=head1 Introduction C is a thread-safe C library for manipulating sets and relations of integer points bounded by affine constraints. The descriptions of the sets and relations may involve both parameters and existentially quantified variables. All computations are performed in exact integer arithmetic using C. The C library offers functionality that is similar to that offered by the C and C libraries, but the underlying algorithms are in most cases completely different. The library is by no means complete and some fairly basic functionality is still missing. Still, even in its current form, the library has been successfully used as a backend polyhedral library for the polyhedral scanner C and as part of an equivalence checker of static affine programs. =head1 Installation The source of C can be obtained either as a tarball or from the git repository. Both are available from L. The installation process depends on how you obtained the source. =head2 Installation from the git repository =over =item 1 Clone or update the repository The first time the source is obtained, you need to clone the repository. git clone git://repo.or.cz/isl.git To obtain updates, you need to pull in the latest changes git pull =item 2 Get submodule (optional) C can optionally use the C library and provides this library as a submodule. If you want to use it, then after you have cloned C, you need to grab the submodules git submodule init git submodule update To obtain updates, you only need git submodule update Note that C currently does not use any C functionality by default. =item 3 Generate C ./autogen.sh =back After performing the above steps, continue with the L. =head2 Common installation instructions =over =item 1 Obtain C Building C requires C, including its headers files. Your distribution may not provide these header files by default and you may need to install a package called C or something similar. Alternatively, C can be built from source, available from L. =item 2 Configure C uses the standard C C script. To run it, just type ./configure optionally followed by some configure options. A complete list of options can be obtained by running ./configure --help Below we discuss some of the more common options. C can optionally use C, but no C functionality is currently used by default. The C<--with-piplib> option can be used to specify which C library to use, either an installed version (C), an externally built version (C) or no version (C). The option C is mostly useful in C scripts of larger projects that bundle both C and C. =over =item C<--prefix> Installation prefix for C =item C<--with-gmp-prefix> Installation prefix for C (architecture-independent files). =item C<--with-gmp-exec-prefix> Installation prefix for C (architecture-dependent files). =item C<--with-piplib> Which copy of C to use, either C (default), C or C. =item C<--with-piplib-prefix> Installation prefix for C C (architecture-independent files). =item C<--with-piplib-exec-prefix> Installation prefix for C C (architecture-dependent files). =item C<--with-piplib-builddir> Location where C C was built. =back =item 3 Compile make =item 4 Install (optional) make install =back =head1 Library =head2 Initialization All manipulations of integer sets and relations occur within the context of an C. A given C can only be used within a single thread. All arguments of a function are required to have been allocated within the same context. There are currently no functions available for moving an object from one C to another C. This means that there is currently no way of safely moving an object from one thread to another, unless the whole C is moved. An C can be allocated using C and freed using C. All objects allocated within an C should be freed before the C itself is freed. isl_ctx *isl_ctx_alloc(); void isl_ctx_free(isl_ctx *ctx); =head2 Integers All operations on integers, mainly the coefficients of the constraints describing the sets and relations, are performed in exact integer arithmetic using C. However, to allow future versions of C to optionally support fixed integer arithmetic, all calls to C are wrapped inside C specific macros. The basic type is C and the following operations are available on this type. The meanings of these operations are essentially the same as their C C counterparts. As always with C types, Cs need to be initialized with C before they can be used and they need to be released with C after the last use. =over =item isl_int_init(i) =item isl_int_clear(i) =item isl_int_set(r,i) =item isl_int_set_si(r,i) =item isl_int_abs(r,i) =item isl_int_neg(r,i) =item isl_int_swap(i,j) =item isl_int_swap_or_set(i,j) =item isl_int_add_ui(r,i,j) =item isl_int_sub_ui(r,i,j) =item isl_int_add(r,i,j) =item isl_int_sub(r,i,j) =item isl_int_mul(r,i,j) =item isl_int_mul_ui(r,i,j) =item isl_int_addmul(r,i,j) =item isl_int_submul(r,i,j) =item isl_int_gcd(r,i,j) =item isl_int_lcm(r,i,j) =item isl_int_divexact(r,i,j) =item isl_int_cdiv_q(r,i,j) =item isl_int_fdiv_q(r,i,j) =item isl_int_fdiv_r(r,i,j) =item isl_int_fdiv_q_ui(r,i,j) =item isl_int_read(r,s) =item isl_int_print(out,i,width) =item isl_int_sgn(i) =item isl_int_cmp(i,j) =item isl_int_cmp_si(i,si) =item isl_int_eq(i,j) =item isl_int_ne(i,j) =item isl_int_lt(i,j) =item isl_int_le(i,j) =item isl_int_gt(i,j) =item isl_int_ge(i,j) =item isl_int_abs_eq(i,j) =item isl_int_abs_ne(i,j) =item isl_int_abs_lt(i,j) =item isl_int_abs_gt(i,j) =item isl_int_abs_ge(i,j) =item isl_int_is_zero(i) =item isl_int_is_one(i) =item isl_int_is_negone(i) =item isl_int_is_pos(i) =item isl_int_is_neg(i) =item isl_int_is_nonpos(i) =item isl_int_is_nonneg(i) =item isl_int_is_divisible_by(i,j) =back =head2 Sets and Relations C uses four types of objects for representing sets and relations, C, C, C and C. C and C represent sets and relations that can be described as a conjunction of affine constraints, while C and C represent unions of Cs and Cs, respectively. The difference between sets and relations (maps) is that sets have one set of variables, while relations have two sets of variables, input variables and output variables. =head2 Memory Management Since a high-level operation on sets and/or relations usually involves several substeps and since the user is usually not interested in the intermediate results, most functions that return a new object will also release all the objects passed as arguments. If the user still wants to use one or more of these arguments after the function call, she should pass along a copy of the object rather than the object itself. The user is then responsible for make sure that the original object gets used somewhere else or is explicitly freed. The arguments and return values of all documents functions are annotated to make clear which arguments are released and which arguments are preserved. In particular, the following annotations are used =over =item C<__isl_give> C<__isl_give> means that a new object is returned. The user should make sure that the returned pointer is used exactly once as a value for an C<__isl_take> argument. In between, it can be used as a value for as many C<__isl_keep> arguments as the user likes. There is one exception, and that is the case where the pointer returned is C. Is this case, the user is free to use it as an C<__isl_take> argument or not. =item C<__isl_take> C<__isl_take> means that the object the argument points to is taken over by the function and may no longer be used by the user as an argument to any other function. The pointer value must be one returned by a function returning an C<__isl_give> pointer. If the user passes in a C value, then this will be treated as an error in the sense that the function will not perform its usual operation. However, it will still make sure that all the the other C<__isl_take> arguments are released. =item C<__isl_keep> C<__isl_keep> means that the function will only use the object temporarily. After the function has finished, the user can still use it as an argument to other functions. A C value will be treated in the same way as a C value for an C<__isl_take> argument. =back =head2 Dimension Specifications Whenever a new set or relation is created from scratch, its dimension needs to be specified using an C. #include __isl_give isl_dim *isl_dim_alloc(isl_ctx *ctx, unsigned nparam, unsigned n_in, unsigned n_out); __isl_give isl_dim *isl_dim_set_alloc(isl_ctx *ctx, unsigned nparam, unsigned dim); __isl_give isl_dim *isl_dim_copy(__isl_keep isl_dim *dim); void isl_dim_free(__isl_take isl_dim *dim); unsigned isl_dim_size(__isl_keep isl_dim *dim, enum isl_dim_type type); The dimension specification used for creating a set needs to be created using C, while that for creating a relation needs to be created using C. C can be used to find out the number of dimensions of each type in a dimension specification, where type may be C, C (only for relations), C (only for relations), C (only for sets) or C. It is often useful to create objects that live in the same space as some other object. This can be accomplished by creating the new objects (see L or L) based on the dimension specification of the original object. #include __isl_give isl_dim *isl_basic_set_get_dim( __isl_keep isl_basic_set *bset); __isl_give isl_dim *isl_set_get_dim(__isl_keep isl_set *set); #include __isl_give isl_dim *isl_basic_map_get_dim( __isl_keep isl_basic_map *bmap); __isl_give isl_dim *isl_map_get_dim(__isl_keep isl_map *map); #include __isl_give isl_dim *isl_qpolynomial_get_dim( __isl_keep isl_qpolynomial *qp); __isl_give isl_dim *isl_pw_qpolynomial_get_dim( __isl_keep isl_pw_qpolynomial *pwqp); The names of the individual dimensions may be set or read off using the following functions. #include __isl_give isl_dim *isl_dim_set_name(__isl_take isl_dim *dim, enum isl_dim_type type, unsigned pos, __isl_keep const char *name); __isl_keep const char *isl_dim_get_name(__isl_keep isl_dim *dim, enum isl_dim_type type, unsigned pos); Note that C returns a pointer to some internal data structure, so the result can only be used while the corresponding C is alive. Also note that every function that operates on two sets or relations requires that both arguments have the same parameters. This also means that if one of the arguments has named parameters, then the other needs to have named parameters too and the names need to match. =head2 Input and Output C supports its own input/output format, which is similar to the C format, but also supports the C format in some cases. =head3 C format The C format is similar to that of C, but has a different syntax for describing the parameters and allows for the definition of an existentially quantified variable as the integer division of an affine expression. For example, the set of integers C between C<0> and C such that C can be described as [n] -> { [i] : exists (a = [i/10] : 0 <= i and i <= n and i - 10 a <= 6) } A set or relation can have several disjuncts, separated by the keyword C. Each disjunct is either a conjunction of constraints or a projection (C) of a conjunction of constraints. The constraints are separated by the keyword C. =head3 C format If the represented set is a union, then the first line contains a single number representing the number of disjuncts. Otherwise, a line containing the number C<1> is optional. Each disjunct is represented by a matrix of constraints. The first line contains two numbers representing the number of rows and columns, where the number of rows is equal to the number of constraints and the number of columns is equal to two plus the number of variables. The following lines contain the actual rows of the constraint matrix. In each row, the first column indicates whether the constraint is an equality (C<0>) or inequality (C<1>). The final column corresponds to the constant term. If the set is parametric, then the coefficients of the parameters appear in the last columns before the constant column. The coefficients of any existentially quantified variables appear between those of the set variables and those of the parameters. =head3 Input #include __isl_give isl_basic_set *isl_basic_set_read_from_file( isl_ctx *ctx, FILE *input, int nparam); __isl_give isl_basic_set *isl_basic_set_read_from_str( isl_ctx *ctx, const char *str, int nparam); __isl_give isl_set *isl_set_read_from_file(isl_ctx *ctx, FILE *input, int nparam); __isl_give isl_set *isl_set_read_from_str(isl_ctx *ctx, const char *str, int nparam); #include __isl_give isl_basic_map *isl_basic_map_read_from_file( isl_ctx *ctx, FILE *input, int nparam); __isl_give isl_basic_map *isl_basic_map_read_from_str( isl_ctx *ctx, const char *str, int nparam); __isl_give isl_map *isl_map_read_from_file( struct isl_ctx *ctx, FILE *input, int nparam); __isl_give isl_map *isl_map_read_from_str(isl_ctx *ctx, const char *str, int nparam); The input format is autodetected and may be either the C format or the C format. C specifies how many of the final columns in the C format correspond to parameters. If input is given in the C format, then the number of parameters needs to be equal to C. If C is negative, then any number of parameters is accepted in the C format and zero parameters are assumed in the C format. =head3 Output Before anything can be printed, an C needs to be created. __isl_give isl_printer *isl_printer_to_file(isl_ctx *ctx, FILE *file); __isl_give isl_printer *isl_printer_to_str(isl_ctx *ctx); void isl_printer_free(__isl_take isl_printer *printer); __isl_give char *isl_printer_get_str( __isl_keep isl_printer *printer); The behavior of the printer can be modified in various ways __isl_give isl_printer *isl_printer_set_output_format( __isl_take isl_printer *p, int output_format); __isl_give isl_printer *isl_printer_set_indent( __isl_take isl_printer *p, int indent); __isl_give isl_printer *isl_printer_set_prefix( __isl_take isl_printer *p, const char *prefix); __isl_give isl_printer *isl_printer_set_suffix( __isl_take isl_printer *p, const char *suffix); The C may be either C, C or C and defaults to C. Each line in the output is indented by C spaces (default: 0), prefixed by C and suffixed by C. In the C format output, the coefficients of the existentially quantified variables appear between those of the set variables and those of the parameters. To actually print something, use #include __isl_give isl_printer *isl_printer_print_basic_set( __isl_take isl_printer *printer, __isl_keep isl_basic_set *bset); __isl_give isl_printer *isl_printer_print_set( __isl_take isl_printer *printer, __isl_keep isl_set *set); #include __isl_give isl_printer *isl_printer_print_basic_map( __isl_take isl_printer *printer, __isl_keep isl_basic_map *bmap); __isl_give isl_printer *isl_printer_print_map( __isl_take isl_printer *printer, __isl_keep isl_map *map); When called on a file printer, the following function flushes the file. When called on a string printer, the buffer is cleared. __isl_give isl_printer *isl_printer_flush( __isl_take isl_printer *p); =head2 Creating New Sets and Relations C has functions for creating some standard sets and relations. =over =item * Empty sets and relations __isl_give isl_basic_set *isl_basic_set_empty( __isl_take isl_dim *dim); __isl_give isl_basic_map *isl_basic_map_empty( __isl_take isl_dim *dim); __isl_give isl_set *isl_set_empty( __isl_take isl_dim *dim); __isl_give isl_map *isl_map_empty( __isl_take isl_dim *dim); =item * Universe sets and relations __isl_give isl_basic_set *isl_basic_set_universe( __isl_take isl_dim *dim); __isl_give isl_basic_map *isl_basic_map_universe( __isl_take isl_dim *dim); __isl_give isl_set *isl_set_universe( __isl_take isl_dim *dim); __isl_give isl_map *isl_map_universe( __isl_take isl_dim *dim); =item * Identity relations __isl_give isl_basic_map *isl_basic_map_identity( __isl_take isl_dim *set_dim); __isl_give isl_map *isl_map_identity( __isl_take isl_dim *set_dim); These functions take a dimension specification for a B and return an identity relation between two such sets. =item * Lexicographic order __isl_give isl_map *isl_map_lex_lt( __isl_take isl_dim *set_dim); __isl_give isl_map *isl_map_lex_le( __isl_take isl_dim *set_dim); __isl_give isl_map *isl_map_lex_gt( __isl_take isl_dim *set_dim); __isl_give isl_map *isl_map_lex_ge( __isl_take isl_dim *set_dim); __isl_give isl_map *isl_map_lex_lt_first( __isl_take isl_dim *dim, unsigned n); __isl_give isl_map *isl_map_lex_le_first( __isl_take isl_dim *dim, unsigned n); __isl_give isl_map *isl_map_lex_gt_first( __isl_take isl_dim *dim, unsigned n); __isl_give isl_map *isl_map_lex_ge_first( __isl_take isl_dim *dim, unsigned n); The first four functions take a dimension specification for a B and return relations that express that the elements in the domain are lexicographically less (C), less or equal (C), greater (C) or greater or equal (C) than the elements in the range. The last four functions take a dimension specification for a map and return relations that express that the first C dimensions in the domain are lexicographically less (C), less or equal (C), greater (C) or greater or equal (C) than the first C dimensions in the range. =back A basic set or relation can be converted to a set or relation using the following functions. __isl_give isl_set *isl_set_from_basic_set( __isl_take isl_basic_set *bset); __isl_give isl_map *isl_map_from_basic_map( __isl_take isl_basic_map *bmap); Sets and relations can be copied and freed again using the following functions. __isl_give isl_basic_set *isl_basic_set_copy( __isl_keep isl_basic_set *bset); __isl_give isl_set *isl_set_copy(__isl_keep isl_set *set); __isl_give isl_basic_map *isl_basic_map_copy( __isl_keep isl_basic_map *bmap); __isl_give isl_map *isl_map_copy(__isl_keep isl_map *map); void isl_basic_set_free(__isl_take isl_basic_set *bset); void isl_set_free(__isl_take isl_set *set); void isl_basic_map_free(__isl_take isl_basic_map *bmap); void isl_map_free(__isl_take isl_map *map); Other sets and relations can be constructed by starting from a universe set or relation, adding equality and/or inequality constraints and then projecting out the existentially quantified variables, if any. Constraints can be constructed, manipulated and added to basic sets and relations using the following functions. #include __isl_give isl_constraint *isl_equality_alloc( __isl_take isl_dim *dim); __isl_give isl_constraint *isl_inequality_alloc( __isl_take isl_dim *dim); void isl_constraint_set_constant( __isl_keep isl_constraint *constraint, isl_int v); void isl_constraint_set_coefficient( __isl_keep isl_constraint *constraint, enum isl_dim_type type, int pos, isl_int v); __isl_give isl_basic_map *isl_basic_map_add_constraint( __isl_take isl_basic_map *bmap, __isl_take isl_constraint *constraint); __isl_give isl_basic_set *isl_basic_set_add_constraint( __isl_take isl_basic_set *bset, __isl_take isl_constraint *constraint); For example, to create a set containing the even integers between 10 and 42, you would use the following code. isl_int v; struct isl_dim *dim; struct isl_constraint *c; struct isl_basic_set *bset; isl_int_init(v); dim = isl_dim_set_alloc(ctx, 0, 2); bset = isl_basic_set_universe(isl_dim_copy(dim)); c = isl_equality_alloc(isl_dim_copy(dim)); isl_int_set_si(v, -1); isl_constraint_set_coefficient(c, isl_dim_set, 0, v); isl_int_set_si(v, 2); isl_constraint_set_coefficient(c, isl_dim_set, 1, v); bset = isl_basic_set_add_constraint(bset, c); c = isl_inequality_alloc(isl_dim_copy(dim)); isl_int_set_si(v, -10); isl_constraint_set_constant(c, v); isl_int_set_si(v, 1); isl_constraint_set_coefficient(c, isl_dim_set, 0, v); bset = isl_basic_set_add_constraint(bset, c); c = isl_inequality_alloc(dim); isl_int_set_si(v, 42); isl_constraint_set_constant(c, v); isl_int_set_si(v, -1); isl_constraint_set_coefficient(c, isl_dim_set, 0, v); bset = isl_basic_set_add_constraint(bset, c); bset = isl_basic_set_project_out(bset, isl_dim_set, 1, 1); isl_int_clear(v); Or, alternatively, struct isl_basic_set *bset; bset = isl_basic_set_read_from_str(ctx, "{[i] : exists (a : i = 2a and i >= 10 and i <= 42)}", -1); =head2 Inspecting Sets and Relations Usually, the user should not have to care about the actual constraints of the sets and maps, but should instead apply the abstract operations explained in the following sections. Occasionally, however, it may be required to inspect the individual coefficients of the constraints. This section explains how to do so. In these cases, it may also be useful to have C compute an explicit representation of the existentially quantified variables. __isl_give isl_set *isl_set_compute_divs( __isl_take isl_set *set); __isl_give isl_map *isl_map_compute_divs( __isl_take isl_map *map); This explicit representation defines the existentially quantified variables as integer divisions of the other variables, possibly including earlier existentially quantified variables. An explicitly represented existentially quantified variable therefore has a unique value when the values of the other variables are known. If, furthermore, the same existentials, i.e., existentials with the same explicit representations, should appear in the same order in each of the disjuncts of a set or map, then the user should call either of the following functions. __isl_give isl_set *isl_set_align_divs( __isl_take isl_set *set); __isl_give isl_map *isl_map_align_divs( __isl_take isl_map *map); To iterate over all the basic sets or maps in a set or map, use int isl_set_foreach_basic_set(__isl_keep isl_set *set, int (*fn)(__isl_take isl_basic_set *bset, void *user), void *user); int isl_map_foreach_basic_map(__isl_keep isl_map *map, int (*fn)(__isl_take isl_basic_map *bmap, void *user), void *user); The callback function C should return 0 if successful and -1 if an error occurs. In the latter case, or if any other error occurs, the above functions will return -1. It should be noted that C does not guarantee that the basic sets or maps passed to C are disjoint. If this is required, then the user should call one of the following functions first. __isl_give isl_set *isl_set_make_disjoint( __isl_take isl_set *set); __isl_give isl_map *isl_map_make_disjoint( __isl_take isl_map *map); To iterate over the constraints of a basic set or map, use #include int isl_basic_map_foreach_constraint( __isl_keep isl_basic_map *bmap, int (*fn)(__isl_take isl_constraint *c, void *user), void *user); void isl_constraint_free(struct isl_constraint *c); Again, the callback function C should return 0 if successful and -1 if an error occurs. In the latter case, or if any other error occurs, the above functions will return -1. The constraint C represents either an equality or an inequality. Use the following function to find out whether a constraint represents an equality. If not, it represents an inequality. int isl_constraint_is_equality( __isl_keep isl_constraint *constraint); The coefficients of the constraints can be inspected using the following functions. void isl_constraint_get_constant( __isl_keep isl_constraint *constraint, isl_int *v); void isl_constraint_get_coefficient( __isl_keep isl_constraint *constraint, enum isl_dim_type type, int pos, isl_int *v); The explicit representations of the existentially quantified variables can be inspected using the following functions. Note that the user is only allowed to use these functions if the inspected set or map is the result of a call to C or C. __isl_give isl_div *isl_constraint_div( __isl_keep isl_constraint *constraint, int pos); void isl_div_get_constant(__isl_keep isl_div *div, isl_int *v); void isl_div_get_denominator(__isl_keep isl_div *div, isl_int *v); void isl_div_get_coefficient(__isl_keep isl_div *div, enum isl_dim_type type, int pos, isl_int *v); =head2 Properties =head3 Unary Properties =over =item * Emptiness The following functions test whether the given set or relation contains any integer points. The ``fast'' variants do not perform any computations, but simply check if the given set or relation is already known to be empty. int isl_basic_set_fast_is_empty(__isl_keep isl_basic_set *bset); int isl_basic_set_is_empty(__isl_keep isl_basic_set *bset); int isl_set_is_empty(__isl_keep isl_set *set); int isl_basic_map_fast_is_empty(__isl_keep isl_basic_map *bmap); int isl_basic_map_is_empty(__isl_keep isl_basic_map *bmap); int isl_map_fast_is_empty(__isl_keep isl_map *map); int isl_map_is_empty(__isl_keep isl_map *map); =item * Universality int isl_basic_set_is_universe(__isl_keep isl_basic_set *bset); int isl_basic_map_is_universe(__isl_keep isl_basic_map *bmap); int isl_set_fast_is_universe(__isl_keep isl_set *set); =item * Single-valuedness int isl_map_is_single_valued(__isl_keep isl_map *map); =back =head3 Binary Properties =over =item * Equality int isl_set_fast_is_equal(__isl_keep isl_set *set1, __isl_keep isl_set *set2); int isl_set_is_equal(__isl_keep isl_set *set1, __isl_keep isl_set *set2); int isl_map_is_equal(__isl_keep isl_map *map1, __isl_keep isl_map *map2); int isl_map_fast_is_equal(__isl_keep isl_map *map1, __isl_keep isl_map *map2); int isl_basic_map_is_equal( __isl_keep isl_basic_map *bmap1, __isl_keep isl_basic_map *bmap2); =item * Disjointness int isl_set_fast_is_disjoint(__isl_keep isl_set *set1, __isl_keep isl_set *set2); =item * Subset int isl_set_is_subset(__isl_keep isl_set *set1, __isl_keep isl_set *set2); int isl_set_is_strict_subset( __isl_keep isl_set *set1, __isl_keep isl_set *set2); int isl_basic_map_is_subset( __isl_keep isl_basic_map *bmap1, __isl_keep isl_basic_map *bmap2); int isl_basic_map_is_strict_subset( __isl_keep isl_basic_map *bmap1, __isl_keep isl_basic_map *bmap2); int isl_map_is_subset( __isl_keep isl_map *map1, __isl_keep isl_map *map2); int isl_map_is_strict_subset( __isl_keep isl_map *map1, __isl_keep isl_map *map2); =back =head2 Unary Operations =over =item * Complement __isl_give isl_set *isl_set_complement( __isl_take isl_set *set); =item * Inverse map __isl_give isl_basic_map *isl_basic_map_reverse( __isl_take isl_basic_map *bmap); __isl_give isl_map *isl_map_reverse( __isl_take isl_map *map); =item * Projection __isl_give isl_basic_set *isl_basic_set_project_out( __isl_take isl_basic_set *bset, enum isl_dim_type type, unsigned first, unsigned n); __isl_give isl_basic_map *isl_basic_map_project_out( __isl_take isl_basic_map *bmap, enum isl_dim_type type, unsigned first, unsigned n); __isl_give isl_set *isl_set_project_out(__isl_take isl_set *set, enum isl_dim_type type, unsigned first, unsigned n); __isl_give isl_map *isl_map_project_out(__isl_take isl_map *map, enum isl_dim_type type, unsigned first, unsigned n); __isl_give isl_basic_set *isl_basic_map_domain( __isl_take isl_basic_map *bmap); __isl_give isl_basic_set *isl_basic_map_range( __isl_take isl_basic_map *bmap); __isl_give isl_set *isl_map_domain( __isl_take isl_map *bmap); __isl_give isl_set *isl_map_range( __isl_take isl_map *map); =item * Coalescing Simplify the representation of a set or relation by trying to combine pairs of basic sets or relations into a single basic set or relation. __isl_give isl_set *isl_set_coalesce(__isl_take isl_set *set); __isl_give isl_map *isl_map_coalesce(__isl_take isl_map *map); =item * Convex hull __isl_give isl_basic_set *isl_set_convex_hull( __isl_take isl_set *set); __isl_give isl_basic_map *isl_map_convex_hull( __isl_take isl_map *map); If the input set or relation has any existentially quantified variables, then the result of these operations is currently undefined. =item * Simple hull __isl_give isl_basic_set *isl_set_simple_hull( __isl_take isl_set *set); __isl_give isl_basic_map *isl_map_simple_hull( __isl_take isl_map *map); These functions compute a single basic set or relation that contains the whole input set or relation. In particular, the output is described by translates of the constraints describing the basic sets or relations in the input. =begin latex (See \autoref{s:simple hull}.) =end latex =item * Affine hull __isl_give isl_basic_set *isl_basic_set_affine_hull( __isl_take isl_basic_set *bset); __isl_give isl_basic_set *isl_set_affine_hull( __isl_take isl_set *set); __isl_give isl_basic_map *isl_basic_map_affine_hull( __isl_take isl_basic_map *bmap); __isl_give isl_basic_map *isl_map_affine_hull( __isl_take isl_map *map); =item * Power __isl_give isl_map *isl_map_power(__isl_take isl_map *map, unsigned param, int *exact); Compute a parametric representation for all positive powers I of C. The power I is equated to the parameter at position C. The result may be an overapproximation. If the result is exact, then C<*exact> is set to C<1>. The current implementation only produces exact results for particular cases of piecewise translations (i.e., piecewise uniform dependences). =item * Transitive closure __isl_give isl_map *isl_map_transitive_closure( __isl_take isl_map *map, int *exact); Compute the transitive closure of C. The result may be an overapproximation. If the result is known to be exact, then C<*exact> is set to C<1>. The current implementation only produces exact results for particular cases of piecewise translations (i.e., piecewise uniform dependences). =back =head2 Binary Operations The two arguments of a binary operation not only need to live in the same C, they currently also need to have the same (number of) parameters. =head3 Basic Operations =over =item * Intersection __isl_give isl_basic_set *isl_basic_set_intersect( __isl_take isl_basic_set *bset1, __isl_take isl_basic_set *bset2); __isl_give isl_set *isl_set_intersect( __isl_take isl_set *set1, __isl_take isl_set *set2); __isl_give isl_basic_map *isl_basic_map_intersect_domain( __isl_take isl_basic_map *bmap, __isl_take isl_basic_set *bset); __isl_give isl_basic_map *isl_basic_map_intersect_range( __isl_take isl_basic_map *bmap, __isl_take isl_basic_set *bset); __isl_give isl_basic_map *isl_basic_map_intersect( __isl_take isl_basic_map *bmap1, __isl_take isl_basic_map *bmap2); __isl_give isl_map *isl_map_intersect_domain( __isl_take isl_map *map, __isl_take isl_set *set); __isl_give isl_map *isl_map_intersect_range( __isl_take isl_map *map, __isl_take isl_set *set); __isl_give isl_map *isl_map_intersect( __isl_take isl_map *map1, __isl_take isl_map *map2); =item * Union __isl_give isl_set *isl_basic_set_union( __isl_take isl_basic_set *bset1, __isl_take isl_basic_set *bset2); __isl_give isl_map *isl_basic_map_union( __isl_take isl_basic_map *bmap1, __isl_take isl_basic_map *bmap2); __isl_give isl_set *isl_set_union( __isl_take isl_set *set1, __isl_take isl_set *set2); __isl_give isl_map *isl_map_union( __isl_take isl_map *map1, __isl_take isl_map *map2); =item * Set difference __isl_give isl_set *isl_set_subtract( __isl_take isl_set *set1, __isl_take isl_set *set2); __isl_give isl_map *isl_map_subtract( __isl_take isl_map *map1, __isl_take isl_map *map2); =item * Application __isl_give isl_basic_set *isl_basic_set_apply( __isl_take isl_basic_set *bset, __isl_take isl_basic_map *bmap); __isl_give isl_set *isl_set_apply( __isl_take isl_set *set, __isl_take isl_map *map); __isl_give isl_basic_map *isl_basic_map_apply_domain( __isl_take isl_basic_map *bmap1, __isl_take isl_basic_map *bmap2); __isl_give isl_basic_map *isl_basic_map_apply_range( __isl_take isl_basic_map *bmap1, __isl_take isl_basic_map *bmap2); __isl_give isl_map *isl_map_apply_domain( __isl_take isl_map *map1, __isl_take isl_map *map2); __isl_give isl_map *isl_map_apply_range( __isl_take isl_map *map1, __isl_take isl_map *map2); =item * Simplification __isl_give isl_basic_set *isl_basic_set_gist( __isl_take isl_basic_set *bset, __isl_take isl_basic_set *context); __isl_give isl_set *isl_set_gist(__isl_take isl_set *set, __isl_take isl_set *context); __isl_give isl_basic_map *isl_basic_map_gist( __isl_take isl_basic_map *bmap, __isl_take isl_basic_map *context); __isl_give isl_map *isl_map_gist(__isl_take isl_map *map, __isl_take isl_map *context); The gist operation returns a set or relation that has the same intersection with the context as the input set or relation. Any implicit equality in the intersection is made explicit in the result, while all inequalities that are redundant with respect to the intersection are removed. =back =head3 Lexicographic Optimization Given a (basic) set C (or C) and a zero-dimensional domain C, the following functions compute a set that contains the lexicographic minimum or maximum of the elements in C (or C) for those values of the parameters that satisfy C. If C is not C, then C<*empty> is assigned a set that contains the parameter values in C for which C (or C) has no elements. In other words, the union of the parameter values for which the result is non-empty and of C<*empty> is equal to C. __isl_give isl_set *isl_basic_set_partial_lexmin( __isl_take isl_basic_set *bset, __isl_take isl_basic_set *dom, __isl_give isl_set **empty); __isl_give isl_set *isl_basic_set_partial_lexmax( __isl_take isl_basic_set *bset, __isl_take isl_basic_set *dom, __isl_give isl_set **empty); __isl_give isl_set *isl_set_partial_lexmin( __isl_take isl_set *set, __isl_take isl_set *dom, __isl_give isl_set **empty); __isl_give isl_set *isl_set_partial_lexmax( __isl_take isl_set *set, __isl_take isl_set *dom, __isl_give isl_set **empty); Given a (basic) set C (or C), the following functions simply return a set containing the lexicographic minimum or maximum of the elements in C (or C). __isl_give isl_set *isl_basic_set_lexmin( __isl_take isl_basic_set *bset); __isl_give isl_set *isl_basic_set_lexmax( __isl_take isl_basic_set *bset); __isl_give isl_set *isl_set_lexmin( __isl_take isl_set *set); __isl_give isl_set *isl_set_lexmax( __isl_take isl_set *set); Given a (basic) relation C (or C) and a domain C, the following functions compute a relation that maps each element of C to the single lexicographic minimum or maximum of the elements that are associated to that same element in C (or C). If C is not C, then C<*empty> is assigned a set that contains the elements in C that do not map to any elements in C (or C). In other words, the union of the domain of the result and of C<*empty> is equal to C. __isl_give isl_map *isl_basic_map_partial_lexmax( __isl_take isl_basic_map *bmap, __isl_take isl_basic_set *dom, __isl_give isl_set **empty); __isl_give isl_map *isl_basic_map_partial_lexmin( __isl_take isl_basic_map *bmap, __isl_take isl_basic_set *dom, __isl_give isl_set **empty); __isl_give isl_map *isl_map_partial_lexmax( __isl_take isl_map *map, __isl_take isl_set *dom, __isl_give isl_set **empty); __isl_give isl_map *isl_map_partial_lexmin( __isl_take isl_map *map, __isl_take isl_set *dom, __isl_give isl_set **empty); Given a (basic) map C (or C), the following functions simply return a map mapping each element in the domain of C (or C) to the lexicographic minimum or maximum of all elements associated to that element. __isl_give isl_map *isl_basic_map_lexmin( __isl_take isl_basic_map *bmap); __isl_give isl_map *isl_basic_map_lexmax( __isl_take isl_basic_map *bmap); __isl_give isl_map *isl_map_lexmin( __isl_take isl_map *map); __isl_give isl_map *isl_map_lexmax( __isl_take isl_map *map); =head2 Points Points are elements of a set. They can be used to construct simple sets (boxes) or they can be used to represent the individual elements of a set. The zero point (the origin) can be created using __isl_give isl_point *isl_point_zero(__isl_take isl_dim *dim); The coordinates of a point can be inspected, set and changed using void isl_point_get_coordinate(__isl_keep isl_point *pnt, enum isl_dim_type type, int pos, isl_int *v); __isl_give isl_point *isl_point_set_coordinate( __isl_take isl_point *pnt, enum isl_dim_type type, int pos, isl_int v); __isl_give isl_point *isl_point_add_ui( __isl_take isl_point *pnt, enum isl_dim_type type, int pos, unsigned val); __isl_give isl_point *isl_point_sub_ui( __isl_take isl_point *pnt, enum isl_dim_type type, int pos, unsigned val); Points can be copied or freed using __isl_give isl_point *isl_point_copy( __isl_keep isl_point *pnt); void isl_point_free(__isl_take isl_point *pnt); A singleton set can be created from a point using __isl_give isl_set *isl_set_from_point( __isl_take isl_point *pnt); and a box can be created from two opposite extremal points using __isl_give isl_set *isl_set_box_from_points( __isl_take isl_point *pnt1, __isl_take isl_point *pnt2); All elements of a B set can be enumerated using the following function. int isl_set_foreach_point(__isl_keep isl_set *set, int (*fn)(__isl_take isl_point *pnt, void *user), void *user); The function C is called for each integer point in C with as second argument the last argument of the C call. The function C should return C<0> on success and C<-1> on failure. In the latter case, C will stop enumerating and return C<-1> as well. If the enumeration is performed successfully and to completion, then C returns C<0>. To obtain a single point of a set, use __isl_give isl_point *isl_set_sample_point( __isl_take isl_set *set); If C does not contain any (integer) points, then the resulting point will be ``void'', a property that can be tested using int isl_point_is_void(__isl_keep isl_point *pnt); =head2 Piecewise Quasipolynomials A piecewise quasipolynomial is a particular kind of function that maps a parametric point to a rational value. More specifically, a quasipolynomial is a polynomial expression in greatest integer parts of affine expressions of parameters and variables. A piecewise quasipolynomial is a subdivision of a given parametric domain into disjoint cells with a quasipolynomial associated to each cell. The value of the piecewise quasipolynomial at a given point is the value of the quasipolynomial associated to the cell that contains the point. Outside of the union of cells, the value is assumed to be zero. For example, the piecewise quasipolynomial [n] -> { [x] -> ((1 + n) - x) : x <= n and x >= 0 } maps C to C<1 + n - x> for values of C between C<0> and C. Piecewise quasipolynomials are mainly used by the C library for representing the number of elements in a parametric set or map. For example, the piecewise quasipolynomial above represents the number of point in the map [n] -> { [x] -> [y] : x,y >= 0 and 0 <= x + y <= n } =head3 Printing (Piecewise) Quasipolynomials Quasipolynomials and piecewise quasipolynomials can be printed using the following functions. __isl_give isl_printer *isl_printer_print_qpolynomial( __isl_take isl_printer *p, __isl_keep isl_qpolynomial *qp); __isl_give isl_printer *isl_printer_print_pw_qpolynomial( __isl_take isl_printer *p, __isl_keep isl_pw_qpolynomial *pwqp); The output format of the printer needs to be set to either C or C. =head3 Creating New (Piecewise) Quasipolynomials Some simple quasipolynomials can be created using the following functions. More complicated quasipolynomials can be created by applying operations such as addition and multiplication on the resulting quasipolynomials __isl_give isl_qpolynomial *isl_qpolynomial_zero( __isl_take isl_dim *dim); __isl_give isl_qpolynomial *isl_qpolynomial_infty( __isl_take isl_dim *dim); __isl_give isl_qpolynomial *isl_qpolynomial_neginfty( __isl_take isl_dim *dim); __isl_give isl_qpolynomial *isl_qpolynomial_nan( __isl_take isl_dim *dim); __isl_give isl_qpolynomial *isl_qpolynomial_rat_cst( __isl_take isl_dim *dim, const isl_int n, const isl_int d); __isl_give isl_qpolynomial *isl_qpolynomial_div( __isl_take isl_div *div); __isl_give isl_qpolynomial *isl_qpolynomial_var( __isl_take isl_dim *dim, enum isl_dim_type type, unsigned pos); The zero piecewise quasipolynomial or a piecewise quasipolynomial with a single cell can be created using the following functions. Multiple of these single cell piecewise quasipolynomials can be combined to create more complicated piecewise quasipolynomials. __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_zero( __isl_take isl_dim *dim); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_alloc( __isl_take isl_set *set, __isl_take isl_qpolynomial *qp); Quasipolynomials can be copied and freed again using the following functions. __isl_give isl_qpolynomial *isl_qpolynomial_copy( __isl_keep isl_qpolynomial *qp); void isl_qpolynomial_free(__isl_take isl_qpolynomial *qp); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_copy( __isl_keep isl_pw_qpolynomial *pwqp); void isl_pw_qpolynomial_free( __isl_take isl_pw_qpolynomial *pwqp); =head3 Inspecting (Piecewise) Quasipolynomials To iterate over the cells in a piecewise quasipolynomial, use either of the following two functions int isl_pw_qpolynomial_foreach_piece( __isl_keep isl_pw_qpolynomial *pwqp, int (*fn)(__isl_take isl_set *set, __isl_take isl_qpolynomial *qp, void *user), void *user); int isl_pw_qpolynomial_foreach_lifted_piece( __isl_keep isl_pw_qpolynomial *pwqp, int (*fn)(__isl_take isl_set *set, __isl_take isl_qpolynomial *qp, void *user), void *user); As usual, the function C should return C<0> on success and C<-1> on failure. The difference between C and C is that C will first compute unique representations for all existentially quantified variables and then turn these existentially quantified variables into extra set variables, adapting the associated quasipolynomial accordingly. This means that the C passed to C will not have any existentially quantified variables, but that the dimensions of the sets may be different for different invocations of C. To iterate over all terms in a quasipolynomial, use int isl_qpolynomial_foreach_term( __isl_keep isl_qpolynomial *qp, int (*fn)(__isl_take isl_term *term, void *user), void *user); The terms themselves can be inspected and freed using these functions unsigned isl_term_dim(__isl_keep isl_term *term, enum isl_dim_type type); void isl_term_get_num(__isl_keep isl_term *term, isl_int *n); void isl_term_get_den(__isl_keep isl_term *term, isl_int *d); int isl_term_get_exp(__isl_keep isl_term *term, enum isl_dim_type type, unsigned pos); __isl_give isl_div *isl_term_get_div( __isl_keep isl_term *term, unsigned pos); void isl_term_free(__isl_take isl_term *term); Each term is a product of parameters, set variables and integer divisions. The function C returns the exponent of a given dimensions in the given term. The Cs in the arguments of C and C need to have been initialized using C before calling these functions. =head3 Properties of (Piecewise) Quasipolynomials To check whether a quasipolynomial is actually a constant, use the following function. int isl_qpolynomial_is_cst(__isl_keep isl_qpolynomial *qp, isl_int *n, isl_int *d); If C is a constant and if C and C are not C then the numerator and denominator of the constant are returned in C<*n> and C<*d>, respectively. =head3 Operations on (Piecewise) Quasipolynomials __isl_give isl_qpolynomial *isl_qpolynomial_neg( __isl_take isl_qpolynomial *qp); __isl_give isl_qpolynomial *isl_qpolynomial_add( __isl_take isl_qpolynomial *qp1, __isl_take isl_qpolynomial *qp2); __isl_give isl_qpolynomial *isl_qpolynomial_sub( __isl_take isl_qpolynomial *qp1, __isl_take isl_qpolynomial *qp2); __isl_give isl_qpolynomial *isl_qpolynomial_mul( __isl_take isl_qpolynomial *qp1, __isl_take isl_qpolynomial *qp2); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_add( __isl_take isl_pw_qpolynomial *pwqp1, __isl_take isl_pw_qpolynomial *pwqp2); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_sub( __isl_take isl_pw_qpolynomial *pwqp1, __isl_take isl_pw_qpolynomial *pwqp2); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_add_disjoint( __isl_take isl_pw_qpolynomial *pwqp1, __isl_take isl_pw_qpolynomial *pwqp2); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_neg( __isl_take isl_pw_qpolynomial *pwqp); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_mul( __isl_take isl_pw_qpolynomial *pwqp1, __isl_take isl_pw_qpolynomial *pwqp2); __isl_give isl_qpolynomial *isl_pw_qpolynomial_eval( __isl_take isl_pw_qpolynomial *pwqp, __isl_take isl_point *pnt); __isl_give isl_set *isl_pw_qpolynomial_domain( __isl_take isl_pw_qpolynomial *pwqp); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_intersect_domain( __isl_take isl_pw_qpolynomial *pwpq, __isl_take isl_set *set); __isl_give isl_pw_qpolynomial *isl_pw_qpolynomial_gist( __isl_take isl_pw_qpolynomial *pwqp, __isl_take isl_set *context); The gist operation applies the gist operation to each of the cells in the domain of the input piecewise quasipolynomial. In future, the operation will also exploit the context to simplify the quasipolynomials associated to each cell. =head2 Dependence Analysis C contains specialized functionality for performing array dataflow analysis. That is, given a I access relation and a collection of possible I access relations, C can compute relations that describe for each iteration of the sink access, which iteration of which of the source access relations was the last to access the same data element before the given iteration of the sink access. To compute standard flow dependences, the sink should be a read, while the sources should be writes. If any of the source accesses are marked as being I accesses, then there will be a dependence to the last I access B to any I access that follows this last I access. In particular, if I sources are I accesses, then memory based dependence analysis is performed. If, on the other hand, all sources are I accesses, then value based dependence analysis is performed. #include __isl_give isl_access_info *isl_access_info_alloc( __isl_take isl_map *sink, void *sink_user, isl_access_level_before fn, int max_source); __isl_give isl_access_info *isl_access_info_add_source( __isl_take isl_access_info *acc, __isl_take isl_map *source, int must, void *source_user); __isl_give isl_flow *isl_access_info_compute_flow( __isl_take isl_access_info *acc); int isl_flow_foreach(__isl_keep isl_flow *deps, int (*fn)(__isl_take isl_map *dep, int must, void *dep_user, void *user), void *user); __isl_give isl_set *isl_flow_get_no_source( __isl_keep isl_flow *deps, int must); void isl_flow_free(__isl_take isl_flow *deps); The function C performs the actual dependence analysis. The other functions are used to construct the input for this function or to read off the output. The input is collected in an C, which can be created through a call to C. The arguments to this functions are the sink access relation C, a token C used to identify the sink access to the user, a callback function for specifying the relative order of source and sink accesses, and the number of source access relations that will be added. The callback function has type C. The function is called with two user supplied tokens identifying either a source or the sink and it should return the shared nesting level and the relative order of the two accesses. In particular, let I be the number of loops shared by the two accesses. If C precedes C textually, then the function should return I<2 * n + 1>; otherwise, it should return I<2 * n>. The sources can be added to the C by performing (at most) C calls to C. C indicates whether the source is a I access or a I access. Note that a multi-valued access relation should only be marked I if every iteration in the domain of the relation accesses I elements in its image. The C token is again used to identify the source access. The range of the source access relation C should have the same dimension as the range of the sink access relation. The result of the dependence analysis is collected in an C. There may be elements in the domain of the sink access for which no preceding source access could be found or for which all preceding sources are I accesses. The sets of these elements can be obtained through calls to C, the first with C set and the second with C unset. In the case of standard flow dependence analysis, with the sink a read and the sources I writes, the first set corresponds to the reads from uninitialized array elements and the second set is empty. The actual flow dependences can be extracted using C. This function will call the user-specified callback function C for each B dependence between a source and the sink. The callback function is called with four arguments, the actual flow dependence relation mapping source iterations to sink iterations, a boolean that indicates whether it is a I or I dependence, a token identifying the source and an additional C with value equal to the third argument of the C call. A dependence is marked I if it originates from a I source and if it is not followed by any I sources. After finishing with an C, the user should call C to free all associated memory. =head2 Parametric Vertex Enumeration The parametric vertex enumeration described in this section is mainly intended to be used internally and by the C library. #include __isl_give isl_vertices *isl_basic_set_compute_vertices( __isl_keep isl_basic_set *bset); The function C performs the actual computation of the parametric vertices and the chamber decomposition and store the result in an C object. This information can be queried by either iterating over all the vertices or iterating over all the chambers or cells and then iterating over all vertices that are active on the chamber. int isl_vertices_foreach_vertex( __isl_keep isl_vertices *vertices, int (*fn)(__isl_take isl_vertex *vertex, void *user), void *user); int isl_vertices_foreach_cell( __isl_keep isl_vertices *vertices, int (*fn)(__isl_take isl_cell *cell, void *user), void *user); int isl_cell_foreach_vertex(__isl_keep isl_cell *cell, int (*fn)(__isl_take isl_vertex *vertex, void *user), void *user); Other operations that can be performed on an C object are the following. isl_ctx *isl_vertices_get_ctx( __isl_keep isl_vertices *vertices); int isl_vertices_get_n_vertices( __isl_keep isl_vertices *vertices); void isl_vertices_free(__isl_take isl_vertices *vertices); Vertices can be inspected and destroyed using the following functions. isl_ctx *isl_vertex_get_ctx(__isl_keep isl_vertex *vertex); int isl_vertex_get_id(__isl_keep isl_vertex *vertex); __isl_give isl_basic_set *isl_vertex_get_domain( __isl_keep isl_vertex *vertex); __isl_give isl_basic_set *isl_vertex_get_expr( __isl_keep isl_vertex *vertex); void isl_vertex_free(__isl_take isl_vertex *vertex); C returns a singleton parametric set describing the vertex, while C returns the activity domain of the vertex. Note that C and C return B basic sets, so they should mainly be used for inspection and should not be mixed with integer sets. Chambers can be inspected and destroyed using the following functions. isl_ctx *isl_cell_get_ctx(__isl_keep isl_cell *cell); __isl_give isl_basic_set *isl_cell_get_domain( __isl_keep isl_cell *cell); void isl_cell_free(__isl_take isl_cell *cell); =head1 Applications Although C is mainly meant to be used as a library, it also contains some basic applications that use some of the functionality of C. The input may be specified in either the L or the L. =head2 C C takes a polyhedron as input and prints an integer element of the polyhedron, if there is any. The first column in the output is the denominator and is always equal to 1. If the polyhedron contains no integer points, then a vector of length zero is printed. =head2 C C takes the same input as the C program from the C distribution, i.e., a set of constraints on the parameters, a line contains only -1 and finally a set of constraints on a parametric polyhedron. The coefficients of the parameters appear in the last columns (but before the final constant column). The output is the lexicographic minimum of the parametric polyhedron. As C currently does not have its own output format, the output is just a dump of the internal state. =head2 C C computes the minimum of some linear or affine objective function over the integer points in a polyhedron. If an affine objective function is given, then the constant should appear in the last column. =head2 C Given a polytope, C prints all integer points in the polytope. =head1 C The C library provides the following functions for converting between C objects and C objects. The library is distributed separately for licensing reasons. #include __isl_give isl_basic_set *isl_basic_set_new_from_polylib( Polyhedron *P, __isl_take isl_dim *dim); Polyhedron *isl_basic_set_to_polylib( __isl_keep isl_basic_set *bset); __isl_give isl_set *isl_set_new_from_polylib(Polyhedron *D, __isl_take isl_dim *dim); Polyhedron *isl_set_to_polylib(__isl_keep isl_set *set); #include __isl_give isl_basic_map *isl_basic_map_new_from_polylib( Polyhedron *P, __isl_take isl_dim *dim); __isl_give isl_map *isl_map_new_from_polylib(Polyhedron *D, __isl_take isl_dim *dim); Polyhedron *isl_basic_map_to_polylib( __isl_keep isl_basic_map *bmap); Polyhedron *isl_map_to_polylib(__isl_keep isl_map *map);