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/* -----------------------------------------------------------------------------
* std_vector.i
*
* SWIG typemaps for std::vector<T>, D implementation.
*
* The D wrapper is made to loosely resemble a tango.util.container.more.Vector
* and to provide built-in array-like access.
*
* If T does define an operator==, then use the SWIG_STD_VECTOR_ENHANCED
* macro to obtain enhanced functionality (none yet), for example:
*
* SWIG_STD_VECTOR_ENHANCED(SomeNamespace::Klass)
* %template(VectKlass) std::vector<SomeNamespace::Klass>;
*
* Warning: heavy macro usage in this file. Use swig -E to get a sane view on
* the real file contents!
* ----------------------------------------------------------------------------- */
// Warning: Use the typemaps here in the expectation that the macros they are in will change name.
%include <std_common.i>
// MACRO for use within the std::vector class body
%define SWIG_STD_VECTOR_MINIMUM_INTERNAL(CONST_REFERENCE, CTYPE...)
#if (SWIG_D_VERSION == 1)
%typemap(dimports) std::vector< CTYPE > "static import tango.core.Exception;"
%proxycode %{
public this($typemap(dtype, CTYPE)[] values) {
this();
append(values);
}
alias push_back add;
alias push_back push;
alias push_back opCatAssign;
alias size length;
alias opSlice slice;
public $typemap(dtype, CTYPE) opIndexAssign($typemap(dtype, CTYPE) value, size_t index) {
if (index >= size()) {
throw new tango.core.Exception.NoSuchElementException("Tried to assign to element out of vector bounds.");
}
setElement(index, value);
return value;
}
public $typemap(dtype, CTYPE) opIndex(size_t index) {
if (index >= size()) {
throw new tango.core.Exception.NoSuchElementException("Tried to read from element out of vector bounds.");
}
return getElement(index);
}
public void append($typemap(dtype, CTYPE)[] value...) {
foreach (v; value) {
add(v);
}
}
public $typemap(dtype, CTYPE)[] opSlice() {
$typemap(dtype, CTYPE)[] array = new $typemap(dtype, CTYPE)[size()];
foreach (i, ref value; array) {
value = getElement(i);
}
return array;
}
public int opApply(int delegate(ref $typemap(dtype, CTYPE) value) dg) {
int result;
size_t currentSize = size();
for (size_t i = 0; i < currentSize; ++i) {
auto value = getElement(i);
result = dg(value);
setElement(i, value);
}
return result;
}
public int opApply(int delegate(ref size_t index, ref $typemap(dtype, CTYPE) value) dg) {
int result;
size_t currentSize = size();
for (size_t i = 0; i < currentSize; ++i) {
auto value = getElement(i);
// Workaround for http://d.puremagic.com/issues/show_bug.cgi?id=2443.
auto index = i;
result = dg(index, value);
setElement(i, value);
}
return result;
}
public void capacity(size_t value) {
if (value < size()) {
throw new tango.core.Exception.IllegalArgumentException("Tried to make the capacity of a vector smaller than its size.");
}
reserve(value);
}
%}
public:
typedef size_t size_type;
typedef ptrdiff_t difference_type;
typedef CTYPE value_type;
typedef value_type* pointer;
typedef const value_type* const_pointer;
typedef value_type& reference;
typedef CONST_REFERENCE const_reference;
void clear();
void push_back(CTYPE const& x);
size_type size() const;
size_type capacity() const;
void reserve(size_type n) throw (std::length_error);
vector();
vector(const vector &other);
%extend {
vector(size_type capacity) throw (std::length_error) {
std::vector< CTYPE >* pv = 0;
pv = new std::vector< CTYPE >();
// Might throw std::length_error.
pv->reserve(capacity);
return pv;
}
size_type unused() const {
return $self->capacity() - $self->size();
}
const_reference remove() throw (std::out_of_range) {
if ($self->empty()) {
throw std::out_of_range("Tried to remove last element from empty vector.");
}
std::vector< CTYPE >::const_reference value = $self->back();
$self->pop_back();
return value;
}
const_reference remove(size_type index) throw (std::out_of_range) {
if (index >= $self->size()) {
throw std::out_of_range("Tried to remove element with invalid index.");
}
std::vector< CTYPE >::iterator it = $self->begin() + index;
std::vector< CTYPE >::const_reference value = *it;
$self->erase(it);
return value;
}
}
// Wrappers for setting/getting items with the possibly thrown exception
// specified (important for SWIG wrapper generation).
%extend {
const_reference getElement(size_type index) throw (std::out_of_range) {
if ((index < 0) || ($self->size() <= index)) {
throw std::out_of_range("Tried to get value of element with invalid index.");
}
return (*$self)[index];
}
}
// Use CTYPE const& instead of const_reference to work around SWIG code
// generation issue when using const pointers as vector elements (like
// std::vector< const int* >).
%extend {
void setElement(size_type index, CTYPE const& val) throw (std::out_of_range) {
if ((index < 0) || ($self->size() <= index)) {
throw std::out_of_range("Tried to set value of element with invalid index.");
}
(*$self)[index] = val;
}
}
%dmethodmodifiers std::vector::getElement "private"
%dmethodmodifiers std::vector::setElement "private"
%dmethodmodifiers std::vector::reserve "private"
#else
%typemap(dimports) std::vector< CTYPE > %{
static import std.algorithm;
static import std.exception;
static import std.range;
static import std.traits;
%}
%proxycode %{
alias size_t KeyType;
alias $typemap(dtype, CTYPE) ValueType;
this(ValueType[] values...) {
this();
reserve(values.length);
foreach (e; values) {
this ~= e;
}
}
struct Range {
private $typemap(dtype, std::vector< CTYPE >) _outer;
private size_t _a, _b;
this($typemap(dtype, std::vector< CTYPE >) data, size_t a, size_t b) {
_outer = data;
_a = a;
_b = b;
}
@property bool empty() const {
assert((cast($typemap(dtype, std::vector< CTYPE >))_outer).length >= _b);
return _a >= _b;
}
@property Range save() {
return this;
}
@property ValueType front() {
std.exception.enforce(!empty);
return _outer[_a];
}
@property void front(ValueType value) {
std.exception.enforce(!empty);
_outer[_a] = std.algorithm.move(value);
}
void popFront() {
std.exception.enforce(!empty);
++_a;
}
void opIndexAssign(ValueType value, size_t i) {
i += _a;
std.exception.enforce(i < _b && _b <= _outer.length);
_outer[i] = value;
}
void opIndexOpAssign(string op)(ValueType value, size_t i) {
std.exception.enforce(_outer && _a + i < _b && _b <= _outer.length);
auto element = _outer[i];
mixin("element "~op~"= value;");
_outer[i] = element;
}
}
// TODO: dup?
Range opSlice() {
return Range(this, 0, length);
}
Range opSlice(size_t a, size_t b) {
std.exception.enforce(a <= b && b <= length);
return Range(this, a, b);
}
size_t opDollar() const {
return length;
}
@property ValueType front() {
std.exception.enforce(!empty);
return getElement(0);
}
@property void front(ValueType value) {
std.exception.enforce(!empty);
setElement(0, value);
}
@property ValueType back() {
std.exception.enforce(!empty);
return getElement(length - 1);
}
@property void back(ValueType value) {
std.exception.enforce(!empty);
setElement(length - 1, value);
}
ValueType opIndex(size_t i) {
return getElement(i);
}
void opIndexAssign(ValueType value, size_t i) {
setElement(i, value);
}
void opIndexOpAssign(string op)(ValueType value, size_t i) {
auto element = this[i];
mixin("element "~op~"= value;");
this[i] = element;
}
ValueType[] opBinary(string op, Stuff)(Stuff stuff) if (op == "~") {
ValueType[] result;
result ~= this[];
assert(result.length == length);
result ~= stuff[];
return result;
}
void opOpAssign(string op, Stuff)(Stuff stuff) if (op == "~") {
static if (is(typeof(insertBack(stuff)))) {
insertBack(stuff);
} else if (is(typeof(insertBack(stuff[])))) {
insertBack(stuff[]);
} else {
static assert(false, "Cannot append " ~ Stuff.stringof ~ " to " ~ typeof(this).stringof);
}
}
alias size length;
alias remove removeAny;
alias removeAny stableRemoveAny;
size_t insertBack(Stuff)(Stuff stuff)
if (std.traits.isImplicitlyConvertible!(Stuff, ValueType)){
push_back(stuff);
return 1;
}
size_t insertBack(Stuff)(Stuff stuff)
if (std.range.isInputRange!Stuff &&
std.traits.isImplicitlyConvertible!(std.range.ElementType!Stuff, ValueType)) {
size_t itemCount;
foreach(item; stuff) {
insertBack(item);
++itemCount;
}
return itemCount;
}
alias insertBack insert;
alias pop_back removeBack;
alias pop_back stableRemoveBack;
size_t insertBefore(Stuff)(Range r, Stuff stuff)
if (std.traits.isImplicitlyConvertible!(Stuff, ValueType)) {
std.exception.enforce(r._outer.swigCPtr == swigCPtr && r._a < length);
insertAt(r._a, stuff);
return 1;
}
size_t insertBefore(Stuff)(Range r, Stuff stuff)
if (std.range.isInputRange!Stuff && std.traits.isImplicitlyConvertible!(ElementType!Stuff, ValueType)) {
std.exception.enforce(r._outer.swigCPtr == swigCPtr && r._a <= length);
size_t insertCount;
foreach(i, item; stuff) {
insertAt(r._a + i, item);
++insertCount;
}
return insertCount;
}
size_t insertAfter(Stuff)(Range r, Stuff stuff) {
// TODO: optimize
immutable offset = r._a + r.length;
std.exception.enforce(offset <= length);
auto result = insertBack(stuff);
std.algorithm.bringToFront(this[offset .. length - result],
this[length - result .. length]);
return result;
}
size_t replace(Stuff)(Range r, Stuff stuff)
if (std.range.isInputRange!Stuff &&
std.traits.isImplicitlyConvertible!(ElementType!Stuff, ValueType)) {
immutable offset = r._a;
std.exception.enforce(offset <= length);
size_t result;
for (; !stuff.empty; stuff.popFront()) {
if (r.empty) {
// append the rest
return result + insertBack(stuff);
}
r.front = stuff.front;
r.popFront();
++result;
}
// Remove remaining stuff in r
remove(r);
return result;
}
size_t replace(Stuff)(Range r, Stuff stuff)
if (std.traits.isImplicitlyConvertible!(Stuff, ValueType))
{
if (r.empty)
{
insertBefore(r, stuff);
}
else
{
r.front = stuff;
r.popFront();
remove(r);
}
return 1;
}
Range linearRemove(Range r) {
std.exception.enforce(r._a <= r._b && r._b <= length);
immutable tailLength = length - r._b;
linearRemove(r._a, r._b);
return this[length - tailLength .. length];
}
alias remove stableLinearRemove;
int opApply(int delegate(ref $typemap(dtype, CTYPE) value) dg) {
int result;
size_t currentSize = size();
for (size_t i = 0; i < currentSize; ++i) {
auto value = getElement(i);
result = dg(value);
setElement(i, value);
}
return result;
}
int opApply(int delegate(ref size_t index, ref $typemap(dtype, CTYPE) value) dg) {
int result;
size_t currentSize = size();
for (size_t i = 0; i < currentSize; ++i) {
auto value = getElement(i);
// Workaround for http://d.puremagic.com/issues/show_bug.cgi?id=2443.
auto index = i;
result = dg(index, value);
setElement(i, value);
}
return result;
}
%}
public:
typedef size_t size_type;
typedef ptrdiff_t difference_type;
typedef CTYPE value_type;
typedef value_type* pointer;
typedef const value_type* const_pointer;
typedef value_type& reference;
typedef CONST_REFERENCE const_reference;
bool empty() const;
void clear();
void push_back(CTYPE const& x);
void pop_back();
size_type size() const;
size_type capacity() const;
void reserve(size_type n) throw (std::length_error);
vector();
vector(const vector &other);
%extend {
vector(size_type capacity) throw (std::length_error) {
std::vector< CTYPE >* pv = 0;
pv = new std::vector< CTYPE >();
// Might throw std::length_error.
pv->reserve(capacity);
return pv;
}
const_reference remove() throw (std::out_of_range) {
if ($self->empty()) {
throw std::out_of_range("Tried to remove last element from empty vector.");
}
std::vector< CTYPE >::const_reference value = $self->back();
$self->pop_back();
return value;
}
const_reference remove(size_type index) throw (std::out_of_range) {
if (index >= $self->size()) {
throw std::out_of_range("Tried to remove element with invalid index.");
}
std::vector< CTYPE >::iterator it = $self->begin() + index;
std::vector< CTYPE >::const_reference value = *it;
$self->erase(it);
return value;
}
void removeBack(size_type how_many) throw (std::out_of_range) {
std::vector< CTYPE >::iterator end = $self->end();
std::vector< CTYPE >::iterator start = end - how_many;
$self->erase(start, end);
}
void linearRemove(size_type start_index, size_type end_index) throw (std::out_of_range) {
std::vector< CTYPE >::iterator start = $self->begin() + start_index;
std::vector< CTYPE >::iterator end = $self->begin() + end_index;
$self->erase(start, end);
}
void insertAt(size_type index, CTYPE const& x) throw (std::out_of_range) {
std::vector< CTYPE >::iterator it = $self->begin() + index;
$self->insert(it, x);
}
}
// Wrappers for setting/getting items with the possibly thrown exception
// specified (important for SWIG wrapper generation).
%extend {
const_reference getElement(size_type index) throw (std::out_of_range) {
if ((index < 0) || ($self->size() <= index)) {
throw std::out_of_range("Tried to get value of element with invalid index.");
}
return (*$self)[index];
}
}
// Use CTYPE const& instead of const_reference to work around SWIG code
// generation issue when using const pointers as vector elements (like
// std::vector< const int* >).
%extend {
void setElement(size_type index, CTYPE const& val) throw (std::out_of_range) {
if ((index < 0) || ($self->size() <= index)) {
throw std::out_of_range("Tried to set value of element with invalid index.");
}
(*$self)[index] = val;
}
}
%dmethodmodifiers std::vector::getElement "private"
%dmethodmodifiers std::vector::setElement "private"
#endif
%enddef
// Extra methods added to the collection class if operator== is defined for the class being wrapped
// The class will then implement IList<>, which adds extra functionality
%define SWIG_STD_VECTOR_EXTRA_OP_EQUALS_EQUALS(CTYPE...)
%extend {
}
%enddef
// For vararg handling in macros, from swigmacros.swg
#define %arg(X...) X
// Macros for std::vector class specializations/enhancements
%define SWIG_STD_VECTOR_ENHANCED(CTYPE...)
namespace std {
template<> class vector<CTYPE > {
SWIG_STD_VECTOR_MINIMUM_INTERNAL(const value_type&, %arg(CTYPE))
SWIG_STD_VECTOR_EXTRA_OP_EQUALS_EQUALS(CTYPE)
};
}
%enddef
%{
#include <vector>
#include <stdexcept>
%}
namespace std {
// primary (unspecialized) class template for std::vector
// does not require operator== to be defined
template<class T> class vector {
SWIG_STD_VECTOR_MINIMUM_INTERNAL(const value_type&, T)
};
// specializations for pointers
template<class T> class vector<T *> {
SWIG_STD_VECTOR_MINIMUM_INTERNAL(const value_type&, T *)
SWIG_STD_VECTOR_EXTRA_OP_EQUALS_EQUALS(T *)
};
// bool is a bit different in the C++ standard - const_reference in particular
template<> class vector<bool> {
SWIG_STD_VECTOR_MINIMUM_INTERNAL(bool, bool)
SWIG_STD_VECTOR_EXTRA_OP_EQUALS_EQUALS(bool)
};
}
// template specializations for std::vector
// these provide extra collections methods as operator== is defined
SWIG_STD_VECTOR_ENHANCED(char)
SWIG_STD_VECTOR_ENHANCED(signed char)
SWIG_STD_VECTOR_ENHANCED(unsigned char)
SWIG_STD_VECTOR_ENHANCED(short)
SWIG_STD_VECTOR_ENHANCED(unsigned short)
SWIG_STD_VECTOR_ENHANCED(int)
SWIG_STD_VECTOR_ENHANCED(unsigned int)
SWIG_STD_VECTOR_ENHANCED(long)
SWIG_STD_VECTOR_ENHANCED(unsigned long)
SWIG_STD_VECTOR_ENHANCED(long long)
SWIG_STD_VECTOR_ENHANCED(unsigned long long)
SWIG_STD_VECTOR_ENHANCED(float)
SWIG_STD_VECTOR_ENHANCED(double)
SWIG_STD_VECTOR_ENHANCED(std::string) // also requires a %include <std_string.i>
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