mirror of
https://github.com/nillerusr/source-engine.git
synced 2024-12-23 14:46:53 +00:00
437 lines
18 KiB
OpenEdge ABL
437 lines
18 KiB
OpenEdge ABL
/* -----------------------------------------------------------------------------
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* See the LICENSE file for information on copyright, usage and redistribution
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* of SWIG, and the README file for authors - http://www.swig.org/release.html.
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*
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* std_vector.i
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*
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* SWIG typemaps for std::vector
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* ----------------------------------------------------------------------------- */
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%include <std_common.i>
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// ------------------------------------------------------------------------
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// std::vector
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//
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// The aim of all that follows would be to integrate std::vector with
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// MzScheme as much as possible, namely, to allow the user to pass and
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// be returned MzScheme vectors or lists.
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// const declarations are used to guess the intent of the function being
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// exported; therefore, the following rationale is applied:
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//
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// -- f(std::vector<T>), f(const std::vector<T>&), f(const std::vector<T>*):
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// the parameter being read-only, either a MzScheme sequence or a
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// previously wrapped std::vector<T> can be passed.
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// -- f(std::vector<T>&), f(std::vector<T>*):
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// the parameter must be modified; therefore, only a wrapped std::vector
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// can be passed.
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// -- std::vector<T> f():
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// the vector is returned by copy; therefore, a MzScheme vector of T:s
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// is returned which is most easily used in other MzScheme functions
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// -- std::vector<T>& f(), std::vector<T>* f(), const std::vector<T>& f(),
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// const std::vector<T>* f():
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// the vector is returned by reference; therefore, a wrapped std::vector
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// is returned
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// ------------------------------------------------------------------------
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%{
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#include <vector>
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#include <algorithm>
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#include <stdexcept>
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%}
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// exported class
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namespace std {
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template<class T> class vector {
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%typemap(in) vector<T> {
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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$1 = std::vector<T >(size);
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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for (unsigned int i=0; i<size; i++) {
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(($1_type &)$1)[i] =
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*((T*) SWIG_MustGetPtr(items[i],
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$descriptor(T *),
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$argnum, 0));
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}
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} else if (SCHEME_NULLP($input)) {
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$1 = std::vector<T >();
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} else if (SCHEME_PAIRP($input)) {
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Scheme_Object *head, *tail;
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$1 = std::vector<T >();
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tail = $input;
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while (!SCHEME_NULLP(tail)) {
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head = scheme_car(tail);
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tail = scheme_cdr(tail);
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$1.push_back(*((T*)SWIG_MustGetPtr(head,
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$descriptor(T *),
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$argnum, 0)));
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}
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} else {
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$1 = *(($&1_type)
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SWIG_MustGetPtr($input,$&1_descriptor,$argnum, 0));
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}
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}
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%typemap(in) const vector<T>& (std::vector<T> temp),
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const vector<T>* (std::vector<T> temp) {
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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temp = std::vector<T >(size);
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$1 = &temp;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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for (unsigned int i=0; i<size; i++) {
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temp[i] = *((T*) SWIG_MustGetPtr(items[i],
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$descriptor(T *),
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$argnum, 0));
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}
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} else if (SCHEME_NULLP($input)) {
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temp = std::vector<T >();
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$1 = &temp;
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} else if (SCHEME_PAIRP($input)) {
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temp = std::vector<T >();
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$1 = &temp;
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Scheme_Object *head, *tail;
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tail = $input;
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while (!SCHEME_NULLP(tail)) {
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head = scheme_car(tail);
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tail = scheme_cdr(tail);
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temp.push_back(*((T*) SWIG_MustGetPtr(head,
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$descriptor(T *),
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$argnum, 0)));
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}
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} else {
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$1 = ($1_ltype) SWIG_MustGetPtr($input,$1_descriptor,$argnum, 0);
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}
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}
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%typemap(out) vector<T> {
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$result = scheme_make_vector($1.size(),scheme_undefined);
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Scheme_Object** els = SCHEME_VEC_ELS($result);
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for (unsigned int i=0; i<$1.size(); i++) {
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T* x = new T((($1_type &)$1)[i]);
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els[i] = SWIG_NewPointerObj(x,$descriptor(T *), 1);
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}
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}
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%typecheck(SWIG_TYPECHECK_VECTOR) vector<T> {
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/* native sequence? */
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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if (size == 0) {
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/* an empty sequence can be of any type */
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$1 = 1;
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} else {
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/* check the first element only */
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T* x;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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if (SWIG_ConvertPtr(items[0],(void**) &x,
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$descriptor(T *), 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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}
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} else if (SCHEME_NULLP($input)) {
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/* again, an empty sequence can be of any type */
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$1 = 1;
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} else if (SCHEME_PAIRP($input)) {
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/* check the first element only */
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T* x;
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Scheme_Object *head = scheme_car($input);
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if (SWIG_ConvertPtr(head,(void**) &x,
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$descriptor(T *), 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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} else {
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/* wrapped vector? */
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std::vector<T >* v;
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if (SWIG_ConvertPtr($input,(void **) &v,
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$&1_descriptor, 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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}
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}
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%typecheck(SWIG_TYPECHECK_VECTOR) const vector<T>&,
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const vector<T>* {
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/* native sequence? */
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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if (size == 0) {
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/* an empty sequence can be of any type */
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$1 = 1;
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} else {
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/* check the first element only */
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T* x;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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if (SWIG_ConvertPtr(items[0],(void**) &x,
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$descriptor(T *), 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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}
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} else if (SCHEME_NULLP($input)) {
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/* again, an empty sequence can be of any type */
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$1 = 1;
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} else if (SCHEME_PAIRP($input)) {
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/* check the first element only */
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T* x;
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Scheme_Object *head = scheme_car($input);
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if (SWIG_ConvertPtr(head,(void**) &x,
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$descriptor(T *), 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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} else {
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/* wrapped vector? */
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std::vector<T >* v;
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if (SWIG_ConvertPtr($input,(void **) &v,
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$1_descriptor, 0) != -1)
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$1 = 1;
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else
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$1 = 0;
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}
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}
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public:
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vector(unsigned int size = 0);
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vector(unsigned int size, const T& value);
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vector(const vector<T>&);
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%rename(length) size;
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unsigned int size() const;
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%rename("empty?") empty;
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bool empty() const;
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%rename("clear!") clear;
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void clear();
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%rename("set!") set;
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%rename("pop!") pop;
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%rename("push!") push_back;
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void push_back(const T& x);
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%extend {
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T pop() throw (std::out_of_range) {
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if (self->size() == 0)
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throw std::out_of_range("pop from empty vector");
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T x = self->back();
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self->pop_back();
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return x;
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}
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T& ref(int i) throw (std::out_of_range) {
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int size = int(self->size());
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if (i>=0 && i<size)
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return (*self)[i];
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else
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throw std::out_of_range("vector index out of range");
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}
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void set(int i, const T& x) throw (std::out_of_range) {
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int size = int(self->size());
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if (i>=0 && i<size)
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(*self)[i] = x;
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else
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throw std::out_of_range("vector index out of range");
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}
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}
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};
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// specializations for built-ins
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%define specialize_std_vector(T,CHECK,CONVERT_FROM,CONVERT_TO)
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template<> class vector<T> {
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%typemap(in) vector<T> {
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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$1 = std::vector<T >(size);
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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for (unsigned int i=0; i<size; i++) {
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Scheme_Object* o = items[i];
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if (CHECK(o))
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(($1_type &)$1)[i] = (T)(CONVERT_FROM(o));
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else
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scheme_wrong_type(FUNC_NAME, "vector<" #T ">",
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$argnum - 1, argc, argv);
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}
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} else if (SCHEME_NULLP($input)) {
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$1 = std::vector<T >();
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} else if (SCHEME_PAIRP($input)) {
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Scheme_Object *head, *tail;
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$1 = std::vector<T >();
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tail = $input;
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while (!SCHEME_NULLP(tail)) {
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head = scheme_car(tail);
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tail = scheme_cdr(tail);
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if (CHECK(head))
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$1.push_back((T)(CONVERT_FROM(head)));
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else
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scheme_wrong_type(FUNC_NAME, "vector<" #T ">",
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$argnum - 1, argc, argv);
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}
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} else {
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$1 = *(($&1_type)
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SWIG_MustGetPtr($input,$&1_descriptor,$argnum, 0));
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}
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}
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%typemap(in) const vector<T>& (std::vector<T> temp),
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const vector<T>* (std::vector<T> temp) {
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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temp = std::vector<T >(size);
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$1 = &temp;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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for (unsigned int i=0; i<size; i++) {
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Scheme_Object* o = items[i];
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if (CHECK(o))
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temp[i] = (T)(CONVERT_FROM(o));
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else
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scheme_wrong_type(FUNC_NAME, "vector<" #T ">",
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$argnum - 1, argc, argv);
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}
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} else if (SCHEME_NULLP($input)) {
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temp = std::vector<T >();
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$1 = &temp;
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} else if (SCHEME_PAIRP($input)) {
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temp = std::vector<T >();
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$1 = &temp;
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Scheme_Object *head, *tail;
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tail = $input;
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while (!SCHEME_NULLP(tail)) {
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head = scheme_car(tail);
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tail = scheme_cdr(tail);
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if (CHECK(head))
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temp.push_back((T)(CONVERT_FROM(head)));
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else
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scheme_wrong_type(FUNC_NAME, "vector<" #T ">",
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$argnum - 1, argc, argv);
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}
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} else {
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$1 = ($1_ltype) SWIG_MustGetPtr($input,$1_descriptor,$argnum - 1, 0);
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}
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}
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%typemap(out) vector<T> {
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$result = scheme_make_vector($1.size(),scheme_undefined);
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Scheme_Object** els = SCHEME_VEC_ELS($result);
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for (unsigned int i=0; i<$1.size(); i++)
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els[i] = CONVERT_TO((($1_type &)$1)[i]);
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}
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%typecheck(SWIG_TYPECHECK_VECTOR) vector<T> {
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/* native sequence? */
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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if (size == 0) {
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/* an empty sequence can be of any type */
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$1 = 1;
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} else {
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/* check the first element only */
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T* x;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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$1 = CHECK(items[0]) ? 1 : 0;
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}
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} else if (SCHEME_NULLP($input)) {
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/* again, an empty sequence can be of any type */
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$1 = 1;
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} else if (SCHEME_PAIRP($input)) {
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/* check the first element only */
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T* x;
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Scheme_Object *head = scheme_car($input);
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$1 = CHECK(head) ? 1 : 0;
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} else {
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/* wrapped vector? */
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std::vector<T >* v;
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$1 = (SWIG_ConvertPtr($input,(void **) &v,
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$&1_descriptor, 0) != -1) ? 1 : 0;
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}
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}
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%typecheck(SWIG_TYPECHECK_VECTOR) const vector<T>&,
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const vector<T>* {
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/* native sequence? */
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if (SCHEME_VECTORP($input)) {
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unsigned int size = SCHEME_VEC_SIZE($input);
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if (size == 0) {
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/* an empty sequence can be of any type */
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$1 = 1;
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} else {
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/* check the first element only */
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T* x;
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Scheme_Object** items = SCHEME_VEC_ELS($input);
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$1 = CHECK(items[0]) ? 1 : 0;
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}
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} else if (SCHEME_NULLP($input)) {
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/* again, an empty sequence can be of any type */
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$1 = 1;
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} else if (SCHEME_PAIRP($input)) {
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/* check the first element only */
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T* x;
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Scheme_Object *head = scheme_car($input);
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$1 = CHECK(head) ? 1 : 0;
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} else {
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/* wrapped vector? */
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std::vector<T >* v;
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$1 = (SWIG_ConvertPtr($input,(void **) &v,
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$1_descriptor, 0) != -1) ? 1 : 0;
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}
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}
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public:
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vector(unsigned int size = 0);
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vector(unsigned int size, const T& value);
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vector(const vector<T>&);
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%rename(length) size;
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unsigned int size() const;
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%rename("empty?") empty;
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bool empty() const;
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%rename("clear!") clear;
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void clear();
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%rename("set!") set;
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%rename("pop!") pop;
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%rename("push!") push_back;
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void push_back(T x);
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%extend {
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T pop() throw (std::out_of_range) {
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if (self->size() == 0)
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throw std::out_of_range("pop from empty vector");
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T x = self->back();
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self->pop_back();
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return x;
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}
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T ref(int i) throw (std::out_of_range) {
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int size = int(self->size());
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if (i>=0 && i<size)
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return (*self)[i];
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else
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throw std::out_of_range("vector index out of range");
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}
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void set(int i, T x) throw (std::out_of_range) {
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int size = int(self->size());
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if (i>=0 && i<size)
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(*self)[i] = x;
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else
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throw std::out_of_range("vector index out of range");
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}
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}
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};
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%enddef
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specialize_std_vector(bool,SCHEME_BOOLP,SCHEME_TRUEP,\
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swig_make_boolean);
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specialize_std_vector(char,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(int,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(short,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(long,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(unsigned char,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(unsigned int,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(unsigned short,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(unsigned long,SCHEME_INTP,SCHEME_INT_VAL,\
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scheme_make_integer_value);
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specialize_std_vector(float,SCHEME_REALP,scheme_real_to_double,\
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scheme_make_double);
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specialize_std_vector(double,SCHEME_REALP,scheme_real_to_double,\
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scheme_make_double);
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specialize_std_vector(std::string,SCHEME_STRINGP,swig_scm_to_string,\
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swig_make_string);
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}
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