern(node);
if (ok < 0)
return isl_schedule_node_free(node);
if (!ok)
return orig;
tile_len = 1 + isl_schedule_node_band_n_member(node);
tile_size = read_tile_sizes(gen, &tile_len);
if (!tile_size)
return isl_schedule_node_free(node);
node = isl_schedule_node_copy(node);
node = split_band(node, tile_len - 1);
node = isl_schedule_node_parent(node);
bounds = ppcg_ht_compute_bounds(gen->prog->scop, node);
node = isl_schedule_node_child(node, 0);
ok = ppcg_ht_bounds_is_valid(bounds);
if (ok >= 0 && ok)
node = gpu_hybrid_tile(gen, node, bounds, tile_size);
else
ppcg_ht_bounds_free(bounds);
free(tile_size);
if (ok >= 0 && !ok) {
isl_schedule_node_free(node);
return orig;
}
isl_schedule_node_free(orig);
if (ok < 0)
return isl_schedule_node_free(node);
return node;
}
/* If "node" is the outermost permutable band that can be mapped to block and
* thread identifiers in its branch (or the root of a subtree with
* no such outer bands),
* then mark the band as such, attaching a ppcg_kernel to the mark.
*
* If hybrid tiling is allowed, then first try and apply it
* to "node" and its parent.
*
* If "node" is the root of a subtree without permutable bands,
* then insert a zero-dimensional permutable band such that
* we can assume that "node" always points to a band node.
* This includes the case where "node" already points to a band node,
* but one without any coincident dimension. In this case,
* the extra node ensures that this original node does not get tiled.
*
* Tile "node" using user specified tile sizes, after splitting the band
* if the number of specified tile sizes is smaller than the dimension
* of the band. Mark the point band of this tiling as the band that
* needs to be mapped to threads and instruct the AST generator to unroll
* the band if the "unroll_gpu_tile" option is set.
* Create a kernel representing the domain instances that reach "node" and
* insert a mark node pointing to the ppcg_kernel before the band node.
*/
static __isl_give isl_schedule_node *mark_outer_permutable(
__isl_take isl_schedule_node *node, void *user)
{
struct gpu_gen *gen = user;
int outer;
int scale;
int tile_len;
int *tile_size;
isl_id *id;
isl_multi_val *sizes;
outer = is_outer_tilable(node);
if (outer < 0)
return isl_schedule_node_free(node);
if (!outer)
return node;
if (gen->options->hybrid) {
isl_schedule_node *saved = isl_schedule_node_copy(node);
node = try_hybrid_tile(gen, node);
isl_schedule_node_free(saved);
if (node != saved)
return node;
}
if (isl_schedule_node_get_type(node) != isl_schedule_node_band ||
!isl_schedule_node_band_member_get_coincident(node, 0))
node = insert_empty_permutable_band(node);
tile_len = isl_schedule_node_band_n_member(node);
tile_size = read_tile_sizes(gen, &tile_len);
if (!tile_size)
return isl_schedule_node_free(node);
if (tile_len < isl_schedule_node_band_n_member(node))
node = isl_schedule_node_band_split(node, tile_len);
sizes = construct_band_tiles_sizes(node, tile_size);
node = tile_band(node, isl_multi_val_copy(sizes));
node = isl_schedule_node_child(node, 0);
if (gen->options->unroll_gpu_tile)
node = ppcg_set_schedule_node_type(node, isl_ast_loop_unroll);
id = isl_id_alloc(gen->ctx, "thread", NULL);
node = isl_schedule_node_insert_mark(node, id);
node = isl_schedule_node_parent(node);
scale = gen->options->scale_tile_loops;
node = gpu_create_kernel(gen, node, scale, sizes);
isl_multi_val_free(sizes);
free(tile_size);
return node;
}
/* Given a set or sequence node, return the union of the filters of
* the initial (if "initial" is set) or final (if "initial" is not set)
* direct subtrees that do not contain any suitably permutable bands
* (according to subtree_has_permutable_bands).
* In the case of a set node, the subtrees can be arbitrarily reordered
* so any subtree is considered potentially initial and final.
*
* If the child of a subtree containing suitably permutable bands
* is itself a set or sequence node, then recursively collect
* further initial/final subtrees.
* In the case of an outer sequence node, only do this for the first/last child
* containing suitably permutable bands.
*/
static __isl_give isl_union_set *get_non_parallel_subtree_filters(
__isl_keep isl_schedule_node *node, int initial)
{
isl_space *space;
isl_union_set *filter;
int i, n;
int in_order;
enum isl_schedule_node_type type;
type = isl_schedule_node_get_type(node);
if (type < 0)
return NULL;
if (type != isl_schedule_node_set && type != isl_schedule_node_sequence)
return isl_union_set_empty_ctx(isl_schedule_node_get_ctx(node));
in_order = type == isl_schedule_node_sequence;
n = isl_schedule_node_n_children(node);
if (n < 0)
return NULL;
node = isl_schedule_node_copy(node);
node = isl_schedule_node_child(node, 0);
filter = isl_schedule_node_filter_get_filter(node);
node = isl_schedule_node_parent(node);
space = isl_union_set_get_space(filter);
isl_union_set_free(filter);
filter = isl_union_set_empty(space);
for (i = 0; i < n; ++i) {
isl_bool parallelism;
int child = initial ? i : n - 1 - i;
node = isl_schedule_node_child(node, child);
parallelism = subtree_has_permutable_bands(node);
if (parallelism < 0) {
filter = isl_union_set_free(filter);
} else if (!parallelism) {
isl_union_set *filter_i;
filter_i = isl_schedule_node_filter_get_filter(node);
filter = isl_union_set_union(filter, filter_i);
} else {
isl_union_set *filter_i;
node = isl_schedule_node_child(node, 0);
filter_i =
get_non_parallel_subtree_filters(node, initial);
filter = isl_union_set_union(filter, filter_i);
node = isl_schedule_node_parent(node);
if (in_order)
break;
}
node = isl_schedule_node_parent(node);
}
isl_schedule_node_free(node);
return filter;
}
/* Mark all variables that are accessed by the statement instances in "domain"
* and that are local to "prog" as requiring a declaration in the host code.
* The statement instances in "domain" correspond to (a subset of)
* the active instances at "node".
* "node" is not modified by this function, except that NULL is returned
* in case of error.
*
* If there are no local variables or if "domain" is empty,
* then clearly no such declarations are needed.
*/
static __isl_give isl_schedule_node *declare_accessed_local_variables(
__isl_take isl_schedule_node *node, struct gpu_prog *prog,
__isl_keep isl_union_set *domain)
{
isl_union_pw_multi_aff *contraction;
isl_union_set *arrays;
isl_bool empty;
int i;
if (!ppcg_scop_any_hidden_declarations(prog->scop))
return node;
empty = isl_union_set_is_empty(domain);
if (empty < 0)
return isl_schedule_node_free(node);
if (empty)
return node;
contraction = isl_schedule_node_get_subtree_contraction(node);
domain = isl_union_set_copy(domain);
domain = isl_union_set_preimage_union_pw_multi_aff(domain, contraction);
arrays = accessed_by_domain(domain, prog);
for (i = 0; i < prog->n_array; ++i) {
isl_space *space;
isl_set *set;
isl_bool empty;
if (!prog->array[i].local)
continue;
space = isl_set_get_space(prog->array[i].extent);
set = isl_union_set_extract_set(arrays, space);
empty = isl_set_plain_is_empty(set);
isl_set_free(set);
if (empty < 0)
goto error;
if (!empty)
prog->array[i].declare_local = 1;
}
isl_union_set_free(arrays);
return node;
error:
isl_union_set_free(arrays);
return isl_schedule_node_free(node);
}
/* If "node" points to a set or sequence node, then separate the initial
* (if "initial" is set) or final (if "initial" is not set)
* children that do not have suitably permutable bands and
* return a pointer to the subsequence of children that do have such bands,
* assuming there are any such subtrees.
*
* Mark all local variables in "prog" that are accessed by
* the group without permutable bands as requiring a declaration on the host.
*/
static __isl_give isl_schedule_node *partial_isolate_permutable_subtrees(
__isl_take isl_schedule_node *node, struct gpu_prog *prog,
int initial)
{
isl_union_set *filter;
enum isl_schedule_node_type type;
if (!node)
return NULL;
type = isl_schedule_node_get_type(node);
if (type != isl_schedule_node_set && type != isl_schedule_node_sequence)
return node;
filter = get_non_parallel_subtree_filters(node, initial);
node = declare_accessed_local_variables(node, prog, filter);
if (initial)
node = isl_schedule_node_order_before(node, filter);
else
node = isl_schedule_node_order_after(node, filter);
return node;
}
/* If "node" points to a set or sequence node, then separate the initial and
* final children that do not have suitably permutable bands and
* return a pointer to the subsequence of children that do have such bands.
*
* In the case of a set node, the children can be arbitrarily reordered,
* so they can all be considered initial and final.
* Separate them out as final children (first) so that they are executed
* after the other children.
* Otherwise the arrays partially written by the non-permutable subtrees
* could get overwritten by the copy-out corresponding to the other subtrees,
* requiring those arrays to be copied in first.
*/
static __isl_give isl_schedule_node *isolate_permutable_subtrees(
__isl_take isl_schedule_node *node, struct gpu_prog *prog)
{
node = partial_isolate_permutable_subtrees(node, prog, 0);
node = partial_isolate_permutable_subtrees(node, prog, 1);
return node;
}
/* Replace any reference to an array element in the range of "copy"
* by a reference to all array elements (defined by the extent of the array).
*/
static __isl_give isl_union_map *approximate_copy_out(
__isl_take isl_union_map *copy, struct gpu_prog *prog)
{
int i;
isl_union_map *res;
res = isl_union_map_empty(isl_union_map_get_space(copy));
for (i = 0; i < prog->n_array; ++i) {
isl_space *space;
isl_set *set;
isl_union_map *copy_i;
isl_union_set *extent, *domain;
space = isl_space_copy(prog->array[i].space);
extent = isl_union_set_from_set(isl_set_universe(space));
copy_i = isl_union_map_copy(copy);
copy_i = isl_union_map_intersect_range(copy_i, extent);
set = isl_set_copy(prog->array[i].extent);
extent = isl_union_set_from_set(set);
domain = isl_union_map_domain(copy_i);
copy_i = isl_union_map_from_domain_and_range(domain, extent);
res = isl_union_map_union(res, copy_i);
}
isl_union_map_free(copy);
return res;
}
/* Insert "kernel" marks that point to a ppcg_kernel structure
* in front of all outermost tilable band that (by construction)
* have at least one parallel loop.
*/
static __isl_give isl_schedule_node *mark_kernels(struct gpu_gen *gen,
__isl_take isl_schedule_node *node)
{
return isl_schedule_node_map_descendant_bottom_up(node,
&mark_outer_permutable, gen);
}
/* Construct schedule constraints from the dependences in prog->scop and
* the array order dependences in prog->array_order.
*
* If live range reordering is allowed, then we need to make sure
* that live ranges on arrays are not run in parallel since doing
* so would require array expansion. We therefore add the array
* order dependences to the coincidence dependences. Non-zero array
* order dependences will then prevent a schedule dimension from being
* considered parallel.
* Live ranges derived from scalars are allowed to be run in parallel
* since we force the scalars to be mapped to private memory in
* check_scalar_live_ranges.
* If live range reordering is allowed, then the false dependences
* are not added to the validity constraints as that would prevent
* reordering. Instead, the external false dependences that enforce that reads
* from potentially live-in data precede any later write and
* that writes of potentially live-out data follow any other earlier write
* are added to the validity and the coincidence constraints.
* The false dependences are still added to the proximity constraints
* for consistency with the case where live range reordering is not allowed.
* The coincidence constraints then consist of flow dependences,
* external false dependences and array order dependences.
* The independences can be filtered out from the first two sets.
* They have already been filtered out from the array order dependences
* on a per array basis in collect_order_dependences.
* There is no need for a per array handling of the other two sets
* as there should be no flow or external false dependence on local
* variables that can be filtered out.
*/
static __isl_give isl_schedule_constraints *construct_schedule_constraints(
struct gpu_prog *prog)
{
isl_union_set *domain;
isl_union_map *dep_raw, *dep;
isl_union_map *validity, *proximity, *coincidence;
isl_schedule_constraints *sc;
domain = isl_union_set_copy(prog->scop->domain);
sc = isl_schedule_constraints_on_domain(domain);
sc = isl_schedule_constraints_set_context(sc,
isl_set_copy(prog->scop->context));
if (prog->scop->options->live_range_reordering) {
sc = isl_schedule_constraints_set_conditional_validity(sc,
isl_union_map_copy(prog->scop->tagged_dep_flow),
isl_union_map_copy(prog->scop->tagged_dep_order));
proximity = isl_union_map_copy(prog->scop->dep_flow);
validity = isl_union_map_copy(proximity);
validity = isl_union_map_union(validity,
isl_union_map_copy(prog->scop->dep_forced));
proximity = isl_union_map_union(proximity,
isl_union_map_copy(prog->scop->dep_false));
coincidence = isl_union_map_copy(validity);
coincidence = isl_union_map_subtract(coincidence,
isl_union_map_copy(prog->scop->independence));
coincidence = isl_union_map_union(coincidence,
isl_union_map_copy(prog->array_order));
} else {
dep_raw = isl_union_map_copy(prog->scop->dep_flow);
dep = isl_union_map_copy(prog->scop->dep_false);
dep = isl_union_map_union(dep, dep_raw);
dep = isl_union_map_coalesce(dep);
proximity = isl_union_map_copy(dep);
coincidence = isl_union_map_copy(dep);
validity = dep;
}
sc = isl_schedule_constraints_set_validity(sc, validity);
sc = isl_schedule_constraints_set_coincidence(sc, coincidence);
sc = isl_schedule_constraints_set_proximity(sc, proximity);
return sc;
}
/* Compute an appropriate schedule based on the accesses in
* gen->read and gen->write.
*
* We derive schedule constraints from the dependences in gen->prog->scop
* and then use isl to compute a schedule that has a parallel loop
* in each tilable band.
* During the schedule construction, some statement instances
* may be grouped first based on the input schedule.
*/
static __isl_give isl_schedule *compute_schedule(struct gpu_gen *gen)
{
isl_schedule_constraints *sc;
isl_schedule *schedule;
sc = construct_schedule_constraints(gen->prog);
schedule = gen->prog->scop->schedule;
schedule = ppcg_compute_schedule(sc, schedule, gen->options);
return schedule;
}
/* If the band node "node" has exactly one member then mark it permutable.
*/
static __isl_give isl_schedule_node *band_set_permutable(
__isl_take isl_schedule_node *node,
__isl_keep isl_schedule_constraints *sc)
{
if (isl_schedule_node_band_n_member(node) == 1)
node = isl_schedule_node_band_set_permutable(node, 1);
return node;
}
/* Return the coincidence constraints between pairs of instances
* that are scheduled together by the ancestors of "node".
* That is, select those coincidence constraints that relate
* pairs of instances that have the same value for the prefix schedule.
* If the schedule depth is zero, then the prefix schedule does not
* contain any information, so we intersect domain and range
* of the schedule constraints with the reaching domain elements instead.
*/
static __isl_give isl_union_map *get_local_coincidence(
__isl_keep isl_schedule_node *node,
__isl_keep isl_schedule_constraints *sc)
{
isl_union_map *coincidence;
isl_multi_union_pw_aff *prefix;
isl_union_pw_multi_aff *contraction;
coincidence = isl_schedule_constraints_get_coincidence(sc);
contraction = isl_schedule_node_get_subtree_contraction(node);
if (isl_schedule_node_get_schedule_depth(node) == 0) {
isl_union_set *domain;
domain = isl_schedule_node_get_domain(node);
domain = isl_union_set_preimage_union_pw_multi_aff(domain,
contraction);
coincidence = isl_union_map_intersect_domain(coincidence,
isl_union_set_copy(domain));
coincidence = isl_union_map_intersect_range(coincidence,
domain);
return coincidence;
}
prefix = isl_schedule_node_get_prefix_schedule_multi_union_pw_aff(node);
prefix = isl_multi_union_pw_aff_pullback_union_pw_multi_aff(prefix,
contraction);
return isl_union_map_eq_at_multi_union_pw_aff(coincidence, prefix);
}
/* For each member in the band node "node", determine whether
* it is coincident with respect to the outer nodes and mark
* it accordingly.
*
* That is, for each coincidence constraint between pairs
* of instances that are scheduled together by the outer nodes,
* check that domain and range are assigned the same value
* by the band member. This test is performed by checking
* that imposing the same value for the band member does not
* remove any elements from the set of coincidence constraints.
*/
static __isl_give isl_schedule_node *band_set_coincident(
__isl_take isl_schedule_node *node,
__isl_keep isl_schedule_constraints *sc)
{
isl_union_map *coincidence;
isl_union_pw_multi_aff *contraction;
isl_multi_union_pw_aff *partial;
int i, n;
coincidence = get_local_coincidence(node, sc);
partial = isl_schedule_node_band_get_partial_schedule(node);
contraction = isl_schedule_node_get_subtree_contraction(node);
partial = isl_multi_union_pw_aff_pullback_union_pw_multi_aff(partial,
contraction);
n = isl_schedule_node_band_n_member(node);
for (i = 0; i < n; ++i) {
isl_union_map *coincidence_i;
isl_union_pw_aff *upa;
isl_multi_union_pw_aff *partial_i;
int subset;
upa = isl_multi_union_pw_aff_get_union_pw_aff(partial, i);
partial_i = isl_multi_union_pw_aff_from_union_pw_aff(upa);
coincidence_i = isl_union_map_copy(coincidence);
coincidence_i = isl_union_map_eq_at_multi_union_pw_aff(
coincidence_i, partial_i);
subset = isl_union_map_is_subset(coincidence, coincidence_i);
isl_union_map_free(coincidence_i);
if (subset < 0)
break;
node = isl_schedule_node_band_member_set_coincident(node, i,
subset);
}
if (i < n)
node = isl_schedule_node_free(node);
isl_multi_union_pw_aff_free(partial);
isl_union_map_free(coincidence);
return node;
}
/* If "node" is a band, then set its properties.
*
* In particular, if the band has exactly one member, then mark it permutable.
* Mark the band members coincident based on the coincidence constraints
* of "sc".
*/
static __isl_give isl_schedule_node *set_band_properties(
__isl_take isl_schedule_node *node, void *user)
{
isl_schedule_constraints *sc = user;
if (isl_schedule_node_get_type(node) != isl_schedule_node_band)
return node;
if (isl_schedule_node_band_n_member(node) == 0)
return node;
node = band_set_permutable(node, sc);
node = band_set_coincident(node, sc);
return node;
}
/* Return the original schedule with all bands marked permutable and
* all band members marked coincident based on the coincidence constraints.
* The bands are explicitly marked permutable so that they will be considered
* by mark_outer_permutable.
*/
static __isl_give isl_schedule *determine_properties_original_schedule(
struct gpu_gen *gen)
{
isl_schedule *schedule;
isl_schedule_constraints *sc;
schedule = isl_schedule_copy(gen->prog->scop->schedule);
sc = construct_schedule_constraints(gen->prog);
schedule = isl_schedule_map_schedule_node_bottom_up(schedule,
&set_band_properties, sc);
isl_schedule_constraints_free(sc);
return schedule;
}
/* Compute a schedule or determine the properties of the original schedule
* depending on the value of the "reschedule" option.
*/
static __isl_give isl_schedule *compute_or_set_properties(void *user)
{
struct gpu_gen *gen = user;
if (gen->options->reschedule)
return compute_schedule(gen);
else
return determine_properties_original_schedule(gen);
}
/* Obtain a schedule for the scop, by reading it from
* a file, by computing one or by determining the properties
* of the original schedule.
*/
static __isl_give isl_schedule *get_schedule(struct gpu_gen *gen)
{
return ppcg_get_schedule(gen->ctx, gen->options,
&compute_or_set_properties, gen);
}
/* Construct the string "<a>_<b>".
*/
static char *concat(isl_ctx *ctx, const char *a, const char *b)
{
isl_printer *p;
char *s;
p = isl_printer_to_str(ctx);
p = isl_printer_print_str(p, a);
p = isl_printer_print_str(p, "_");
p = isl_printer_print_str(p, b);
s = isl_printer_get_str(p);
isl_printer_free(p);
return s;
}
/* For each array in "prog" of which an element appears in "accessed" and
* that is not a read only scalar, create a zero-dimensional universe set
* of which the tuple id has name "<prefix>_<name of array>" and a user
* pointer pointing to the array (gpu_array_info).
*
* If the array is local to "prog", then make sure it will be declared
* in the host code.
*
* Return the list of these universe sets.
*/
static __isl_give isl_union_set_list *create_copy_filters(struct gpu_prog *prog,
const char *prefix, __isl_take isl_union_set *accessed)
{
int i;
isl_ctx *ctx;
isl_union_set_list *filters;
ctx = prog->ctx;
filters = isl_union_set_list_alloc(ctx, 0);
for (i = 0; i < prog->n_array; ++i) {
struct gpu_array_info *array = &prog->array[i];
isl_space *space;
isl_set *accessed_i;
int empty;
char *name;
isl_id *id;
isl_union_set *uset;
if (gpu_array_is_read_only_scalar(array))
continue;
space = isl_space_copy(array->space);
accessed_i = isl_union_set_extract_set(accessed, space);
empty = isl_set_plain_is_empty(accessed_i);
isl_set_free(accessed_i);
if (empty < 0) {
filters = isl_union_set_list_free(filters);
break;
}
if (empty)
continue;
array->global = 1;
if (array->local)
array->declare_local = 1;
name = concat(ctx, prefix, array->name);
id = name ? isl_id_alloc(ctx, name, array) : NULL;
free(name);
space = isl_space_set_alloc(ctx, 0, 0);
space = isl_space_set_tuple_id(space, isl_dim_set, id);
uset = isl_union_set_from_set(isl_set_universe(space));
filters = isl_union_set_list_add(filters, uset);
}
isl_union_set_free(accessed);
return filters;
}
/* Make sure that code for the statements in "filters" that
* copy arrays to or from the device is only generated when
* the size of the corresponding array is positive.
* That is, add a set node underneath "graft" with "filters" as children
* and for each child add a guard that the selects the parameter
* values for which the corresponding array has a positive size.
* The array is available in the user pointer of the statement identifier.
* "depth" is the schedule depth of the position where "graft"
* will be added.
*/
static __isl_give isl_schedule_node *insert_positive_size_guards(
__isl_take isl_schedule_node *graft,
__isl_take isl_union_set_list *filters, int depth)
{
int i, n;
graft = isl_schedule_node_child(graft, 0);
graft = isl_schedule_node_insert_set(graft, filters);
n = isl_schedule_node_n_children(graft);
for (i = 0; i < n; ++i) {
isl_union_set *filter;
isl_set *domain, *guard;
isl_id *id;
struct gpu_array_info *array;
graft = isl_schedule_node_child(graft, i);
filter = isl_schedule_node_filter_get_filter(graft);
domain = isl_set_from_union_set(filter);
id = isl_set_get_tuple_id(domain);
array = isl_id_get_user(id);
isl_id_free(id);
isl_set_free(domain);
guard = gpu_array_positive_size_guard(array);
guard = isl_set_from_params(guard);
guard = isl_set_add_dims(guard, isl_dim_set, depth);
graft = isl_schedule_node_child(graft, 0);
graft = isl_schedule_node_insert_guard(graft, guard);
graft = isl_schedule_node_parent(graft);
graft = isl_schedule_node_parent(graft);
}
graft = isl_schedule_node_parent(graft);
return graft;
}
/* Create a graft for copying arrays to or from the device,
* whenever the size of the array is strictly positive.
* Each statement is called "<prefix>_<name of array>" and
* the identifier has a user pointer pointing to the array.
* The graft will be added at the position specified by "node".
* "copy" contains the array elements that need to be copied.
* Only arrays of which some elements need to be copied
* will have a corresponding statement in the graph.
* Note though that each such statement will copy the entire array.
*/
static __isl_give isl_schedule_node *create_copy_device(struct gpu_prog *prog,
__isl_keep isl_schedule_node *node, const char *prefix,
__isl_take isl_union_set *copy)
{
int depth;
isl_ctx *ctx;
isl_space *space;
isl_union_set *all, *domain;
isl_union_set_list *filters;
isl_union_map *extension;
isl_schedule_node *graft;
ctx = prog->ctx;
depth = isl_schedule_node_get_schedule_depth(node);
filters = create_copy_filters(prog, prefix, copy);
all = isl_union_set_list_union(isl_union_set_list_copy(filters));
space = depth < 0 ? NULL : isl_space_set_alloc(ctx, 0, depth);
domain = isl_union_set_from_set(isl_set_universe(space));
extension = isl_union_map_from_domain_and_range(domain, all);
graft = isl_schedule_node_from_extension(extension);
if (!filters)
return isl_schedule_node_free(graft);
if (isl_union_set_list_n_union_set(filters) == 0) {
isl_union_set_list_free(filters);
return graft;
}
return insert_positive_size_guards(graft, filters, depth);
}
/* Return (the universe spaces of) the arrays that are declared
* inside the scop corresponding to "prog" and for which all
* potential writes inside the scop form a subset of "domain".
*/
static __isl_give isl_union_set *extract_local_accesses(struct gpu_prog *prog,
__isl_keep isl_union_set *domain)
{
int i;
isl_union_set *local;
local = isl_union_set_empty(isl_union_set_get_space(domain));
for (i = 0; i < prog->n_array; ++i) {
isl_set *set;
isl_union_map *to_outer;
isl_union_map *may_write;
isl_union_set *write_domain;
isl_union_set *fields;
int subset;
if (!prog->array[i].local)
continue;
set = isl_set_universe(isl_space_copy(prog->array[i].space));
to_outer = isl_union_map_copy(prog->to_outer);
to_outer = isl_union_map_intersect_range(to_outer,
isl_union_set_from_set(isl_set_copy(set)));
fields = isl_union_map_domain(to_outer);
may_write = isl_union_map_copy(prog->may_write);
may_write = isl_union_map_intersect_range(may_write, fields);
write_domain = isl_union_map_domain(may_write);
subset = isl_union_set_is_subset(write_domain, domain);
isl_union_set_free(write_domain);
if (subset < 0) {
isl_set_free(set);
return isl_union_set_free(local);
} else if (subset) {
local = isl_union_set_add_set(local, set);
} else {
isl_set_free(set);
}
}
return local;
}
/* Internal data structure for node_may_persist.
*
* "tagger" maps tagged iteration domains to the corresponding untagged
* iteration domain.
*
* "may_persist_flow" is the set of all tagged dataflow dependences
* with those dependences removed that either precede or follow
* the kernel launch in a sequence.
* "inner_band_flow" is the set of all tagged dataflow dependences
* that are local to a given iteration of the outer band nodes
* with respect to the current node.
* "local_flow" is equal to "inner_band_flow", except that the domain
* and the range have been intersected with intermediate filters
* on children of sets or sequences.
*
* "local_may_overwrite" and "outer_may_overwrite" are subsets
* of tagged dependences between potentially live-out write accesses and
* write accesses to the same array (but not necessarily the same element)
* that cause the array to be copied out from the device.
* Such a dependence means that the array needs to be copied in first
* to ensure that the potentially live-out write access is not overwritten
* by the copy-ouy from the device.
* "local_may_overwrite" are those that are local to a given iteration
* of the outer band nodes with respect to the current node.
* "outer_may_overwrite" are those where the domain may be executed
* before the range.
*/
struct ppcg_may_persist_data {
isl_union_pw_multi_aff *tagger;
isl_union_map *local_flow;
isl_union_map *inner_band_flow;
isl_union_map *may_persist_flow;
isl_union_map *local_may_overwrite;
isl_union_map *outer_may_overwrite;
};
/* Update the may-overwrite information in "data"
* based on the partial schedule "partial" of some band ancestor node.
* The partial schedule is formulated in terms of the tagged
* original statement instances.
*
* "outer_may_overwrite" is extended with those dependences
* that are local to the outer nodes, but where the live-out write access
* appears before copy-out inducing access in the current band node.
* "local_may_overwrite" is narrowed down to those dependences
* that are also local to the current band node.
*/
static isl_stat update_may_overwrite_at_band(
__isl_keep isl_multi_union_pw_aff *partial,
struct ppcg_may_persist_data *data)
{
isl_union_map *local, *outer;
outer = isl_union_map_copy(data->local_may_overwrite);
outer = isl_union_map_lex_lt_at_multi_union_pw_aff(outer,
isl_multi_union_pw_aff_copy(partial));
outer = isl_union_map_union(data->outer_may_overwrite, outer);
data->outer_may_overwrite = outer;
local = data->local_may_overwrite;
local = isl_union_map_eq_at_multi_union_pw_aff(local,
isl_multi_union_pw_aff_copy(partial));
data->local_may_overwrite = local;
return isl_stat_ok;
}
/* Update the information in "data" based on the band ancestor "node".
*
* In particular, update the may-overwrite information.
* Also, restrict the dependences in data->local_flow
* to those dependence where the source and the sink occur in
* the same iteration of the given band node.
* We also update data->inner_band_flow to the new value of
* data->local_flow.
*/
static isl_stat update_may_persist_at_band(__isl_keep isl_schedule_node *node,
struct ppcg_may_persist_data *data)
{
isl_multi_union_pw_aff *partial;
isl_union_pw_multi_aff *contraction;
isl_union_map *flow;
if (isl_schedule_node_band_n_member(node) == 0)
return isl_stat_ok;
partial = isl_schedule_node_band_get_partial_schedule(node);
contraction = isl_schedule_node_get_subtree_contraction(node);
partial = isl_multi_union_pw_aff_pullback_union_pw_multi_aff(partial,
contraction);
partial = isl_multi_union_pw_aff_pullback_union_pw_multi_aff(partial,
isl_union_pw_multi_aff_copy(data->tagger));
if (update_may_overwrite_at_band(partial, data) < 0)
partial = isl_multi_union_pw_aff_free(partial);
flow = data->local_flow;
flow = isl_union_map_eq_at_multi_union_pw_aff(flow, partial);
data->local_flow = flow;
isl_union_map_free(data->inner_band_flow);
data->inner_band_flow = isl_union_map_copy(data->local_flow);
return isl_stat_ok;
}
/* Given a set of local reaching domain elements "domain",
* expand them to the corresponding leaf domain elements using "contraction"
* and insert the array references tags using data->tagger.
*/
static __isl_give isl_union_set *expand_and_tag(
__isl_take isl_union_set *domain,
__isl_take isl_union_pw_multi_aff *contraction,
struct ppcg_may_persist_data *data)
{
domain = isl_union_set_preimage_union_pw_multi_aff(domain,
contraction);
domain = isl_union_set_preimage_union_pw_multi_aff(domain,
isl_union_pw_multi_aff_copy(data->tagger));
return domain;
}
/* Apply the filter "filter" to both domain and range of "flow" and
* return the result.
*/
static __isl_give isl_union_map *apply_filter(__isl_take isl_union_map *flow,
__isl_take isl_union_set *filter)
{
flow = isl_union_map_intersect_domain(flow, isl_union_set_copy(filter));
flow = isl_union_map_intersect_range(flow, filter);
return flow;
}
/* Given a filter node that is the child of a set or sequence node,
* restrict data->local_flow and data->local_may_overwrite
* to refer only to those elements in the filter of the node.
* "contraction" maps the leaf domain elements of the schedule tree
* to the corresponding domain elements at (the parent of) "node".
*/
static isl_stat filter_flow(__isl_keep isl_schedule_node *node,
struct ppcg_may_persist_data *data,
__isl_take isl_union_pw_multi_aff *contraction)
{
isl_union_set *filter;
filter = isl_schedule_node_filter_get_filter(node);
filter = expand_and_tag(filter, contraction, data);
data->local_may_overwrite = apply_filter(data->local_may_overwrite,
isl_union_set_copy(filter));
data->local_flow = apply_filter(data->local_flow, filter);
return isl_stat_ok;
}
/* Given a filter node "node", collect the filters on all preceding siblings
* (which are also filter nodes), add them to "filters" and return the result.
*/
static __isl_give isl_union_set *add_previous_filters(
__isl_take isl_union_set *filters, __isl_keep isl_schedule_node *node)
{
isl_schedule_node *sibling;
sibling = isl_schedule_node_copy(node);
while (sibling && isl_schedule_node_has_previous_sibling(sibling)) {
isl_union_set *filter;
sibling = isl_schedule_node_previous_sibling(sibling);
filter = isl_schedule_node_filter_get_filter(sibling);
filters = isl_union_set_union(filters, filter);
}
isl_schedule_node_free(sibling);
if (!sibling)
return isl_union_set_free(filters);
return filters;
}
/* Given a filter node "node", collect the filters on all following siblings
* (which are also filter nodes), add them to "filters" and return the result.
*/
static __isl_give isl_union_set *add_next_filters(
__isl_take isl_union_set *filters, __isl_keep isl_schedule_node *node)
{
isl_schedule_node *sibling;
sibling = isl_schedule_node_copy(node);
while (sibling && isl_schedule_node_has_next_sibling(sibling)) {
isl_union_set *filter;
sibling = isl_schedule_node_next_sibling(sibling);
filter = isl_schedule_node_filter_get_filter(sibling);
filters = isl_union_set_union(filters, filter);
}
isl_schedule_node_free(sibling);
if (!sibling)
return isl_union_set_free(filters);
return filters;
}
/* Remove those flow dependences from data->may_persist_flow
* that flow between elements of "domain" within the same iteration
* of all outer band nodes.
* "contraction" maps the leaf domain elements of the schedule tree
* to the corresponding elements "domain".
*/
static void remove_external_flow(struct ppcg_may_persist_data *data,
__isl_take isl_union_set *domain,
__isl_keep isl_union_pw_multi_aff *contraction)
{
isl_union_map *flow;
contraction = isl_union_pw_multi_aff_copy(contraction);
domain = expand_and_tag(domain, contraction, data);
flow = isl_union_map_copy(data->local_flow);
flow = isl_union_map_intersect_domain(flow, isl_union_set_copy(domain));
flow = isl_union_map_intersect_range(flow, domain);
data->may_persist_flow = isl_union_map_subtract(data->may_persist_flow,
flow);
}
/* Remove those flow dependences from data->may_persist_flow
* that flow between statement instances that are both executed either before or
* after "node", within the same iteration of outer bands.
* "contraction" maps the leaf domain elements of the schedule tree
* to the corresponding elements of the filters of "domain" and its siblings.
*/
static void remove_all_external_flow(__isl_keep isl_schedule_node *node,
struct ppcg_may_persist_data *data,
__isl_keep isl_union_pw_multi_aff *contraction)
{
isl_space *space;
isl_union_set *before, *after, *filter;
filter = isl_schedule_node_filter_get_filter(node);
space = isl_union_set_get_space(filter);
isl_union_set_free(filter);
before = isl_union_set_empty(space);
after = isl_union_set_copy(before);
before = add_previous_filters(before, node);
after = add_next_filters(after, node);
remove_external_flow(data, before, contraction);
remove_external_flow(data, after, contraction);
}
/* Update the may-overwrite information in "data"
* based on the filter ancestor "node".
* "parent_type" is the type of the parent of the filter and
* is either isl_schedule_node_set or isl_schedule_node_sequence.
* "contraction" maps the leaf domain elements of the schedule tree
* to the corresponding domain elements at (the parent of) "node".
*
* First collect the filters of the siblings that may be executed
* before the current sibling. In the case of a sequence,
* these are the previous sibling. In the case of a set,
* these are all siblings of the current node.
* "outer_may_overwrite" is then extended with those dependences
* that are local to the outer nodes, but where the live-out write access
* appears in one of those siblings.
*/
static isl_stat update_may_overwrite_at_filter(
__isl_keep isl_schedule_node *node, struct ppcg_may_persist_data *data,
enum isl_schedule_node_type parent_type,
__isl_keep isl_union_pw_multi_aff *contraction)
{
isl_ctx *ctx;
isl_union_set *may_before;
isl_union_map *outer;
ctx = isl_schedule_node_get_ctx(node);
may_before = isl_union_set_empty_ctx(ctx);
may_before = add_previous_filters(may_before, node);
if (parent_type == isl_schedule_node_set)
may_before = add_next_filters(may_before, node);
may_before = isl_union_set_preimage_union_pw_multi_aff(may_before,
isl_union_pw_multi_aff_copy(contraction));
outer = isl_union_map_copy(data->local_may_overwrite);
outer = isl_union_map_intersect_domain_wrapped_domain_union_set(outer,
may_before);
data->outer_may_overwrite =
isl_union_map_union(data->outer_may_overwrite, outer);
return isl_stat_ok;
}
/* Update the information in "data" based on the filter ancestor "node".
* We only need to modify anything if the filter is the child
* of a set or sequence node.
*
* In particular, update the may-overwrite information.
*
* In the case of a sequence, we remove the dependences between
* statement instances that are both executed either before or
* after the subtree that will be mapped to a kernel, within
* the same iteration of outer bands.
*
* In both cases, data->local_flow and data->local_may_overwrite
* are restricted to the current child.
*/
static isl_stat update_may_persist_at_filter(__isl_keep isl_schedule_node *node,
struct ppcg_may_persist_data *data)
{
enum isl_schedule_node_type type;
isl_schedule_node *parent;
isl_union_pw_multi_aff *contraction;
type = isl_schedule_node_get_parent_type(node);
if (type != isl_schedule_node_sequence && type != isl_schedule_node_set)
return isl_stat_ok;
parent = isl_schedule_node_copy(node);
parent = isl_schedule_node_parent(parent);
contraction = isl_schedule_node_get_subtree_contraction(parent);
isl_schedule_node_free(parent);
if (update_may_overwrite_at_filter(node, data, type, contraction) < 0)
contraction = isl_union_pw_multi_aff_free(contraction);
if (type == isl_schedule_node_sequence)
remove_all_external_flow(node, data, contraction);
return filter_flow(node, data, contraction);
}
/* Update the information in "data" based on the ancestor "node".
*/
static isl_stat update_may_persist_at(__isl_keep isl_schedule_node *node,
void *user)
{
struct ppcg_may_persist_data *data = user;
switch (isl_schedule_node_get_type(node)) {
case isl_schedule_node_error:
return isl_stat_error;
case isl_schedule_node_context:
case isl_schedule_node_domain:
case isl_schedule_node_expansion:
case isl_schedule_node_extension:
case isl_schedule_node_guard:
case isl_schedule_node_leaf:
case isl_schedule_node_mark:
case isl_schedule_node_sequence:
case isl_schedule_node_set:
break;
case isl_schedule_node_band:
if (update_may_persist_at_band(node, data) < 0)
return isl_stat_error;
break;
case isl_schedule_node_filter:
if (update_may_persist_at_filter(node, data) < 0)
return isl_stat_error;
break;
}
return isl_stat_ok;
}
/* Initialize the "local_may_overwrite" and "outer_may_overwrite" fields
* of "data".
* "domain" contains the original statement instances covered
* by the copy-out, i.e.,
* those that correspond to the domains of the access relations in "prog".
* "copy_out" contains the outer arrays that will be copied out,
* relative to the statement instances that write to (some element of)
* the arrays.
*
* First consider the potential live-out writes from statement instances
* outside of "domain" and add the corresponding reference tags.
* Similarly, extend "copy_out" to map to the inner arrays and
* to include the reference tags.
*
* The initial value of "local_may_overwrite" maps the domain elements
* of these two relations that map to some common array element.
* The initial value of "outer_may_overwrite" is empty.
*/
static void init_may_overwrite(struct ppcg_may_persist_data *data,
__isl_keep isl_union_set *domain, __isl_keep isl_union_map *copy_out,
struct gpu_prog *prog)
{
isl_union_map *live_out, *tagged_live_out, *tagged_may_writes;
live_out = isl_union_map_copy(prog->scop->live_out);
live_out = isl_union_map_subtract_domain(live_out,
isl_union_set_copy(domain));
tagged_may_writes = isl_union_map_copy(prog->scop->tagged_may_writes);
tagged_live_out =
isl_union_map_intersect_domain_factor_domain(tagged_may_writes,
live_out);
copy_out = isl_union_map_copy(copy_out);
copy_out = isl_union_map_apply_range(copy_out,
isl_union_map_copy(prog->to_inner));
tagged_may_writes = isl_union_map_copy(prog->scop->tagged_may_writes);
tagged_may_writes = isl_union_map_universe(tagged_may_writes);
copy_out =
isl_union_map_intersect_domain_factor_domain(tagged_may_writes,
copy_out);
data->local_may_overwrite = isl_union_map_apply_range(tagged_live_out,
isl_union_map_reverse(copy_out));
data->outer_may_overwrite = isl_union_map_empty_ctx(prog->ctx);
}
/* Determine the set of array elements that may need to be preserved
* by a kernel constructed from the subtree at "node".
* This includes the set of array elements that may need to be preserved
* by the entire scop (prog->may_persist), the elements for which
* there is a potential flow dependence that may cross a kernel launch and
* the elements that are live-out that may get overwritten by a copy-out.
* "domain" contains the original statement instances, i.e.,
* those that correspond to the domains of the access relations in "prog".
* "copy_out" contains the outer arrays that will be copied out,
* relative to the statement instances that write to (some element of)
* the arrays.
*
* To determine the third set, relate all potential live-out write instances
* outside of "domain" to statement instances (in "domain")
* that write to the same array and collect those where
* the live-out write may occur before the other write.
* These live-out writes will be overwritten by the copy-out,
* so they need to be copied in first.
*
* To determine the second set, we start from all flow dependences.
* From this set of dependences, we remove those that cannot possibly
* require data to be preserved by a kernel launch.
* In particular, we consider the following sets of dependences.
* - dependences of which the write occurs inside the kernel.
* If the data is needed outside the kernel, then it will
* be copied out immediately after the kernel launch, so there
* is no need for any special care.
* - dependences of which the read occurs inside the kernel and the
* corresponding write occurs inside the same iteration of the
* outer band nodes. This means that the data is needed in
* the first kernel launch after the write, which is already
* taken care of by the standard copy-in. That is, the data
* do not need to be preserved by any intermediate call to
* the same kernel.
* - dependences of which the write and the read either both occur
* before the kernel launch or both occur after the kernel launch,
* within the same iteration of the outer band nodes with respect
* to the sequence that determines the ordering of the dependence
* and the kernel launch. Such flow dependences cannot cross
* any kernel launch.
*
* For the remaining (tagged) dependences, we take the domain
* (i.e., the tagged writes) and apply the tagged access relation
* to obtain the accessed data elements.
* These are then combined with the elements that may need to be
* preserved by the entire scop.
*/
static __isl_give isl_union_set *node_may_persist(
__isl_keep isl_schedule_node *node, __isl_keep isl_union_set *domain,
__isl_keep isl_union_map *copy_out, struct gpu_prog *prog)
{
struct ppcg_may_persist_data data;
isl_union_pw_multi_aff *contraction;
isl_union_set *persist;
isl_union_map *flow, *local_flow;
data.tagger = prog->scop->tagger;
flow = isl_union_map_copy(prog->scop->tagged_dep_flow);
data.local_flow = isl_union_map_copy(flow);
data.inner_band_flow = isl_union_map_copy(flow);
data.may_persist_flow = flow;
init_may_overwrite(&data, domain, copy_out, prog);
if (isl_schedule_node_foreach_ancestor_top_down(node,
&update_may_persist_at, &data) < 0)
data.may_persist_flow =
isl_union_map_free(data.may_persist_flow);
flow = data.may_persist_flow;
isl_union_map_free(data.local_flow);
domain = isl_union_set_copy(domain);
domain = isl_union_set_preimage_union_pw_multi_aff(domain,
isl_union_pw_multi_aff_copy(data.tagger));
flow = isl_union_map_subtract_domain(flow, isl_union_set_copy(domain));
local_flow = data.inner_band_flow;
local_flow = isl_union_map_intersect_range(local_flow, domain);
flow = isl_union_map_subtract(flow, local_flow);
flow = isl_union_map_union(flow, data.outer_may_overwrite);
isl_union_map_free(data.local_may_overwrite);
persist = isl_union_map_domain(flow);
persist = isl_union_set_apply(persist,
isl_union_map_copy(prog->scop->tagged_may_writes));
persist = isl_union_set_union(persist,
isl_union_set_copy(prog->may_persist));
return persist;
}
/* Add nodes for copying outer arrays in and out of the device
* before and after the subtree "node", which contains one or more kernels.
* "domain" contains the original statement instances, i.e.,
* those that correspond to the domains of the access relations in "prog".
* In particular, the domain has not been contracted in any way.
* "prefix" contains the prefix schedule at that point, in terms
* of the same original statement instances.
*
* We first compute the sets of outer array elements that need
* to be copied in and out and then graft in the nodes for
* performing this copying.
*
* In particular, for each array that is possibly written anywhere in
* the subtree "node" and that may be used after "node"
* or that may be visible outside the corresponding scop,
* we copy out its entire extent.
*
* Any array elements that is read without first being written inside
* the subtree "node" needs to be copied in.
* Furthermore, if there are any array elements that
* are copied out, but that may not be written inside "node", then
* they also need to be copied in to ensure that the value after execution
* is the same as the value before execution, at least for those array
* elements that may have their values preserved by the scop or that
* may be written before "node" and read after "node".
* In case the array elements are structures, we need to take into
* account that all members of the structures need to be written
* by "node" before we can avoid copying the data structure in.
*
* Note that the may_write relation is intersected with the domain,
* which has been intersected with the context.
* This helps in those cases where the arrays are declared with a fixed size,
* while the accesses are parametric and the context assigns a fixed value
* to the parameters.
*
* If an element from a local array is read without first being written,
* then there is no point in copying it in since it cannot have been
* written prior to the scop. Warn about the uninitialized read instead.
*/
static __isl_give isl_schedule_node *add_to_from_device(
__isl_take isl_schedule_node *node, __isl_take isl_union_set *domain,
__isl_take isl_union_map *prefix, struct gpu_prog *prog)
{
isl_union_set *local;
isl_union_set *may_persist;
isl_union_map *may_write, *must_write, *copy_out, *not_written;
isl_union_map *read, *copy_in;
isl_union_map *tagged;
isl_union_map *local_uninitialized;
isl_schedule_node *graft;
tagged = isl_union_map_copy(prog->scop->tagged_reads);
tagged = isl_union_map_union(tagged,
isl_union_map_copy(prog->scop->tagged_may_writes));
may_write = isl_union_map_copy(prog->may_write);
may_write = isl_union_map_intersect_domain(may_write,
isl_union_set_copy(domain));
may_write = remove_local_accesses(prog,
isl_union_map_copy(tagged), may_write,
isl_union_map_copy(prefix), 0);
may_write = isl_union_map_apply_range(may_write,
isl_union_map_copy(prog->to_outer));
copy_out = approximate_copy_out(may_write, prog);
may_persist = node_may_persist(node, domain, copy_out, prog);
copy_out = isl_union_map_apply_domain(copy_out,
isl_union_map_copy(prefix));
may_write = isl_union_map_copy(copy_out);
may_write = isl_union_map_apply_range(may_write,
isl_union_map_copy(prog->to_inner));
must_write = isl_union_map_copy(prog->must_write);
must_write = isl_union_map_apply_domain(must_write,
isl_union_map_copy(prefix));
may_write = isl_union_map_intersect_range(may_write, may_persist);
not_written = isl_union_map_subtract(may_write, must_write);
local = extract_local_accesses(prog, domain);
read = isl_union_map_copy(prog->read);
read = isl_union_map_intersect_domain(read, domain);
read = remove_local_accesses(prog, tagged, read,
isl_union_map_copy(prefix), 1);
local = isl_union_set_apply(local, isl_union_map_copy(prog->to_inner));
local_uninitialized = isl_union_map_copy(prog->scop->live_in);
local_uninitialized = isl_union_map_intersect_range(local_uninitialized,
local);
local_uninitialized = isl_union_map_intersect(local_uninitialized,
isl_union_map_copy(read));
if (!isl_union_map_is_empty(local_uninitialized)) {
fprintf(stderr,
"possibly uninitialized reads (not copied in):\n");
isl_union_map_dump(local_uninitialized);
}
read = isl_union_map_subtract(read, local_uninitialized);
read = isl_union_map_apply_domain(read, prefix);
copy_in = isl_union_map_union(read, not_written);
copy_in = isl_union_map_apply_range(copy_in,
isl_union_map_copy(prog->to_outer));
graft = create_copy_device(prog, node, "to_device",
isl_union_map_range(copy_in));
node = isl_schedule_node_graft_before(node, graft);
graft = create_copy_device(prog, node, "from_device",
isl_union_map_range(copy_out));
node = isl_schedule_node_graft_after(node, graft);
return node;
}
/* Add nodes for initializing ("init_device") and clearing ("clear_device")
* the device before and after "node".
*/
static __isl_give isl_schedule_node *add_init_clear_device(
__isl_take isl_schedule_node *node)
{
isl_ctx *ctx;
isl_space *space;
isl_union_set *domain;
isl_schedule_node *graft;
ctx = isl_schedule_node_get_ctx(node);
space = isl_space_set_alloc(ctx, 0, 0);
space = isl_space_set_tuple_name(space, isl_dim_set, "init_device");
domain = isl_union_set_from_set(isl_set_universe(space));
graft = isl_schedule_node_from_domain(domain);
node = isl_schedule_node_graft_before(node, graft);
space = isl_space_set_alloc(ctx, 0, 0);
space = isl_space_set_tuple_name(space, isl_dim_set, "clear_device");
domain = isl_union_set_from_set(isl_set_universe(space));
graft = isl_schedule_node_from_domain(domain);
node = isl_schedule_node_graft_after(node, graft);
return node;
}
/* Update "schedule" for mapping to a GPU device.
*
* In particular, insert a context node, create kernels for
* each outermost tilable band and introduce nodes for copying arrays
* in and out of the device and for initializing and clearing the device.
* If the child of the initial root points to a set node,
* then children of this node that do not contain any tilable bands
* are separated from the other children and are not mapped to
* the device.
*
* The GPU code is generated in a context where at least one
* statement instance is executed. The corresponding guard is inserted
* around the entire schedule.
*/
static __isl_give isl_schedule *map_to_device(struct gpu_gen *gen,
__isl_take isl_schedule *schedule)
{
isl_schedule_node *node;
isl_set *context;
isl_set *guard;
isl_union_set *domain;
isl_union_map *prefix;
isl_union_pw_multi_aff *contraction;
struct gpu_prog *prog;
context = isl_set_copy(gen->prog->context);
context = isl_set_from_params(context);
schedule = isl_schedule_insert_context(schedule, context);
prog = gen->prog;
guard = isl_union_set_params(isl_union_set_copy(prog->scop->domain));
prog->context = isl_set_intersect(prog->context, isl_set_copy(guard));
guard = isl_set_from_params(guard);
node = isl_schedule_get_root(schedule);
isl_schedule_free(schedule);
node = isl_schedule_node_child(node, 0);
node = isl_schedule_node_child(node, 0);
node = isolate_permutable_subtrees(node, gen->prog);
domain = isl_schedule_node_get_domain(node);
contraction = isl_schedule_node_get_subtree_contraction(node);
domain = isl_union_set_preimage_union_pw_multi_aff(domain,
isl_union_pw_multi_aff_copy(contraction));
prefix = isl_schedule_node_get_prefix_schedule_union_map(node);
prefix = isl_union_map_preimage_domain_union_pw_multi_aff(prefix,
contraction);
node = mark_kernels(gen, node);
node = add_to_from_device(node, domain, prefix, gen->prog);
node = isl_schedule_node_root(node);
node = isl_schedule_node_child(node, 0);
node = isl_schedule_node_child(node, 0);
node = isl_schedule_node_insert_guard(node, guard);
node = isl_schedule_node_child(node, 0);
node = add_init_clear_device(node);
schedule = isl_schedule_node_get_schedule(node);
isl_schedule_node_free(node);
return schedule;
}
/* Internal data structure for extract_access.
* "next_access" points to the end of a linked list that is extended
* by extract_access.
* "single_expression" is set if the access expressions belong to
* an expression statement (i.e., a statement without internal control).
* "any_to_outer" maps all intermediate arrays to their outer arrays.
*/
struct ppcg_extract_access_data {
struct gpu_stmt_access **next_access;
int single_expression;
isl_union_map *any_to_outer;
};
/* Given a tagged access relation to a single array "tagged", extract it
* as a map, taking into account that the input may be empty.
* If the access relation is empty, then it does not contain
* any space information, so we try to recover it from the index
* expression.
* The space of the index expression is of the form I -> A,
* with I the statement instances and A the array, or [I -> F] -> A,
* with F the filters corresponding to arguments.
* We first drop F, if present, obtaining I -> A.
* Then we construct I -> R, with R the reference tag,
* combine the two into I -> [R -> A] and uncurry to obtain
* the final result [I -> R] -> A.
* Note that the index expression may have a lower dimension
* than that of the array, but this dimension is not used
* if the access relation is empty.
*/
static __isl_give isl_map *extract_single_tagged_access(
__isl_take isl_union_map *tagged, __isl_keep pet_expr *expr)
{
int empty;
isl_id *id;
isl_space *space, *space2;
isl_multi_pw_aff *index;
empty = isl_union_map_is_empty(tagged);
if (empty < 0)
goto error;
if (!empty)
return isl_map_from_union_map(tagged);
isl_union_map_free(tagged);
index = pet_expr_access_get_index(expr);
space = isl_multi_pw_aff_get_space(index);
isl_multi_pw_aff_free(index);
if (isl_space_domain_is_wrapping(space))
space = isl_space_domain_factor_domain(space);
space2 = isl_space_from_domain(isl_space_domain(isl_space_copy(space)));
id = pet_expr_access_get_ref_id(expr);
space2 = isl_space_set_tuple_id(space2, isl_dim_out, id);
space = isl_space_range_product(space2, space);
space = isl_space_uncurry(space);
return isl_map_empty(space);
error:
isl_union_map_free(tagged);
return NULL;
}
/* Does the index expression "index" of "expr" represent an access
* to a single element?
* That is, is "index" completely specified?
*
* If "expr" accesses elements from different spaces (i.e., fields
* of a structure), then it does not access a single element.
* Otherwise, if the single space of the access matches the space
* of "index", then the index expression is completely specified
* (no pointer to a lower-dimensional slice of the accessed array)
* and a single element is being accessed.
*/
static isl_bool complete_index(__isl_keep pet_expr *expr,
__isl_keep isl_multi_pw_aff *index)
{
isl_union_map *read, *write, *all;
isl_map *map;
isl_space *space1, *space2;
isl_bool complete;
read = pet_expr_access_get_may_read(expr);
write = pet_expr_access_get_may_write(expr);
all = isl_union_map_union(read, write);
if (!all)
return isl_bool_error;
if (isl_union_map_n_map(all) != 1) {
isl_union_map_free(all);
return isl_bool_false;
}
map = isl_map_from_union_map(all);
space1 = isl_map_get_space(map);
isl_map_free(map);
space2 = isl_multi_pw_aff_get_space(index);
complete = isl_space_tuple_is_equal(space1, isl_dim_out,
space2, isl_dim_out);
isl_space_free(space1);
isl_space_free(space2);
return complete;
}
/* Does "expr" access a single, fixed element (independently of the statement
* instance)?
* That is, does it have a completely specified constant index expression?
*
* Note that it is not sufficient for the index expression to be
* piecewise constant. isl_multi_pw_aff_is_cst can therefore not be used.
*/
static isl_bool accesses_fixed_element(__isl_keep pet_expr *expr)
{
int i, n;
isl_multi_pw_aff *index;
isl_bool fixed = isl_bool_true;
index = pet_expr_access_get_index(expr);
if (index < 0)
return isl_bool_error;
n = isl_multi_pw_aff_dim(index, isl_dim_out);
for (i = 0; i < n; ++i) {
isl_pw_aff *pa;
pa = isl_multi_pw_aff_get_pw_aff(index, 0);
fixed = isl_pw_aff_n_piece(pa) == 1;
if (fixed)
fixed = isl_pw_aff_is_cst(pa);
isl_pw_aff_free(pa);
if (fixed < 0 || !fixed)
break;
}
if (fixed >= 0 && fixed)
fixed = complete_index(expr, index);
isl_multi_pw_aff_free(index);
return fixed;
}
/* Extract a gpu_stmt_access from "expr", append it to the list
* that ends in *data->next_access and update the end of the list.
* If the access expression performs a write, then it is considered
* exact only if it appears in a single expression statement and
* if its may access relation is equal to its must access relation.
*
* The combined set of may accesses may be a union if member accesses
* are involved, but the entire set is derived from a single reference and
* therefore from a single index expression. These accesses therefore
* all map to the same outer array.
*/
static int extract_access(__isl_keep pet_expr *expr, void *user)
{
struct ppcg_extract_access_data *data = user;
isl_union_map *tagged;
struct gpu_stmt_access *access;
isl_ctx *ctx = pet_expr_get_ctx(expr);
isl_multi_pw_aff *index;
access = isl_alloc_type(ctx, struct gpu_stmt_access);
if (!access)
return -1;
access->next = NULL;
access->read = pet_expr_access_is_read(expr);
access->write = pet_expr_access_is_write(expr);
tagged = pet_expr_access_get_tagged_may_read(expr);
tagged = isl_union_map_union(tagged,
pet_expr_access_get_tagged_may_write(expr));
tagged = isl_union_map_apply_range(tagged,
isl_union_map_copy(data->any_to_outer));
if (!access->write) {
access->exact_write = 1;
} else if (!data->single_expression) {
access->exact_write = 0;
} else {
isl_union_map *must, *may;
may = isl_union_map_copy(tagged);
may = isl_union_map_domain_factor_domain(may);
must = pet_expr_access_get_must_write(expr);
access->exact_write = isl_union_map_is_equal(must, may);
isl_union_map_free(must);
isl_union_map_free(may);
}
index = pet_expr_access_get_index(expr);
access->n_index = isl_multi_pw_aff_dim(index, isl_dim_out);
isl_multi_pw_aff_free(index);
access->ref_id = pet_expr_access_get_ref_id(expr);
access->tagged_access = extract_single_tagged_access(tagged, expr);
access->access = isl_map_copy(access->tagged_access);
access->access = isl_map_domain_factor_domain(access->access);
access->fixed_element = accesses_fixed_element(expr);
*data->next_access = access;
data->next_access = &(*data->next_access)->next;
if (!access->access || access->fixed_element < 0)
return -1;
return 0;
}
/* Construct a linked list of gpu_stmt_access objects,
* one for each access expression in the statement body.
* "any_to_outer" maps all intermediate arrays to their outer arrays.
*/
static int pet_stmt_extract_accesses(struct gpu_stmt *stmt,
__isl_keep isl_union_map *any_to_outer)
{
struct ppcg_extract_access_data data;
stmt->accesses = NULL;
data.next_access = &stmt->accesses;
data.single_expression =
pet_tree_get_type(stmt->stmt->body) == pet_tree_expr;
data.any_to_outer = any_to_outer;
return pet_tree_foreach_access_expr(stmt->stmt->body,
&extract_access, &data);
}
/* Has statement "stmt" been killed from "scop"?
* That is, is the instance set of "scop" free from any
* instances of "stmt"?
*/
static isl_bool is_stmt_killed(struct ppcg_scop *scop, struct pet_stmt *stmt)
{
isl_space *space;
isl_set *left;
isl_bool empty;
if (!scop || !stmt)
return isl_bool_error;
space = isl_set_get_space(stmt->domain);
left = isl_union_set_extract_set(scop->domain, space);
empty = isl_set_plain_is_empty(left);
isl_set_free(left);
return empty;
}
/* Return an array of gpu_stmt representing the statements in "scop".
* Do not collect array accesses for statements that have been killed.
*/
static struct gpu_stmt *extract_stmts(isl_ctx *ctx, struct ppcg_scop *scop,
__isl_keep isl_union_map *any_to_outer)
{
int i;
struct gpu_stmt *stmts;
stmts = isl_calloc_array(ctx, struct gpu_stmt, scop->pet->n_stmt);
if (!stmts)
return NULL;
for (i = 0; i < scop->pet->n_stmt; ++i) {
struct gpu_stmt *s = &stmts[i];
isl_bool killed;
s->id = isl_set_get_tuple_id(scop->pet->stmts[i]->domain);
s->stmt = scop->pet->stmts[i];
killed = is_stmt_killed(scop, scop->pet->stmts[i]);
if (killed < 0)
return free_stmts(stmts, i + 1);
if (killed)
continue;
if (pet_stmt_extract_accesses(s, any_to_outer) < 0)
return free_stmts(stmts, i + 1);
}
return stmts;
}
/* Generate CUDA code for "scop" and print it to "p".
* After generating an AST for the transformed scop as explained below,
* we call "gen->print" to print the AST in the desired output format
* to "p".
*
* If it turns out that it does not make sense to generate GPU code,
* then we generate CPU code instead.
*
* The declarations of the arrays that are visible outside of the scop
* are printed outside of the code generated from the schedule,
* because the generated code may involve a guard around the entire code.
*
* We first compute a schedule that respects the dependences
* of the original program and select the outermost bands
* of tilable dimensions that have at least one parallel loop.
* If the --load-schedule is specified, then the loaded schedule
* is used instead of a computed schedule.
*
* Each of these bands B is then tiled according to "tile" sizes, resulting
* in two nested bands, with a kernel marker on top
*
* K
* |
* T
* |
* P
*
* We then split off at most 2 parallel dimensions from the T band and
* at most 3 parallel dimension from the P band
*
* K
* |
* T
* T1
* |
* T2
* |
* P1
* |
* P2
*
* A filter is introduced in front of T1 that maps the domain instances
* to block identifiers. Similarly, a filter is introduced in front of P1
* that maps the domain instances to thread identifiers.
*
* For each iteration of the T2 band and for each array, we compute
* the array elements accessed by that iteration, construct a rectangular
* box around it and shift it to the origin. The result is used
* as shared memory for the array.
*
* Copying and synchronization statements are added to this schedule tree.
* In principle, these are added in front of the P1 band, but some of
* them may get hoisted up to higher levels.
*
* The entire AST is then generated from the single resulting schedule tree.
* During the generation the subtrees at kernel nodes (K) are saved
* aside and replaced by kernel calls. The result is printed as host code
* while the saved subtrees are printed as device code.
*/
static __isl_give isl_printer *generate(__isl_take isl_printer *p,
struct gpu_gen *gen, struct ppcg_scop *scop,
struct ppcg_options *options)
{
struct gpu_prog *prog;
isl_ctx *ctx;
isl_schedule *schedule;
isl_bool any_permutable;
if (!scop)
return isl_printer_free(p);
ctx = isl_printer_get_ctx(p);
prog = gpu_prog_alloc(ctx, scop);
if (!prog)
return isl_printer_free(p);
gen->prog = prog;
schedule = get_schedule(gen);
any_permutable = has_any_permutable_node(schedule);
if (any_permutable < 0 || !any_permutable) {
if (any_permutable < 0)
p = isl_printer_free(p);
else
p = print_cpu(p, scop, options);
isl_schedule_free(schedule);
} else {
schedule = map_to_device(gen, schedule);
gen->tree = generate_code(gen, schedule);
p = ppcg_set_macro_names(p);
p = ppcg_print_exposed_declarations(p, prog->scop);
p = gen->print(p, gen->prog, gen->tree, &gen->types,
gen->print_user);
isl_ast_node_free(gen->tree);
}
gpu_prog_free(prog);
return p;
}
/* Wrapper around generate for use as a ppcg_transform callback.
*/
static __isl_give isl_printer *generate_wrap(__isl_take isl_printer *p,
struct ppcg_scop *scop, void *user)
{
struct gpu_gen *gen = user;
return generate(p, gen, scop, gen->options);
}
/* Transform the code in the file called "input" by replacing
* all scops by corresponding GPU code and write the results to "out".
*/
int generate_gpu(isl_ctx *ctx, const char *input, FILE *out,
struct ppcg_options *options,
__isl_give isl_printer *(*print)(__isl_take isl_printer *p,
struct gpu_prog *prog, __isl_keep isl_ast_node *tree,
struct gpu_types *types, void *user), void *user)
{
struct gpu_gen gen;
int r;
int i;
gen.ctx = ctx;
gen.sizes = extract_sizes_from_str(ctx, options->sizes);
gen.options = options;
gen.kernel_id = 0;
gen.print = print;
gen.print_user = user;
gen.types.n = 0;
gen.types.name = NULL;
if (options->debug->dump_sizes) {
isl_space *space = isl_space_params_alloc(ctx, 0);
gen.used_sizes = isl_union_map_empty(space);
}
r = ppcg_transform(ctx, input, out, options, &generate_wrap, &gen);
if (options->debug->dump_sizes) {
isl_union_map_dump(gen.used_sizes);
isl_union_map_free(gen.used_sizes);
}
isl_union_map_free(gen.sizes);
for (i = 0; i < gen.types.n; ++i)
free(gen.types.name[i]);
free(gen.types.name);
return r;
}
/* Compute the set of inner array elements that may have their values
* preserved by "prog". In particular, collect the array elements of
* arrays that are not local to "prog" and remove those elements that
* are definitely killed or definitely written by "prog".
*/
static __isl_give isl_union_set *compute_may_persist(struct gpu_prog *prog)
{
int i;
isl_union_set *may_persist, *killed;
isl_union_map *must_kill;
may_persist = isl_union_set_empty(isl_set_get_space(prog->context));
for (i = 0; i < prog->n_array; ++i) {
isl_set *extent;
if (prog->array[i].local)
continue;
extent = isl_set_copy(prog->array[i].extent);
may_persist = isl_union_set_add_set(may_persist, extent);
}
may_persist = isl_union_set_intersect_params(may_persist,
isl_set_copy(prog->context));
may_persist = isl_union_set_apply(may_persist,
isl_union_map_copy(prog->to_inner));
must_kill = isl_union_map_copy(prog->tagged_must_kill);
killed = isl_union_map_range(must_kill);
must_kill = isl_union_map_copy(prog->must_write);
killed = isl_union_set_union(killed, isl_union_map_range(must_kill));
may_persist = isl_union_set_subtract(may_persist, killed);
return may_persist;
}
struct gpu_prog *gpu_prog_alloc(isl_ctx *ctx, struct ppcg_scop *scop)
{
struct gpu_prog *prog;
isl_space *space;
isl_map *id;
if (!scop)
return NULL;
prog = isl_calloc_type(ctx, struct gpu_prog);
if (!prog)
return NULL;
prog->ctx = ctx;
prog->scop = scop;
prog->context = isl_set_copy(scop->context);
prog->n_stmts = scop->pet->n_stmt;
prog->any_to_outer = pet_scop_compute_outer_to_any(scop->pet);
prog->any_to_outer = isl_union_map_reverse(prog->any_to_outer);
space = isl_union_map_get_space(prog->any_to_outer);
space = isl_space_set_from_params(space);
space = isl_space_add_dims(space, isl_dim_set, 1);
space = isl_space_map_from_set(space);
id = isl_map_identity(space);
prog->any_to_outer = isl_union_map_add_map(prog->any_to_outer, id);
prog->stmts = extract_stmts(ctx, scop, prog->any_to_outer);
prog->read = isl_union_map_copy(scop->reads);
prog->may_write = isl_union_map_copy(scop->may_writes);
prog->must_write = isl_union_map_copy(scop->must_writes);
prog->tagged_must_kill = isl_union_map_copy(scop->tagged_must_kills);
prog->to_inner = pet_scop_compute_outer_to_inner(scop->pet);
prog->to_outer = isl_union_map_copy(prog->to_inner);
prog->to_outer = isl_union_map_reverse(prog->to_outer);
if (!prog->stmts)
return gpu_prog_free(prog);
if (collect_array_info(prog) < 0)
return gpu_prog_free(prog);
prog->may_persist = compute_may_persist(prog);
return prog;
}
void *gpu_prog_free(struct gpu_prog *prog)
{
if (!prog)
return NULL;
free_array_info(prog);
free_stmts(prog->stmts, prog->n_stmts);
isl_union_map_free(prog->any_to_outer);
isl_union_map_free(prog->to_outer);
isl_union_map_free(prog->to_inner);
isl_union_map_free(prog->read);
isl_union_map_free(prog->may_write);
isl_union_map_free(prog->must_write);
isl_union_map_free(prog->tagged_must_kill);
isl_union_map_free(prog->array_order);
isl_union_set_free(prog->may_persist);
isl_set_free(prog->context);
free(prog);
return NULL;
}
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