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swig/Lib/d/std_vector.i
William S Fulton 449aa08124 %extend changes and remove default use of javatype, dtype, cstype %typemaps 
1) The %extend directive can now optionally support one of the 'class', 'struct' or 'union'.
2) The SWIG library no longer uses the javatype, dtype or cstype typemaps, thereby
   completely freeing them up for users to use without having to replicate the library
   code that they previously added

Tested by changes to test: java_lib_arrays
2017-01-15 16:50:24 +00:00

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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 CTYPE value_type;
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 $typemap(dtype, CTYPE) value) dg) {
int result;
size_t currentSize = size();
for (size_t i = 0; i < currentSize; ++i) {
auto value = getElement(i);
// Workaround for http://d.puremagic.com/issues/show_bug.cgi?id=2443.
auto index = i;
result = dg(index, value);
setElement(i, value);
}
return result;
}
%}
public:
typedef size_t size_type;
typedef CTYPE value_type;
typedef CONST_REFERENCE const_reference;
bool empty() const;
void clear();
void push_back(CTYPE const& x);
void pop_back();
size_type size() const;
size_type capacity() const;
void reserve(size_type n) throw (std::length_error);
vector();
vector(const vector &other);
%extend {
vector(size_type capacity) throw (std::length_error) {
std::vector< CTYPE >* pv = 0;
pv = new std::vector< CTYPE >();
// Might throw std::length_error.
pv->reserve(capacity);
return pv;
}
CONST_REFERENCE remove() throw (std::out_of_range) {
if ($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(%arg(CTYPE const&), %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(T const&, T)
};
// specializations for pointers
template<class T> class vector<T *> {
SWIG_STD_VECTOR_MINIMUM_INTERNAL(T *const&, 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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