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Factored out commonly repeated code into functions

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This commit is contained in:
Max Ehrlich 2015-02-05 14:09:52 -05:00
parent b4a04b112a
commit eb4808cebd
1 changed files with 156 additions and 261 deletions
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417
src/Calib3D.cc
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@ -1,6 +1,123 @@
#include "Calib3D.h"
#include "Matrix.h"
inline Local<Object> matrixFromMat(cv::Mat &input)
{
Local<Object> matrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *matrix = ObjectWrap::Unwrap<Matrix>(matrixWrap);
matrix->mat = input;
return matrixWrap;
}
inline cv::Mat matFromMatrix(Handle<Value> matrix)
{
Matrix* m = ObjectWrap::Unwrap<Matrix>(matrix->ToObject());
return m->mat;
}
inline cv::Size sizeFromArray(Handle<Value> jsArray)
{
cv::Size patternSize;
if (jsArray->IsArray())
{
Local<Object> v8sz = jsArray->ToObject();
patternSize = cv::Size(v8sz->Get(0)->IntegerValue(), v8sz->Get(1)->IntegerValue());
}
else
{
JSTHROW_TYPE("Size is not a valid array");
}
return patternSize;
}
inline std::vector<cv::Point2f> points2fFromArray(Handle<Value> array)
{
std::vector<cv::Point2f> points;
if(array->IsArray())
{
Local<Array> pointsArray = Local<Array>::Cast(array->ToObject());
for(unsigned int i = 0; i < pointsArray->Length(); i++)
{
Local<Object> pt = pointsArray->Get(i)->ToObject();
points.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
}
else
{
JSTHROW_TYPE("Points not a valid array");
}
return points;
}
inline std::vector<cv::Point3f> points3fFromArray(Handle<Value> array)
{
std::vector<cv::Point3f> points;
if(array->IsArray()) {
Local<Array> pointsArray = Local<Array>::Cast(array->ToObject());
for(unsigned int i = 0; i < pointsArray->Length(); i++)
{
Local<Object> pt = pointsArray->Get(i)->ToObject();
points.push_back(cv::Point3f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value(),
pt->Get(NanNew<String>("z"))->ToNumber()->Value()));
}
}
else
{
JSTHROW_TYPE("Must pass array of object points for each frame")
}
return points;
}
inline std::vector<std::vector<cv::Point2f> > points2fFromArrayOfArrays(Handle<Value> array)
{
std::vector<std::vector<cv::Point2f> > points;
if(array->IsArray())
{
Local<Array> pointsArray = Local<Array>::Cast(array->ToObject());
for(unsigned int i = 0; i < pointsArray->Length(); i++)
{
points.push_back(points2fFromArray(pointsArray->Get(i)));
}
}
else
{
JSTHROW_TYPE("Must pass array of object points for each frame")
}
return points;
}
inline std::vector<std::vector<cv::Point3f> > points3fFromArrayOfArrays(Handle<Value> array)
{
std::vector<std::vector<cv::Point3f> > points;
if(array->IsArray())
{
Local<Array> pointsArray = Local<Array>::Cast(array->ToObject());
for(unsigned int i = 0; i < pointsArray->Length(); i++)
{
points.push_back(points3fFromArray(pointsArray->Get(i)));
}
}
else
{
JSTHROW_TYPE("Must pass array of object points for each frame")
}
return points;
}
void Calib3D::Init(Handle<Object> target)
{
Persistent<Object> inner;
@ -26,18 +143,10 @@ NAN_METHOD(Calib3D::FindChessboardCorners)
// Get the arguments from javascript
// Arg 0 is the image
Matrix* m = ObjectWrap::Unwrap<Matrix>(args[0]->ToObject());
cv::Mat mat = m->mat;
cv::Mat mat = matFromMatrix(args[0]);
// Arg 1 is the pattern size
cv::Size patternSize;
if (args[1]->IsArray()) {
Local<Object> v8sz = args[1]->ToObject();
patternSize = cv::Size(v8sz->Get(0)->IntegerValue(), v8sz->Get(1)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass pattern size");
}
cv::Size patternSize = sizeFromArray(args[1]);
// Arg 2 would normally be the flags, ignoring this for now and using the default flags
@ -81,33 +190,13 @@ NAN_METHOD(Calib3D::DrawChessboardCorners)
// Get the arguments
// Arg 0 is the image
Matrix* m = ObjectWrap::Unwrap<Matrix>(args[0]->ToObject());
cv::Mat mat = m->mat;
cv::Mat mat = matFromMatrix(args[0]);
// Arg 1 is the pattern size
cv::Size patternSize;
if (args[1]->IsArray()) {
Local<Object> v8sz = args[1]->ToObject();
patternSize = cv::Size(v8sz->Get(0)->IntegerValue(), v8sz->Get(1)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass pattern size");
}
cv::Size patternSize = sizeFromArray(args[1]);
// Arg 2 is the corners array
std::vector<cv::Point2f> corners;
if(args[2]->IsArray()) {
Local<Array> cornersArray = Local<Array>::Cast(args[2]);
for(unsigned int i = 0; i < cornersArray->Length(); i++)
{
Local<Object> pt = cornersArray->Get(i)->ToObject();
corners.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
} else {
JSTHROW_TYPE("Must pass corners array");
}
std::vector<cv::Point2f> corners = points2fFromArray(args[2]);
// Arg 3, pattern found boolean
bool patternWasFound = args[3]->ToBoolean()->Value();
@ -134,61 +223,13 @@ NAN_METHOD(Calib3D::CalibrateCamera)
// Get the arguments
// Arg 0, the array of object points, an array of arrays
std::vector<std::vector<cv::Point3f> > objectPoints;
if(args[0]->IsArray()) {
Local<Array> objectPointsArray = Local<Array>::Cast(args[0]);
std::vector<std::vector<cv::Point3f> > objectPoints = points3fFromArrayOfArrays(args[0]);
for(unsigned int i = 0; i < objectPointsArray->Length(); i++)
{
std::vector<cv::Point3f> points;
Local<Array> pointsArray = Local<Array>::Cast(objectPointsArray->Get(i));
for(unsigned int j = 0; j < pointsArray->Length(); j++)
{
Local<Object> pt = pointsArray->Get(j)->ToObject();
points.push_back(cv::Point3f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value(),
pt->Get(NanNew<String>("z"))->ToNumber()->Value()));
}
objectPoints.push_back(points);
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
// Arg 1, the image points, another array of arrays =(
std::vector<std::vector<cv::Point2f> > imagePoints;
if(args[1]->IsArray()) {
Local<Array> imagePointsArray = Local<Array>::Cast(args[1]);
for(unsigned int i = 0; i < imagePointsArray->Length(); i++)
{
std::vector<cv::Point2f> points;
Local<Array> pointsArray = Local<Array>::Cast(imagePointsArray->Get(i));
for(unsigned int j = 0; j < pointsArray->Length(); j++)
{
Local<Object> pt = pointsArray->Get(j)->ToObject();
points.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
imagePoints.push_back(points);
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
// Arg 1, the image points, another array of arrays
std::vector<std::vector<cv::Point2f> > imagePoints = points2fFromArrayOfArrays(args[1]);
// Arg 2, the image size
cv::Size imageSize;
if (args[2]->IsArray()) {
Local<Object> v8sz = args[2]->ToObject();
imageSize = cv::Size(v8sz->Get(1)->IntegerValue(), v8sz->Get(0)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass pattern size");
}
cv::Size imageSize = sizeFromArray(args[2]);
// Arg 3, 4, input guesses for the camrea matrix and distortion coefficients, skipping for now
cv::Mat K, dist;
@ -207,17 +248,11 @@ NAN_METHOD(Calib3D::CalibrateCamera)
ret->Set(NanNew<String>("reprojectionError"), NanNew<Number>(error));
// K
Local<Object> KMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *KMatrix = ObjectWrap::Unwrap<Matrix>(KMatrixWrap);
KMatrix->mat = K;
Local<Object> KMatrixWrap = matrixFromMat(K);
ret->Set(NanNew<String>("K"), KMatrixWrap);
// dist
Local<Object> distMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *distMatrix = ObjectWrap::Unwrap<Matrix>(distMatrixWrap);
distMatrix->mat = dist;
Local<Object> distMatrixWrap = matrixFromMat(dist);
ret->Set(NanNew<String>("distortion"), distMatrixWrap);
// Per frame R and t, skiping for now
@ -241,43 +276,16 @@ NAN_METHOD(Calib3D::SolvePnP)
// Get the arguments
// Arg 0, the array of object points
std::vector<cv::Point3f> objectPoints;
if(args[0]->IsArray()) {
Local<Array> objectPointsArray = Local<Array>::Cast(args[0]);
for(unsigned int i = 0; i < objectPointsArray->Length(); i++)
{
Local<Object> pt = objectPointsArray->Get(i)->ToObject();
objectPoints.push_back(cv::Point3f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value(),
pt->Get(NanNew<String>("z"))->ToNumber()->Value()));
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
std::vector<cv::Point3f> objectPoints = points3fFromArray(args[0]);
// Arg 1, the image points
std::vector<cv::Point2f> imagePoints;
if(args[1]->IsArray()) {
Local<Array> imagePointsArray = Local<Array>::Cast(args[1]);
for(unsigned int i = 0; i < imagePointsArray->Length(); i++)
{
Local<Object> pt = imagePointsArray->Get(i)->ToObject();
imagePoints.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
std::vector<cv::Point2f> imagePoints = points2fFromArray(args[1]);
// Arg 2, the camera matrix
Matrix* kWrap = ObjectWrap::Unwrap<Matrix>(args[2]->ToObject());
cv::Mat K = kWrap->mat;
cv::Mat K = matFromMatrix(args[2]);
// Arg 3, the distortion coefficients
Matrix* distWrap = ObjectWrap::Unwrap<Matrix>(args[3]->ToObject());
cv::Mat dist = distWrap->mat;
cv::Mat dist = matFromMatrix(args[3]);
// Arg 4, use extrinsic guess, skipped for now
@ -292,17 +300,11 @@ NAN_METHOD(Calib3D::SolvePnP)
Local<Object> ret = NanNew<Object>();
// rvec
Local<Object> rMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *rMatrix = ObjectWrap::Unwrap<Matrix>(rMatrixWrap);
rMatrix->mat = rvec;
Local<Object> rMatrixWrap = matrixFromMat(rvec);
ret->Set(NanNew<String>("rvec"), rMatrixWrap);
// tvec
Local<Object> tMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *tMatrix = ObjectWrap::Unwrap<Matrix>(tMatrixWrap);
tMatrix->mat = tvec;
Local<Object> tMatrixWrap = matrixFromMat(tvec);
ret->Set(NanNew<String>("tvec"), tMatrixWrap);
// Return
@ -324,35 +326,19 @@ NAN_METHOD(Calib3D::GetOptimalNewCameraMatrix)
// Get the arguments
// Arg 0 is the original camera matrix
Matrix* m0 = ObjectWrap::Unwrap<Matrix>(args[0]->ToObject());
cv::Mat Kin = m0->mat;
cv::Mat Kin = matFromMatrix(args[0]);
// Arg 1 is the distortion coefficients
Matrix* m1 = ObjectWrap::Unwrap<Matrix>(args[1]->ToObject());
cv::Mat dist = m1->mat;
cv::Mat dist = matFromMatrix(args[1]);
// Arg 2, the image size
cv::Size imageSize;
if (args[2]->IsArray()) {
Local<Object> v8sz = args[2]->ToObject();
imageSize = cv::Size(v8sz->Get(1)->IntegerValue(), v8sz->Get(0)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass original image size");
}
cv::Size imageSize = sizeFromArray(args[2]);
// Arg 3 is the alpha free scaling parameter
double alpha = args[3]->ToNumber()->Value();
// Arg 4, the new image size
cv::Size newImageSize;
if (args[4]->IsArray()) {
Local<Object> v8sz = args[4]->ToObject();
newImageSize = cv::Size(v8sz->Get(1)->IntegerValue(), v8sz->Get(0)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass new image size");
}
cv::Size newImageSize = sizeFromArray(args[4]);
// Arg 5, valid ROI, skip for now
// Arg 6, center principal point, skip for now
@ -361,9 +347,7 @@ NAN_METHOD(Calib3D::GetOptimalNewCameraMatrix)
cv::Mat Kout = cv::getOptimalNewCameraMatrix(Kin, dist, imageSize, alpha, newImageSize);
// Wrap the output K
Local<Object> KMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *KMatrix = ObjectWrap::Unwrap<Matrix>(KMatrixWrap);
KMatrix->mat = Kout;
Local<Object> KMatrixWrap = matrixFromMat(Kout);
// Return the new K matrix
NanReturnValue(KMatrixWrap);
@ -384,99 +368,26 @@ NAN_METHOD(Calib3D::StereoCalibrate)
// Get the arguments
// Arg 0, the array of object points, an array of arrays
std::vector<std::vector<cv::Point3f> > objectPoints;
if(args[0]->IsArray()) {
Local<Array> objectPointsArray = Local<Array>::Cast(args[0]);
std::vector<std::vector<cv::Point3f> > objectPoints = points3fFromArrayOfArrays(args[0]);
for(unsigned int i = 0; i < objectPointsArray->Length(); i++)
{
std::vector<cv::Point3f> points;
Local<Array> pointsArray = Local<Array>::Cast(objectPointsArray->Get(i));
for(unsigned int j = 0; j < pointsArray->Length(); j++)
{
Local<Object> pt = pointsArray->Get(j)->ToObject();
points.push_back(cv::Point3f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value(),
pt->Get(NanNew<String>("z"))->ToNumber()->Value()));
}
objectPoints.push_back(points);
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
// Arg 1, the image points1, another array of arrays =(
std::vector<std::vector<cv::Point2f> > imagePoints1;
if(args[1]->IsArray()) {
Local<Array> imagePointsArray = Local<Array>::Cast(args[1]);
for(unsigned int i = 0; i < imagePointsArray->Length(); i++)
{
std::vector<cv::Point2f> points;
Local<Array> pointsArray = Local<Array>::Cast(imagePointsArray->Get(i));
for(unsigned int j = 0; j < pointsArray->Length(); j++)
{
Local<Object> pt = pointsArray->Get(j)->ToObject();
points.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
imagePoints1.push_back(points);
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
// Arg 1, the image points1, another array of arrays
std::vector<std::vector<cv::Point2f> > imagePoints1 = points2fFromArrayOfArrays(args[1]);
// Arg 2, the image points2, another array of arrays =(
std::vector<std::vector<cv::Point2f> > imagePoints2;
if(args[2]->IsArray()) {
Local<Array> imagePointsArray = Local<Array>::Cast(args[2]);
for(unsigned int i = 0; i < imagePointsArray->Length(); i++)
{
std::vector<cv::Point2f> points;
Local<Array> pointsArray = Local<Array>::Cast(imagePointsArray->Get(i));
for(unsigned int j = 0; j < pointsArray->Length(); j++)
{
Local<Object> pt = pointsArray->Get(j)->ToObject();
points.push_back(cv::Point2f(pt->Get(NanNew<String>("x"))->ToNumber()->Value(),
pt->Get(NanNew<String>("y"))->ToNumber()->Value()));
}
imagePoints2.push_back(points);
}
} else {
JSTHROW_TYPE("Must pass array of object points for each frame")
}
std::vector<std::vector<cv::Point2f> > imagePoints2 = points2fFromArrayOfArrays(args[2]);
// Arg 3 is the image size (follows the PYTHON api not the C++ api since all following arguments are optional or outputs)
cv::Size imageSize;
if (args[3]->IsArray()) {
Local<Object> v8sz = args[3]->ToObject();
imageSize = cv::Size(v8sz->Get(1)->IntegerValue(), v8sz->Get(0)->IntegerValue());
} else {
JSTHROW_TYPE("Must pass original image size");
}
cv::Size imageSize = sizeFromArray(args[3]);
// Arg 4,5,6,7 is the camera matrix and distortion coefficients (optional but must pass all 4 or none)
cv::Mat k1, d1, k2, d2;
if(args.Length() >= 8)
{
Matrix* mk1 = ObjectWrap::Unwrap<Matrix>(args[4]->ToObject());
Matrix* md1 = ObjectWrap::Unwrap<Matrix>(args[5]->ToObject());
Matrix* mk2 = ObjectWrap::Unwrap<Matrix>(args[6]->ToObject());
Matrix* md2 = ObjectWrap::Unwrap<Matrix>(args[7]->ToObject());
k1 = matFromMatrix(args[4]);
d1 = matFromMatrix(args[5]);
k1 = mk1->mat;
d1 = md1->mat;
k2 = mk2->mat;
d2 = md2->mat;
k2 = matFromMatrix(args[6]);
d2 = matFromMatrix(args[7]);
}
// Last argument is flags, skipping for now
@ -493,44 +404,28 @@ NAN_METHOD(Calib3D::StereoCalibrate)
// Make the output arguments
// k1
Local<Object> K1MatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *K1Matrix = ObjectWrap::Unwrap<Matrix>(K1MatrixWrap);
K1Matrix->mat = k1;
Local<Object> K1MatrixWrap = matrixFromMat(k1);
// d1
Local<Object> d1MatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *d1Matrix = ObjectWrap::Unwrap<Matrix>(d1MatrixWrap);
d1Matrix->mat = d1;
Local<Object> d1MatrixWrap = matrixFromMat(d1);
// k2
Local<Object> K2MatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *K2Matrix = ObjectWrap::Unwrap<Matrix>(K2MatrixWrap);
K2Matrix->mat = k2;
Local<Object> K2MatrixWrap = matrixFromMat(k2);
// d2
Local<Object> d2MatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *d2Matrix = ObjectWrap::Unwrap<Matrix>(d2MatrixWrap);
d2Matrix->mat = d2;
Local<Object> d2MatrixWrap = matrixFromMat(d2);
// R
Local<Object> RMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *RMatrix = ObjectWrap::Unwrap<Matrix>(RMatrixWrap);
RMatrix->mat = R;
Local<Object> RMatrixWrap = matrixFromMat(R);
// t
Local<Object> tMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *tMatrix = ObjectWrap::Unwrap<Matrix>(tMatrixWrap);
tMatrix->mat = t;
Local<Object> tMatrixWrap = matrixFromMat(t);
// E
Local<Object> EMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *EMatrix = ObjectWrap::Unwrap<Matrix>(EMatrixWrap);
EMatrix->mat = E;
Local<Object> EMatrixWrap = matrixFromMat(E);
// F
Local<Object> FMatrixWrap = NanNew(Matrix::constructor)->GetFunction()->NewInstance();
Matrix *FMatrix = ObjectWrap::Unwrap<Matrix>(FMatrixWrap);
FMatrix->mat = F;
Local<Object> FMatrixWrap = matrixFromMat(F);
// Add to return object
ret->Set(NanNew<String>("K1"), K1MatrixWrap);