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android / toolchain / cloog / 98972d5434ffcb4d11d2c81a46600e9a1cda9110 / . / cloog-0.17.0 / source / clast.c
blob: 0b67532e5fa2435ee27dd088e49afa72da0ccc1a [file] [log] [blame]
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "../include/cloog/cloog.h"
#define ALLOC(type) (type*)malloc(sizeof(type))
#define ALLOCN(type,n) (type*)malloc((n)*sizeof(type))
/**
* CloogInfos structure:
* this structure contains all the informations necessary for pretty printing,
* they come from the original CloogProgram structure (language, names), from
* genereral options (options) or are built only for pretty printing (stride).
* This structure is mainly there to reduce the number of function parameters,
* since most pprint.c functions need most of its field.
*/
struct clooginfos {
CloogState *state; /**< State. */
CloogStride **stride;
int stride_level; /**< Number of valid entries in stride array. */
int nb_scattdims ; /**< Scattering dimension number. */
int * scaldims ; /**< Boolean array saying whether a given
* scattering dimension is scalar or not.
*/
CloogNames * names ; /**< Names of iterators and parameters. */
CloogOptions * options ; /**< Options on CLooG's behaviour. */
CloogEqualities *equal; /**< Matrix of equalities. */
} ;
typedef struct clooginfos CloogInfos ;
static int clast_expr_cmp(struct clast_expr *e1, struct clast_expr *e2);
static int clast_term_cmp(struct clast_term *t1, struct clast_term *t2);
static int clast_binary_cmp(struct clast_binary *b1, struct clast_binary *b2);
static int clast_reduction_cmp(struct clast_reduction *r1,
struct clast_reduction *r2);
static struct clast_expr *clast_expr_copy(struct clast_expr *e);
static int clast_equal_add(CloogEqualities *equal,
CloogConstraintSet *constraints,
int level, CloogConstraint *constraint,
CloogInfos *infos);
static struct clast_stmt *clast_equal(int level, CloogInfos *infos);
static struct clast_expr *clast_minmax(CloogConstraintSet *constraints,
int level, int max, int guard,
int lower_bound, int no_earlier,
CloogInfos *infos);
static void insert_guard(CloogConstraintSet *constraints, int level,
struct clast_stmt ***next, CloogInfos *infos);
static int insert_modulo_guard(CloogConstraint *upper,
CloogConstraint *lower, int level,
struct clast_stmt ***next, CloogInfos *infos);
static int insert_equation(CloogDomain *domain, CloogConstraint *upper,
CloogConstraint *lower, int level,
struct clast_stmt ***next, CloogInfos *infos);
static int insert_for(CloogDomain *domain, CloogConstraintSet *constraints,
int level, int otl, struct clast_stmt ***next,
CloogInfos *infos);
static void insert_block(CloogDomain *domain, CloogBlock *block, int level,
struct clast_stmt ***next, CloogInfos *infos);
static void insert_loop(CloogLoop * loop, int level,
struct clast_stmt ***next, CloogInfos *infos);
struct clast_name *new_clast_name(const char *name)
{
struct clast_name *n = malloc(sizeof(struct clast_name));
n->expr.type = clast_expr_name;
n->name = name;
return n;
}
struct clast_term *new_clast_term(cloog_int_t c, struct clast_expr *v)
{
struct clast_term *t = malloc(sizeof(struct clast_term));
t->expr.type = clast_expr_term;
cloog_int_init(t->val);
cloog_int_set(t->val, c);
t->var = v;
return t;
}
struct clast_binary *new_clast_binary(enum clast_bin_type t,
struct clast_expr *lhs, cloog_int_t rhs)
{
struct clast_binary *b = malloc(sizeof(struct clast_binary));
b->expr.type = clast_expr_bin;
b->type = t;
b->LHS = lhs;
cloog_int_init(b->RHS);
cloog_int_set(b->RHS, rhs);
return b;
}
struct clast_reduction *new_clast_reduction(enum clast_red_type t, int n)
{
int i;
struct clast_reduction *r;
r = malloc(sizeof(struct clast_reduction)+(n-1)*sizeof(struct clast_expr *));
r->expr.type = clast_expr_red;
r->type = t;
r->n = n;
for (i = 0; i < n; ++i)
r->elts[i] = NULL;
return r;
}
static void free_clast_root(struct clast_stmt *s);
const struct clast_stmt_op stmt_root = { free_clast_root };
static void free_clast_root(struct clast_stmt *s)
{
struct clast_root *r = (struct clast_root *)s;
assert(CLAST_STMT_IS_A(s, stmt_root));
cloog_names_free(r->names);
free(r);
}
struct clast_root *new_clast_root(CloogNames *names)
{
struct clast_root *r = malloc(sizeof(struct clast_root));
r->stmt.op = &stmt_root;
r->stmt.next = NULL;
r->names = cloog_names_copy(names);
return r;
}
static void free_clast_assignment(struct clast_stmt *s);
const struct clast_stmt_op stmt_ass = { free_clast_assignment };
static void free_clast_assignment(struct clast_stmt *s)
{
struct clast_assignment *a = (struct clast_assignment *)s;
assert(CLAST_STMT_IS_A(s, stmt_ass));
free_clast_expr(a->RHS);
free(a);
}
struct clast_assignment *new_clast_assignment(const char *lhs,
struct clast_expr *rhs)
{
struct clast_assignment *a = malloc(sizeof(struct clast_assignment));
a->stmt.op = &stmt_ass;
a->stmt.next = NULL;
a->LHS = lhs;
a->RHS = rhs;
return a;
}
static void free_clast_user_stmt(struct clast_stmt *s);
const struct clast_stmt_op stmt_user = { free_clast_user_stmt };
static void free_clast_user_stmt(struct clast_stmt *s)
{
struct clast_user_stmt *u = (struct clast_user_stmt *)s;
assert(CLAST_STMT_IS_A(s, stmt_user));
cloog_domain_free(u->domain);
cloog_statement_free(u->statement);
cloog_clast_free(u->substitutions);
free(u);
}
struct clast_user_stmt *new_clast_user_stmt(CloogDomain *domain,
CloogStatement *stmt, struct clast_stmt *subs)
{
struct clast_user_stmt *u = malloc(sizeof(struct clast_user_stmt));
u->stmt.op = &stmt_user;
u->stmt.next = NULL;
u->domain = cloog_domain_copy(domain);
u->statement = cloog_statement_copy(stmt);
u->substitutions = subs;
return u;
}
static void free_clast_block(struct clast_stmt *b);
const struct clast_stmt_op stmt_block = { free_clast_block };
static void free_clast_block(struct clast_stmt *s)
{
struct clast_block *b = (struct clast_block *)s;
assert(CLAST_STMT_IS_A(s, stmt_block));
cloog_clast_free(b->body);
free(b);
}
struct clast_block *new_clast_block()
{
struct clast_block *b = malloc(sizeof(struct clast_block));
b->stmt.op = &stmt_block;
b->stmt.next = NULL;
b->body = NULL;
return b;
}
static void free_clast_for(struct clast_stmt *s);
const struct clast_stmt_op stmt_for = { free_clast_for };
static void free_clast_for(struct clast_stmt *s)
{
struct clast_for *f = (struct clast_for *)s;
assert(CLAST_STMT_IS_A(s, stmt_for));
cloog_domain_free(f->domain);
free_clast_expr(f->LB);
free_clast_expr(f->UB);
cloog_int_clear(f->stride);
cloog_clast_free(f->body);
free(f);
}
struct clast_for *new_clast_for(CloogDomain *domain, const char *it,
struct clast_expr *LB, struct clast_expr *UB,
CloogStride *stride)
{
struct clast_for *f = malloc(sizeof(struct clast_for));
f->stmt.op = &stmt_for;
f->stmt.next = NULL;
f->domain = cloog_domain_copy(domain);
f->iterator = it;
f->LB = LB;
f->UB = UB;
f->body = NULL;
cloog_int_init(f->stride);
if (stride)
cloog_int_set(f->stride, stride->stride);
else
cloog_int_set_si(f->stride, 1);
return f;
}
static void free_clast_guard(struct clast_stmt *s);
const struct clast_stmt_op stmt_guard = { free_clast_guard };
static void free_clast_guard(struct clast_stmt *s)
{
int i;
struct clast_guard *g = (struct clast_guard *)s;
assert(CLAST_STMT_IS_A(s, stmt_guard));
cloog_clast_free(g->then);
for (i = 0; i < g->n; ++i) {
free_clast_expr(g->eq[i].LHS);
free_clast_expr(g->eq[i].RHS);
}
free(g);
}
struct clast_guard *new_clast_guard(int n)
{
int i;
struct clast_guard *g = malloc(sizeof(struct clast_guard) +
(n-1) * sizeof(struct clast_equation));
g->stmt.op = &stmt_guard;
g->stmt.next = NULL;
g->then = NULL;
g->n = n;
for (i = 0; i < n; ++i) {
g->eq[i].LHS = NULL;
g->eq[i].RHS = NULL;
}
return g;
}
void free_clast_name(struct clast_name *n)
{
free(n);
}
void free_clast_term(struct clast_term *t)
{
cloog_int_clear(t->val);
free_clast_expr(t->var);
free(t);
}
void free_clast_binary(struct clast_binary *b)
{
cloog_int_clear(b->RHS);
free_clast_expr(b->LHS);
free(b);
}
void free_clast_reduction(struct clast_reduction *r)
{
int i;
for (i = 0; i < r->n; ++i)
free_clast_expr(r->elts[i]);
free(r);
}
void free_clast_expr(struct clast_expr *e)
{
if (!e)
return;
switch (e->type) {
case clast_expr_name:
free_clast_name((struct clast_name*) e);
break;
case clast_expr_term:
free_clast_term((struct clast_term*) e);
break;
case clast_expr_red:
free_clast_reduction((struct clast_reduction*) e);
break;
case clast_expr_bin:
free_clast_binary((struct clast_binary*) e);
break;
default:
assert(0);
}
}
void free_clast_stmt(struct clast_stmt *s)
{
assert(s->op);
assert(s->op->free);
s->op->free(s);
}
void cloog_clast_free(struct clast_stmt *s)
{
struct clast_stmt *next;
while (s) {
next = s->next;
free_clast_stmt(s);
s = next;
}
}
static int clast_name_cmp(struct clast_name *n1, struct clast_name *n2)
{
return n1->name == n2->name ? 0 : strcmp(n1->name, n2->name);
}
static int clast_term_cmp(struct clast_term *t1, struct clast_term *t2)
{
int c;
if (!t1->var && t2->var)
return -1;
if (t1->var && !t2->var)
return 1;
c = clast_expr_cmp(t1->var, t2->var);
if (c)
return c;
return cloog_int_cmp(t1->val, t2->val);
}
static int clast_binary_cmp(struct clast_binary *b1, struct clast_binary *b2)
{
int c;
if (b1->type != b2->type)
return b1->type - b2->type;
if ((c = cloog_int_cmp(b1->RHS, b2->RHS)))
return c;
return clast_expr_cmp(b1->LHS, b2->LHS);
}
static int clast_reduction_cmp(struct clast_reduction *r1, struct clast_reduction *r2)
{
int i;
int c;
if (r1->n == 1 && r2->n == 1)
return clast_expr_cmp(r1->elts[0], r2->elts[0]);
if (r1->type != r2->type)
return r1->type - r2->type;
if (r1->n != r2->n)
return r1->n - r2->n;
for (i = 0; i < r1->n; ++i)
if ((c = clast_expr_cmp(r1->elts[i], r2->elts[i])))
return c;
return 0;
}
static int clast_expr_cmp(struct clast_expr *e1, struct clast_expr *e2)
{
if (!e1 && !e2)
return 0;
if (!e1)
return -1;
if (!e2)
return 1;
if (e1->type != e2->type)
return e1->type - e2->type;
switch (e1->type) {
case clast_expr_name:
return clast_name_cmp((struct clast_name*) e1,
(struct clast_name*) e2);
case clast_expr_term:
return clast_term_cmp((struct clast_term*) e1,
(struct clast_term*) e2);
case clast_expr_bin:
return clast_binary_cmp((struct clast_binary*) e1,
(struct clast_binary*) e2);
case clast_expr_red:
return clast_reduction_cmp((struct clast_reduction*) e1,
(struct clast_reduction*) e2);
default:
assert(0);
}
}
int clast_expr_equal(struct clast_expr *e1, struct clast_expr *e2)
{
return clast_expr_cmp(e1, e2) == 0;
}
/**
* Return 1 is both expressions are constant terms and e1 is bigger than e2.
*/
int clast_expr_is_bigger_constant(struct clast_expr *e1, struct clast_expr *e2)
{
struct clast_term *t1, *t2;
struct clast_reduction *r;
if (!e1 || !e2)
return 0;
if (e1->type == clast_expr_red) {
r = (struct clast_reduction *)e1;
return r->n == 1 && clast_expr_is_bigger_constant(r->elts[0], e2);
}
if (e2->type == clast_expr_red) {
r = (struct clast_reduction *)e2;
return r->n == 1 && clast_expr_is_bigger_constant(e1, r->elts[0]);
}
if (e1->type != clast_expr_term || e2->type != clast_expr_term)
return 0;
t1 = (struct clast_term *)e1;
t2 = (struct clast_term *)e2;
if (t1->var || t2->var)
return 0;
return cloog_int_gt(t1->val, t2->val);
}
static int qsort_expr_cmp(const void *p1, const void *p2)
{
return clast_expr_cmp(*(struct clast_expr **)p1, *(struct clast_expr **)p2);
}
static void clast_reduction_sort(struct clast_reduction *r)
{
qsort(&r->elts[0], r->n, sizeof(struct clast_expr *), qsort_expr_cmp);
}
static int qsort_eq_cmp(const void *p1, const void *p2)
{
struct clast_equation *eq1 = (struct clast_equation *)p1;
struct clast_equation *eq2 = (struct clast_equation *)p2;
int cmp;
cmp = clast_expr_cmp(eq1->LHS, eq2->LHS);
if (cmp)
return cmp;
cmp = clast_expr_cmp(eq1->RHS, eq2->RHS);
if (cmp)
return cmp;
return eq1->sign - eq2->sign;
}
/**
* Sort equations in a clast_guard.
*/
static void clast_guard_sort(struct clast_guard *g)
{
qsort(&g->eq[0], g->n, sizeof(struct clast_equation), qsort_eq_cmp);
}
/**
* Construct a (deep) copy of an expression clast.
*/
static struct clast_expr *clast_expr_copy(struct clast_expr *e)
{
if (!e)
return NULL;
switch (e->type) {
case clast_expr_name: {
struct clast_name* n = (struct clast_name*) e;
return &new_clast_name(n->name)->expr;
}
case clast_expr_term: {
struct clast_term* t = (struct clast_term*) e;
return &new_clast_term(t->val, clast_expr_copy(t->var))->expr;
}
case clast_expr_red: {
int i;
struct clast_reduction *r = (struct clast_reduction*) e;
struct clast_reduction *r2 = new_clast_reduction(r->type, r->n);
for (i = 0; i < r->n; ++i)
r2->elts[i] = clast_expr_copy(r->elts[i]);
return &r2->expr;
}
case clast_expr_bin: {
struct clast_binary *b = (struct clast_binary*) e;
return &new_clast_binary(b->type, clast_expr_copy(b->LHS), b->RHS)->expr;
}
default:
assert(0);
}
}
/******************************************************************************
* Equalities spreading functions *
******************************************************************************/
/**
* clast_equal_allow function:
* This function checks whether the options allow us to spread the equality or
* not. It returns 1 if so, 0 otherwise.
* - equal is the matrix of equalities,
* - level is the column number in equal of the element which is 'equal to',
* - line is the line number in equal of the constraint we want to study,
* - the infos structure gives the user all options on code printing and more.
**
* - October 27th 2005: first version (extracted from old pprint_equal_add).
*/
static int clast_equal_allow(CloogEqualities *equal, int level, int line,
CloogInfos *infos)
{
if (level < infos->options->fsp)
return 0 ;
if ((cloog_equal_type(equal, level) == EQTYPE_EXAFFINE) &&
!infos->options->esp)
return 0 ;
return 1 ;
}
/**
* clast_equal_add function:
* This function updates the row (level-1) of the equality matrix (equal) with
* the row that corresponds to the row (line) of the matrix (matrix). It returns
* 1 if the row can be updated, 0 otherwise.
* - equal is the matrix of equalities,
* - matrix is the matrix of constraints,
* - level is the column number in matrix of the element which is 'equal to',
* - line is the line number in matrix of the constraint we want to study,
* - the infos structure gives the user all options on code printing and more.
*/
static int clast_equal_add(CloogEqualities *equal,
CloogConstraintSet *constraints,
int level, CloogConstraint *constraint,
CloogInfos *infos)
{
cloog_equal_add(equal, constraints, level, constraint,
infos->names->nb_parameters);
return clast_equal_allow(equal, level, level-1, infos);
}
/**
* clast_equal function:
* This function prints the substitution data of a statement into a clast_stmt.
* Using this function instead of pprint_equal is useful for generating
* a compilable pseudo-code by using preprocessor macro for each statement.
* By opposition to pprint_equal, the result is less human-readable. For
* instance this function will print (i,i+3,k,3) where pprint_equal would
* return (j=i+3,l=3).
* - level is the number of loops enclosing the statement,
* - the infos structure gives the user all options on code printing and more.
**
* - March 12th 2004: first version.
* - November 21th 2005: (debug) now works well with GMP version.
*/
static struct clast_stmt *clast_equal(int level, CloogInfos *infos)
{
int i ;
struct clast_expr *e;
struct clast_stmt *a = NULL;
struct clast_stmt **next = &a;
CloogEqualities *equal = infos->equal;
CloogConstraint *equal_constraint;
for (i=infos->names->nb_scattering;i<level-1;i++)
{ if (cloog_equal_type(equal, i+1)) {
equal_constraint = cloog_equal_constraint(equal, i);
e = clast_bound_from_constraint(equal_constraint, i+1, infos->names);
cloog_constraint_release(equal_constraint);
} else {
e = &new_clast_term(infos->state->one, &new_clast_name(
cloog_names_name_at_level(infos->names, i+1))->expr)->expr;
}
*next = &new_clast_assignment(NULL, e)->stmt;
next = &(*next)->next;
}
return a;
}
/**
* clast_bound_from_constraint function:
* This function returns a clast_expr containing the printing of the
* 'right part' of a constraint according to an element.
* For instance, for the constraint -3*i + 2*j - M >=0 and the element j,
* we have j >= (3*i + M)/2. As we are looking for integral solutions, this
* function should return 'ceild(3*i+M,2)'.
* - matrix is the polyhedron containing all the constraints,
* - line_num is the line number in domain of the constraint we want to print,
* - level is the column number in domain of the element we want to use,
* - names structure gives the user some options about code printing,
* the number of parameters in domain (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - November 2nd 2001: first version.
* - June 27th 2003: 64 bits version ready.
*/
struct clast_expr *clast_bound_from_constraint(CloogConstraint *constraint,
int level, CloogNames *names)
{
int i, sign, nb_elts=0, len;
cloog_int_t *line, numerator, denominator, temp, division;
struct clast_expr *e = NULL;
struct cloog_vec *line_vector;
len = cloog_constraint_total_dimension(constraint) + 2;
line_vector = cloog_vec_alloc(len);
line = line_vector->p;
cloog_constraint_copy_coefficients(constraint, line+1);
cloog_int_init(temp);
cloog_int_init(numerator);
cloog_int_init(denominator);
if (!cloog_int_is_zero(line[level])) {
struct clast_reduction *r;
/* Maybe we need to invert signs in such a way that the element sign is>0.*/
sign = -cloog_int_sgn(line[level]);
for (i = 1, nb_elts = 0; i <= len - 1; ++i)
if (i != level && !cloog_int_is_zero(line[i]))
nb_elts++;
r = new_clast_reduction(clast_red_sum, nb_elts);
nb_elts = 0;
/* First, we have to print the iterators and the parameters. */
for (i = 1; i <= len - 2; i++) {
struct clast_expr *v;
if (i == level || cloog_int_is_zero(line[i]))
continue;
v = cloog_constraint_variable_expr(constraint, i, names);
if (sign == -1)
cloog_int_neg(temp,line[i]);
else
cloog_int_set(temp,line[i]);
r->elts[nb_elts++] = &new_clast_term(temp, v)->expr;
}
if (sign == -1) {
cloog_int_neg(numerator, line[len - 1]);
cloog_int_set(denominator, line[level]);
}
else {
cloog_int_set(numerator, line[len - 1]);
cloog_int_neg(denominator, line[level]);
}
/* Finally, the constant, and the final printing. */
if (nb_elts) {
if (!cloog_int_is_zero(numerator))
r->elts[nb_elts++] = &new_clast_term(numerator, NULL)->expr;
if (!cloog_int_is_one(line[level]) && !cloog_int_is_neg_one(line[level]))
{ if (!cloog_constraint_is_equality(constraint))
{ if (cloog_int_is_pos(line[level]))
e = &new_clast_binary(clast_bin_cdiv, &r->expr, denominator)->expr;
else
e = &new_clast_binary(clast_bin_fdiv, &r->expr, denominator)->expr;
} else
e = &new_clast_binary(clast_bin_div, &r->expr, denominator)->expr;
}
else
e = &r->expr;
} else {
free_clast_reduction(r);
if (cloog_int_is_zero(numerator))
e = &new_clast_term(numerator, NULL)->expr;
else
{ if (!cloog_int_is_one(denominator))
{ if (!cloog_constraint_is_equality(constraint)) { /* useful? */
if (cloog_int_is_divisible_by(numerator, denominator)) {
cloog_int_divexact(temp, numerator, denominator);
e = &new_clast_term(temp, NULL)->expr;
}
else {
cloog_int_init(division);
cloog_int_tdiv_q(division, numerator, denominator);
if (cloog_int_is_neg(numerator)) {
if (cloog_int_is_pos(line[level])) {
/* nb<0 need max */
e = &new_clast_term(division, NULL)->expr;
} else {
/* nb<0 need min */
cloog_int_sub_ui(temp, division, 1);
e = &new_clast_term(temp, NULL)->expr;
}
}
else
{ if (cloog_int_is_pos(line[level]))
{ /* nb>0 need max */
cloog_int_add_ui(temp, division, 1);
e = &new_clast_term(temp, NULL)->expr;
}
else
/* nb>0 need min */
e = &new_clast_term(division, NULL)->expr;
}
cloog_int_clear(division);
}
}
else
e = &new_clast_binary(clast_bin_div,
&new_clast_term(numerator, NULL)->expr,
denominator)->expr;
}
else
e = &new_clast_term(numerator, NULL)->expr;
}
}
}
cloog_vec_free(line_vector);
cloog_int_clear(temp);
cloog_int_clear(numerator);
cloog_int_clear(denominator);
return e;
}
/* Temporary structure for communication between clast_minmax and
* its cloog_constraint_set_foreach_constraint callback functions.
*/
struct clast_minmax_data {
int level;
int max;
int guard;
int lower_bound;
int no_earlier;
CloogInfos *infos;
int n;
struct clast_reduction *r;
};
/* Should constraint "c" be considered by clast_minmax?
*
* If d->no_earlier is set, then the constraint may not involve
* any earlier variables.
*/
static int valid_bound(CloogConstraint *c, struct clast_minmax_data *d)
{
int i;
if (d->max && !cloog_constraint_is_lower_bound(c, d->level - 1))
return 0;
if (!d->max && !cloog_constraint_is_upper_bound(c, d->level - 1))
return 0;
if (cloog_constraint_is_equality(c))
return 0;
if (d->guard && cloog_constraint_involves(c, d->guard - 1))
return 0;
if (d->no_earlier)
for (i = 0; i < d->level - 1; ++i)
if (cloog_constraint_involves(c, i))
return 0;
return 1;
}
/* Increment n for each bound that should be considered by clast_minmax.
*/
static int count_bounds(CloogConstraint *c, void *user)
{
struct clast_minmax_data *d = (struct clast_minmax_data *) user;
if (!valid_bound(c, d))
return 0;
d->n++;
return 0;
}
/* Update the given lower bound based on stride information,
* for those cases where the stride offset is represented by
* a constraint.
* Note that cloog_loop_stride may have already performed a
* similar update of the lower bounds, but the updated lower
* bounds may have been eliminated because they are redundant
* by definition. On the other hand, performing the update
* on an already updated constraint is an identity operation
* and is therefore harmless.
*/
static CloogConstraint *update_lower_bound_c(CloogConstraint *c, int level,
CloogStride *stride)
{
if (!stride->constraint)
return c;
return cloog_constraint_stride_lower_bound(c, level, stride);
}
/* Update the given lower bound based on stride information.
* If the stride offset is represented by a constraint,
* then we have already performed the update in update_lower_bound_c.
* Otherwise, the original lower bound is known to be a constant.
* If the bound has already been updated and it just happens
* to be a constant, then this function performs an identity
* operation on the constant.
*/
static void update_lower_bound(struct clast_expr *expr, int level,
CloogStride *stride)
{
struct clast_term *t;
if (stride->constraint)
return;
if (expr->type != clast_expr_term)
return;
t = (struct clast_term *)expr;
if (t->var)
return;
cloog_int_sub(t->val, t->val, stride->offset);
cloog_int_cdiv_q(t->val, t->val, stride->stride);
cloog_int_mul(t->val, t->val, stride->stride);
cloog_int_add(t->val, t->val, stride->offset);
}
/* Add all relevant bounds to r->elts and update lower bounds
* based on stride information.
*/
static int collect_bounds(CloogConstraint *c, void *user)
{
struct clast_minmax_data *d = (struct clast_minmax_data *) user;
if (!valid_bound(c, d))
return 0;
c = cloog_constraint_copy(c);
if (d->lower_bound && d->infos->stride[d->level - 1])
c = update_lower_bound_c(c, d->level, d->infos->stride[d->level - 1]);
d->r->elts[d->n] = clast_bound_from_constraint(c, d->level,
d->infos->names);
if (d->lower_bound && d->infos->stride[d->level - 1]) {
update_lower_bound(d->r->elts[d->n], d->level,
d->infos->stride[d->level - 1]);
}
cloog_constraint_release(c);
d->n++;
return 0;
}
/**
* clast_minmax function:
* This function returns a clast_expr containing the printing of a minimum or a
* maximum of the 'right parts' of all constraints according to an element.
* For instance consider the constraints:
* -3*i +2*j -M >= 0
* 2*i +j >= 0
* -i -j +2*M >= 0
* if we are looking for the minimum for the element j, the function should
* return 'max(ceild(3*i+M,2),-2*i)'.
* - constraints is the constraints,
* - level is the column number in domain of the element we want to use,
* - max is a boolean set to 1 if we are looking for a maximum, 0 for a minimum,
* - guard is set to 0 if there is no guard, and set to the level of the element
* with a guard otherwise (then the function gives the max or the min only
* for the constraint where the guarded coefficient is 0),
* - lower is set to 1 if the maximum is to be used a lower bound on a loop
* - no_earlier is set if no constraints should be used that involve
* earlier dimensions,
* - the infos structure gives the user some options about code printing,
* the number of parameters in domain (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - November 2nd 2001: first version.
*/
static struct clast_expr *clast_minmax(CloogConstraintSet *constraints,
int level, int max, int guard,
int lower_bound, int no_earlier,
CloogInfos *infos)
{
struct clast_minmax_data data = { level, max, guard, lower_bound,
no_earlier, infos };
data.n = 0;
cloog_constraint_set_foreach_constraint(constraints, count_bounds, &data);
if (!data.n)
return NULL;
data.r = new_clast_reduction(max ? clast_red_max : clast_red_min, data.n);
data.n = 0;
cloog_constraint_set_foreach_constraint(constraints, collect_bounds, &data);
clast_reduction_sort(data.r);
return &data.r->expr;
}
/**
* Insert modulo guards defined by existentially quantified dimensions,
* not involving the given level.
*
* This function is called from within insert_guard.
* Any constraint used in constructing a modulo guard is removed
* from the constraint set to avoid insert_guard
* adding a duplicate (pair of) constraint(s).
*
* Return the updated CloogConstraintSet.
*/
static CloogConstraintSet *insert_extra_modulo_guards(
CloogConstraintSet *constraints, int level,
struct clast_stmt ***next, CloogInfos *infos)
{
int i;
int nb_iter;
int total_dim;
CloogConstraint *upper, *lower;
total_dim = cloog_constraint_set_total_dimension(constraints);
nb_iter = cloog_constraint_set_n_iterators(constraints,
infos->names->nb_parameters);
for (i = total_dim - infos->names->nb_parameters; i >= nb_iter + 1; i--) {
if (cloog_constraint_is_valid(upper =
cloog_constraint_set_defining_equality(constraints, i))) {
if (!level || (nb_iter < level) ||
!cloog_constraint_involves(upper, level-1)) {
insert_modulo_guard(upper,
cloog_constraint_invalid(), i, next, infos);
constraints = cloog_constraint_set_drop_constraint(constraints,
upper);
}
cloog_constraint_release(upper);
} else if (cloog_constraint_is_valid(upper =
cloog_constraint_set_defining_inequalities(constraints,
i, &lower, infos->names->nb_parameters))) {
if (!level || (nb_iter < level) ||
!cloog_constraint_involves(upper, level-1)) {
insert_modulo_guard(upper, lower, i, next, infos);
constraints = cloog_constraint_set_drop_constraint(constraints,
upper);
constraints = cloog_constraint_set_drop_constraint(constraints,
lower);
}
cloog_constraint_release(upper);
cloog_constraint_release(lower);
}
}
return constraints;
}
/* Temporary structure for communication between insert_guard and
* its cloog_constraint_set_foreach_constraint callback function.
*/
struct clast_guard_data {
int level;
CloogInfos *infos;
int n;
int i;
int nb_iter;
CloogConstraintSet *copy;
struct clast_guard *g;
int min;
int max;
};
static int guard_count_bounds(CloogConstraint *c, void *user)
{
struct clast_guard_data *d = (struct clast_guard_data *) user;
d->n++;
return 0;
}
/* Insert a guard, if necesessary, for constraint j.
*
* If the constraint involves any earlier dimensions, then we have
* already considered it during a previous iteration over the constraints.
*
* If we have already generated a min [max] for the current level d->i
* and if the current constraint is an upper [lower] bound, then we
* can skip the constraint as it will already have been used
* in that previously generated min [max].
*/
static int insert_guard_constraint(CloogConstraint *j, void *user)
{
int i;
struct clast_guard_data *d = (struct clast_guard_data *) user;
int minmax = -1;
int individual_constraint;
struct clast_expr *v;
struct clast_term *t;
if (!cloog_constraint_involves(j, d->i - 1))
return 0;
for (i = 0; i < d->i - 1; ++i)
if (cloog_constraint_involves(j, i))
return 0;
if (d->level && d->nb_iter >= d->level &&
cloog_constraint_involves(j, d->level - 1))
return 0;
individual_constraint = !d->level || cloog_constraint_is_equality(j);
if (!individual_constraint) {
if (d->max && cloog_constraint_is_lower_bound(j, d->i - 1))
return 0;
if (d->min && cloog_constraint_is_upper_bound(j, d->i - 1))
return 0;
}
v = cloog_constraint_variable_expr(j, d->i, d->infos->names);
d->g->eq[d->n].LHS = &(t = new_clast_term(d->infos->state->one, v))->expr;
if (individual_constraint) {
/* put the "denominator" in the LHS */
cloog_constraint_coefficient_get(j, d->i - 1, &t->val);
cloog_constraint_coefficient_set(j, d->i - 1, d->infos->state->one);
if (cloog_int_is_neg(t->val)) {
cloog_int_neg(t->val, t->val);
cloog_constraint_coefficient_set(j, d->i - 1, d->infos->state->negone);
}
if (d->level || cloog_constraint_is_equality(j))
d->g->eq[d->n].sign = 0;
else if (cloog_constraint_is_lower_bound(j, d->i - 1))
d->g->eq[d->n].sign = 1;
else
d->g->eq[d->n].sign = -1;
d->g->eq[d->n].RHS = clast_bound_from_constraint(j, d->i, d->infos->names);
} else {
int guarded;
if (cloog_constraint_is_lower_bound(j, d->i - 1)) {
minmax = 1;
d->max = 1;
d->g->eq[d->n].sign = 1;
} else {
minmax = 0;
d->min = 1;
d->g->eq[d->n].sign = -1;
}
guarded = (d->nb_iter >= d->level) ? d->level : 0 ;
d->g->eq[d->n].RHS = clast_minmax(d->copy, d->i, minmax, guarded, 0, 1,
d->infos);
}
d->n++;
return 0;
}
/**
* insert_guard function:
* This function inserts a guard in the clast.
* A guard on an element (level) is :
* -> the conjunction of all the existing constraints where the coefficient of
* this element is 0 if the element is an iterator,
* -> the conjunction of all the existing constraints if the element isn't an
* iterator.
* For instance, considering these constraints and the element j:
* -3*i +2*j -M >= 0
* 2*i +M >= 0
* this function should return 'if (2*i+M>=0) {'.
* - matrix is the polyhedron containing all the constraints,
* - level is the column number of the element in matrix we want to use,
* - the infos structure gives the user some options about code printing,
* the number of parameters in matrix (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - November 3rd 2001: first version.
* - November 14th 2001: a lot of 'purifications'.
* - July 31th 2002: (debug) some guard parts are no more redundants.
* - August 12th 2002: polyhedra union ('or' conditions) are now supported.
* - October 27th 2005: polyhedra union ('or' conditions) are no more supported
* (the need came from loop_simplify that may result in
* domain unions, now it should be fixed directly in
* cloog_loop_simplify).
*/
static void insert_guard(CloogConstraintSet *constraints, int level,
struct clast_stmt ***next, CloogInfos *infos)
{
int total_dim;
struct clast_guard_data data = { level, infos, 0 };
if (!constraints)
return;
data.copy = cloog_constraint_set_copy(constraints);
data.copy = insert_extra_modulo_guards(data.copy, level, next, infos);
cloog_constraint_set_foreach_constraint(constraints,
guard_count_bounds, &data);
data.g = new_clast_guard(data.n);
data.n = 0;
/* Well, it looks complicated because I wanted to have a particular, more
* readable, ordering, obviously this function may be far much simpler !
*/
data.nb_iter = cloog_constraint_set_n_iterators(constraints,
infos->names->nb_parameters);
/* We search for guard parts. */
total_dim = cloog_constraint_set_total_dimension(constraints);
for (data.i = 1; data.i <= total_dim; data.i++) {
data.min = 0;
data.max = 0;
cloog_constraint_set_foreach_constraint(data.copy,
insert_guard_constraint, &data);
}
cloog_constraint_set_free(data.copy);
data.g->n = data.n;
if (data.n) {
clast_guard_sort(data.g);
**next = &data.g->stmt;
*next = &data.g->then;
} else
free_clast_stmt(&data.g->stmt);
}
/**
* Check if the constant "cst" satisfies the modulo guard that
* would be introduced by insert_computed_modulo_guard.
* The constant is assumed to have been reduced prior to calling
* this function.
*/
static int constant_modulo_guard_is_satisfied(CloogConstraint *lower,
cloog_int_t bound, cloog_int_t cst)
{
if (cloog_constraint_is_valid(lower))
return cloog_int_le(cst, bound);
else
return cloog_int_is_zero(cst);
}
/**
* Insert a modulo guard "r % mod == 0" or "r % mod <= bound",
* depending on whether lower represents a valid constraint.
*/
static void insert_computed_modulo_guard(struct clast_reduction *r,
CloogConstraint *lower, cloog_int_t mod, cloog_int_t bound,
struct clast_stmt ***next)
{
struct clast_expr *e;
struct clast_guard *g;
e = &new_clast_binary(clast_bin_mod, &r->expr, mod)->expr;
g = new_clast_guard(1);
if (!cloog_constraint_is_valid(lower)) {
g->eq[0].LHS = e;
cloog_int_set_si(bound, 0);
g->eq[0].RHS = &new_clast_term(bound, NULL)->expr;
g->eq[0].sign = 0;
} else {
g->eq[0].LHS = e;
g->eq[0].RHS = &new_clast_term(bound, NULL)->expr;
g->eq[0].sign = -1;
}
**next = &g->stmt;
*next = &g->then;
}
/* Try and eliminate coefficients from a modulo constraint based on
* stride information of an earlier level.
* The modulo of the constraint being constructed is "m".
* The stride information at level "level" is given by "stride"
* and indicated that the iterator i at level "level" is equal to
* some expression modulo stride->stride.
* If stride->stride is a multiple of "m' then i is also equal to
* the expression modulo m and so we can eliminate the coefficient of i.
*
* If stride->constraint is NULL, then i has a constant value modulo m, stored
* stride->offset. We simply multiply this constant with the coefficient
* of i and add the result to the constant term, reducing it modulo m.
*
* If stride->constraint is not NULL, then it is a constraint of the form
*
* e + k i = s a
*
* with s equal to stride->stride, e an expression in terms of the
* parameters and earlier iterators and a some arbitrary expression
* in terms of existentially quantified variables.
* stride->factor is a value f such that f * k = -1 mod s.
* Adding stride->constraint f * c times to the current modulo constraint,
* with c the coefficient of i eliminates i in favor of parameters and
* earlier variables.
*/
static void eliminate_using_stride_constraint(cloog_int_t *line, int len,
int nb_iter, CloogStride *stride, int level, cloog_int_t m)
{
if (!stride)
return;
if (!cloog_int_is_divisible_by(stride->stride, m))
return;
if (stride->constraint) {
int i, s_len;
cloog_int_t t, v;
cloog_int_init(t);
cloog_int_init(v);
cloog_int_mul(t, line[level], stride->factor);
for (i = 1; i < level; ++i) {
cloog_constraint_coefficient_get(stride->constraint,
i - 1, &v);
cloog_int_addmul(line[i], t, v);
cloog_int_fdiv_r(line[i], line[i], m);
}
s_len = cloog_constraint_total_dimension(stride->constraint)+2;
for (i = nb_iter + 1; i <= len - 2; ++i) {
cloog_constraint_coefficient_get(stride->constraint,
i - (len - s_len) - 1, &v);
cloog_int_addmul(line[i], t, v);
cloog_int_fdiv_r(line[i], line[i], m);
}
cloog_constraint_constant_get(stride->constraint, &v);
cloog_int_addmul(line[len - 1], t, v);
cloog_int_fdiv_r(line[len - 1], line[len - 1], m);
cloog_int_clear(v);
cloog_int_clear(t);
} else {
cloog_int_addmul(line[len - 1], line[level], stride->offset);
cloog_int_fdiv_r(line[len - 1], line[len - 1], m);
}
cloog_int_set_si(line[level], 0);
}
/* Temporary structure for communication between insert_modulo_guard and
* its cloog_constraint_set_foreach_constraint callback function.
*/
struct clast_modulo_guard_data {
CloogConstraint *lower;
int level;
struct clast_stmt ***next;
CloogInfos *infos;
int empty;
cloog_int_t val, bound;
};
/* Insert a modulo guard for constraint c.
* The constraint may be either an equality or an inequality.
* Since this function returns -1, it is only called on a single constraint.
* In case of an inequality, the constraint is usually an upper bound
* on d->level. However, if this variable is an existentially
* quantified variable, the upper bound constraint may get removed
* as trivially holding and then this function is called with
* a lower bound instead. In this case, we need to adjust the constraint
* based on the sum of the constant terms of the lower and upper bound
* stored in d->bound.
*/
static int insert_modulo_guard_constraint(CloogConstraint *c, void *user)
{
struct clast_modulo_guard_data *d = (struct clast_modulo_guard_data *) user;
int level = d->level;
CloogInfos *infos = d->infos;
int i, nb_elts = 0, len, nb_iter, nb_par;
int constant;
struct cloog_vec *line_vector;
cloog_int_t *line;
len = cloog_constraint_total_dimension(c) + 2;
nb_par = infos->names->nb_parameters;
nb_iter = len - 2 - nb_par;
line_vector = cloog_vec_alloc(len);
line = line_vector->p;
cloog_constraint_copy_coefficients(c, line + 1);
if (cloog_int_is_pos(line[level])) {
cloog_seq_neg(line + 1, line + 1, len - 1);
if (!cloog_constraint_is_equality(c))
cloog_int_add(line[len - 1], line[len - 1], d->bound);
}
cloog_int_neg(line[level], line[level]);
assert(cloog_int_is_pos(line[level]));
nb_elts = 0;
for (i = 1; i <= len-1; ++i) {
if (i == level)
continue;
cloog_int_fdiv_r(line[i], line[i], line[level]);
if (cloog_int_is_zero(line[i]))
continue;
if (i == len-1)
continue;
nb_elts++;
}
if (nb_elts || !cloog_int_is_zero(line[len-1])) {
struct clast_reduction *r;
const char *name;
r = new_clast_reduction(clast_red_sum, nb_elts + 1);
nb_elts = 0;
/* First, the modulo guard : the iterators... */
i = level - 1;
if (i > infos->stride_level)
i = infos->stride_level;
for (; i >= 1; --i)
eliminate_using_stride_constraint(line, len, nb_iter,
infos->stride[i - 1], i, line[level]);
for (i=1;i<=nb_iter;i++) {
if (i == level || cloog_int_is_zero(line[i]))
continue;
name = cloog_names_name_at_level(infos->names, i);
r->elts[nb_elts++] = &new_clast_term(line[i],
&new_clast_name(name)->expr)->expr;
}
/* ...the parameters... */
for (i=nb_iter+1;i<=len-2;i++) {
if (cloog_int_is_zero(line[i]))
continue;
name = infos->names->parameters[i-nb_iter-1] ;
r->elts[nb_elts++] = &new_clast_term(line[i],
&new_clast_name(name)->expr)->expr;
}
constant = nb_elts == 0;
/* ...the constant. */
if (!cloog_int_is_zero(line[len-1]))
r->elts[nb_elts++] = &new_clast_term(line[len-1], NULL)->expr;
/* our initial computation may have been an overestimate */
r->n = nb_elts;
if (constant) {
d->empty = !constant_modulo_guard_is_satisfied(d->lower, d->bound,
line[len - 1]);
free_clast_reduction(r);
} else
insert_computed_modulo_guard(r, d->lower, line[level], d->bound,
d->next);
}
cloog_vec_free(line_vector);
return -1;
}
/**
* insert_modulo_guard:
* This function inserts a modulo guard corresponding to an equality
* or a pair of inequalities.
* Returns 0 if the modulo guard is discovered to be unsatisfiable.
*
* See insert_equation.
* - matrix is the polyhedron containing all the constraints,
* - upper and lower are the line numbers of the constraint in matrix
* we want to print; in particular, if we want to print an equality,
* then lower == -1 and upper is the row of the equality; if we want
* to print an inequality, then upper is the row of the upper bound
* and lower in the row of the lower bound
* - level is the column number of the element in matrix we want to use,
* - the infos structure gives the user some options about code printing,
* the number of parameters in matrix (nb_par), and the arrays of iterator
* names and parameters (iters and params).
*/
static int insert_modulo_guard(CloogConstraint *upper,
CloogConstraint *lower, int level,
struct clast_stmt ***next, CloogInfos *infos)
{
int nb_par;
CloogConstraintSet *set;
struct clast_modulo_guard_data data = { lower, level, next, infos, 0 };
cloog_int_init(data.val);
cloog_constraint_coefficient_get(upper, level-1, &data.val);
if (cloog_int_is_one(data.val) || cloog_int_is_neg_one(data.val)) {
cloog_int_clear(data.val);
return 1;
}
nb_par = infos->names->nb_parameters;
cloog_int_init(data.bound);
/* Check if would be emitting the redundant constraint mod(e,m) <= m-1 */
if (cloog_constraint_is_valid(lower)) {
cloog_constraint_constant_get(upper, &data.val);
cloog_constraint_constant_get(lower, &data.bound);
cloog_int_add(data.bound, data.val, data.bound);
cloog_constraint_coefficient_get(lower, level-1, &data.val);
cloog_int_sub_ui(data.val, data.val, 1);
if (cloog_int_eq(data.val, data.bound)) {
cloog_int_clear(data.val);
cloog_int_clear(data.bound);
return 1;
}
}
if (cloog_constraint_needs_reduction(upper, level)) {
set = cloog_constraint_set_for_reduction(upper, lower);
set = cloog_constraint_set_reduce(set, level, infos->equal,
nb_par, &data.bound);
cloog_constraint_set_foreach_constraint(set,
insert_modulo_guard_constraint, &data);
cloog_constraint_set_free(set);
} else
insert_modulo_guard_constraint(upper, &data);
cloog_int_clear(data.val);
cloog_int_clear(data.bound);
return !data.empty;
}
/**
* We found an equality or a pair of inequalities identifying
* a loop with a single iteration, but the user wants us to generate
* a loop anyway, so we do it here.
*/
static int insert_equation_as_loop(CloogDomain *domain, CloogConstraint *upper,
CloogConstraint *lower, int level, struct clast_stmt ***next,
CloogInfos *infos)
{
const char *iterator = cloog_names_name_at_level(infos->names, level);
struct clast_expr *e1, *e2;
struct clast_for *f;
e2 = clast_bound_from_constraint(upper, level, infos->names);
if (!cloog_constraint_is_valid(lower))
e1 = clast_expr_copy(e2);
else
e1 = clast_bound_from_constraint(lower, level, infos->names);
f = new_clast_for(domain, iterator, e1, e2, infos->stride[level-1]);
**next = &f->stmt;
*next = &f->body;
cloog_constraint_release(lower);
cloog_constraint_release(upper);
return 1;
}
/**
* insert_equation function:
* This function inserts an equality
* constraint according to an element in the clast.
* Returns 1 if the calling function should recurse into inner loops.
*
* An equality can be preceded by a 'modulo guard'.
* For instance, consider the constraint i -2*j = 0 and the
* element j: pprint_equality should return 'if(i%2==0) { j = i/2 ;'.
* - matrix is the polyhedron containing all the constraints,
* - num is the line number of the constraint in matrix we want to print,
* - level is the column number of the element in matrix we want to use,
* - the infos structure gives the user some options about code printing,
* the number of parameters in matrix (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - November 13th 2001: first version.
* - June 26th 2003: simplification of the modulo guards (remove parts such as
* modulo is 0, compare vivien or vivien2 with a previous
* version for an idea).
* - June 29th 2003: non-unit strides support.
* - July 14th 2003: (debug) no more print the constant in the modulo guard when
* it was previously included in a stride calculation.
*/
static int insert_equation(CloogDomain *domain, CloogConstraint *upper,
CloogConstraint *lower, int level, struct clast_stmt
***next, CloogInfos *infos)
{
struct clast_expr *e;
struct clast_assignment *ass;
if (!infos->options->otl)
return insert_equation_as_loop(domain, upper, lower, level, next, infos);
if (!insert_modulo_guard(upper, lower, level, next, infos)) {
cloog_constraint_release(lower);
cloog_constraint_release(upper);
return 0;
}
if (cloog_constraint_is_valid(lower) ||
!clast_equal_add(infos->equal, NULL, level, upper, infos))
{ /* Finally, the equality. */
/* If we have to make a block by dimension, we start the block. Function
* pprint knows if there is an equality, if this is the case, it checks
* for the same following condition to close the brace.
*/
if (infos->options->block) {
struct clast_block *b = new_clast_block();
**next = &b->stmt;
*next = &b->body;
}
e = clast_bound_from_constraint(upper, level, infos->names);
ass = new_clast_assignment(cloog_names_name_at_level(infos->names, level), e);
**next = &ass->stmt;
*next = &(**next)->next;
}
cloog_constraint_release(lower);
cloog_constraint_release(upper);
return 1;
}
/**
* Insert a loop that is executed exactly once as an assignment.
* In particular, the loop
*
* for (i = e; i <= e; ++i) {
* S;
* }
*
* is generated as
*
* i = e;
* S;
*
*/
static void insert_otl_for(CloogConstraintSet *constraints, int level,
struct clast_expr *e, struct clast_stmt ***next, CloogInfos *infos)
{
const char *iterator;
iterator = cloog_names_name_at_level(infos->names, level);
if (!clast_equal_add(infos->equal, constraints, level,
cloog_constraint_invalid(), infos)) {
struct clast_assignment *ass;
if (infos->options->block) {
struct clast_block *b = new_clast_block();
**next = &b->stmt;
*next = &b->body;
}
ass = new_clast_assignment(iterator, e);
**next = &ass->stmt;
*next = &(**next)->next;
} else {
free_clast_expr(e);
}
}
/**
* Insert a loop that is executed at most once as an assignment followed
* by a guard. In particular, the loop
*
* for (i = e1; i <= e2; ++i) {
* S;
* }
*
* is generated as
*
* i = e1;
* if (i <= e2) {
* S;
* }
*
*/
static void insert_guarded_otl_for(CloogConstraintSet *constraints, int level,
struct clast_expr *e1, struct clast_expr *e2,
struct clast_stmt ***next, CloogInfos *infos)
{
const char *iterator;
struct clast_assignment *ass;
struct clast_guard *guard;
iterator = cloog_names_name_at_level(infos->names, level);
if (infos->options->block) {
struct clast_block *b = new_clast_block();
**next = &b->stmt;
*next = &b->body;
}
ass = new_clast_assignment(iterator, e1);
**next = &ass->stmt;
*next = &(**next)->next;
guard = new_clast_guard(1);
guard->eq[0].sign = -1;
guard->eq[0].LHS = &new_clast_term(infos->state->one,
&new_clast_name(iterator)->expr)->expr;
guard->eq[0].RHS = e2;
**next = &guard->stmt;
*next = &guard->then;
}
/**
* insert_for function:
* This function inserts a for loop in the clast.
* Returns 1 if the calling function should recurse into inner loops.
*
* A loop header according to an element is the conjunction of a minimum and a
* maximum on a given element (they give the loop bounds).
* For instance, considering these constraints and the element j:
* i + j -9*M >= 0
* -j +5*M >= 0
* j -4*M >= 0
* this function should return 'for (j=max(-i+9*M,4*M),j<=5*M;j++) {'.
* - constraints contains all constraints,
* - level is the column number of the element in matrix we want to use,
* - otl is set if the loop is executed at most once,
* - the infos structure gives the user some options about code printing,
* the number of parameters in matrix (nb_par), and the arrays of iterator
* names and parameters (iters and params).
*/
static int insert_for(CloogDomain *domain, CloogConstraintSet *constraints,
int level, int otl, struct clast_stmt ***next,
CloogInfos *infos)
{
const char *iterator;
struct clast_expr *e1;
struct clast_expr *e2;
e1 = clast_minmax(constraints, level, 1, 0, 1, 0, infos);
e2 = clast_minmax(constraints, level, 0, 0, 0, 0, infos);
if (clast_expr_is_bigger_constant(e1, e2)) {
free_clast_expr(e1);
free_clast_expr(e2);
return 0;
}
/* If min and max are not equal there is a 'for' else, there is a '='.
* In the special case e1 = e2 = NULL, this is an infinite loop
* so this is not a '='.
*/
if (e1 && e2 && infos->options->otl && clast_expr_equal(e1, e2)) {
free_clast_expr(e2);
insert_otl_for(constraints, level, e1, next, infos);
} else if (otl) {
insert_guarded_otl_for(constraints, level, e1, e2, next, infos);
} else {
struct clast_for *f;
iterator = cloog_names_name_at_level(infos->names, level);
f = new_clast_for(domain, iterator, e1, e2, infos->stride[level-1]);
**next = &f->stmt;
*next = &f->body;
}
return 1;
}
/**
* insert_block function:
* This function inserts a statement block.
* - block is the statement block,
* - level is the number of loops enclosing the statement,
* - the infos structure gives the user some options about code printing,
* the number of parameters in domain (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - September 21th 2003: first version (pick from pprint function).
*/
static void insert_block(CloogDomain *domain, CloogBlock *block, int level,
struct clast_stmt ***next, CloogInfos *infos)
{
CloogStatement * statement ;
struct clast_stmt *subs;
if (!block)
return;
for (statement = block->statement; statement; statement = statement->next) {
CloogStatement *s_next = statement->next;
subs = clast_equal(level,infos);
statement->next = NULL;
**next = &new_clast_user_stmt(domain, statement, subs)->stmt;
statement->next = s_next;
*next = &(**next)->next;
}
}
/**
* insert_loop function:
* This function converts the content of a CloogLoop structure (loop) into a
* clast_stmt (inserted at **next).
* The iterator (level) of
* the current loop is given by 'level': this is the column number of the
* domain corresponding to the current loop iterator. The data of a loop are
* written in this order:
* 1. The guard of the loop, i.e. each constraint in the domain that does not
* depend on the iterator (when the entry in the column 'level' is 0).
* 2. The iteration domain of the iterator, given by the constraints in the
* domain depending on the iterator, i.e.:
* * an equality if the iterator has only one value (possibly preceded by
* a guard verifying if this value is integral), *OR*
* * a loop from the minimum possible value of the iterator to the maximum
* possible value.
* 3. The included statement block.
* 4. The inner loops (recursive call).
* 5. The following loops (recursive call).
* - level is the recursion level or the iteration level that we are printing,
* - the infos structure gives the user some options about code printing,
* the number of parameters in domain (nb_par), and the arrays of iterator
* names and parameters (iters and params).
**
* - November 2nd 2001: first version.
* - March 6th 2003: infinite domain support.
* - April 19th 2003: (debug) NULL loop support.
* - June 29th 2003: non-unit strides support.
* - April 28th 2005: (debug) level is level+equality when print statement!
* - June 16th 2005: (debug) the N. Vasilache normalization step has been
* added to avoid iteration duplication (see DaeGon Kim
* bug in cloog_program_generate). Try vasilache.cloog
* with and without the call to cloog_polylib_matrix_normalize,
* using -f 8 -l 9 options for an idea.
* - September 15th 2005: (debug) don't close equality braces when unnecessary.
* - October 16th 2005: (debug) scalar value is saved for next loops.
*/
static void insert_loop(CloogLoop * loop, int level,
struct clast_stmt ***next, CloogInfos *infos)
{
int equality = 0;
CloogConstraintSet *constraints, *temp;
struct clast_stmt **top = *next;
CloogConstraint *i, *j;
int empty_loop = 0;
/* It can happen that loop be NULL when an input polyhedron is empty. */
if (loop == NULL)
return;
/* The constraints do not always have a shape that allows us to generate code from it,
* thus we normalize it, we also simplify it with the equalities.
*/
temp = cloog_domain_constraints(loop->domain);
cloog_constraint_set_normalize(temp,level);
constraints = cloog_constraint_set_simplify(temp,infos->equal,level,
infos->names->nb_parameters);
cloog_constraint_set_free(temp);
if (level) {
infos->stride[level - 1] = loop->stride;
infos->stride_level++;
}
/* First of all we have to print the guard. */
insert_guard(constraints,level, next, infos);
if (level && cloog_constraint_set_contains_level(constraints, level,
infos->names->nb_parameters)) {
/* We scan all the constraints to know in which case we are :
* [[if] equation] or [for].
*/
if (cloog_constraint_is_valid(i =
cloog_constraint_set_defining_equality(constraints, level))) {
empty_loop = !insert_equation(loop->unsimplified, i,
cloog_constraint_invalid(), level, next,
infos);
equality = 1 ;
} else if (cloog_constraint_is_valid(i =
cloog_constraint_set_defining_inequalities(constraints,
level, &j, infos->names->nb_parameters))) {
empty_loop = !insert_equation(loop->unsimplified, i, j, level, next,
infos);
} else
empty_loop = !insert_for(loop->unsimplified, constraints, level,
loop->otl, next, infos);
}
if (!empty_loop) {
/* Finally, if there is an included statement block, print it. */
insert_block(loop->unsimplified, loop->block, level+equality, next, infos);
/* Go to the next level. */
if (loop->inner != NULL)
insert_loop(loop->inner, level+1, next, infos);
}
if (level) {
cloog_equal_del(infos->equal,level);
infos->stride_level--;
}
cloog_constraint_set_free(constraints);
/* Go to the next loop on the same level. */
while (*top)
top = &(*top)->next;
if (loop->next != NULL)
insert_loop(loop->next, level, &top,infos);
}
struct clast_stmt *cloog_clast_create(CloogProgram *program,
CloogOptions *options)
{
CloogInfos *infos = ALLOC(CloogInfos);
int nb_levels;
struct clast_stmt *root = &new_clast_root(program->names)->stmt;
struct clast_stmt **next = &root->next;
infos->state = options->state;
infos->names = program->names;
infos->options = options;
infos->scaldims = program->scaldims;
infos->nb_scattdims = program->nb_scattdims;
/* Allocation for the array of strides, there is a +1 since the statement can
* be included inside an external loop without iteration domain.
*/
nb_levels = program->names->nb_scattering+program->names->nb_iterators+1;
infos->stride = ALLOCN(CloogStride *, nb_levels);
infos->stride_level = 0;
infos->equal = cloog_equal_alloc(nb_levels,
nb_levels, program->names->nb_parameters);
insert_loop(program->loop, 0, &next, infos);
cloog_equal_free(infos->equal);
free(infos->stride);
free(infos);
return root;
}
struct clast_stmt *cloog_clast_create_from_input(CloogInput *input,
CloogOptions *options)
{
CloogProgram *program;
struct clast_stmt *root;
program = cloog_program_alloc(input->context, input->ud, options);
free(input);
program = cloog_program_generate(program, options);
root = cloog_clast_create(program, options);
cloog_program_free(program);
return root;
}