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diff --git a/gruel/src/swig/pmt_swig.i b/gruel/src/swig/pmt_swig.i new file mode 100644 index 000000000..3b0eb45c8 --- /dev/null +++ b/gruel/src/swig/pmt_swig.i @@ -0,0 +1,761 @@ +/* -*- c++ -*- */ +/* + * Copyright 2011 Free Software Foundation, Inc. + * + * This file is part of GNU Radio + * + * GNU Radio is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 3, or (at your option) + * any later version. + * + * GNU Radio is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with GNU Radio; see the file COPYING. If not, write to + * the Free Software Foundation, Inc., 51 Franklin Street, + * Boston, MA 02110-1301, USA. + */ + +%module pmt +%include "std_string.i" +%include "stdint.i" +%{ +#include <boost/intrusive_ptr.hpp> +#include <boost/shared_ptr.hpp> +#include <boost/any.hpp> +#include <complex> +#include <string> +#include <stdint.h> +#include <iosfwd> +#include <stdexcept> +#include <gruel/pmt.h> +using namespace pmt; +%} + +// Template intrusive_ptr for Swig to avoid dereferencing issues +class pmt_base; +//%import <intrusive_ptr.i> +%import <gr_intrusive_ptr.i> +%template(swig_int_ptr) boost::intrusive_ptr<pmt_base>; + +typedef boost::intrusive_ptr<pmt_base> pmt_t; + +/* + * ------------------------------------------------------------------------ + * Booleans. Two constants, #t and #f. + * + * In predicates, anything that is not #f is considered true. + * I.e., there is a single false value, #f. + * ------------------------------------------------------------------------ + */ +extern const pmt_t PMT_T; +extern const pmt_t PMT_F; + +//! Return true if obj is \#t or \#f, else return false. +bool pmt_is_bool(pmt_t obj); + +//! Return false if obj is \#f, else return true. +bool pmt_is_true(pmt_t obj); + +//! Return true if obj is \#f, else return true. +bool pmt_is_false(pmt_t obj); + +//! Return \#f is val is false, else return \#t. +pmt_t pmt_from_bool(bool val); + +//! Return true if val is PMT_T, return false when val is PMT_F, +// else raise wrong_type exception. +bool pmt_to_bool(pmt_t val); + +/* + * ------------------------------------------------------------------------ + * Symbols + * ------------------------------------------------------------------------ + */ + +//! Return true if obj is a symbol, else false. +bool pmt_is_symbol(const pmt_t& obj); + +//! Return the symbol whose name is \p s. +pmt_t pmt_string_to_symbol(const std::string &s); + +//! Alias for pmt_string_to_symbol +pmt_t pmt_intern(const std::string &s); + + +/*! + * If \p is a symbol, return the name of the symbol as a string. + * Otherwise, raise the wrong_type exception. + */ +const std::string pmt_symbol_to_string(const pmt_t& sym); + +/* + * ------------------------------------------------------------------------ + * Numbers: we support integer, real and complex + * ------------------------------------------------------------------------ + */ + +//! Return true if obj is any kind of number, else false. +bool pmt_is_number(pmt_t obj); + +/* + * ------------------------------------------------------------------------ + * Integers + * ------------------------------------------------------------------------ + */ + +//! Return true if \p x is an integer number, else false +bool pmt_is_integer(pmt_t x); + +//! Return the pmt value that represents the integer \p x. +pmt_t pmt_from_long(long x); + +/*! + * \brief Convert pmt to long if possible. + * + * When \p x represents an exact integer that fits in a long, + * return that integer. Else raise an exception, either wrong_type + * when x is not an exact integer, or out_of_range when it doesn't fit. + */ +long pmt_to_long(pmt_t x); + +/* + * ------------------------------------------------------------------------ + * uint64_t + * ------------------------------------------------------------------------ + */ + +//! Return true if \p x is an uint64 number, else false +bool pmt_is_uint64(pmt_t x); + +//! Return the pmt value that represents the uint64 \p x. +pmt_t pmt_from_uint64(uint64_t x); + +/*! + * \brief Convert pmt to uint64 if possible. + * + * When \p x represents an exact integer that fits in a uint64, + * return that uint64. Else raise an exception, either wrong_type + * when x is not an exact uint64, or out_of_range when it doesn't fit. + */ +uint64_t pmt_to_uint64(pmt_t x); + +/* + * ------------------------------------------------------------------------ + * Reals + * ------------------------------------------------------------------------ + */ + +/* + * \brief Return true if \p obj is a real number, else false. + */ +bool pmt_is_real(pmt_t obj); + +//! Return the pmt value that represents double \p x. +pmt_t pmt_from_double(double x); + +/*! + * \brief Convert pmt to double if possible. + * + * Returns the number closest to \p val that is representable + * as a double. The argument \p val must be a real or integer, otherwise + * a wrong_type exception is raised. + */ +double pmt_to_double(pmt_t x); + +/* + * ------------------------------------------------------------------------ + * Complex + * ------------------------------------------------------------------------ + */ + +/*! + * \brief return true if \p obj is a complex number, false otherwise. + */ +bool pmt_is_complex(pmt_t obj); + +//! Return a complex number constructed of the given real and imaginary parts. +pmt_t pmt_make_rectangular(double re, double im); + +/*! + * If \p z is complex, real or integer, return the closest complex<double>. + * Otherwise, raise the wrong_type exception. + */ +std::complex<double> pmt_to_complex(pmt_t z); + +/* + * ------------------------------------------------------------------------ + * Pairs + * ------------------------------------------------------------------------ + */ + +extern const pmt_t PMT_NIL; //< the empty list + +//! Return true if \p x is the empty list, otherwise return false. +bool pmt_is_null(const pmt_t& x); + +//! Return true if \p obj is a pair, else false. +bool pmt_is_pair(const pmt_t& obj); + +//! Return a newly allocated pair whose car is \p x and whose cdr is \p y. +pmt_t pmt_cons(const pmt_t& x, const pmt_t& y); + +//! If \p pair is a pair, return the car of the \p pair, otherwise raise wrong_type. +pmt_t pmt_car(const pmt_t& pair); + +//! If \p pair is a pair, return the cdr of the \p pair, otherwise raise wrong_type. +pmt_t pmt_cdr(const pmt_t& pair); + +//! Stores \p value in the car field of \p pair. +void pmt_set_car(pmt_t pair, pmt_t value); + +//! Stores \p value in the cdr field of \p pair. +void pmt_set_cdr(pmt_t pair, pmt_t value); + +pmt_t pmt_caar(pmt_t pair); +pmt_t pmt_cadr(pmt_t pair); +pmt_t pmt_cdar(pmt_t pair); +pmt_t pmt_cddr(pmt_t pair); +pmt_t pmt_caddr(pmt_t pair); +pmt_t pmt_cadddr(pmt_t pair); + +/* + * ------------------------------------------------------------------------ + * Tuples + * + * Store a fixed number of objects. Tuples are not modifiable, and thus + * are excellent for use as messages. Indexing is zero based. + * Access time to an element is O(1). + * ------------------------------------------------------------------------ + */ + +//! Return true if \p x is a tuple, othewise false. +bool pmt_is_tuple(pmt_t x); + +pmt_t pmt_make_tuple(); +pmt_t pmt_make_tuple(const pmt_t &e0); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4, const pmt_t &e5); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4, const pmt_t &e5, const pmt_t &e6); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4, const pmt_t &e5, const pmt_t &e6, const pmt_t &e7); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4, const pmt_t &e5, const pmt_t &e6, const pmt_t &e7, const pmt_t &e8); +pmt_t pmt_make_tuple(const pmt_t &e0, const pmt_t &e1, const pmt_t &e2, const pmt_t &e3, const pmt_t &e4, const pmt_t &e5, const pmt_t &e6, const pmt_t &e7, const pmt_t &e8, const pmt_t &e9); + +/*! + * If \p x is a vector or proper list, return a tuple containing the elements of x + */ +pmt_t pmt_to_tuple(const pmt_t &x); + +/*! + * Return the contents of position \p k of \p tuple. + * \p k must be a valid index of \p tuple. + */ +pmt_t pmt_tuple_ref(const pmt_t &tuple, size_t k); + +/* + * ------------------------------------------------------------------------ + * Vectors + * + * These vectors can hold any kind of objects. Indexing is zero based. + * ------------------------------------------------------------------------ + */ + +//! Return true if \p x is a vector, othewise false. +bool pmt_is_vector(pmt_t x); + +//! Make a vector of length \p k, with initial values set to \p fill +pmt_t pmt_make_vector(size_t k, pmt_t fill); + +/*! + * Return the contents of position \p k of \p vector. + * \p k must be a valid index of \p vector. + */ +pmt_t pmt_vector_ref(pmt_t vector, size_t k); + +//! Store \p obj in position \p k. +void pmt_vector_set(pmt_t vector, size_t k, pmt_t obj); + +//! Store \p fill in every position of \p vector +void pmt_vector_fill(pmt_t vector, pmt_t fill); + +/* + * ------------------------------------------------------------------------ + * Binary Large Objects (BLOBs) + * + * Handy for passing around uninterpreted chunks of memory. + * ------------------------------------------------------------------------ + */ + +//! Return true if \p x is a blob, othewise false. +bool pmt_is_blob(pmt_t x); + +/*! + * \brief Make a blob given a pointer and length in bytes + * + * \param buf is the pointer to data to use to create blob + * \param len is the size of the data in bytes. + * + * The data is copied into the blob. + */ +pmt_t pmt_make_blob(const void *buf, size_t len); + +//! Return a pointer to the blob's data +const void *pmt_blob_data(pmt_t blob); + +//! Return the blob's length in bytes +size_t pmt_blob_length(pmt_t blob); + +/*! + * <pre> + * ------------------------------------------------------------------------ + * Uniform Numeric Vectors + * + * A uniform numeric vector is a vector whose elements are all of single + * numeric type. pmt offers uniform numeric vectors for signed and + * unsigned 8-bit, 16-bit, 32-bit, and 64-bit integers, two sizes of + * floating point values, and complex floating-point numbers of these + * two sizes. Indexing is zero based. + * + * The names of the functions include these tags in their names: + * + * u8 unsigned 8-bit integers + * s8 signed 8-bit integers + * u16 unsigned 16-bit integers + * s16 signed 16-bit integers + * u32 unsigned 32-bit integers + * s32 signed 32-bit integers + * u64 unsigned 64-bit integers + * s64 signed 64-bit integers + * f32 the C++ type float + * f64 the C++ type double + * c32 the C++ type complex<float> + * c64 the C++ type complex<double> + * ------------------------------------------------------------------------ + * </pre> + */ + +//! true if \p x is any kind of uniform numeric vector +bool pmt_is_uniform_vector(pmt_t x); + +bool pmt_is_u8vector(pmt_t x); +bool pmt_is_s8vector(pmt_t x); +bool pmt_is_u16vector(pmt_t x); +bool pmt_is_s16vector(pmt_t x); +bool pmt_is_u32vector(pmt_t x); +bool pmt_is_s32vector(pmt_t x); +bool pmt_is_u64vector(pmt_t x); +bool pmt_is_s64vector(pmt_t x); +bool pmt_is_f32vector(pmt_t x); +bool pmt_is_f64vector(pmt_t x); +bool pmt_is_c32vector(pmt_t x); +bool pmt_is_c64vector(pmt_t x); + +pmt_t pmt_make_u8vector(size_t k, uint8_t fill); +pmt_t pmt_make_s8vector(size_t k, int8_t fill); +pmt_t pmt_make_u16vector(size_t k, uint16_t fill); +pmt_t pmt_make_s16vector(size_t k, int16_t fill); +pmt_t pmt_make_u32vector(size_t k, uint32_t fill); +pmt_t pmt_make_s32vector(size_t k, int32_t fill); +pmt_t pmt_make_u64vector(size_t k, uint64_t fill); +pmt_t pmt_make_s64vector(size_t k, int64_t fill); +pmt_t pmt_make_f32vector(size_t k, float fill); +pmt_t pmt_make_f64vector(size_t k, double fill); +pmt_t pmt_make_c32vector(size_t k, std::complex<float> fill); +pmt_t pmt_make_c64vector(size_t k, std::complex<double> fill); + +pmt_t pmt_init_u8vector(size_t k, const uint8_t *data); +pmt_t pmt_init_s8vector(size_t k, const int8_t *data); +pmt_t pmt_init_u16vector(size_t k, const uint16_t *data); +pmt_t pmt_init_s16vector(size_t k, const int16_t *data); +pmt_t pmt_init_u32vector(size_t k, const uint32_t *data); +pmt_t pmt_init_s32vector(size_t k, const int32_t *data); +pmt_t pmt_init_f32vector(size_t k, const float *data); +pmt_t pmt_init_f64vector(size_t k, const double *data); +pmt_t pmt_init_c32vector(size_t k, const std::complex<float> *data); +pmt_t pmt_init_c64vector(size_t k, const std::complex<double> *data); + +uint8_t pmt_u8vector_ref(pmt_t v, size_t k); +int8_t pmt_s8vector_ref(pmt_t v, size_t k); +uint16_t pmt_u16vector_ref(pmt_t v, size_t k); +int16_t pmt_s16vector_ref(pmt_t v, size_t k); +uint32_t pmt_u32vector_ref(pmt_t v, size_t k); +int32_t pmt_s32vector_ref(pmt_t v, size_t k); +uint64_t pmt_u64vector_ref(pmt_t v, size_t k); +int64_t pmt_s64vector_ref(pmt_t v, size_t k); +float pmt_f32vector_ref(pmt_t v, size_t k); +double pmt_f64vector_ref(pmt_t v, size_t k); +std::complex<float> pmt_c32vector_ref(pmt_t v, size_t k); +std::complex<double> pmt_c64vector_ref(pmt_t v, size_t k); + +void pmt_u8vector_set(pmt_t v, size_t k, uint8_t x); //< v[k] = x +void pmt_s8vector_set(pmt_t v, size_t k, int8_t x); +void pmt_u16vector_set(pmt_t v, size_t k, uint16_t x); +void pmt_s16vector_set(pmt_t v, size_t k, int16_t x); +void pmt_u32vector_set(pmt_t v, size_t k, uint32_t x); +void pmt_s32vector_set(pmt_t v, size_t k, int32_t x); +void pmt_u64vector_set(pmt_t v, size_t k, uint64_t x); +void pmt_s64vector_set(pmt_t v, size_t k, int64_t x); +void pmt_f32vector_set(pmt_t v, size_t k, float x); +void pmt_f64vector_set(pmt_t v, size_t k, double x); +void pmt_c32vector_set(pmt_t v, size_t k, std::complex<float> x); +void pmt_c64vector_set(pmt_t v, size_t k, std::complex<double> x); + +// Return const pointers to the elements + +const void *pmt_uniform_vector_elements(pmt_t v, size_t &len); //< works with any; len is in bytes + +const uint8_t *pmt_u8vector_elements(pmt_t v, size_t &len); //< len is in elements +const int8_t *pmt_s8vector_elements(pmt_t v, size_t &len); //< len is in elements +const uint16_t *pmt_u16vector_elements(pmt_t v, size_t &len); //< len is in elements +const int16_t *pmt_s16vector_elements(pmt_t v, size_t &len); //< len is in elements +const uint32_t *pmt_u32vector_elements(pmt_t v, size_t &len); //< len is in elements +const int32_t *pmt_s32vector_elements(pmt_t v, size_t &len); //< len is in elements +const uint64_t *pmt_u64vector_elements(pmt_t v, size_t &len); //< len is in elements +const int64_t *pmt_s64vector_elements(pmt_t v, size_t &len); //< len is in elements +const float *pmt_f32vector_elements(pmt_t v, size_t &len); //< len is in elements +const double *pmt_f64vector_elements(pmt_t v, size_t &len); //< len is in elements +const std::complex<float> *pmt_c32vector_elements(pmt_t v, size_t &len); //< len is in elements +const std::complex<double> *pmt_c64vector_elements(pmt_t v, size_t &len); //< len is in elements + +// Return non-const pointers to the elements + +void *pmt_uniform_vector_writable_elements(pmt_t v, size_t &len); //< works with any; len is in bytes + +uint8_t *pmt_u8vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +int8_t *pmt_s8vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +uint16_t *pmt_u16vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +int16_t *pmt_s16vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +uint32_t *pmt_u32vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +int32_t *pmt_s32vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +uint64_t *pmt_u64vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +int64_t *pmt_s64vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +float *pmt_f32vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +double *pmt_f64vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +std::complex<float> *pmt_c32vector_writable_elements(pmt_t v, size_t &len); //< len is in elements +std::complex<double> *pmt_c64vector_writable_elements(pmt_t v, size_t &len); //< len is in elements + +/* + * ------------------------------------------------------------------------ + * Dictionary (a.k.a associative array, hash, map) + * + * This is a functional data structure that is persistent. Updating a + * functional data structure does not destroy the existing version, but + * rather creates a new version that coexists with the old. + * ------------------------------------------------------------------------ + */ + +//! Return true if \p obj is a dictionary +bool pmt_is_dict(const pmt_t &obj); + +//! Make an empty dictionary +pmt_t pmt_make_dict(); + +//! Return a new dictionary with \p key associated with \p value. +pmt_t pmt_dict_add(const pmt_t &dict, const pmt_t &key, const pmt_t &value); + +//! Return a new dictionary with \p key removed. +pmt_t pmt_dict_delete(const pmt_t &dict, const pmt_t &key); + +//! Return true if \p key exists in \p dict +bool pmt_dict_has_key(const pmt_t &dict, const pmt_t &key); + +//! If \p key exists in \p dict, return associated value; otherwise return \p not_found. +pmt_t pmt_dict_ref(const pmt_t &dict, const pmt_t &key, const pmt_t ¬_found); + +//! Return list of (key . value) pairs +pmt_t pmt_dict_items(pmt_t dict); + +//! Return list of keys +pmt_t pmt_dict_keys(pmt_t dict); + +//! Return list of values +pmt_t pmt_dict_values(pmt_t dict); + +/* + * ------------------------------------------------------------------------ + * Any (wraps boost::any -- can be used to wrap pretty much anything) + * + * Cannot be serialized or used across process boundaries. + * See http://www.boost.org/doc/html/any.html + * ------------------------------------------------------------------------ + */ + +//! Return true if \p obj is an any +bool pmt_is_any(pmt_t obj); + +//! make an any +pmt_t pmt_make_any(const boost::any &any); + +//! Return underlying boost::any +boost::any pmt_any_ref(pmt_t obj); + +//! Store \p any in \p obj +void pmt_any_set(pmt_t obj, const boost::any &any); + + +/* + * ------------------------------------------------------------------------ + * msg_accepter -- pmt representation of gruel::msg_accepter + * ------------------------------------------------------------------------ + */ +//! Return true if \p obj is a msg_accepter +bool pmt_is_msg_accepter(const pmt_t &obj); + +//! make a msg_accepter +pmt_t pmt_make_msg_accepter(boost::shared_ptr<gruel::msg_accepter> ma); + +//! Return underlying msg_accepter +boost::shared_ptr<gruel::msg_accepter> pmt_msg_accepter_ref(const pmt_t &obj); + +/* + * ------------------------------------------------------------------------ + * General functions + * ------------------------------------------------------------------------ + */ + +//! Return true if x and y are the same object; otherwise return false. +bool pmt_eq(const pmt_t& x, const pmt_t& y); + +/*! + * \brief Return true if x and y should normally be regarded as the same object, else false. + * + * <pre> + * eqv returns true if: + * x and y are the same object. + * x and y are both \#t or both \#f. + * x and y are both symbols and their names are the same. + * x and y are both numbers, and are numerically equal. + * x and y are both the empty list (nil). + * x and y are pairs or vectors that denote same location in store. + * </pre> + */ +bool pmt_eqv(const pmt_t& x, const pmt_t& y); + +/*! + * pmt_equal recursively compares the contents of pairs and vectors, + * applying pmt_eqv on other objects such as numbers and symbols. + * pmt_equal may fail to terminate if its arguments are circular data + * structures. + */ +bool pmt_equal(const pmt_t& x, const pmt_t& y); + + +//! Return the number of elements in v +size_t pmt_length(const pmt_t& v); + +/*! + * \brief Find the first pair in \p alist whose car field is \p obj + * and return that pair. + * + * \p alist (for "association list") must be a list of pairs. If no pair + * in \p alist has \p obj as its car then \#f is returned. + * Uses pmt_eq to compare \p obj with car fields of the pairs in \p alist. + */ +pmt_t pmt_assq(pmt_t obj, pmt_t alist); + +/*! + * \brief Find the first pair in \p alist whose car field is \p obj + * and return that pair. + * + * \p alist (for "association list") must be a list of pairs. If no pair + * in \p alist has \p obj as its car then \#f is returned. + * Uses pmt_eqv to compare \p obj with car fields of the pairs in \p alist. + */ +pmt_t pmt_assv(pmt_t obj, pmt_t alist); + +/*! + * \brief Find the first pair in \p alist whose car field is \p obj + * and return that pair. + * + * \p alist (for "association list") must be a list of pairs. If no pair + * in \p alist has \p obj as its car then \#f is returned. + * Uses pmt_equal to compare \p obj with car fields of the pairs in \p alist. + */ +pmt_t pmt_assoc(pmt_t obj, pmt_t alist); + +/*! + * \brief Apply \p proc element-wise to the elements of list and returns + * a list of the results, in order. + * + * \p list must be a list. The dynamic order in which \p proc is + * applied to the elements of \p list is unspecified. + */ +pmt_t pmt_map(pmt_t proc(const pmt_t&), pmt_t list); + +/*! + * \brief reverse \p list. + * + * \p list must be a proper list. + */ +pmt_t pmt_reverse(pmt_t list); + +/*! + * \brief destructively reverse \p list. + * + * \p list must be a proper list. + */ +pmt_t pmt_reverse_x(pmt_t list); + +/*! + * \brief (acons x y a) == (cons (cons x y) a) + */ +inline static pmt_t +pmt_acons(pmt_t x, pmt_t y, pmt_t a) +{ + return pmt_cons(pmt_cons(x, y), a); +} + +/*! + * \brief locates \p nth element of \n list where the car is the 'zeroth' element. + */ +pmt_t pmt_nth(size_t n, pmt_t list); + +/*! + * \brief returns the tail of \p list that would be obtained by calling + * cdr \p n times in succession. + */ +pmt_t pmt_nthcdr(size_t n, pmt_t list); + +/*! + * \brief Return the first sublist of \p list whose car is \p obj. + * If \p obj does not occur in \p list, then \#f is returned. + * pmt_memq use pmt_eq to compare \p obj with the elements of \p list. + */ +pmt_t pmt_memq(pmt_t obj, pmt_t list); + +/*! + * \brief Return the first sublist of \p list whose car is \p obj. + * If \p obj does not occur in \p list, then \#f is returned. + * pmt_memv use pmt_eqv to compare \p obj with the elements of \p list. + */ +pmt_t pmt_memv(pmt_t obj, pmt_t list); + +/*! + * \brief Return the first sublist of \p list whose car is \p obj. + * If \p obj does not occur in \p list, then \#f is returned. + * pmt_member use pmt_equal to compare \p obj with the elements of \p list. + */ +pmt_t pmt_member(pmt_t obj, pmt_t list); + +/*! + * \brief Return true if every element of \p list1 appears in \p list2, and false otherwise. + * Comparisons are done with pmt_eqv. + */ +bool pmt_subsetp(pmt_t list1, pmt_t list2); + +/*! + * \brief Return a list of length 1 containing \p x1 + */ +pmt_t pmt_list1(const pmt_t& x1); + +/*! + * \brief Return a list of length 2 containing \p x1, \p x2 + */ +pmt_t pmt_list2(const pmt_t& x1, const pmt_t& x2); + +/*! + * \brief Return a list of length 3 containing \p x1, \p x2, \p x3 + */ +pmt_t pmt_list3(const pmt_t& x1, const pmt_t& x2, const pmt_t& x3); + +/*! + * \brief Return a list of length 4 containing \p x1, \p x2, \p x3, \p x4 + */ +pmt_t pmt_list4(const pmt_t& x1, const pmt_t& x2, const pmt_t& x3, const pmt_t& x4); + +/*! + * \brief Return a list of length 5 containing \p x1, \p x2, \p x3, \p x4, \p x5 + */ +pmt_t pmt_list5(const pmt_t& x1, const pmt_t& x2, const pmt_t& x3, const pmt_t& x4, const pmt_t& x5); + +/*! + * \brief Return a list of length 6 containing \p x1, \p x2, \p x3, \p x4, \p + * x5, \p x6 + */ +pmt_t pmt_list6(const pmt_t& x1, const pmt_t& x2, const pmt_t& x3, const pmt_t& x4, const pmt_t& x5, const pmt_t& x6); + +/*! + * \brief Return \p list with \p item added to it. + */ +pmt_t pmt_list_add(pmt_t list, const pmt_t& item); + + +/* + * ------------------------------------------------------------------------ + * read / write + * ------------------------------------------------------------------------ + */ +extern const pmt_t PMT_EOF; //< The end of file object + +//! return true if obj is the EOF object, otherwise return false. +bool pmt_is_eof_object(pmt_t obj); + +/*! + * read converts external representations of pmt objects into the + * objects themselves. Read returns the next object parsable from + * the given input port, updating port to point to the first + * character past the end of the external representation of the + * object. + * + * If an end of file is encountered in the input before any + * characters are found that can begin an object, then an end of file + * object is returned. The port remains open, and further attempts + * to read will also return an end of file object. If an end of file + * is encountered after the beginning of an object's external + * representation, but the external representation is incomplete and + * therefore not parsable, an error is signaled. + */ +pmt_t pmt_read(std::istream &port); + +/*! + * Write a written representation of \p obj to the given \p port. + */ +void pmt_write(pmt_t obj, std::ostream &port); + +/*! + * Return a string representation of \p obj. + * This is the same output as would be generated by pmt_write. + */ +std::string pmt_write_string(pmt_t obj); + + +/*! + * \brief Write pmt string representation to stdout. + */ +void pmt_print(pmt_t v); + + +/* + * ------------------------------------------------------------------------ + * portable byte stream representation + * ------------------------------------------------------------------------ + */ +/*! + * \brief Write portable byte-serial representation of \p obj to \p sink + */ +bool pmt_serialize(pmt_t obj, std::streambuf &sink); + +/*! + * \brief Create obj from portable byte-serial representation + */ +pmt_t pmt_deserialize(std::streambuf &source); + + +void pmt_dump_sizeof(); // debugging + +/*! + * \brief Provide a simple string generating interface to pmt's serialize function + */ +std::string pmt_serialize_str(pmt_t obj); + +/*! + * \brief Provide a simple string generating interface to pmt's deserialize function + */ +pmt_t pmt_deserialize_str(std::string str); |