Stop forcing c-contiguous in py::vectorize

The only part of the vectorize code that actually needs c-contiguous is
the "trivial" broadcast; for non-trivial arguments, the code already
uses strides properly (and so handles C-style, F-style, neither, slices,
etc.)

This commit rewrites `broadcast` to additionally check for C-contiguous
storage, then takes off the `c_style` flag for the arguments, which
will keep the functionality more or less the same, except for no longer
requiring an array copy for non-c-contiguous input arrays.

Additionally, if we're given a singleton slice (e.g. a[0::4, 0::4] for a
4x4 or smaller array), we no longer fail triviality because the trivial
code path never actually uses the strides on a singleton.
This commit is contained in:
Jason Rhinelander 2017-03-15 00:57:56 -03:00
parent cd3d1fc7df
commit ae5a8f7eb3
3 changed files with 110 additions and 24 deletions

View File

@ -1052,28 +1052,47 @@ private:
std::array<common_iter, N> m_common_iterator; std::array<common_iter, N> m_common_iterator;
}; };
// Populates the shape and number of dimensions for the set of buffers. Returns true if the
// broadcast is "trivial"--that is, has each buffer being either a singleton or a full-size,
// C-contiguous storage buffer.
template <size_t N> template <size_t N>
bool broadcast(const std::array<buffer_info, N>& buffers, size_t& ndim, std::vector<size_t>& shape) { bool broadcast(const std::array<buffer_info, N> &buffers, size_t &ndim, std::vector<size_t> &shape) {
ndim = std::accumulate(buffers.begin(), buffers.end(), size_t(0), [](size_t res, const buffer_info& buf) { ndim = std::accumulate(buffers.begin(), buffers.end(), size_t(0), [](size_t res, const buffer_info& buf) {
return std::max(res, buf.ndim); return std::max(res, buf.ndim);
}); });
shape = std::vector<size_t>(ndim, 1); shape.clear();
shape.resize(ndim, 1);
bool trivial_broadcast = true; bool trivial_broadcast = true;
for (size_t i = 0; i < N; ++i) { for (size_t i = 0; i < N; ++i) {
trivial_broadcast = trivial_broadcast && (buffers[i].size == 1 || buffers[i].ndim == ndim);
size_t expect_stride = buffers[i].itemsize;
auto res_iter = shape.rbegin(); auto res_iter = shape.rbegin();
bool i_trivial_broadcast = (buffers[i].size == 1) || (buffers[i].ndim == ndim); auto stride_iter = buffers[i].strides.rbegin();
for (auto shape_iter = buffers[i].shape.rbegin(); auto shape_iter = buffers[i].shape.rbegin();
shape_iter != buffers[i].shape.rend(); ++shape_iter, ++res_iter) { while (shape_iter != buffers[i].shape.rend()) {
const auto &dim_size_in = *shape_iter;
auto &dim_size_out = *res_iter;
if (*res_iter == 1) // Each input dimension can either be 1 or `n`, but `n` values must match across buffers
*res_iter = *shape_iter; if (dim_size_out == 1)
else if ((*shape_iter != 1) && (*res_iter != *shape_iter)) dim_size_out = dim_size_in;
else if (dim_size_in != 1 && dim_size_in != dim_size_out)
pybind11_fail("pybind11::vectorize: incompatible size/dimension of inputs!"); pybind11_fail("pybind11::vectorize: incompatible size/dimension of inputs!");
i_trivial_broadcast = i_trivial_broadcast && (*res_iter == *shape_iter); if (trivial_broadcast && buffers[i].size > 1) {
if (dim_size_in == dim_size_out && expect_stride == *stride_iter) {
expect_stride *= dim_size_in;
++stride_iter;
} else {
trivial_broadcast = false;
}
}
++shape_iter;
++res_iter;
} }
trivial_broadcast = trivial_broadcast && i_trivial_broadcast;
} }
return trivial_broadcast; return trivial_broadcast;
} }
@ -1081,18 +1100,17 @@ bool broadcast(const std::array<buffer_info, N>& buffers, size_t& ndim, std::vec
template <typename Func, typename Return, typename... Args> template <typename Func, typename Return, typename... Args>
struct vectorize_helper { struct vectorize_helper {
typename std::remove_reference<Func>::type f; typename std::remove_reference<Func>::type f;
static constexpr size_t N = sizeof...(Args);
template <typename T> template <typename T>
explicit vectorize_helper(T&&f) : f(std::forward<T>(f)) { } explicit vectorize_helper(T&&f) : f(std::forward<T>(f)) { }
object operator()(array_t<Args, array::c_style | array::forcecast>... args) { object operator()(array_t<Args, array::forcecast>... args) {
return run(args..., make_index_sequence<sizeof...(Args)>()); return run(args..., make_index_sequence<N>());
} }
template <size_t ... Index> object run(array_t<Args, array::c_style | array::forcecast>&... args, index_sequence<Index...> index) { template <size_t ... Index> object run(array_t<Args, array::forcecast>&... args, index_sequence<Index...> index) {
/* Request buffers from all parameters */ /* Request buffers from all parameters */
const size_t N = sizeof...(Args);
std::array<buffer_info, N> buffers {{ args.request()... }}; std::array<buffer_info, N> buffers {{ args.request()... }};
/* Determine dimensions parameters of output array */ /* Determine dimensions parameters of output array */
@ -1112,27 +1130,24 @@ struct vectorize_helper {
} }
if (size == 1) if (size == 1)
return cast(f(*((Args *) buffers[Index].ptr)...)); return cast(f(*reinterpret_cast<Args *>(buffers[Index].ptr)...));
array_t<Return> result(shape, strides); array_t<Return, array::c_style> result(shape, strides);
auto buf = result.request(); auto buf = result.request();
auto output = (Return *) buf.ptr; auto output = (Return *) buf.ptr;
if (trivial_broadcast) { if (trivial_broadcast) {
/* Call the function */ /* Call the function */
for (size_t i = 0; i < size; ++i) { for (size_t i = 0; i < size; ++i)
output[i] = f((buffers[Index].size == 1 output[i] = f((reinterpret_cast<Args *>(buffers[Index].ptr)[buffers[Index].size == 1 ? 0 : i])...);
? *((Args *) buffers[Index].ptr)
: ((Args *) buffers[Index].ptr)[i])...);
}
} else { } else {
apply_broadcast<N, Index...>(buffers, buf, index); apply_broadcast<Index...>(buffers, buf, index);
} }
return result; return result;
} }
template <size_t N, size_t... Index> template <size_t... Index>
void apply_broadcast(const std::array<buffer_info, N> &buffers, void apply_broadcast(const std::array<buffer_info, N> &buffers,
buffer_info &output, index_sequence<Index...>) { buffer_info &output, index_sequence<Index...>) {
using input_iterator = multi_array_iterator<N>; using input_iterator = multi_array_iterator<N>;

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@ -38,4 +38,17 @@ test_initializer numpy_vectorize([](py::module &m) {
m.def("selective_func", [](py::array_t<int, py::array::c_style>) { return "Int branch taken."; }); m.def("selective_func", [](py::array_t<int, py::array::c_style>) { return "Int branch taken."; });
m.def("selective_func", [](py::array_t<float, py::array::c_style>) { return "Float branch taken."; }); m.def("selective_func", [](py::array_t<float, py::array::c_style>) { return "Float branch taken."; });
m.def("selective_func", [](py::array_t<std::complex<float>, py::array::c_style>) { return "Complex float branch taken."; }); m.def("selective_func", [](py::array_t<std::complex<float>, py::array::c_style>) { return "Complex float branch taken."; });
// Internal optimization test for whether the input is trivially broadcastable:
m.def("vectorized_is_trivial", [](
py::array_t<int, py::array::forcecast> arg1,
py::array_t<float, py::array::forcecast> arg2,
py::array_t<double, py::array::forcecast> arg3
) {
size_t ndim;
std::vector<size_t> shape;
std::array<py::buffer_info, 3> buffers {{ arg1.request(), arg2.request(), arg3.request() }};
return py::detail::broadcast(buffers, ndim, shape);
});
}); });

View File

@ -57,6 +57,35 @@ def test_vectorize(capture):
my_func(x:int=5, y:float=3, z:float=2) my_func(x:int=5, y:float=3, z:float=2)
my_func(x:int=6, y:float=3, z:float=2) my_func(x:int=6, y:float=3, z:float=2)
""" """
with capture:
a, b, c = np.array([[1, 2, 3], [4, 5, 6]], order='F'), np.array([[2], [3]]), 2
assert np.allclose(f(a, b, c), a * b * c)
assert capture == """
my_func(x:int=1, y:float=2, z:float=2)
my_func(x:int=2, y:float=2, z:float=2)
my_func(x:int=3, y:float=2, z:float=2)
my_func(x:int=4, y:float=3, z:float=2)
my_func(x:int=5, y:float=3, z:float=2)
my_func(x:int=6, y:float=3, z:float=2)
"""
with capture:
a, b, c = np.array([[1, 2, 3], [4, 5, 6]])[::, ::2], np.array([[2], [3]]), 2
assert np.allclose(f(a, b, c), a * b * c)
assert capture == """
my_func(x:int=1, y:float=2, z:float=2)
my_func(x:int=3, y:float=2, z:float=2)
my_func(x:int=4, y:float=3, z:float=2)
my_func(x:int=6, y:float=3, z:float=2)
"""
with capture:
a, b, c = np.array([[1, 2, 3], [4, 5, 6]], order='F')[::, ::2], np.array([[2], [3]]), 2
assert np.allclose(f(a, b, c), a * b * c)
assert capture == """
my_func(x:int=1, y:float=2, z:float=2)
my_func(x:int=3, y:float=2, z:float=2)
my_func(x:int=4, y:float=3, z:float=2)
my_func(x:int=6, y:float=3, z:float=2)
"""
def test_type_selection(): def test_type_selection():
@ -73,3 +102,32 @@ def test_docs(doc):
assert doc(vectorized_func) == """ assert doc(vectorized_func) == """
vectorized_func(arg0: numpy.ndarray[int32], arg1: numpy.ndarray[float32], arg2: numpy.ndarray[float64]) -> object vectorized_func(arg0: numpy.ndarray[int32], arg1: numpy.ndarray[float32], arg2: numpy.ndarray[float64]) -> object
""" # noqa: E501 line too long """ # noqa: E501 line too long
def test_trivial_broadcasting():
from pybind11_tests import vectorized_is_trivial
assert vectorized_is_trivial(1, 2, 3)
assert vectorized_is_trivial(np.array(1), np.array(2), 3)
assert vectorized_is_trivial(np.array([1, 3]), np.array([2, 4]), 3)
assert vectorized_is_trivial(
np.array([[1, 3, 5], [7, 9, 11]]), np.array([[2, 4, 6], [8, 10, 12]]), 3)
assert not vectorized_is_trivial(
np.array([[1, 2, 3], [4, 5, 6]]), np.array([2, 3, 4]), 2)
assert not vectorized_is_trivial(
np.array([[1, 2, 3], [4, 5, 6]]), np.array([[2], [3]]), 2)
z1 = np.array([[1, 2, 3, 4], [5, 6, 7, 8]], dtype='int32')
z2 = np.array(z1, dtype='float32')
z3 = np.array(z1, dtype='float64')
assert vectorized_is_trivial(z1, z2, z3)
assert not vectorized_is_trivial(z1[::2, ::2], 1, 1)
assert vectorized_is_trivial(1, 1, z1[::2, ::2])
assert not vectorized_is_trivial(1, 1, z3[::2, ::2])
assert vectorized_is_trivial(z1, 1, z3[1::4, 1::4])
y1 = np.array(z1, order='F')
y2 = np.array(y1)
y3 = np.array(y1)
assert not vectorized_is_trivial(y1, y2, y3)
assert not vectorized_is_trivial(y1, z2, z3)
assert not vectorized_is_trivial(y1, 1, 1)