Implement cv.gin and multiple output for python

4 years ago · e998d89e88
parent 295afd5882
commit e998d89e88
9 changed files with 269 additions and 14 deletions
--- a/modules/gapi/include/opencv2/gapi/core.hpp
+++ b/modules/gapi/include/opencv2/gapi/core.hpp
@ -1331,7 +1331,7 @@ GAPI_EXPORTS GMat threshold(const GMat& src, const GScalar& thresh, const GScala
 This function applicable for all threshold types except CV_THRESH_OTSU and CV_THRESH_TRIANGLE
@note Function textual ID is "org.opencv.core.matrixop.thresholdOT"
 */
-GAPI_EXPORTS std::tuple<GMat, GScalar> threshold(const GMat& src, const GScalar& maxval, int type);
+GAPI_EXPORTS_W std::tuple<GMat, GScalar> threshold(const GMat& src, const GScalar& maxval, int type);
 /** @brief Applies a range-level threshold to each matrix element.
--- a/modules/gapi/include/opencv2/gapi/gcomputation.hpp
+++ b/modules/gapi/include/opencv2/gapi/gcomputation.hpp
@ -259,6 +259,9 @@ public:
     */
    void apply(GRunArgs &&ins, GRunArgsP &&outs, GCompileArgs &&args = {});       // Arg-to-arg overload
    /// @private -- Exclude this function from OpenCV documentation
    GAPI_WRAP GRunArgs apply(GRunArgs &&ins, GCompileArgs &&args = {});
    /// @private -- Exclude this function from OpenCV documentation
    void apply(const std::vector<cv::Mat>& ins,                                   // Compatibility overload
               const std::vector<cv::Mat>& outs,
@ -286,7 +289,7 @@ public:
     * @param args compilation arguments for underlying compilation
     * process.
     */
-    GAPI_WRAP void apply(cv::Mat in, CV_OUT cv::Scalar &out, GCompileArgs &&args = {}); // Unary overload (scalar)
+    void apply(cv::Mat in, cv::Scalar &out, GCompileArgs &&args = {}); // Unary overload (scalar)
    /**
     * @brief Execute a binary computation (with compilation on the fly)
@ -298,7 +301,7 @@ public:
     * @param args compilation arguments for underlying compilation
     * process.
     */
-    GAPI_WRAP void apply(cv::Mat in1, cv::Mat in2, CV_OUT cv::Mat &out, GCompileArgs &&args = {}); // Binary overload
+    void apply(cv::Mat in1, cv::Mat in2, cv::Mat &out, GCompileArgs &&args = {}); // Binary overload
    /**
     * @brief Execute an binary computation (with compilation on the fly)
@ -528,6 +531,7 @@ protected:
        GCompileArgs comp_args = std::get<sizeof...(Ts)-1>(meta_and_compile_args);
        return compileStreaming(std::move(meta_args), std::move(comp_args));
    }
    void recompile(GMetaArgs&& in_metas, GCompileArgs &&args);
    /// @private
    std::shared_ptr<Priv> m_priv;
 };
--- a/modules/gapi/misc/python/pyopencv_gapi.hpp
+++ b/modules/gapi/misc/python/pyopencv_gapi.hpp
@ -1,3 +1,8 @@
 #ifndef OPENCV_GAPI_PYOPENCV_GAPI_HPP
 #define OPENCV_GAPI_PYOPENCV_GAPI_HPP
 #ifdef HAVE_OPENCV_GAPI
 using gapi_GKernelPackage = cv::gapi::GKernelPackage;
 template<>
@ -12,6 +17,67 @@ PyObject* pyopencv_from(const std::vector<GCompileArg>& value)
    return pyopencv_from_generic_vec(value);
 }
 template<>
 bool pyopencv_to(PyObject* obj, GRunArgs& value, const ArgInfo& info)
 {
    return pyopencv_to_generic_vec(obj, value, info);
 }
 static PyObject* from_grunarg(const GRunArg& v)
 {
    switch (v.index())
    {
        case GRunArg::index_of<cv::Mat>():
        {
            const auto& m = util::get<cv::Mat>(v);
            return pyopencv_from(m);
        }
        case GRunArg::index_of<cv::Scalar>():
        {
            const auto& s = util::get<cv::Scalar>(v);
            return pyopencv_from(s);
        }
        default:
            return NULL;
    }
    GAPI_Assert(false);
 }
 template<>
 PyObject* pyopencv_from(const GRunArgs& value)
 {
    size_t i, n = value.size();
    // NB: It doesn't make sense to return list with a single element
    if (n == 1)
    {
        PyObject* item = from_grunarg(value[0]);
        if(!item)
        {
            PyErr_SetString(PyExc_TypeError, "Failed to unpack GRunArgs");
            return NULL;
        }
        return item;
    }
    PyObject* list = PyList_New(n);
    for(i = 0; i < n; ++i)
    {
        PyObject* item = from_grunarg(value[i]);
        if(!item)
        {
            Py_DECREF(list);
            PyErr_SetString(PyExc_TypeError, "Failed to unpack GRunArgs");
            return NULL;
        }
        PyList_SetItem(list, i, item);
    }
    return list;
 }
 template <typename T>
 static PyObject* extract_proto_args(PyObject* py_args, PyObject* kw)
 {
@ -19,13 +85,19 @@ static PyObject* extract_proto_args(PyObject* py_args, PyObject* kw)
    GProtoArgs args;
    Py_ssize_t size = PyTuple_Size(py_args);
-    for (int i = 0; i < size; ++i) {
+    for (int i = 0; i < size; ++i)
    {
        PyObject* item = PyTuple_GetItem(py_args, i);
-        if (PyObject_TypeCheck(item, reinterpret_cast<PyTypeObject*>(pyopencv_GScalar_TypePtr))) {
+        if (PyObject_TypeCheck(item, reinterpret_cast<PyTypeObject*>(pyopencv_GScalar_TypePtr)))
        {
            args.emplace_back(reinterpret_cast<pyopencv_GScalar_t*>(item)->v);
-        } else if (PyObject_TypeCheck(item, reinterpret_cast<PyTypeObject*>(pyopencv_GMat_TypePtr))) {
+        }
        else if (PyObject_TypeCheck(item, reinterpret_cast<PyTypeObject*>(pyopencv_GMat_TypePtr)))
        {
            args.emplace_back(reinterpret_cast<pyopencv_GMat_t*>(item)->v);
-        } else {
+        }
        else
        {
            PyErr_SetString(PyExc_TypeError, "cv.GIn() supports only cv.GMat and cv.GScalar");
            return NULL;
        }
@ -43,3 +115,51 @@ static PyObject* pyopencv_cv_GOut(PyObject* , PyObject* py_args, PyObject* kw)
 {
    return extract_proto_args<GProtoOutputArgs>(py_args, kw);
 }
 static PyObject* pyopencv_cv_gin(PyObject* , PyObject* py_args, PyObject* kw)
 {
    using namespace cv;
    GRunArgs args;
    Py_ssize_t size = PyTuple_Size(py_args);
    for (int i = 0; i < size; ++i)
    {
        PyObject* item = PyTuple_GetItem(py_args, i);
        if (PyTuple_Check(item))
        {
            cv::Scalar s;
            if (pyopencv_to(item, s, ArgInfo("scalar", true)))
            {
                args.emplace_back(s);
            }
            else
            {
                PyErr_SetString(PyExc_TypeError, "Failed convert tuple to cv::Scalar");
                return NULL;
            }
        }
        else if (PyArray_Check(item))
        {
            cv::Mat m;
            if (pyopencv_to(item, m, ArgInfo("mat", true)))
            {
                args.emplace_back(m);
            }
            else
            {
                PyErr_SetString(PyExc_TypeError, "Failed convert array to cv::Mat");
                return NULL;
            }
        }
    }
    return pyopencv_from_generic_vec(args);
 }
 static PyObject* pyopencv_cv_gout(PyObject* o, PyObject* py_args, PyObject* kw)
 {
    return pyopencv_cv_gin(o, py_args, kw);
 }
 #endif  // HAVE_OPENCV_GAPI
 #endif  // OPENCV_GAPI_PYOPENCV_GAPI_HPP
--- a/modules/gapi/misc/python/shadow_gapi.hpp
+++ b/modules/gapi/misc/python/shadow_gapi.hpp
@ -4,9 +4,11 @@
 namespace cv
 {
   GAPI_EXPORTS_W GCompileArgs compile_args(gapi::GKernelPackage pkg);
   class GAPI_EXPORTS_W_SIMPLE GProtoArg { };
   class GAPI_EXPORTS_W_SIMPLE GProtoInputArgs { };
   class GAPI_EXPORTS_W_SIMPLE GProtoOutputArgs { };
   class GAPI_EXPORTS_W_SIMPLE GRunArg {  };
   using GProtoInputArgs  = GIOProtoArgs<In_Tag>;
   using GProtoOutputArgs = GIOProtoArgs<Out_Tag>;
--- a/modules/gapi/misc/python/test/test_gapi_core.py
+++ b/modules/gapi/misc/python/test/test_gapi_core.py
@ -33,7 +33,7 @@ class gapi_core_test(NewOpenCVTests):
        comp = cv.GComputation(cv.GIn(g_in1, g_in2), cv.GOut(g_out))
        for pkg in pkgs:
-            actual = comp.apply(in1, in2, args=cv.compile_args(pkg))
+            actual = comp.apply(cv.gin(in1, in2), args=cv.compile_args(pkg))
            # Comparison
            self.assertEqual(0.0, cv.norm(expected, actual, cv.NORM_INF))
@ -51,10 +51,51 @@ class gapi_core_test(NewOpenCVTests):
        comp = cv.GComputation(g_in, g_out)
        for pkg in pkgs:
-            actual = comp.apply(in_mat, args=cv.compile_args(pkg))
+            actual = comp.apply(cv.gin(in_mat), args=cv.compile_args(pkg))
            # Comparison
            self.assertEqual(0.0, cv.norm(expected, actual, cv.NORM_INF))
    def test_split3(self):
        sz = (1280, 720, 3)
        in_mat = np.random.randint(0, 100, sz).astype(np.uint8)
        # OpenCV
        expected = cv.split(in_mat)
        # G-API
        g_in = cv.GMat()
        b, g, r = cv.gapi.split3(g_in)
        comp = cv.GComputation(cv.GIn(g_in), cv.GOut(b, g, r))
        for pkg in pkgs:
            actual = comp.apply(cv.gin(in_mat), args=cv.compile_args(pkg))
            # Comparison
            for e, a in zip(expected, actual):
                self.assertEqual(0.0, cv.norm(e, a, cv.NORM_INF))
    def test_threshold(self):
        sz = (1280, 720)
        in_mat = np.random.randint(0, 100, sz).astype(np.uint8)
        rand_int = np.random.randint(0, 50)
        maxv = (rand_int, rand_int)
        # OpenCV
        expected_thresh, expected_mat = cv.threshold(in_mat, maxv[0], maxv[0], cv.THRESH_TRIANGLE)
        # G-API
        g_in = cv.GMat()
        g_sc = cv.GScalar()
        mat, threshold = cv.gapi.threshold(g_in, g_sc, cv.THRESH_TRIANGLE)
        comp = cv.GComputation(cv.GIn(g_in, g_sc), cv.GOut(mat, threshold))
        for pkg in pkgs:
            actual_mat, actual_thresh = comp.apply(cv.gin(in_mat, maxv), args=cv.compile_args(pkg))
            # Comparison
            self.assertEqual(0.0, cv.norm(expected_mat, actual_mat, cv.NORM_INF))
            self.assertEqual(expected_thresh, actual_thresh[0])
 if __name__ == '__main__':
    NewOpenCVTests.bootstrap()
--- a/modules/gapi/misc/python/test/test_gapi_sample_pipelines.py
+++ b/modules/gapi/misc/python/test/test_gapi_sample_pipelines.py
@ -33,7 +33,7 @@ class gapi_sample_pipelines(NewOpenCVTests):
        comp = cv.GComputation(g_in, g_out)
        for pkg in pkgs:
-            actual = comp.apply(in_mat, args=cv.compile_args(pkg))
+            actual = comp.apply(cv.gin(in_mat), args=cv.compile_args(pkg))
            # Comparison
            self.assertEqual(0.0, cv.norm(expected, actual, cv.NORM_INF))
--- a/modules/gapi/src/api/gcomputation.cpp
+++ b/modules/gapi/src/api/gcomputation.cpp
@ -129,15 +129,14 @@ static bool formats_are_same(const cv::GMetaArgs& metas1, const cv::GMetaArgs& m
                     });
 }
-void cv::GComputation::apply(GRunArgs &&ins, GRunArgsP &&outs, GCompileArgs &&args)
+void cv::GComputation::recompile(GMetaArgs&& in_metas, GCompileArgs &&args)
 {
    const auto in_metas = descr_of(ins);
    // FIXME Graph should be recompiled when GCompileArgs have changed
    if (m_priv->m_lastMetas != in_metas)
    {
        if (m_priv->m_lastCompiled &&
-            m_priv->m_lastCompiled.canReshape() &&
+                m_priv->m_lastCompiled.canReshape() &&
-            formats_are_same(m_priv->m_lastMetas, in_metas))
+                formats_are_same(m_priv->m_lastMetas, in_metas))
        {
            m_priv->m_lastCompiled.reshape(in_metas, args);
        }
@ -148,6 +147,11 @@ void cv::GComputation::apply(GRunArgs &&ins, GRunArgsP &&outs, GCompileArgs &&ar
        }
        m_priv->m_lastMetas = in_metas;
    }
 }
 void cv::GComputation::apply(GRunArgs &&ins, GRunArgsP &&outs, GCompileArgs &&args)
 {
    recompile(descr_of(ins), std::move(args));
    m_priv->m_lastCompiled(std::move(ins), std::move(outs));
 }
@ -165,6 +169,41 @@ void cv::GComputation::apply(const std::vector<cv::Mat> &ins,
    apply(std::move(call_ins), std::move(call_outs), std::move(args));
 }
 // NB: This overload is called from python code
 cv::GRunArgs cv::GComputation::apply(GRunArgs &&ins, GCompileArgs &&args)
 {
    recompile(descr_of(ins), std::move(args));
    const auto& out_metas = m_priv->m_lastCompiled.outMetas();
    GRunArgs run_args;
    GRunArgsP outs;
    run_args.reserve(out_metas.size());
    outs.reserve(out_metas.size());
    for (auto&& meta : out_metas)
    {
        switch (meta.index())
        {
            case cv::GMetaArg::index_of<cv::GMatDesc>():
            {
                run_args.emplace_back(cv::Mat{});
                outs.emplace_back(&cv::util::get<cv::Mat>(run_args.back()));
                break;
            }
            case cv::GMetaArg::index_of<cv::GScalarDesc>():
            {
                run_args.emplace_back(cv::Scalar{});
                outs.emplace_back(&cv::util::get<cv::Scalar>(run_args.back()));
                break;
            }
            default:
                util::throw_error(std::logic_error("Only cv::GMat and cv::GScalar are supported for python output"));
        }
    }
    m_priv->m_lastCompiled(std::move(ins), std::move(outs));
    return run_args;
 }
 #if !defined(GAPI_STANDALONE)
 void cv::GComputation::apply(cv::Mat in, cv::Mat &out, GCompileArgs &&args)
 {
--- a/modules/gapi/test/gapi_gcomputation_tests.cpp
+++ b/modules/gapi/test/gapi_gcomputation_tests.cpp
@ -6,6 +6,9 @@
 #include "test_precomp.hpp"
 #include <opencv2/gapi/s11n.hpp>
 #include <opencv2/gapi/cpu/gcpukernel.hpp>
 #include <ade/util/zip_range.hpp>
@ -87,6 +90,51 @@ namespace opencv_test
              }
          }
      };
      // NB: Check an apply specifically designed to be called from Python,
      // but can also be used from C++
      struct GComputationPythonApplyTest: public ::testing::Test
      {
          cv::Size sz;
          MatType type;
          cv::Mat in_mat1, in_mat2, out_mat_ocv;
          cv::GComputation m_c;
          GComputationPythonApplyTest() : sz(cv::Size(300,300)), type(CV_8UC1),
          in_mat1(sz, type), in_mat2(sz, type), out_mat_ocv(sz, type),
          m_c([&](){
                       cv::GMat in1, in2;
                       cv::GMat out = in1 + in2;
                       return cv::GComputation(cv::GIn(in1, in2), cv::GOut(out));
                   })
          {
              cv::randu(in_mat1, cv::Scalar::all(0), cv::Scalar::all(255));
              cv::randu(in_mat2, cv::Scalar::all(0), cv::Scalar::all(255));
              out_mat_ocv = in_mat1 + in_mat2;
          }
      };
  }
  TEST_F(GComputationPythonApplyTest, WithoutSerialization)
  {
      auto output = m_c.apply(cv::gin(in_mat1, in_mat2));
      EXPECT_EQ(1u, output.size());
      const auto& out_mat_gapi = cv::util::get<cv::Mat>(output[0]);
      EXPECT_EQ(0, cvtest::norm(out_mat_ocv, out_mat_gapi, NORM_INF));
  }
  TEST_F(GComputationPythonApplyTest, WithSerialization)
  {
      auto p = cv::gapi::serialize(m_c);
      auto c = cv::gapi::deserialize<cv::GComputation>(p);
      auto output = c.apply(cv::gin(in_mat1, in_mat2));
      EXPECT_EQ(1u, output.size());
      const auto& out_mat_gapi = cv::util::get<cv::Mat>(output[0]);
      EXPECT_EQ(0, cvtest::norm(out_mat_ocv, out_mat_gapi, NORM_INF));
  }
  TEST_F(GComputationApplyTest, ThrowDontPassCustomKernel)
--- a/modules/python/src2/cv2.cpp
+++ b/modules/python/src2/cv2.cpp
@ -1954,6 +1954,7 @@ static PyMethodDef special_methods[] = {
 #ifdef HAVE_OPENCV_GAPI
  {"GIn", CV_PY_FN_WITH_KW(pyopencv_cv_GIn), "GIn(...) -> GInputProtoArgs"},
  {"GOut", CV_PY_FN_WITH_KW(pyopencv_cv_GOut), "GOut(...) -> GOutputProtoArgs"},
  {"gin", CV_PY_FN_WITH_KW(pyopencv_cv_gin), "gin(...) -> GRunArgs"},
 #endif
  {NULL, NULL},
 };