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Commit ad6c87b0 authored by Davis King's avatar Davis King
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Merge github.com:davisking/dlib

parents 1ab34825 d4cbaecd
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.hgtags
View file @ ad6c87b0
......@@ -21,3 +21,4 @@ a6c2b16111b8023dbded7299dcc7e6acd26671b8 v18.8
4de62892e10850e8f0205b4857cf48b31fd730c8 v18.9
5a14394843c04628990857e5db94ff6bc43c2da0 v18.10
dd8e950033d5026373acce9ed4b2ffb85908d3b5 v18.11
4e3941b13ca859f788853cfcef9973ac4b161e65 v18.12
dlib/CMakeLists.txt
View file @ ad6c87b0
......@@ -12,6 +12,9 @@ set(CMAKE_LEGACY_CYGWIN_WIN32 0) # Remove when CMake >= 2.8.4 is required
# Suppress cmake warnings about changes in new versions.
if(COMMAND cmake_policy)
cmake_policy(SET CMP0003 NEW)
if (POLICY CMP0054)
cmake_policy(SET CMP0054 NEW)
endif()
endif()
......
dlib/add_python_module
View file @ ad6c87b0
......@@ -20,10 +20,13 @@
# A list of various paths you need to search on windows since people install
# boost in a bunch of different places.
set(CMAKE_PREFIX_PATH ${CMAKE_PREFIX_PATH}
"C:/local/boost_1_*"
"C:/Program Files (x86)/boost/boost_1_*"
"C:/Program Files/boost/boost_1_*")
set(BOOST_LIBRARYDIR "C:/local/boost_1_*/lib32-msvc-*")
C:/local/boost_*
C:/Program\ Files\ \(x86\)/boost/boost_*
C:/Program\ Files/boost/boost_*
)
set(BOOST_LIBRARYDIR ${BOOST_LIBRARYDIR} $ENV{BOOST_LIBRARYDIR}
C:/local/boost_*/lib32-msvc-*
)
......@@ -32,8 +35,10 @@ set(BOOST_LIBRARYDIR "C:/local/boost_1_*/lib32-msvc-*")
#SET(Boost_USE_STATIC_RUNTIME OFF)
set(Boost_NO_BOOST_CMAKE ON)
set(BOOST_LIBRARYDIR /usr/lib/x86_64-linux-gnu/)
if (NOT WIN32)
set(BOOST_LIBRARYDIR ${BOOST_LIBRARYDIR} $ENV{BOOST_LIBRARYDIR}
/usr/lib/x86_64-linux-gnu/)
endif()
if (PYTHON3)
FIND_PACKAGE(Boost 1.41.0 COMPONENTS python-py34 REQUIRED)
FIND_PACKAGE(PythonLibs 3.4 REQUIRED)
......
dlib/cmake
View file @ ad6c87b0
......@@ -3,6 +3,9 @@ cmake_minimum_required(VERSION 2.6.4)
set(CMAKE_LEGACY_CYGWIN_WIN32 0) # Remove when CMake >= 2.8.4 is required
if (POLICY CMP0054)
cmake_policy(SET CMP0054 NEW)
endif()
# Don't add dlib if it's already been added to the cmake project
if (NOT TARGET dlib)
......
dlib/image_processing/shape_predictor.h
View file @ ad6c87b0
......@@ -315,10 +315,6 @@ namespace dlib
unsigned long num_parts (
) const
/*!
ensures
- returns the number of points in the shape
!*/
{
return initial_shape.size()/2;
}
......@@ -328,13 +324,6 @@ namespace dlib
const image_type& img,
const rectangle& rect
) const
/*!
ensures
- runs the tree regressor on the detection rect inside img and returns a
full_object_detection DET such that:
- DET.get_rect() == rect
- DET.num_parts() == num_parts()
!*/
{
using namespace impl;
matrix<float,0,1> current_shape = initial_shape;
......
dlib/image_processing/shape_predictor_abstract.h
View file @ ad6c87b0
......@@ -270,7 +270,7 @@ namespace dlib
of the box. So a padding of 0.5 would cause the algorithm to sample
pixels from a box that was 2x2, effectively multiplying the area pixels
are sampled from by 4. Similarly, setting the padding to -0.2 would
cause it to sample from a box 0.8x0.8 in size.
cause it to sample from a box 0.6x0.6 in size.
!*/
void set_feature_pool_region_padding (
......
dlib/image_transforms/interpolation.h
View file @ ad6c87b0
......@@ -1621,7 +1621,7 @@ namespace dlib
}
// now make an image pyramid
dlib::array<image_type1> levels(max_depth);
dlib::array<image_type2> levels(max_depth);
if (levels.size() != 0)
pyr(img,levels[0]);
for (unsigned long i = 1; i < levels.size(); ++i)
......
dlib/image_transforms/morphological_operations.h
View file @ ad6c87b0
......@@ -6,6 +6,7 @@
#include "../pixel.h"
#include "thresholding.h"
#include "morphological_operations_abstract.h"
#include "assign_image.h"
namespace dlib
{
......@@ -662,6 +663,182 @@ namespace dlib
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
namespace impl
{
template <typename image_type>
inline bool should_remove_pixel (
const image_type& img,
long r,
long c,
int iter
)
{
unsigned int p2 = img[r-1][c];
unsigned int p3 = img[r-1][c+1];
unsigned int p4 = img[r][c+1];
unsigned int p5 = img[r+1][c+1];
unsigned int p6 = img[r+1][c];
unsigned int p7 = img[r+1][c-1];
unsigned int p8 = img[r][c-1];
unsigned int p9 = img[r-1][c-1];
int A = (p2 == 0 && p3 == 255) + (p3 == 0 && p4 == 255) +
(p4 == 0 && p5 == 255) + (p5 == 0 && p6 == 255) +
(p6 == 0 && p7 == 255) + (p7 == 0 && p8 == 255) +
(p8 == 0 && p9 == 255) + (p9 == 0 && p2 == 255);
int B = p2 + p3 + p4 + p5 + p6 + p7 + p8 + p9;
int m1 = iter == 0 ? (p2 * p4 * p6) : (p2 * p4 * p8);
int m2 = iter == 0 ? (p4 * p6 * p8) : (p2 * p6 * p8);
// Decide if we should remove the pixel img[r][c].
return (A == 1 && (B >= 2*255 && B <= 6*255) && m1 == 0 && m2 == 0);
}
template <typename image_type>
inline void add_to_remove (
std::vector<point>& to_remove,
array2d<unsigned char>& marker,
const image_type& img,
long r,
long c,
int iter
)
{
if (marker[r][c]&&should_remove_pixel(img,r,c,iter))
{
to_remove.push_back(point(c,r));
marker[r][c] = 0;
}
}
template <typename image_type>
inline bool is_bw_border_pixel(
const image_type& img,
long r,
long c
)
{
unsigned int p2 = img[r-1][c];
unsigned int p3 = img[r-1][c+1];
unsigned int p4 = img[r][c+1];
unsigned int p5 = img[r+1][c+1];
unsigned int p6 = img[r+1][c];
unsigned int p7 = img[r+1][c-1];
unsigned int p8 = img[r][c-1];
unsigned int p9 = img[r-1][c-1];
int B = p2 + p3 + p4 + p5 + p6 + p7 + p8 + p9;
// If you are on but at least one of your neighbors isn't.
return B<8*255 && img[r][c];
}
inline void add_if(
std::vector<point>& to_check2,
const array2d<unsigned char>& marker,
long c,
long r
)
{
if (marker[r][c])
to_check2.push_back(point(c,r));
}
} // end namespace impl
// ----------------------------------------------------------------------------------------
template <
typename image_type
>
void skeleton(
image_type& img_
)
{
/*
The implementation of this function is based on the paper
"A fast parallel algorithm for thinning digital patterns” by T.Y. Zhang and C.Y. Suen.
and also the excellent discussion of it at:
http://opencv-code.com/quick-tips/implementation-of-thinning-algorithm-in-opencv/
*/
typedef typename image_traits<image_type>::pixel_type pixel_type;
// This function only works on grayscale images
COMPILE_TIME_ASSERT(pixel_traits<pixel_type>::grayscale);
using namespace impl;
// Note that it's important to zero the border for 2 reasons. First, it allows
// thinning to being at the border of the image. But more importantly, it causes
// the mask to have a border of 0 pixels as well which we use later to avoid
// indexing outside the image inside add_to_remove().
zero_border_pixels(img_,1,1);
image_view<image_type> img(img_);
// We use the marker to keep track of pixels we have committed to removing but
// haven't yet removed from img.
array2d<unsigned char> marker(img.nr(), img.nc());
assign_image(marker, img);
// Begin by making a list of the pixels on the borders of binary blobs.
std::vector<point> to_remove, to_check, to_check2;
for (int r = 1; r < img.nr()-1; r++)
{
for (int c = 1; c < img.nc()-1; c++)
{
if (is_bw_border_pixel(img, r, c))
{
to_check.push_back(point(c,r));
}
}
}
// Now start iteratively looking at the border pixels and removing them.
while(to_check.size() != 0)
{
for (int iter = 0; iter <= 1; ++iter)
{
// Check which pixels we should remove
to_remove.clear();
for (unsigned long i = 0; i < to_check.size(); ++i)
{
long r = to_check[i].y();
long c = to_check[i].x();
add_to_remove(to_remove, marker, img, r, c, iter);
}
for (unsigned long i = 0; i < to_check2.size(); ++i)
{
long r = to_check2[i].y();
long c = to_check2[i].x();
add_to_remove(to_remove, marker, img, r, c, iter);
}
// Now remove those pixels. Also add their neighbors into the "to check"
// pixel list for the next iteration.
for (unsigned long i = 0; i < to_remove.size(); ++i)
{
long r = to_remove[i].y();
long c = to_remove[i].x();
// remove the pixel
img[r][c] = 0;
add_if(to_check2, marker, c-1, r-1);
add_if(to_check2, marker, c, r-1);
add_if(to_check2, marker, c+1, r-1);
add_if(to_check2, marker, c-1, r);
add_if(to_check2, marker, c+1, r);
add_if(to_check2, marker, c-1, r+1);
add_if(to_check2, marker, c, r+1);
add_if(to_check2, marker, c+1, r+1);
}
}
to_check.clear();
to_check.swap(to_check2);
}
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
}
......
dlib/image_transforms/morphological_operations_abstract.h
View file @ ad6c87b0
......@@ -283,6 +283,30 @@ namespace dlib
- calls binary_complement(img,img);
!*/
// ----------------------------------------------------------------------------------------
template <
typename image_type
>
void skeleton(
image_type& img
);
/*!
requires
- image_type is an object that implement the interface defined in
dlib/image_processing/generic_image.h
- img must contain a grayscale pixel type.
- all pixels in img are set to either on_pixel or off_pixel.
(i.e. it must be a binary image)
ensures
- This function computes the skeletonization of img and stores the result in
#img. That is, given a binary image, we progressively thin the binary blobs
(composed of on_pixel values) until only a single pixel wide skeleton of the
original blobs remains.
- #img.nc() == img.nc()
- #img.nr() == img.nr()
!*/
// ----------------------------------------------------------------------------------------
}
......
dlib/image_transforms/spatial_filtering.h
View file @ ad6c87b0
......@@ -1217,7 +1217,7 @@ namespace dlib
typename in_image_type,
typename out_image_type
>
void gaussian_blur (
rectangle gaussian_blur (
const in_image_type& in_img,
out_image_type& out_img,
double sigma = 1,
......@@ -1241,7 +1241,7 @@ namespace dlib
ptype scale = sum(filt);
scale = scale*scale;
spatially_filter_image_separable(in_img, out_img, filt, filt, scale);
return spatially_filter_image_separable(in_img, out_img, filt, filt, scale);
}
......
dlib/image_transforms/spatial_filtering_abstract.h
View file @ ad6c87b0
......@@ -353,7 +353,7 @@ namespace dlib
typename in_image_type,
typename out_image_type
>
void gaussian_blur (
rectangle gaussian_blur (
const in_image_type& in_img,
out_image_type& out_img,
double sigma = 1,
......@@ -384,6 +384,8 @@ namespace dlib
inside the image are set to zero.
- #out_img.nc() == in_img.nc()
- #out_img.nr() == in_img.nr()
- returns a rectangle which indicates what pixels in #out_img are considered
non-border pixels and therefore contain output from the filter.
!*/
// ----------------------------------------------------------------------------------------
......
dlib/matlab/CMakeLists.txt
View file @ ad6c87b0
cmake_minimum_required(VERSION 2.8.4)
PROJECT(mex_functions)
include(cmake_mex_wrapper)
include(../cmake)
# Compile the example_mex_function.cpp file and link it to dlib. Note
# that you can give a list of things to link to here. E.g.
# add_mex_function(some_other_mex_function pthread dlib fftw)
add_mex_function(example_mex_function dlib)
add_mex_function(example_mex_callback dlib)
cmake_minimum_required(VERSION 2.8.4)
PROJECT(mex_functions)
include(cmake_mex_wrapper)
include(../cmake)
# Compile the example_mex_function.cpp file and link it to dlib. Note
# that you can give a list of things to link to here. E.g.
# add_mex_function(some_other_mex_function pthread dlib fftw)
add_mex_function(example_mex_function dlib)
add_mex_function(example_mex_callback dlib)
dlib/matlab/README.txt
View file @ ad6c87b0
This folder contains a set of tools which make it easy to create MATLAB mex
functions. To understand how they work, you should read the
example_mex_function.cpp and example_mex_callback.cpp examples.
To compile them, you can use CMake. In particular, from this folder execute
these commands:
mkdir build
cd build
cmake ..
cmake --build . --config release --target install
That should build the mex files on any platform.
Note that on windows you will probably need to tell CMake to use a 64bit
version of visual studio. You can do this by using a command like:
cmake -G "Visual Studio 10 Win64" ..
instead of
cmake ..
This folder contains a set of tools which make it easy to create MATLAB mex
functions. To understand how they work, you should read the
example_mex_function.cpp and example_mex_callback.cpp examples.
To compile them, you can use CMake. In particular, from this folder execute
these commands:
mkdir build
cd build
cmake ..
cmake --build . --config release --target install
That should build the mex files on any platform.
Note that on windows you will probably need to tell CMake to use a 64bit
version of visual studio. You can do this by using a command like:
cmake -G "Visual Studio 10 Win64" ..
instead of
cmake ..
dlib/matlab/call_matlab.h
View file @ ad6c87b0
// Copyright (C) 2012 Massachusetts Institute of Technology, Lincoln Laboratory
// License: Boost Software License See LICENSE.txt for the full license.
// Authors: Davis E. King (davis@dlib.net)
#ifndef MIT_LL_CALL_MATLAB_H__
#define MIT_LL_CALL_MATLAB_H__
#include <string>
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <typename T>
struct output_decorator
{
output_decorator(T& item_):item(item_){}
T& item;
};
template <typename T>
output_decorator<T> returns(T& item) { return output_decorator<T>(item); }
/*!
ensures
- decorates item as an output type. This stuff is used by the call_matlab()
functions to tell if an argument is an input to the function or is supposed
to be bound to one of the return arguments.
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
struct function_handle
{
/*!
WHAT THIS OBJECT REPRESENTS
This type is used to represent function handles passed from MATLAB into a
mex function. You can call the function referenced by the handle by
saying:
call_matlab(my_handle);
!*/
// These two lines are just implementation details, ignore them.
function_handle():h(0){}
void* const h;
};
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const std::string& function_name
);
/*!
ensures
- Calls MATLAB's function of the given name
!*/
// ----------------------------------------------------------------------------------------
void call_matlab (
const function_handle& funct
);
/*!
ensures
- Calls MATLAB's function represented by the handle funct
!*/
// ----------------------------------------------------------------------------------------
template <
typename T1
>
void call_matlab (
const std::string& function_name,
const T1& A1
);
/*!
ensures
- calls MATLAB's function of the given name.
- if (A1 is not decorated as an output by returns()) then
- A1 is passed as an argument into the MATLAB function
- else
- A1 is treated as the first return value from the MATLAB function.
!*/
template <
typename T1
>
void call_matlab (
const function_handle& funct,
const T1& A1
) { call_matlab("feval", funct, A1); }
/*!
ensures
- Calls MATLAB's function represented by the handle funct
- if (A1 is not decorated as an output by returns()) then
- A1 is passed as an argument into the MATLAB function
- else
- A1 is treated as the first return value from the MATLAB function.
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
/*
The rest of this file is just overloads of call_matlab() for up to 10 arguments (or
just 9 arguments if function_handle is used). They all do the same thing as the above
version of call_matlab(). Generally, any argument not decorated by returns() is an
input to the MATLAB function. On the other hand, all arguments decorated by returns()
are treated as outputs.
*/
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9,
typename T10
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9,
const T10& A10
);
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2
)
{
call_matlab("feval", funct, A1, A2);
}
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3
)
{
call_matlab("feval", funct, A1, A2, A3);
}
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
)
{
call_matlab("feval", funct, A1, A2, A3, A4);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7, A8);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7, A8, A9);
}
// ----------------------------------------------------------------------------------------
#endif // MIT_LL_CALL_MATLAB_H__
// Copyright (C) 2012 Massachusetts Institute of Technology, Lincoln Laboratory
// License: Boost Software License See LICENSE.txt for the full license.
// Authors: Davis E. King (davis@dlib.net)
#ifndef MIT_LL_CALL_MATLAB_H__
#define MIT_LL_CALL_MATLAB_H__
#include <string>
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <typename T>
struct output_decorator
{
output_decorator(T& item_):item(item_){}
T& item;
};
template <typename T>
output_decorator<T> returns(T& item) { return output_decorator<T>(item); }
/*!
ensures
- decorates item as an output type. This stuff is used by the call_matlab()
functions to tell if an argument is an input to the function or is supposed
to be bound to one of the return arguments.
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
struct function_handle
{
/*!
WHAT THIS OBJECT REPRESENTS
This type is used to represent function handles passed from MATLAB into a
mex function. You can call the function referenced by the handle by
saying:
call_matlab(my_handle);
!*/
// These two lines are just implementation details, ignore them.
function_handle():h(0){}
void* const h;
};
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const std::string& function_name
);
/*!
ensures
- Calls MATLAB's function of the given name
!*/
// ----------------------------------------------------------------------------------------
void call_matlab (
const function_handle& funct
);
/*!
ensures
- Calls MATLAB's function represented by the handle funct
!*/
// ----------------------------------------------------------------------------------------
template <
typename T1
>
void call_matlab (
const std::string& function_name,
const T1& A1
);
/*!
ensures
- calls MATLAB's function of the given name.
- if (A1 is not decorated as an output by returns()) then
- A1 is passed as an argument into the MATLAB function
- else
- A1 is treated as the first return value from the MATLAB function.
!*/
template <
typename T1
>
void call_matlab (
const function_handle& funct,
const T1& A1
) { call_matlab("feval", funct, A1); }
/*!
ensures
- Calls MATLAB's function represented by the handle funct
- if (A1 is not decorated as an output by returns()) then
- A1 is passed as an argument into the MATLAB function
- else
- A1 is treated as the first return value from the MATLAB function.
!*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
/*
The rest of this file is just overloads of call_matlab() for up to 10 arguments (or
just 9 arguments if function_handle is used). They all do the same thing as the above
version of call_matlab(). Generally, any argument not decorated by returns() is an
input to the MATLAB function. On the other hand, all arguments decorated by returns()
are treated as outputs.
*/
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
);
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9,
typename T10
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9,
const T10& A10
);
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <
typename T1,
typename T2
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2
)
{
call_matlab("feval", funct, A1, A2);
}
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3
)
{
call_matlab("feval", funct, A1, A2, A3);
}
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
)
{
call_matlab("feval", funct, A1, A2, A3, A4);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7, A8);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const function_handle& funct,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
)
{
call_matlab("feval", funct, A1, A2, A3, A4, A5, A6, A7, A8, A9);
}
// ----------------------------------------------------------------------------------------
#endif // MIT_LL_CALL_MATLAB_H__
dlib/matlab/cmake_mex_wrapper
View file @ ad6c87b0
# This file figured out where MATLAB is and then defines a macro, add_mex_function(name)
# which when called instructs CMake to build a mex file from a file called name.cpp. Note
# that additional library dependencies can be added like this: add_mex_function(name lib1 dlib libetc).
# That is, just add more libraries after the name and they will be build into the mex file.
cmake_minimum_required(VERSION 2.8.4)
# Find MATLAB's include directory and needed libraries
find_program(MATLAB_EXECUTABLE matlab PATHS
"C:/Program Files/MATLAB/*/bin"
"C:/Program Files (x86)/MATLAB/*/bin"
)
# Resolve symbolic links to try and get the real path to the MATLAB executable
get_filename_component(MATLAB_EXECUTABLE ${MATLAB_EXECUTABLE} REALPATH)
# Now get MATLAB root directory
get_filename_component(MATLAB_HOME ${MATLAB_EXECUTABLE} PATH)
get_filename_component(MATLAB_HOME ${MATLAB_HOME} PATH)
set(MATLAB_LIB_FOLDERS
"${MATLAB_HOME}/extern/lib/win64/microsoft"
"${MATLAB_HOME}/bin/glnxa64"
)
# Find the MATLAB libraries that need to get linked into the mex file
if (WIN32)
find_library(MATLAB_MEX_LIBRARY libmex PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_MX_LIBRARY libmx PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_ENG_LIBRARY libeng PATHS ${MATLAB_LIB_FOLDERS} )
else()
find_library(MATLAB_MEX_LIBRARY mex PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_MX_LIBRARY mx PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_ENG_LIBRARY eng PATHS ${MATLAB_LIB_FOLDERS} )
endif()
set(MATLAB_LIBRARIES ${MATLAB_MEX_LIBRARY} ${MATLAB_MX_LIBRARY} ${MATLAB_ENG_LIBRARY})
INCLUDE_DIRECTORIES("${MATLAB_HOME}/extern/include")
# Determine the path to cmake_mex_wrapper file so we can add it to the include search path..
string(REGEX REPLACE "cmake_mex_wrapper$" "" dlib_matlab_binding_path ${CMAKE_CURRENT_LIST_FILE})
INCLUDE_DIRECTORIES("${dlib_matlab_binding_path}")
# Determine the path to dlib so we can add it to the include search path.
string(REGEX REPLACE "cmake_mex_wrapper$" "" dlib_path ${CMAKE_CURRENT_LIST_FILE})
INCLUDE_DIRECTORIES(${dlib_path}/../..)
ADD_DEFINITIONS(-DMATLAB_MEX_FILE)
# Determine the path to our CMakeLists.txt file. This is the file that
# includeded the one you are reading right now. So here we make it so that
# when you run the install target it will copy the compiled mex files into the
# same folder as the parent CMakeLists.txt file.
string(REGEX REPLACE "CMakeLists.txt$" "" install_dir ${CMAKE_PARENT_LIST_FILE})
set(CMAKE_INSTALL_PREFIX "${install_dir}")
set(CMAKE_INSTALL_SYSTEM_RUNTIME_DESTINATION "${install_dir}")
INCLUDE(InstallRequiredSystemLibraries)
MACRO(add_mex_function name )
ADD_LIBRARY(${name} MODULE ${name}.cpp )
# Change the output file extension to a mex extension.
if (WIN32)
set_target_properties(${name} PROPERTIES SUFFIX ".mexw64")
elseif(APPLE)
set_target_properties(${name} PROPERTIES SUFFIX ".mexmaci64")
else()
set_target_properties(${name} PROPERTIES SUFFIX ".mexa64")
endif()
set_target_properties(${name} PROPERTIES PREFIX "")
TARGET_LINK_LIBRARIES(${name} ${MATLAB_LIBRARIES} ${ARGN})
install(TARGETS ${name} DESTINATION "${install_dir}")
ENDMACRO()
# This file figures out where MATLAB is and then defines a macro, add_mex_function(name)
# which when called instructs CMake to build a mex file from a file called name.cpp. Note
# that additional library dependencies can be added like this: add_mex_function(name lib1 dlib libetc).
# That is, just add more libraries after the name and they will be build into the mex file.
cmake_minimum_required(VERSION 2.8.4)
# Find MATLAB's include directory and needed libraries
find_program(MATLAB_EXECUTABLE matlab PATHS
"C:/Program Files/MATLAB/*/bin"
"C:/Program Files (x86)/MATLAB/*/bin"
)
# Resolve symbolic links to try and get the real path to the MATLAB executable
get_filename_component(MATLAB_EXECUTABLE ${MATLAB_EXECUTABLE} REALPATH)
# Now get MATLAB root directory
get_filename_component(MATLAB_HOME ${MATLAB_EXECUTABLE} PATH)
get_filename_component(MATLAB_HOME ${MATLAB_HOME} PATH)
set(MATLAB_LIB_FOLDERS
"${MATLAB_HOME}/extern/lib/win64/microsoft"
"${MATLAB_HOME}/bin/glnxa64"
)
# Find the MATLAB libraries that need to get linked into the mex file
if (WIN32)
find_library(MATLAB_MEX_LIBRARY libmex PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_MX_LIBRARY libmx PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_ENG_LIBRARY libeng PATHS ${MATLAB_LIB_FOLDERS} )
else()
find_library(MATLAB_MEX_LIBRARY mex PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_MX_LIBRARY mx PATHS ${MATLAB_LIB_FOLDERS} )
find_library(MATLAB_ENG_LIBRARY eng PATHS ${MATLAB_LIB_FOLDERS} )
endif()
set(MATLAB_LIBRARIES ${MATLAB_MEX_LIBRARY} ${MATLAB_MX_LIBRARY} ${MATLAB_ENG_LIBRARY})
INCLUDE_DIRECTORIES("${MATLAB_HOME}/extern/include")
# Determine the path to cmake_mex_wrapper file so we can add it to the include search path..
string(REGEX REPLACE "cmake_mex_wrapper$" "" dlib_matlab_binding_path ${CMAKE_CURRENT_LIST_FILE})
INCLUDE_DIRECTORIES("${dlib_matlab_binding_path}")
# Determine the path to dlib so we can add it to the include search path.
string(REGEX REPLACE "cmake_mex_wrapper$" "" dlib_path ${CMAKE_CURRENT_LIST_FILE})
INCLUDE_DIRECTORIES(${dlib_path}/../..)
ADD_DEFINITIONS(-DMATLAB_MEX_FILE)
# Determine the path to our CMakeLists.txt file. This is the file that
# includeded the one you are reading right now. So here we make it so that
# when you run the install target it will copy the compiled mex files into the
# same folder as the parent CMakeLists.txt file.
string(REGEX REPLACE "CMakeLists.txt$" "" install_dir ${CMAKE_PARENT_LIST_FILE})
set(CMAKE_INSTALL_PREFIX "${install_dir}")
set(CMAKE_INSTALL_SYSTEM_RUNTIME_DESTINATION "${install_dir}")
INCLUDE(InstallRequiredSystemLibraries)
MACRO(add_mex_function name )
ADD_LIBRARY(${name} MODULE ${name}.cpp )
# Change the output file extension to a mex extension.
if (WIN32)
set_target_properties(${name} PROPERTIES SUFFIX ".mexw64")
elseif(APPLE)
set_target_properties(${name} PROPERTIES SUFFIX ".mexmaci64")
else()
set_target_properties(${name} PROPERTIES SUFFIX ".mexa64")
endif()
set_target_properties(${name} PROPERTIES PREFIX "")
TARGET_LINK_LIBRARIES(${name} ${MATLAB_LIBRARIES} ${ARGN})
install(TARGETS ${name} DESTINATION "${install_dir}")
ENDMACRO()
dlib/matlab/example_mex_callback.cpp
View file @ ad6c87b0
#include "call_matlab.h"
#include "dlib/matrix.h"
using namespace dlib;
using namespace std;
/*
This mex function takes a MATLAB function handle, calls it, and
returns the results.
For example, you can call this function in MATLAB like so:
A = magic(3)
y = example_mex_callback(A, @(x)x+x)
This will result in y containing the value 2*A.
*/
void mex_function (
const matrix<double>& A,
const function_handle& f,
matrix<double>& result
)
{
// The f argument to this function is a function handle passed from MATLAB. To
// call it we use the following syntax:
call_matlab(f, A, returns(result));
// This is equivalent to result = f(A). Therefore, the returns(variable) syntax
// is used to indicate which variables are outputs of the function.
// Another thing we can do is call MATLAB functions based on their string name
// rather than a function_handle. Here is an example of calling eigs().
matrix<double> m(2,2);
m = 1,2,
3,4;
matrix<double> v,d;
// This is equivalent to [v,d] = eigs(m);
call_matlab("eigs", m, returns(v), returns(d));
cout << "eigenvectors: \n" << v << endl;
cout << "eigenvalues: \n" << d << endl;
}
// #including this brings in all the mex boiler plate needed by MATLAB.
#include "mex_wrapper.cpp"
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
#include "call_matlab.h"
#include "dlib/matrix.h"
using namespace dlib;
using namespace std;
/*
This mex function takes a MATLAB function handle, calls it, and
returns the results.
For example, you can call this function in MATLAB like so:
A = magic(3)
y = example_mex_callback(A, @(x)x+x)
This will result in y containing the value 2*A.
*/
void mex_function (
const matrix<double>& A,
const function_handle& f,
matrix<double>& result
)
{
// The f argument to this function is a function handle passed from MATLAB. To
// call it we use the following syntax:
call_matlab(f, A, returns(result));
// This is equivalent to result = f(A). Therefore, the returns(variable) syntax
// is used to indicate which variables are outputs of the function.
// Another thing we can do is call MATLAB functions based on their string name
// rather than a function_handle. Here is an example of calling eigs().
matrix<double> m(2,2);
m = 1,2,
3,4;
matrix<double> v,d;
// This is equivalent to [v,d] = eigs(m);
call_matlab("eigs", m, returns(v), returns(d));
cout << "eigenvectors: \n" << v << endl;
cout << "eigenvalues: \n" << d << endl;
}
// #including this brings in all the mex boiler plate needed by MATLAB.
#include "mex_wrapper.cpp"
dlib/matlab/example_mex_function.cpp
View file @ ad6c87b0
#include "dlib/matrix.h"
using namespace dlib;
using namespace std;
/*!
This file defines a function callable from MATLAB once you mex it.
It computes the same thing as the following MATLAB function:
function [A, B] = example_mex_function(x, y, some_number)
A = x+y;
B = sum(sum(x+y));
disp(['some_number: ' num2str(some_number)])
end
VALID INPUT AND OUTPUT ARGUMENTS
The mex wrapper can handle the following kinds of input and output arguments:
- Types corresponding to a MATLAB matrix
- a dlib::matrix containing any kind of scalar value.
- a dlib::array2d containing any kind of scalar value.
- a dlib::vector containing any kind of scalar value.
- a dlib::point
- RGB color images
- dlib::array2d<dlib::rgb_pixel> can be used to represent
MATLAB uint8 MxNx3 images.
- Types corresponding to a MATLAB scalar
- any kind of scalar value, e.g. double, int, etc.
- Types corresponding to a MATLAB string
- std::string
- Types corresponding to a MATLAB cell array
- a std::vector or dlib::array containing any of the above
types of objects or std::vector or dlib::array objects.
!*/
// You can also define default values for your input arguments. So
// here we say that if the user in MATLAB doesn't provide the "some_number"
// then it will get a value of 3.141.
#define ARG_5_DEFAULT 3.141
// Make a function named mex_function() and put your code inside it.
// Note that the return type should be void. Use non-const reference
// arguments to return outputs. Finally, mex_function() must have no
// more than 10 arguments.
void mex_function (
const matrix<double>& x,
const matrix<double>& y,
matrix<double>& out1,
double& out2,
double some_number
)
{
out1 = x + y;
out2 = sum(x+y);
// we can also use cout to print things as usual:
cout << "some_number: "<< some_number << endl;
}
// #including this brings in all the mex boiler plate needed by MATLAB.
#include "mex_wrapper.cpp"
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
#include "dlib/matrix.h"
using namespace dlib;
using namespace std;
/*!
This file defines a function callable from MATLAB once you mex it.
It computes the same thing as the following MATLAB function:
function [A, B] = example_mex_function(x, y, some_number)
A = x+y;
B = sum(sum(x+y));
disp(['some_number: ' num2str(some_number)])
end
VALID INPUT AND OUTPUT ARGUMENTS
The mex wrapper can handle the following kinds of input and output arguments:
- Types corresponding to a MATLAB matrix
- a dlib::matrix containing any kind of scalar value.
- a dlib::array2d containing any kind of scalar value.
- a dlib::vector containing any kind of scalar value.
- a dlib::point
- RGB color images
- dlib::array2d<dlib::rgb_pixel> can be used to represent
MATLAB uint8 MxNx3 images.
- Types corresponding to a MATLAB scalar
- any kind of scalar value, e.g. double, int, etc.
- Types corresponding to a MATLAB string
- std::string
- Types corresponding to a MATLAB cell array
- a std::vector or dlib::array containing any of the above
types of objects or std::vector or dlib::array objects.
!*/
// You can also define default values for your input arguments. So
// here we say that if the user in MATLAB doesn't provide the "some_number"
// then it will get a value of 3.141.
#define ARG_5_DEFAULT 3.141
// Make a function named mex_function() and put your code inside it.
// Note that the return type should be void. Use non-const reference
// arguments to return outputs. Finally, mex_function() must have no
// more than 10 arguments.
void mex_function (
const matrix<double>& x,
const matrix<double>& y,
matrix<double>& out1,
double& out2,
double some_number
)
{
out1 = x + y;
out2 = sum(x+y);
// we can also use cout to print things as usual:
cout << "some_number: "<< some_number << endl;
}
// #including this brings in all the mex boiler plate needed by MATLAB.
#include "mex_wrapper.cpp"
dlib/matlab/mex_wrapper.cpp
View file @ ad6c87b0
/*
READ THIS FIRST
######
######
######
######
######
######
######
######
######
######
######
######
######
\############/
\##########/
\########/
\######/
\####/
\##/
\/
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
See example_mex_function.cpp for a discussion of how to use the mex wrapper.
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
/\
/##\
/####\
/######\
/########\
/##########\
/############\
######
######
######
######
######
######
######
######
######
######
######
######
######
READ THIS FIRST
*/
// Copyright (C) 2012 Massachusetts Institute of Technology, Lincoln Laboratory
// License: Boost Software License See LICENSE.txt for the full license.
// Authors: Davis E. King (davis@dlib.net)
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// BEGIN IMPLEMENTATION DETAILS
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
#include "../matrix.h"
#include "../array2d.h"
#include "../array.h"
#include "../image_transforms.h"
#include "../is_kind.h"
#include "../any.h" // for sig_traits
#if defined(_MSC_VER)
#define DLL_EXPORT_SYM __declspec(dllexport)
#endif
#include "mex.h"
#include <sstream>
#include "call_matlab.h"
// ----------------------------------------------------------------------------------------
#ifdef ARG_1_DEFAULT
#define ELSE_ASSIGN_ARG_1 else A1 = ARG_1_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_1
#endif
#ifdef ARG_2_DEFAULT
#define ELSE_ASSIGN_ARG_2 else A2 = ARG_2_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_2
#endif
#ifdef ARG_3_DEFAULT
#define ELSE_ASSIGN_ARG_3 else A3 = ARG_3_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_3
#endif
#ifdef ARG_4_DEFAULT
#define ELSE_ASSIGN_ARG_4 else A4 = ARG_4_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_4
#endif
#ifdef ARG_5_DEFAULT
#define ELSE_ASSIGN_ARG_5 else A5 = ARG_5_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_5
#endif
#ifdef ARG_6_DEFAULT
#define ELSE_ASSIGN_ARG_6 else A6 = ARG_6_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_6
#endif
#ifdef ARG_7_DEFAULT
#define ELSE_ASSIGN_ARG_7 else A7 = ARG_7_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_7
#endif
#ifdef ARG_8_DEFAULT
#define ELSE_ASSIGN_ARG_8 else A8 = ARG_8_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_8
#endif
#ifdef ARG_9_DEFAULT
#define ELSE_ASSIGN_ARG_9 else A9 = ARG_9_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_9
#endif
#ifdef ARG_10_DEFAULT
#define ELSE_ASSIGN_ARG_10 else A10 = ARG_10_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_10
#endif
// ----------------------------------------------------------------------------------------
namespace mex_binding
{
using namespace dlib;
template <typename T>
struct is_input_type
{
const static unsigned long value = (!is_same_type<void,T>::value && (!is_reference_type<T>::value || is_const_type<T>::value )) ? 1 : 0;
};
template <typename T>
struct is_output_type
{
const static unsigned long value = (!is_same_type<void,T>::value && is_reference_type<T>::value && !is_const_type<T>::value) ? 1 : 0;
};
template <typename funct>
struct funct_traits
{
const static unsigned long num_inputs = is_input_type<typename sig_traits<funct>::arg1_type>::value +
is_input_type<typename sig_traits<funct>::arg2_type>::value +
is_input_type<typename sig_traits<funct>::arg3_type>::value +
is_input_type<typename sig_traits<funct>::arg4_type>::value +
is_input_type<typename sig_traits<funct>::arg5_type>::value +
is_input_type<typename sig_traits<funct>::arg6_type>::value +
is_input_type<typename sig_traits<funct>::arg7_type>::value +
is_input_type<typename sig_traits<funct>::arg8_type>::value +
is_input_type<typename sig_traits<funct>::arg9_type>::value +
is_input_type<typename sig_traits<funct>::arg10_type>::value;
const static unsigned long num_outputs= is_output_type<typename sig_traits<funct>::arg1_type>::value +
is_output_type<typename sig_traits<funct>::arg2_type>::value +
is_output_type<typename sig_traits<funct>::arg3_type>::value +
is_output_type<typename sig_traits<funct>::arg4_type>::value +
is_output_type<typename sig_traits<funct>::arg5_type>::value +
is_output_type<typename sig_traits<funct>::arg6_type>::value +
is_output_type<typename sig_traits<funct>::arg7_type>::value +
is_output_type<typename sig_traits<funct>::arg8_type>::value +
is_output_type<typename sig_traits<funct>::arg9_type>::value +
is_output_type<typename sig_traits<funct>::arg10_type>::value;
};
// ----------------------------------------------------------------------------------------
template <typename T>
struct is_array_type
{
// true if T is std::vector or dlib::array
const static bool value = is_std_vector<T>::value || dlib::is_array<T>::value;
};
// ----------------------------------------------------------------------------------------
template <
typename T,
typename enabled = void
>
struct inner_type
{
typedef T type;
};
template < typename T>
struct inner_type<T, typename dlib::enable_if_c<is_matrix<T>::value || is_array2d<T>::value || dlib::is_array<T>::value >::type>
{
typedef typename T::type type;
};
template < typename T>
struct inner_type<T, typename dlib::enable_if<is_std_vector<T> >::type>
{
typedef typename T::value_type type;
};
// -------------------------------------------------------
struct invalid_args_exception
{
invalid_args_exception(const std::string& msg_): msg(msg_) {}
std::string msg;
};
// -------------------------------------------------------
template <
typename matrix_type,
typename EXP
>
typename dlib::enable_if_c<is_matrix<matrix_type>::value && is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& m,
const matrix_exp<EXP>& src
)
{
if (matrix_type::NR != 0 && matrix_type::NR != src.nc())
{
std::ostringstream sout;
sout << "Argument " << arg_idx+1 << " expects a matrix with " << matrix_type::NR << " rows but got one with " << src.nc();
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
if (matrix_type::NC != 0 && matrix_type::NC != src.nr())
{
std::ostringstream sout;
sout << "Argument " << arg_idx+1 << " expects a matrix with " << matrix_type::NC << " columns but got one with " << src.nr();
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
m = trans(src);
}
template <
typename matrix_type,
typename EXP
>
typename dlib::enable_if_c<is_array2d<matrix_type>::value && is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& m,
const matrix_exp<EXP>& src
)
{
assign_image(m , trans(src));
}
template <
typename matrix_type,
typename EXP
>
typename disable_if_c<(is_array2d<matrix_type>::value || is_matrix<matrix_type>::value) &&
is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& ,
const matrix_exp<EXP>&
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <
typename T,
typename U
>
typename dlib::enable_if_c<is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value >::type
assign_scalar (
const long arg_idx,
T& dest,
const U& src
)
{
if (is_signed_type<U>::value && src < 0 && is_unsigned_type<T>::value)
{
std::ostringstream sout;
sout << "Error, input argument " << arg_idx+1 << " must be a non-negative number.";
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
else
{
dest = src;
}
}
template <
typename T,
typename U
>
typename dlib::disable_if_c<is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value >::type
assign_scalar (
const long arg_idx,
T& ,
const U&
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
void assign_function_handle (
const long arg_idx,
function_handle& dest,
const mxArray* src
)
{
const_cast<void*&>(dest.h) = (void*)src;
}
template <
typename T
>
void assign_function_handle (
const long arg_idx,
T& ,
const mxArray*
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <
typename T
>
typename dlib::enable_if<is_array_type<T> >::type
assign_std_vector (
const long arg_idx,
T& dest,
const mxArray* src
)
{
const long nr = mxGetM(src);
const long nc = mxGetN(src);
typedef typename inner_type<T>::type type;
if (!mxIsCell(src))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a cell array";
throw invalid_args_exception(sout.str());
}
if (nr != 1 && nc != 1)
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a cell array with exactly 1 row or 1 column (i.e. a row or column vector)";
throw invalid_args_exception(sout.str());
}
const long size = nr*nc;
dest.resize(size);
for (unsigned long i = 0; i < dest.size(); ++i)
{
try
{
validate_and_populate_arg(i, mxGetCell(src, i), dest[i]);
}
catch (invalid_args_exception& e)
{
std::ostringstream sout;
sout << "Error in argument " << arg_idx+1 << ": element " << i+1 << " of cell array not the expected type.\n";
sout << "\t" << e.msg;
throw invalid_args_exception(sout.str());
}
}
}
template <
typename T
>
typename disable_if<is_array_type<T> >::type
assign_std_vector (
const long arg_idx,
T& ,
const mxArray*
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <typename T>
void assign_image (
const long arg_idx,
T&,
const dlib::uint8* data,
long nr,
long nc
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
template <typename MM>
void assign_image(
const long ,
array2d<dlib::rgb_pixel,MM>& img,
const dlib::uint8* data,
long nr,
long nc
)
{
img.set_size(nr, nc);
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].red = *data++;
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].green = *data++;
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].blue = *data++;
}
// -------------------------------------------------------
template <typename T>
void validate_and_populate_arg (
long arg_idx,
const mxArray *prhs,
T& arg
)
{
using namespace mex_binding;
if (is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value)
{
if( !(mxIsDouble(prhs) || mxIsSingle(prhs) || mxIsLogical(prhs) ) ||
mxIsComplex(prhs) ||
mxGetNumberOfElements(prhs)!=1 )
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a scalar";
throw invalid_args_exception(sout.str());
}
assign_scalar(arg_idx, arg , mxGetScalar(prhs));
}
else if (is_matrix<T>::value || is_array2d<T>::value)
{
typedef typename inner_type<T>::type type;
const int num_dims = mxGetNumberOfDimensions(prhs);
const long nr = mxGetM(prhs);
const long nc = mxGetN(prhs);
if (is_same_type<type,dlib::rgb_pixel>::value)
{
if (!(num_dims == 3 && mxGetDimensions(prhs)[2] == 3 && mxIsUint8(prhs)))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a 3-D NxMx3 image matrix of uint8";
throw invalid_args_exception(sout.str());
}
const long rows = mxGetDimensions(prhs)[0];
const long cols = mxGetDimensions(prhs)[1];
assign_image(arg_idx, arg , (const dlib::uint8*)mxGetData(prhs), rows, cols);
return;
}
if (num_dims != 2)
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a 2-D matrix (got a " << num_dims << "-D matrix)";
throw invalid_args_exception(sout.str());
}
if (is_same_type<type,double>::value)
{
if (!mxIsDouble(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of doubles";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix(mxGetPr(prhs), nc, nr));
}
else if (is_same_type<type, float>::value)
{
if (!mxIsSingle(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of single/float";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const float*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, bool>::value)
{
if (!mxIsLogical(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of logical elements.";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const bool*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint8>::value)
{
if (!mxIsUint8(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint8";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const dlib::uint8*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int8>::value)
{
if (!mxIsInt8(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int8";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const dlib::int8*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int16>::value ||
(is_same_type<type, short>::value && sizeof(short) == sizeof(dlib::int16)))
{
if (!mxIsInt16(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int16";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint16>::value ||
(is_same_type<type, unsigned short>::value && sizeof(unsigned short) == sizeof(dlib::uint16)))
{
if (!mxIsUint16(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint16";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int32>::value ||
(is_same_type<type, int>::value && sizeof(int) == sizeof(dlib::int32)) ||
(is_same_type<type, long>::value && sizeof(long) == sizeof(dlib::int32)))
{
if (!mxIsInt32(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int32";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint32>::value ||
(is_same_type<type, unsigned int>::value && sizeof(unsigned int) == sizeof(dlib::uint32)) ||
(is_same_type<type, unsigned long>::value && sizeof(unsigned long) == sizeof(dlib::uint32)))
{
if (!mxIsUint32(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint32";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint64>::value ||
(is_same_type<type, unsigned int>::value && sizeof(unsigned int) == sizeof(dlib::uint64)) ||
(is_same_type<type, unsigned long>::value && sizeof(unsigned long) == sizeof(dlib::uint64)))
{
if (!mxIsUint64(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint64";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int64>::value ||
(is_same_type<type, int>::value && sizeof(int) == sizeof(dlib::int64)) ||
(is_same_type<type, long>::value && sizeof(long) == sizeof(dlib::int64)))
{
if (!mxIsInt64(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int64";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported matrix type");
}
}
else if (is_array_type<T>::value)
{
assign_std_vector(arg_idx, arg, prhs);
}
else if (is_same_type<T,function_handle>::value)
{
if (!mxIsClass(prhs, "function_handle"))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a function handle.";
throw invalid_args_exception(sout.str());
}
assign_function_handle(arg_idx, arg, prhs);
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported input argument type");
}
}
void validate_and_populate_arg(
long arg_idx,
const mxArray *prhs,
std::string& arg
)
{
if (!mxIsChar(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a char string";
throw invalid_args_exception(sout.str());
}
const long nr = mxGetM(prhs);
const long nc = mxGetN(prhs);
const long size = nr*nc;
arg.resize(size+1);
if (mxGetString(prhs, &arg[0], arg.size()))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " encountered an error while calling mxGetString()";
throw invalid_args_exception(sout.str());
}
arg.resize(size);
}
// ----------------------------------------------------------------------------------------
template <typename EXP>
typename dlib::enable_if<is_same_type<dlib::rgb_pixel,typename EXP::type> >::type assign_image_to_matlab (
dlib::uint8* mat,
const matrix_exp<EXP>& item
)
{
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).red;
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).green;
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).blue;
}
template <typename T, typename EXP>
typename disable_if<is_same_type<dlib::rgb_pixel,typename EXP::type> >::type assign_image_to_matlab (
T* mat,
const matrix_exp<EXP>&
)
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported output image argument type");
}
template <typename T>
typename dlib::enable_if<is_matrix<T> >::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
typedef typename T::type type;
type* mat = 0;
if (is_same_type<double, type>::value)
{
plhs = mxCreateDoubleMatrix(item.nr(),
item.nc(),
mxREAL);
mat = (type*)mxGetPr(plhs);
}
else if (is_same_type<float, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxSINGLE_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<bool, type>::value )
{
plhs = mxCreateLogicalMatrix(item.nr(),
item.nc());
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint8, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT8_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int8, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT8_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int16, type>::value ||
(is_same_type<short,type>::value && sizeof(short) == sizeof(dlib::int16)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT16_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint16, type>::value ||
(is_same_type<unsigned short,type>::value && sizeof(unsigned short) == sizeof(dlib::uint16)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT16_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int32, type>::value ||
(is_same_type<long,type>::value && sizeof(long) == sizeof(dlib::int32)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT32_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint32, type>::value ||
(is_same_type<unsigned long,type>::value && sizeof(unsigned long) == sizeof(dlib::uint32)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT32_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint64, type>::value ||
(is_same_type<unsigned long,type>::value && sizeof(unsigned long) == sizeof(dlib::uint64)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT64_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int64, type>::value ||
(is_same_type<long,type>::value && sizeof(long) == sizeof(dlib::int64)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT64_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::rgb_pixel, type>::value)
{
mwSize dims[3] = {item.nr(), item.nc(), 3};
plhs = mxCreateNumericArray(3, dims, mxUINT8_CLASS, mxREAL);
assign_image_to_matlab((dlib::uint8*)mxGetData(plhs), item);
return;
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported output argument type");
}
for (long c = 0; c < item.nc(); ++c)
{
for ( long r= 0; r < item.nr(); ++r)
{
*mat++ = item(r,c);
}
}
}
void assign_to_matlab(
mxArray*& plhs,
const std::string& item
)
{
plhs = mxCreateString(item.c_str());
}
template <typename T, typename MM>
void assign_to_matlab(
mxArray*& plhs,
const array2d<T,MM>& item
)
{
assign_to_matlab(plhs,array_to_matrix(item));
}
template <typename T>
typename dlib::enable_if<is_array_type<T> >::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
mwSize dims[1] = {item.size()};
plhs = mxCreateCellArray(1,dims);
for (unsigned long i = 0; i < item.size(); ++i)
{
mxArray* next = 0;
assign_to_matlab(next, item[i]);
mxSetCell(plhs, i, next);
}
}
template <typename T>
typename dlib::disable_if_c<is_matrix<T>::value || is_array_type<T>::value ||
is_same_type<T,function_handle>::value>::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
plhs = mxCreateDoubleScalar(item);
}
void assign_to_matlab (
mxArray*& plhs,
const char* str
)
{
assign_to_matlab(plhs, std::string(str));
}
void assign_to_matlab(
mxArray*& plhs,
const function_handle& h
)
{
}
// ----------------------------------------------------------------------------------------
template <
unsigned long num_args
>
struct call_mex_function_helper;
template <>
struct call_mex_function_helper<1>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typename basic_type<arg1_type>::type A1;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
mex_function(A1);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
}
};
template <>
struct call_mex_function_helper<2>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
mex_function(A1,A2);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
}
};
template <>
struct call_mex_function_helper<3>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
mex_function(A1,A2,A3);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
}
};
template <>
struct call_mex_function_helper<4>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
mex_function(A1,A2,A3,A4);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
}
};
template <>
struct call_mex_function_helper<5>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
mex_function(A1,A2,A3,A4,A5);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
}
};
template <>
struct call_mex_function_helper<6>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
mex_function(A1,A2,A3,A4,A5,A6);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
}
};
template <>
struct call_mex_function_helper<7>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
mex_function(A1,A2,A3,A4,A5,A6,A7);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
}
};
template <>
struct call_mex_function_helper<8>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
}
};
template <>
struct call_mex_function_helper<9>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typedef typename sig_traits<funct>::arg9_type arg9_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
typename basic_type<arg9_type>::type A9;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
if (i < nrhs && is_input_type<arg9_type>::value) {validate_and_populate_arg(i,prhs[i],A9); ++i;} ELSE_ASSIGN_ARG_9;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8,A9);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
if (is_output_type<arg9_type>::value) {assign_to_matlab(plhs[i],A9); ++i;}
}
};
template <>
struct call_mex_function_helper<10>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typedef typename sig_traits<funct>::arg9_type arg9_type;
typedef typename sig_traits<funct>::arg10_type arg10_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
typename basic_type<arg9_type>::type A9;
typename basic_type<arg10_type>::type A10;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
if (i < nrhs && is_input_type<arg9_type>::value) {validate_and_populate_arg(i,prhs[i],A9); ++i;} ELSE_ASSIGN_ARG_9;
if (i < nrhs && is_input_type<arg10_type>::value) {validate_and_populate_arg(i,prhs[i],A10); ++i;} ELSE_ASSIGN_ARG_10;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8,A9,A10);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
if (is_output_type<arg9_type>::value) {assign_to_matlab(plhs[i],A9); ++i;}
if (is_output_type<arg10_type>::value) {assign_to_matlab(plhs[i],A10); ++i;}
}
};
// ----------------------------------------------------------------------------------------
template <
typename funct
>
void call_mex_function (
const funct& f,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
)
{
const long expected_nrhs = funct_traits<funct>::num_inputs;
const long expected_nlhs = funct_traits<funct>::num_outputs;
const long expected_args = expected_nrhs + expected_nlhs;
long defaulted_args = 0;
#ifdef ARG_1_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg1_type>::value);
#ifndef ARG_2_DEFAULT
// You can't define a default for argument 1 if you don't define one for argument 2 also.
COMPILE_TIME_ASSERT(expected_args < 2);
#endif
COMPILE_TIME_ASSERT(1 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_2_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg2_type>::value);
#ifndef ARG_3_DEFAULT
// You can't define a default for argument 2 if you don't define one for argument 3 also.
COMPILE_TIME_ASSERT(expected_args < 3);
#endif
COMPILE_TIME_ASSERT(2 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_3_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg3_type>::value);
#ifndef ARG_4_DEFAULT
// You can't define a default for argument 3 if you don't define one for argument 4 also.
COMPILE_TIME_ASSERT(expected_args < 4);
#endif
COMPILE_TIME_ASSERT(3 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_4_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg4_type>::value);
#ifndef ARG_5_DEFAULT
// You can't define a default for argument 4 if you don't define one for argument 5 also.
COMPILE_TIME_ASSERT(expected_args < 5);
#endif
COMPILE_TIME_ASSERT(4 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_5_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg5_type>::value);
#ifndef ARG_6_DEFAULT
// You can't define a default for argument 5 if you don't define one for argument 6 also.
COMPILE_TIME_ASSERT(expected_args < 6);
#endif
COMPILE_TIME_ASSERT(5 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_6_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg6_type>::value);
#ifndef ARG_7_DEFAULT
// You can't define a default for argument 6 if you don't define one for argument 7 also.
COMPILE_TIME_ASSERT(expected_args < 7);
#endif
COMPILE_TIME_ASSERT(6 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_7_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg7_type>::value);
#ifndef ARG_8_DEFAULT
// You can't define a default for argument 7 if you don't define one for argument 8 also.
COMPILE_TIME_ASSERT(expected_args < 8);
#endif
COMPILE_TIME_ASSERT(7 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_8_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg8_type>::value);
#ifndef ARG_9_DEFAULT
// You can't define a default for argument 8 if you don't define one for argument 9 also.
COMPILE_TIME_ASSERT(expected_args < 9);
#endif
COMPILE_TIME_ASSERT(8 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_9_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg9_type>::value);
#ifndef ARG_10_DEFAULT
// You can't define a default for argument 9 if you don't define one for argument 10 also.
COMPILE_TIME_ASSERT(expected_args < 10);
#endif
COMPILE_TIME_ASSERT(9 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_10_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg10_type>::value);
COMPILE_TIME_ASSERT(10 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
/* check for proper number of arguments */
if(nrhs > expected_nrhs || nrhs < expected_nrhs - defaulted_args)
{
std::ostringstream sout;
sout << "Expected between " << expected_nrhs-defaulted_args
<< " and " << expected_nrhs << " input arguments, got " << nrhs << ".";
mexErrMsgIdAndTxt("mex_function:nrhs",
sout.str().c_str());
}
if (nlhs > expected_nlhs)
{
std::ostringstream sout;
sout << "Expected at most " << expected_nlhs << " output arguments, got " << nlhs << ".";
mexErrMsgIdAndTxt("mex_function:nlhs",
sout.str().c_str());
}
try
{
call_mex_function_helper<sig_traits<funct>::num_args> helper;
helper.callit(f, nlhs, plhs, nrhs, prhs);
}
catch (invalid_args_exception& e)
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
("Input" + e.msg).c_str());
}
catch (dlib::error& e)
{
mexErrMsgIdAndTxt("mex_function:error",
e.what());
}
}
// ----------------------------------------------------------------------------------------
class mex_streambuf : public std::streambuf
{
public:
mex_streambuf (
)
{
buf.resize(1000);
setp(&buf[0], &buf[0] + buf.size()-2);
// make cout send data to mex_streambuf
std::cout.rdbuf(this);
}
protected:
int sync (
)
{
int num = static_cast<int>(pptr()-pbase());
if (num != 0)
{
buf[num] = 0; // null terminate the string
mexPrintf("%s",&buf[0]);
mexEvalString("drawnow"); // flush print to screen
pbump(-num);
}
return 0;
}
int_type overflow (
int_type c
)
{
if (c != EOF)
{
*pptr() = c;
pbump(1);
}
sync();
return c;
}
private:
std::vector<char> buf;
};
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <typename T>
void setup_input_args (
mxArray*& array,
const T& item,
int& nrhs
)
{
assign_to_matlab(array, item);
++nrhs;
}
void setup_input_args (
mxArray*& array,
const function_handle& item,
int& nrhs
)
{
array = static_cast<mxArray*>(item.h);
++nrhs;
}
template <typename T>
void setup_input_args (
mxArray*& array,
const output_decorator<T>& item,
int& nrhs
)
{
}
template <typename T>
void setup_output_args (
const std::string& function_name,
mxArray* array,
const T& item,
int& nrhs
)
{
}
template <typename T>
void setup_output_args (
const std::string& function_name,
mxArray* array,
const output_decorator<T>& item,
int& i
)
{
try
{
validate_and_populate_arg(i,array,const_cast<T&>(item.item));
++i;
}
catch (invalid_args_exception& e)
{
throw dlib::error("Error occurred calling MATLAB function '" + function_name + "' from mex file. \n"
"The MATLAB function didn't return what we expected it to. \nIn particular, return" + e.msg);
}
}
void call_matlab_for_real (
int nlhs,
mxArray* plhs[],
int nrhs,
mxArray* prhs[],
const std::string& function_name
)
{
int status = mexCallMATLAB(nlhs, plhs, nrhs, prhs, function_name.c_str());
if (status)
{
throw dlib::error("Error, an exception was thrown when we tried to call the MATLAB function '" + function_name + "'.");
}
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const std::string& function_name
)
{
using namespace mex_binding;
call_matlab_for_real(0,NULL,0,NULL, function_name);
}
template <typename T1>
void free_callback_resources (
int nlhs,
mxArray* plhs[],
int nrhs,
mxArray* prhs[]
)
{
// free resources
for (int i = 0; i < nlhs; ++i)
mxDestroyArray(plhs[i]);
for (int i = 0; i < nrhs; ++i)
{
// don't call mxDestroyArray() on function handles (which should only ever be in prhs[0])
if (i == 0 && dlib::is_same_type<T1,function_handle>::value)
continue;
mxDestroyArray(prhs[i]);
}
}
template <
typename T1
>
void call_matlab (
const std::string& function_name,
const T1& A1
)
{
using namespace mex_binding;
const int num_args = 1;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2
)
{
using namespace mex_binding;
const int num_args = 2;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3
)
{
using namespace mex_binding;
const int num_args = 3;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
)
{
using namespace mex_binding;
const int num_args = 4;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
)
{
using namespace mex_binding;
const int num_args = 5;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
)
{
using namespace mex_binding;
const int num_args = 6;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
)
{
using namespace mex_binding;
const int num_args = 7;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
)
{
using namespace mex_binding;
const int num_args = 8;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
)
{
using namespace mex_binding;
const int num_args = 9;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
setup_input_args(prhs[nrhs], A9, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
setup_output_args(function_name, plhs[i], A9, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9,
typename T10
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9,
const T10& A10
)
{
using namespace mex_binding;
const int num_args = 10;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
setup_input_args(prhs[nrhs], A10, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
setup_output_args(function_name, plhs[i], A10, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const function_handle& funct
)
{
call_matlab("feval", funct);
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
/* The gateway function called by MATLAB*/
void mexFunction( int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[])
{
// Only remap cout if we aren't using octave since octave already does this.
#if !defined(OCTAVE_IMPORT) && !defined(OCTAVE_API)
// make it so cout prints to mexPrintf()
static mex_binding::mex_streambuf sb;
#endif
mex_binding::call_mex_function(mex_function, nlhs, plhs, nrhs, prhs);
}
// ----------------------------------------------------------------------------------------
// Copyright (C) 2012 Massachusetts Institute of Technology, Lincoln Laboratory
// License: Boost Software License See LICENSE.txt for the full license.
// Authors: Davis E. King (davis@dlib.net)
/*
READ THIS FIRST
######
######
######
######
######
######
######
######
######
######
######
######
######
\############/
\##########/
\########/
\######/
\####/
\##/
\/
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
See example_mex_function.cpp for a discussion of how to use the mex wrapper.
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
/\
/##\
/####\
/######\
/########\
/##########\
/############\
######
######
######
######
######
######
######
######
######
######
######
######
######
READ THIS FIRST
*/
// Copyright (C) 2012 Massachusetts Institute of Technology, Lincoln Laboratory
// License: Boost Software License See LICENSE.txt for the full license.
// Authors: Davis E. King (davis@dlib.net)
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// BEGIN IMPLEMENTATION DETAILS
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
#include "../matrix.h"
#include "../array2d.h"
#include "../array.h"
#include "../image_transforms.h"
#include "../is_kind.h"
#include "../any.h" // for sig_traits
#if defined(_MSC_VER)
#define DLL_EXPORT_SYM __declspec(dllexport)
#endif
#include "mex.h"
#include <sstream>
#include "call_matlab.h"
// ----------------------------------------------------------------------------------------
#ifdef ARG_1_DEFAULT
#define ELSE_ASSIGN_ARG_1 else A1 = ARG_1_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_1
#endif
#ifdef ARG_2_DEFAULT
#define ELSE_ASSIGN_ARG_2 else A2 = ARG_2_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_2
#endif
#ifdef ARG_3_DEFAULT
#define ELSE_ASSIGN_ARG_3 else A3 = ARG_3_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_3
#endif
#ifdef ARG_4_DEFAULT
#define ELSE_ASSIGN_ARG_4 else A4 = ARG_4_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_4
#endif
#ifdef ARG_5_DEFAULT
#define ELSE_ASSIGN_ARG_5 else A5 = ARG_5_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_5
#endif
#ifdef ARG_6_DEFAULT
#define ELSE_ASSIGN_ARG_6 else A6 = ARG_6_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_6
#endif
#ifdef ARG_7_DEFAULT
#define ELSE_ASSIGN_ARG_7 else A7 = ARG_7_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_7
#endif
#ifdef ARG_8_DEFAULT
#define ELSE_ASSIGN_ARG_8 else A8 = ARG_8_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_8
#endif
#ifdef ARG_9_DEFAULT
#define ELSE_ASSIGN_ARG_9 else A9 = ARG_9_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_9
#endif
#ifdef ARG_10_DEFAULT
#define ELSE_ASSIGN_ARG_10 else A10 = ARG_10_DEFAULT;
#else
#define ELSE_ASSIGN_ARG_10
#endif
// ----------------------------------------------------------------------------------------
namespace mex_binding
{
using namespace dlib;
template <typename T>
struct is_input_type
{
const static unsigned long value = (!is_same_type<void,T>::value && (!is_reference_type<T>::value || is_const_type<T>::value )) ? 1 : 0;
};
template <typename T>
struct is_output_type
{
const static unsigned long value = (!is_same_type<void,T>::value && is_reference_type<T>::value && !is_const_type<T>::value) ? 1 : 0;
};
template <typename funct>
struct funct_traits
{
const static unsigned long num_inputs = is_input_type<typename sig_traits<funct>::arg1_type>::value +
is_input_type<typename sig_traits<funct>::arg2_type>::value +
is_input_type<typename sig_traits<funct>::arg3_type>::value +
is_input_type<typename sig_traits<funct>::arg4_type>::value +
is_input_type<typename sig_traits<funct>::arg5_type>::value +
is_input_type<typename sig_traits<funct>::arg6_type>::value +
is_input_type<typename sig_traits<funct>::arg7_type>::value +
is_input_type<typename sig_traits<funct>::arg8_type>::value +
is_input_type<typename sig_traits<funct>::arg9_type>::value +
is_input_type<typename sig_traits<funct>::arg10_type>::value;
const static unsigned long num_outputs= is_output_type<typename sig_traits<funct>::arg1_type>::value +
is_output_type<typename sig_traits<funct>::arg2_type>::value +
is_output_type<typename sig_traits<funct>::arg3_type>::value +
is_output_type<typename sig_traits<funct>::arg4_type>::value +
is_output_type<typename sig_traits<funct>::arg5_type>::value +
is_output_type<typename sig_traits<funct>::arg6_type>::value +
is_output_type<typename sig_traits<funct>::arg7_type>::value +
is_output_type<typename sig_traits<funct>::arg8_type>::value +
is_output_type<typename sig_traits<funct>::arg9_type>::value +
is_output_type<typename sig_traits<funct>::arg10_type>::value;
};
// ----------------------------------------------------------------------------------------
template <typename T>
struct is_array_type
{
// true if T is std::vector or dlib::array
const static bool value = is_std_vector<T>::value || dlib::is_array<T>::value;
};
// ----------------------------------------------------------------------------------------
template <
typename T,
typename enabled = void
>
struct inner_type
{
typedef T type;
};
template < typename T>
struct inner_type<T, typename dlib::enable_if_c<is_matrix<T>::value || is_array2d<T>::value || dlib::is_array<T>::value >::type>
{
typedef typename T::type type;
};
template < typename T>
struct inner_type<T, typename dlib::enable_if<is_std_vector<T> >::type>
{
typedef typename T::value_type type;
};
// -------------------------------------------------------
struct invalid_args_exception
{
invalid_args_exception(const std::string& msg_): msg(msg_) {}
std::string msg;
};
// -------------------------------------------------------
template <
typename matrix_type,
typename EXP
>
typename dlib::enable_if_c<is_matrix<matrix_type>::value && is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& m,
const matrix_exp<EXP>& src
)
{
if (matrix_type::NR != 0 && matrix_type::NR != src.nc())
{
std::ostringstream sout;
sout << "Argument " << arg_idx+1 << " expects a matrix with " << matrix_type::NR << " rows but got one with " << src.nc();
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
if (matrix_type::NC != 0 && matrix_type::NC != src.nr())
{
std::ostringstream sout;
sout << "Argument " << arg_idx+1 << " expects a matrix with " << matrix_type::NC << " columns but got one with " << src.nr();
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
m = trans(src);
}
template <
typename matrix_type,
typename EXP
>
typename dlib::enable_if_c<is_array2d<matrix_type>::value && is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& m,
const matrix_exp<EXP>& src
)
{
assign_image(m , trans(src));
}
template <
typename matrix_type,
typename EXP
>
typename disable_if_c<(is_array2d<matrix_type>::value || is_matrix<matrix_type>::value) &&
is_same_type<typename inner_type<matrix_type>::type,typename EXP::type>::value >::type
assign_mat (
const long arg_idx,
matrix_type& ,
const matrix_exp<EXP>&
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <
typename T,
typename U
>
typename dlib::enable_if_c<is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value >::type
assign_scalar (
const long arg_idx,
T& dest,
const U& src
)
{
if (is_signed_type<U>::value && src < 0 && is_unsigned_type<T>::value)
{
std::ostringstream sout;
sout << "Error, input argument " << arg_idx+1 << " must be a non-negative number.";
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
else
{
dest = src;
}
}
template <
typename T,
typename U
>
typename dlib::disable_if_c<is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value >::type
assign_scalar (
const long arg_idx,
T& ,
const U&
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
void assign_function_handle (
const long arg_idx,
function_handle& dest,
const mxArray* src
)
{
const_cast<void*&>(dest.h) = (void*)src;
}
template <
typename T
>
void assign_function_handle (
const long arg_idx,
T& ,
const mxArray*
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <
typename T
>
typename dlib::enable_if<is_array_type<T> >::type
assign_std_vector (
const long arg_idx,
T& dest,
const mxArray* src
)
{
const long nr = mxGetM(src);
const long nc = mxGetN(src);
typedef typename inner_type<T>::type type;
if (!mxIsCell(src))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a cell array";
throw invalid_args_exception(sout.str());
}
if (nr != 1 && nc != 1)
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a cell array with exactly 1 row or 1 column (i.e. a row or column vector)";
throw invalid_args_exception(sout.str());
}
const long size = nr*nc;
dest.resize(size);
for (unsigned long i = 0; i < dest.size(); ++i)
{
try
{
validate_and_populate_arg(i, mxGetCell(src, i), dest[i]);
}
catch (invalid_args_exception& e)
{
std::ostringstream sout;
sout << "Error in argument " << arg_idx+1 << ": element " << i+1 << " of cell array not the expected type.\n";
sout << "\t" << e.msg;
throw invalid_args_exception(sout.str());
}
}
}
template <
typename T
>
typename disable_if<is_array_type<T> >::type
assign_std_vector (
const long arg_idx,
T& ,
const mxArray*
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
// -------------------------------------------------------
template <typename T>
void assign_image (
const long arg_idx,
T&,
const dlib::uint8* data,
long nr,
long nc
)
{
std::ostringstream sout;
sout << "mex_function has some bug in it related to processing input argument " << arg_idx+1;
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
sout.str().c_str());
}
template <typename MM>
void assign_image(
const long ,
array2d<dlib::rgb_pixel,MM>& img,
const dlib::uint8* data,
long nr,
long nc
)
{
img.set_size(nr, nc);
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].red = *data++;
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].green = *data++;
for (long c = 0; c < img.nc(); ++c)
for (long r = 0; r < img.nr(); ++r)
img[r][c].blue = *data++;
}
// -------------------------------------------------------
template <typename T>
void validate_and_populate_arg (
long arg_idx,
const mxArray *prhs,
T& arg
)
{
using namespace mex_binding;
if (is_built_in_scalar_type<T>::value || is_same_type<T,bool>::value)
{
if( !(mxIsDouble(prhs) || mxIsSingle(prhs) || mxIsLogical(prhs) ) ||
mxIsComplex(prhs) ||
mxGetNumberOfElements(prhs)!=1 )
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a scalar";
throw invalid_args_exception(sout.str());
}
assign_scalar(arg_idx, arg , mxGetScalar(prhs));
}
else if (is_matrix<T>::value || is_array2d<T>::value)
{
typedef typename inner_type<T>::type type;
const int num_dims = mxGetNumberOfDimensions(prhs);
const long nr = mxGetM(prhs);
const long nc = mxGetN(prhs);
if (is_same_type<type,dlib::rgb_pixel>::value)
{
if (!(num_dims == 3 && mxGetDimensions(prhs)[2] == 3 && mxIsUint8(prhs)))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a 3-D NxMx3 image matrix of uint8";
throw invalid_args_exception(sout.str());
}
const long rows = mxGetDimensions(prhs)[0];
const long cols = mxGetDimensions(prhs)[1];
assign_image(arg_idx, arg , (const dlib::uint8*)mxGetData(prhs), rows, cols);
return;
}
if (num_dims != 2)
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a 2-D matrix (got a " << num_dims << "-D matrix)";
throw invalid_args_exception(sout.str());
}
if (is_same_type<type,double>::value)
{
if (!mxIsDouble(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of doubles";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix(mxGetPr(prhs), nc, nr));
}
else if (is_same_type<type, float>::value)
{
if (!mxIsSingle(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of single/float";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const float*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, bool>::value)
{
if (!mxIsLogical(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of logical elements.";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const bool*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint8>::value)
{
if (!mxIsUint8(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint8";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const dlib::uint8*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int8>::value)
{
if (!mxIsInt8(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int8";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const dlib::int8*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int16>::value ||
(is_same_type<type, short>::value && sizeof(short) == sizeof(dlib::int16)))
{
if (!mxIsInt16(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int16";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint16>::value ||
(is_same_type<type, unsigned short>::value && sizeof(unsigned short) == sizeof(dlib::uint16)))
{
if (!mxIsUint16(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint16";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int32>::value ||
(is_same_type<type, int>::value && sizeof(int) == sizeof(dlib::int32)) ||
(is_same_type<type, long>::value && sizeof(long) == sizeof(dlib::int32)))
{
if (!mxIsInt32(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int32";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint32>::value ||
(is_same_type<type, unsigned int>::value && sizeof(unsigned int) == sizeof(dlib::uint32)) ||
(is_same_type<type, unsigned long>::value && sizeof(unsigned long) == sizeof(dlib::uint32)))
{
if (!mxIsUint32(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint32";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::uint64>::value ||
(is_same_type<type, unsigned int>::value && sizeof(unsigned int) == sizeof(dlib::uint64)) ||
(is_same_type<type, unsigned long>::value && sizeof(unsigned long) == sizeof(dlib::uint64)))
{
if (!mxIsUint64(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of uint64";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else if (is_same_type<type, dlib::int64>::value ||
(is_same_type<type, int>::value && sizeof(int) == sizeof(dlib::int64)) ||
(is_same_type<type, long>::value && sizeof(long) == sizeof(dlib::int64)))
{
if (!mxIsInt64(prhs) || mxIsComplex(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a matrix of int64";
throw invalid_args_exception(sout.str());
}
assign_mat(arg_idx, arg , pointer_to_matrix((const type*)mxGetData(prhs), nc, nr));
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported matrix type");
}
}
else if (is_array_type<T>::value)
{
assign_std_vector(arg_idx, arg, prhs);
}
else if (is_same_type<T,function_handle>::value)
{
if (!mxIsClass(prhs, "function_handle"))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a function handle.";
throw invalid_args_exception(sout.str());
}
assign_function_handle(arg_idx, arg, prhs);
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported input argument type");
}
}
void validate_and_populate_arg(
long arg_idx,
const mxArray *prhs,
std::string& arg
)
{
if (!mxIsChar(prhs))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " must be a char string";
throw invalid_args_exception(sout.str());
}
const long nr = mxGetM(prhs);
const long nc = mxGetN(prhs);
const long size = nr*nc;
arg.resize(size+1);
if (mxGetString(prhs, &arg[0], arg.size()))
{
std::ostringstream sout;
sout << " argument " << arg_idx+1 << " encountered an error while calling mxGetString()";
throw invalid_args_exception(sout.str());
}
arg.resize(size);
}
// ----------------------------------------------------------------------------------------
template <typename EXP>
typename dlib::enable_if<is_same_type<dlib::rgb_pixel,typename EXP::type> >::type assign_image_to_matlab (
dlib::uint8* mat,
const matrix_exp<EXP>& item
)
{
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).red;
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).green;
for (long c = 0; c < item.nc(); ++c)
for (long r = 0; r < item.nr(); ++r)
*mat++ = item(r,c).blue;
}
template <typename T, typename EXP>
typename disable_if<is_same_type<dlib::rgb_pixel,typename EXP::type> >::type assign_image_to_matlab (
T* mat,
const matrix_exp<EXP>&
)
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported output image argument type");
}
template <typename T>
typename dlib::enable_if<is_matrix<T> >::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
typedef typename T::type type;
type* mat = 0;
if (is_same_type<double, type>::value)
{
plhs = mxCreateDoubleMatrix(item.nr(),
item.nc(),
mxREAL);
mat = (type*)mxGetPr(plhs);
}
else if (is_same_type<float, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxSINGLE_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<bool, type>::value )
{
plhs = mxCreateLogicalMatrix(item.nr(),
item.nc());
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint8, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT8_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int8, type>::value )
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT8_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int16, type>::value ||
(is_same_type<short,type>::value && sizeof(short) == sizeof(dlib::int16)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT16_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint16, type>::value ||
(is_same_type<unsigned short,type>::value && sizeof(unsigned short) == sizeof(dlib::uint16)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT16_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int32, type>::value ||
(is_same_type<long,type>::value && sizeof(long) == sizeof(dlib::int32)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT32_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint32, type>::value ||
(is_same_type<unsigned long,type>::value && sizeof(unsigned long) == sizeof(dlib::uint32)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT32_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::uint64, type>::value ||
(is_same_type<unsigned long,type>::value && sizeof(unsigned long) == sizeof(dlib::uint64)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxUINT64_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::int64, type>::value ||
(is_same_type<long,type>::value && sizeof(long) == sizeof(dlib::int64)))
{
plhs = mxCreateNumericMatrix(item.nr(),
item.nc(),
mxINT64_CLASS,
mxREAL);
mat = (type*)mxGetData(plhs);
}
else if (is_same_type<dlib::rgb_pixel, type>::value)
{
mwSize dims[3] = {item.nr(), item.nc(), 3};
plhs = mxCreateNumericArray(3, dims, mxUINT8_CLASS, mxREAL);
assign_image_to_matlab((dlib::uint8*)mxGetData(plhs), item);
return;
}
else
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
"mex_function uses unsupported output argument type");
}
for (long c = 0; c < item.nc(); ++c)
{
for ( long r= 0; r < item.nr(); ++r)
{
*mat++ = item(r,c);
}
}
}
void assign_to_matlab(
mxArray*& plhs,
const std::string& item
)
{
plhs = mxCreateString(item.c_str());
}
template <typename T, typename MM>
void assign_to_matlab(
mxArray*& plhs,
const array2d<T,MM>& item
)
{
assign_to_matlab(plhs,array_to_matrix(item));
}
template <typename T>
typename dlib::enable_if<is_array_type<T> >::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
mwSize dims[1] = {item.size()};
plhs = mxCreateCellArray(1,dims);
for (unsigned long i = 0; i < item.size(); ++i)
{
mxArray* next = 0;
assign_to_matlab(next, item[i]);
mxSetCell(plhs, i, next);
}
}
template <typename T>
typename dlib::disable_if_c<is_matrix<T>::value || is_array_type<T>::value ||
is_same_type<T,function_handle>::value>::type assign_to_matlab(
mxArray*& plhs,
const T& item
)
{
plhs = mxCreateDoubleScalar(item);
}
void assign_to_matlab (
mxArray*& plhs,
const char* str
)
{
assign_to_matlab(plhs, std::string(str));
}
void assign_to_matlab(
mxArray*& plhs,
const function_handle& h
)
{
}
// ----------------------------------------------------------------------------------------
template <
unsigned long num_args
>
struct call_mex_function_helper;
template <>
struct call_mex_function_helper<1>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typename basic_type<arg1_type>::type A1;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
mex_function(A1);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
}
};
template <>
struct call_mex_function_helper<2>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
mex_function(A1,A2);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
}
};
template <>
struct call_mex_function_helper<3>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
mex_function(A1,A2,A3);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
}
};
template <>
struct call_mex_function_helper<4>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
mex_function(A1,A2,A3,A4);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
}
};
template <>
struct call_mex_function_helper<5>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
mex_function(A1,A2,A3,A4,A5);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
}
};
template <>
struct call_mex_function_helper<6>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
mex_function(A1,A2,A3,A4,A5,A6);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
}
};
template <>
struct call_mex_function_helper<7>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
mex_function(A1,A2,A3,A4,A5,A6,A7);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
}
};
template <>
struct call_mex_function_helper<8>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
}
};
template <>
struct call_mex_function_helper<9>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typedef typename sig_traits<funct>::arg9_type arg9_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
typename basic_type<arg9_type>::type A9;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
if (i < nrhs && is_input_type<arg9_type>::value) {validate_and_populate_arg(i,prhs[i],A9); ++i;} ELSE_ASSIGN_ARG_9;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8,A9);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
if (is_output_type<arg9_type>::value) {assign_to_matlab(plhs[i],A9); ++i;}
}
};
template <>
struct call_mex_function_helper<10>
{
template <typename funct>
void callit(
const funct& ,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
) const
{
typedef typename sig_traits<funct>::arg1_type arg1_type;
typedef typename sig_traits<funct>::arg2_type arg2_type;
typedef typename sig_traits<funct>::arg3_type arg3_type;
typedef typename sig_traits<funct>::arg4_type arg4_type;
typedef typename sig_traits<funct>::arg5_type arg5_type;
typedef typename sig_traits<funct>::arg6_type arg6_type;
typedef typename sig_traits<funct>::arg7_type arg7_type;
typedef typename sig_traits<funct>::arg8_type arg8_type;
typedef typename sig_traits<funct>::arg9_type arg9_type;
typedef typename sig_traits<funct>::arg10_type arg10_type;
typename basic_type<arg1_type>::type A1;
typename basic_type<arg2_type>::type A2;
typename basic_type<arg3_type>::type A3;
typename basic_type<arg4_type>::type A4;
typename basic_type<arg5_type>::type A5;
typename basic_type<arg6_type>::type A6;
typename basic_type<arg7_type>::type A7;
typename basic_type<arg8_type>::type A8;
typename basic_type<arg9_type>::type A9;
typename basic_type<arg10_type>::type A10;
int i = 0;
if (i < nrhs && is_input_type<arg1_type>::value) {validate_and_populate_arg(i,prhs[i],A1); ++i;} ELSE_ASSIGN_ARG_1;
if (i < nrhs && is_input_type<arg2_type>::value) {validate_and_populate_arg(i,prhs[i],A2); ++i;} ELSE_ASSIGN_ARG_2;
if (i < nrhs && is_input_type<arg3_type>::value) {validate_and_populate_arg(i,prhs[i],A3); ++i;} ELSE_ASSIGN_ARG_3;
if (i < nrhs && is_input_type<arg4_type>::value) {validate_and_populate_arg(i,prhs[i],A4); ++i;} ELSE_ASSIGN_ARG_4;
if (i < nrhs && is_input_type<arg5_type>::value) {validate_and_populate_arg(i,prhs[i],A5); ++i;} ELSE_ASSIGN_ARG_5;
if (i < nrhs && is_input_type<arg6_type>::value) {validate_and_populate_arg(i,prhs[i],A6); ++i;} ELSE_ASSIGN_ARG_6;
if (i < nrhs && is_input_type<arg7_type>::value) {validate_and_populate_arg(i,prhs[i],A7); ++i;} ELSE_ASSIGN_ARG_7;
if (i < nrhs && is_input_type<arg8_type>::value) {validate_and_populate_arg(i,prhs[i],A8); ++i;} ELSE_ASSIGN_ARG_8;
if (i < nrhs && is_input_type<arg9_type>::value) {validate_and_populate_arg(i,prhs[i],A9); ++i;} ELSE_ASSIGN_ARG_9;
if (i < nrhs && is_input_type<arg10_type>::value) {validate_and_populate_arg(i,prhs[i],A10); ++i;} ELSE_ASSIGN_ARG_10;
mex_function(A1,A2,A3,A4,A5,A6,A7,A8,A9,A10);
i = 0;
if (is_output_type<arg1_type>::value) {assign_to_matlab(plhs[i],A1); ++i;}
if (is_output_type<arg2_type>::value) {assign_to_matlab(plhs[i],A2); ++i;}
if (is_output_type<arg3_type>::value) {assign_to_matlab(plhs[i],A3); ++i;}
if (is_output_type<arg4_type>::value) {assign_to_matlab(plhs[i],A4); ++i;}
if (is_output_type<arg5_type>::value) {assign_to_matlab(plhs[i],A5); ++i;}
if (is_output_type<arg6_type>::value) {assign_to_matlab(plhs[i],A6); ++i;}
if (is_output_type<arg7_type>::value) {assign_to_matlab(plhs[i],A7); ++i;}
if (is_output_type<arg8_type>::value) {assign_to_matlab(plhs[i],A8); ++i;}
if (is_output_type<arg9_type>::value) {assign_to_matlab(plhs[i],A9); ++i;}
if (is_output_type<arg10_type>::value) {assign_to_matlab(plhs[i],A10); ++i;}
}
};
// ----------------------------------------------------------------------------------------
template <
typename funct
>
void call_mex_function (
const funct& f,
int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[]
)
{
const long expected_nrhs = funct_traits<funct>::num_inputs;
const long expected_nlhs = funct_traits<funct>::num_outputs;
const long expected_args = expected_nrhs + expected_nlhs;
long defaulted_args = 0;
#ifdef ARG_1_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg1_type>::value);
#ifndef ARG_2_DEFAULT
// You can't define a default for argument 1 if you don't define one for argument 2 also.
COMPILE_TIME_ASSERT(expected_args < 2);
#endif
COMPILE_TIME_ASSERT(1 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_2_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg2_type>::value);
#ifndef ARG_3_DEFAULT
// You can't define a default for argument 2 if you don't define one for argument 3 also.
COMPILE_TIME_ASSERT(expected_args < 3);
#endif
COMPILE_TIME_ASSERT(2 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_3_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg3_type>::value);
#ifndef ARG_4_DEFAULT
// You can't define a default for argument 3 if you don't define one for argument 4 also.
COMPILE_TIME_ASSERT(expected_args < 4);
#endif
COMPILE_TIME_ASSERT(3 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_4_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg4_type>::value);
#ifndef ARG_5_DEFAULT
// You can't define a default for argument 4 if you don't define one for argument 5 also.
COMPILE_TIME_ASSERT(expected_args < 5);
#endif
COMPILE_TIME_ASSERT(4 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_5_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg5_type>::value);
#ifndef ARG_6_DEFAULT
// You can't define a default for argument 5 if you don't define one for argument 6 also.
COMPILE_TIME_ASSERT(expected_args < 6);
#endif
COMPILE_TIME_ASSERT(5 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_6_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg6_type>::value);
#ifndef ARG_7_DEFAULT
// You can't define a default for argument 6 if you don't define one for argument 7 also.
COMPILE_TIME_ASSERT(expected_args < 7);
#endif
COMPILE_TIME_ASSERT(6 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_7_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg7_type>::value);
#ifndef ARG_8_DEFAULT
// You can't define a default for argument 7 if you don't define one for argument 8 also.
COMPILE_TIME_ASSERT(expected_args < 8);
#endif
COMPILE_TIME_ASSERT(7 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_8_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg8_type>::value);
#ifndef ARG_9_DEFAULT
// You can't define a default for argument 8 if you don't define one for argument 9 also.
COMPILE_TIME_ASSERT(expected_args < 9);
#endif
COMPILE_TIME_ASSERT(8 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_9_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg9_type>::value);
#ifndef ARG_10_DEFAULT
// You can't define a default for argument 9 if you don't define one for argument 10 also.
COMPILE_TIME_ASSERT(expected_args < 10);
#endif
COMPILE_TIME_ASSERT(9 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
#ifdef ARG_10_DEFAULT
++defaulted_args;
// You can only set an argument's default value if it is an input argument.
COMPILE_TIME_ASSERT(is_input_type<typename sig_traits<funct>::arg10_type>::value);
COMPILE_TIME_ASSERT(10 <= expected_args); // You can't define a default for an argument that doesn't exist.
#endif
/* check for proper number of arguments */
if(nrhs > expected_nrhs || nrhs < expected_nrhs - defaulted_args)
{
std::ostringstream sout;
sout << "Expected between " << expected_nrhs-defaulted_args
<< " and " << expected_nrhs << " input arguments, got " << nrhs << ".";
mexErrMsgIdAndTxt("mex_function:nrhs",
sout.str().c_str());
}
if (nlhs > expected_nlhs)
{
std::ostringstream sout;
sout << "Expected at most " << expected_nlhs << " output arguments, got " << nlhs << ".";
mexErrMsgIdAndTxt("mex_function:nlhs",
sout.str().c_str());
}
try
{
call_mex_function_helper<sig_traits<funct>::num_args> helper;
helper.callit(f, nlhs, plhs, nrhs, prhs);
}
catch (invalid_args_exception& e)
{
mexErrMsgIdAndTxt("mex_function:validate_and_populate_arg",
("Input" + e.msg).c_str());
}
catch (dlib::error& e)
{
mexErrMsgIdAndTxt("mex_function:error",
e.what());
}
}
// ----------------------------------------------------------------------------------------
class mex_streambuf : public std::streambuf
{
public:
mex_streambuf (
)
{
buf.resize(1000);
setp(&buf[0], &buf[0] + buf.size()-2);
// make cout send data to mex_streambuf
std::cout.rdbuf(this);
}
protected:
int sync (
)
{
int num = static_cast<int>(pptr()-pbase());
if (num != 0)
{
buf[num] = 0; // null terminate the string
mexPrintf("%s",&buf[0]);
mexEvalString("drawnow"); // flush print to screen
pbump(-num);
}
return 0;
}
int_type overflow (
int_type c
)
{
if (c != EOF)
{
*pptr() = c;
pbump(1);
}
sync();
return c;
}
private:
std::vector<char> buf;
};
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
template <typename T>
void setup_input_args (
mxArray*& array,
const T& item,
int& nrhs
)
{
assign_to_matlab(array, item);
++nrhs;
}
void setup_input_args (
mxArray*& array,
const function_handle& item,
int& nrhs
)
{
array = static_cast<mxArray*>(item.h);
++nrhs;
}
template <typename T>
void setup_input_args (
mxArray*& array,
const output_decorator<T>& item,
int& nrhs
)
{
}
template <typename T>
void setup_output_args (
const std::string& function_name,
mxArray* array,
const T& item,
int& nrhs
)
{
}
template <typename T>
void setup_output_args (
const std::string& function_name,
mxArray* array,
const output_decorator<T>& item,
int& i
)
{
try
{
validate_and_populate_arg(i,array,const_cast<T&>(item.item));
++i;
}
catch (invalid_args_exception& e)
{
throw dlib::error("Error occurred calling MATLAB function '" + function_name + "' from mex file. \n"
"The MATLAB function didn't return what we expected it to. \nIn particular, return" + e.msg);
}
}
void call_matlab_for_real (
int nlhs,
mxArray* plhs[],
int nrhs,
mxArray* prhs[],
const std::string& function_name
)
{
int status = mexCallMATLAB(nlhs, plhs, nrhs, prhs, function_name.c_str());
if (status)
{
throw dlib::error("Error, an exception was thrown when we tried to call the MATLAB function '" + function_name + "'.");
}
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const std::string& function_name
)
{
using namespace mex_binding;
call_matlab_for_real(0,NULL,0,NULL, function_name);
}
template <typename T1>
void free_callback_resources (
int nlhs,
mxArray* plhs[],
int nrhs,
mxArray* prhs[]
)
{
// free resources
for (int i = 0; i < nlhs; ++i)
mxDestroyArray(plhs[i]);
for (int i = 0; i < nrhs; ++i)
{
// don't call mxDestroyArray() on function handles (which should only ever be in prhs[0])
if (i == 0 && dlib::is_same_type<T1,function_handle>::value)
continue;
mxDestroyArray(prhs[i]);
}
}
template <
typename T1
>
void call_matlab (
const std::string& function_name,
const T1& A1
)
{
using namespace mex_binding;
const int num_args = 1;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2
)
{
using namespace mex_binding;
const int num_args = 2;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3
)
{
using namespace mex_binding;
const int num_args = 3;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4
)
{
using namespace mex_binding;
const int num_args = 4;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5
)
{
using namespace mex_binding;
const int num_args = 5;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6
)
{
using namespace mex_binding;
const int num_args = 6;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7
)
{
using namespace mex_binding;
const int num_args = 7;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8
)
{
using namespace mex_binding;
const int num_args = 8;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9
)
{
using namespace mex_binding;
const int num_args = 9;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
setup_input_args(prhs[nrhs], A9, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
setup_output_args(function_name, plhs[i], A9, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
template <
typename T1,
typename T2,
typename T3,
typename T4,
typename T5,
typename T6,
typename T7,
typename T8,
typename T9,
typename T10
>
void call_matlab (
const std::string& function_name,
const T1& A1,
const T2& A2,
const T3& A3,
const T4& A4,
const T5& A5,
const T6& A6,
const T7& A7,
const T8& A8,
const T9& A9,
const T10& A10
)
{
using namespace mex_binding;
const int num_args = 10;
mxArray* plhs[num_args] = {0};
mxArray* prhs[num_args] = {0};
int nrhs = 0;
setup_input_args(prhs[nrhs], A1, nrhs);
setup_input_args(prhs[nrhs], A2, nrhs);
setup_input_args(prhs[nrhs], A3, nrhs);
setup_input_args(prhs[nrhs], A4, nrhs);
setup_input_args(prhs[nrhs], A5, nrhs);
setup_input_args(prhs[nrhs], A6, nrhs);
setup_input_args(prhs[nrhs], A7, nrhs);
setup_input_args(prhs[nrhs], A8, nrhs);
setup_input_args(prhs[nrhs], A10, nrhs);
const int nlhs = num_args - nrhs;
call_matlab_for_real(nlhs,plhs,nrhs,prhs, function_name);
int i = 0;
setup_output_args(function_name, plhs[i], A1, i);
setup_output_args(function_name, plhs[i], A2, i);
setup_output_args(function_name, plhs[i], A3, i);
setup_output_args(function_name, plhs[i], A4, i);
setup_output_args(function_name, plhs[i], A5, i);
setup_output_args(function_name, plhs[i], A6, i);
setup_output_args(function_name, plhs[i], A7, i);
setup_output_args(function_name, plhs[i], A8, i);
setup_output_args(function_name, plhs[i], A10, i);
free_callback_resources<T1>(nlhs,plhs,nrhs,prhs);
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
void call_matlab (
const function_handle& funct
)
{
call_matlab("feval", funct);
}
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
/* The gateway function called by MATLAB*/
void mexFunction( int nlhs, mxArray *plhs[],
int nrhs, const mxArray *prhs[])
{
// Only remap cout if we aren't using octave since octave already does this.
#if !defined(OCTAVE_IMPORT) && !defined(OCTAVE_API)
// make it so cout prints to mexPrintf()
static mex_binding::mex_streambuf sb;
#endif
mex_binding::call_mex_function(mex_function, nlhs, plhs, nrhs, prhs);
}
// ----------------------------------------------------------------------------------------
dlib/test/image.cpp
View file @ ad6c87b0
......@@ -1800,6 +1800,16 @@ namespace
for (int i = 0; i < 100; ++i)
test_separable_filtering_center<float>(rnd);
{
print_spinner();
matrix<unsigned char> img(40,80);
assign_all_pixels(img, 255);
skeleton(img);
DLIB_TEST(sum(matrix_cast<int>(mat(img)))/255 == 40);
draw_line(img, point(20,19), point(59,19), 00);
DLIB_TEST(sum(matrix_cast<int>(mat(img))) == 0);
}
}
} a;
......
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