feat(mge/opr): add meshgrid opr

GitOrigin-RevId: 6f703295be
2 years ago · d3b2b51918
--- a/imperative/python/megengine/functional/tensor.py
+++ b/imperative/python/megengine/functional/tensor.py
@@ -1,6 +1,6 @@
 # -*- coding: utf-8 -*-
 from functools import lru_cache
 from typing import Iterable, Optional, Sequence, Tuple, Union
 from typing import Iterable, List, Optional, Sequence, Tuple, Union
 import numpy as np
@@ -36,6 +36,7 @@ __all__ = [
    "full_like",
    "gather",
    "linspace",
    "meshgrid",
    "ones",
    "ones_like",
    "repeat",
@@ -1205,3 +1206,49 @@ def cumsum(inp: Tensor, axis: int):
    assert isinstance(inp, Tensor), "input of cumsum must be type of Tensor"
    op = builtin.Cumsum(axis=axis, exclusive=False, reverse=False)
    return apply(op, inp)[0]
 def meshgrid(*inputs: Tensor, indexing: str = "xy") -> List[Tensor]:
    r"""Returns coordinate matrices from coordinate vectors.
    Args:
        inputs: an arbitrary number of one-dimensional tensors representing grid 
            coordinates. Each input should have the same numeric data type.
        indexing:  Cartesian ``'xy'`` or matrix ``'ij'`` indexing of output. 
            If provided zero or one one-dimensional vector(s) (i.e., the zero- and one-dimensional 
            cases, respectively), the indexing keyword has no effect and should be ignored.
    Returns:
        out: list of N tensors, where N is the number of provided one-dimensional input tensors. 
            Each returned tensor must have rank N. For N one-dimensional tensors having lengths ``Ni = len(xi)``, 
            * if matrix indexing ``ij``, then each returned tensor must have the shape ``(N1, N2, N3, ..., Nn)``.
            * if Cartesian indexing ``xy``, then each returned tensor must have shape ``(N2, N1, N3, ..., Nn)``.
            Accordingly, for the two-dimensional case with input one-dimensional tensors of length ``M`` and ``N``, 
            if matrix indexing ``ij``, then each returned tensor must have shape ``(M, N)``, and, if Cartesian indexing ``xy``, 
            then each returned tensor must have shape ``(N, M)``.
            Similarly, for the three-dimensional case with input one-dimensional tensor of length ``M``, ``N``, and ``P``, 
            if matrix indexing  ``ij``, then each returned tensor must have shape ``(M, N, P)``, and, if Cartesian indexing ``xy``, 
            then each returned tensor must have shape ``(N, M, P)``.
            Each returned tensor should have the same data type as the input tensors.
    Examples:
        >>> nx, ny = (3, 2)
        >>> x = F.linspace(0, 1, nx)
        >>> y = F.linspace(0, 1, ny)
        >>> xv, yv = F.meshgrid(x, y)
        >>> xv
        Tensor([[0.  0.5 1. ]
        [0.  0.5 1. ]], device=xpux:0)        
        >>> yv
        Tensor([[0. 0. 0.]
        [1. 1. 1.]], device=xpux:0)
    """
    op = builtin.MeshGrid(indexing)
    return apply(op, *inputs)
--- a/imperative/src/impl/ops/broadcast.cpp
+++ b/imperative/src/impl/ops/broadcast.cpp
@@ -1,13 +1,129 @@
 #include <numeric>
 #include "megbrain/graph/helper.h"
 #include "megbrain/imperative/ops/autogen.h"
 #include "megbrain/opr/io.h"
 #include "megbrain/opr/tensor_manip.h"
 #include "megbrain/graph/helper.h"
 #include "../op_trait.h"
 namespace mgb {
 namespace imperative {
 namespace meshgrid {
 SmallVector<VarNode::LayoutConstraintCallback> get_input_layout_constraint(
        const OpDef& def, const SmallVector<TensorPtr>& inputs) {
    return SmallVector<VarNode::LayoutConstraintCallback>(inputs.size());
 }
 std::tuple<SmallVector<LogicalTensorDesc>, bool> infer_output_attrs_fallible(
        const OpDef& def, const SmallVector<LogicalTensorDesc>& inputs) {
    for (size_t i = 0; i < inputs.size() - 1; i++) {
        mgb_assert(inputs[i].layout.dtype == inputs[i + 1].layout.dtype);
        mgb_assert(inputs[i].comp_node == inputs[i + 1].comp_node);
    }
    auto&& op = def.cast_final_safe<MeshGrid>();
    mgb_assert(op.indexing == "xy" || op.indexing == "ij");
    bool success = true;
    SmallVector<size_t> shp;
    for (size_t i = 0; i < inputs.size(); i++) {
        mgb_assert(inputs[i].layout.ndim <= 1);
        if (inputs[i].layout.ndim == 0) {
            success = false;
        }
        shp.push_back(inputs[i].layout.total_nr_elems());
    }
    if (op.indexing == "xy" and shp.size() >= 2) {
        std::swap(shp[0], shp[1]);
    }
    TensorShape tshp(shp);
    SmallVector<LogicalTensorDesc> descs;
    for (size_t i = 0; i < inputs.size(); i++) {
        if (success) {
            descs.push_back(
                    {TensorLayout(tshp, inputs[0].layout.dtype), inputs[0].comp_node});
        } else {
            descs.push_back(
                    {TensorLayout(inputs[0].layout.dtype), inputs[0].comp_node});
        }
    }
    return {descs, success};
 }
 VarNodeArray apply_on_var_node(const OpDef& def, const VarNodeArray& inputs) {
    auto&& op = def.cast_final_safe<MeshGrid>();
    std::vector<size_t> indexs(inputs.size());
    std::iota(indexs.begin(), indexs.end(), 0);
    auto cn = inputs[0]->comp_node();
    auto graph = inputs[0]->owner_graph();
    if (op.indexing == "xy") {
        if (indexs.size() >= 2) {
            std::swap(indexs[0], indexs[1]);
        }
    } else {
        mgb_assert(op.indexing == "ij", "meshgrid only support \"ij\" or \"xy\"");
    }
    VarNodeArray shps;
    for (size_t ind = 0; ind < inputs.size(); ind++) {
        auto&& inp = inputs[indexs[ind]];
        shps.push_back(opr::GetVarShape::make(inp).node());
    }
    VarNode* tshp = opr::Concat::make(shps, 0, cn).node();
    VarNodeArray results;
    auto t_ndim = inputs.size();
    for (size_t ind = 0; ind < inputs.size(); ind++) {
        auto axis = indexs[ind];
        HostTensorND hv = HostTensorND(cn, {t_ndim}, dtype::Int32());
        auto* ptr = hv.ptr<dt_int32>();
        std::fill_n(ptr, t_ndim, 1);
        ptr[axis] = -1;
        auto shp = opr::ImmutableTensor::make(*graph, hv, cn).node();
        auto tmp = opr::Reshape::make(inputs[ind], shp, axis).node();
        results.push_back(opr::Broadcast::make(tmp, tshp).node());
    }
    return results;
 }
 SmallVector<TensorPtr> apply_on_physical_tensor(
        const OpDef& def, const SmallVector<TensorPtr>& inputs,
        SmallVector<LogicalTensorDesc>& output_descs, const bool& validated) {
    auto&& op = def.cast_final_safe<MeshGrid>();
    TensorShape tshp;
    TensorShape view_shp;
    tshp.ndim = inputs.size();
    view_shp.ndim = inputs.size();
    std::vector<size_t> indexs(inputs.size());
    std::iota(indexs.begin(), indexs.end(), 0);
    if (op.indexing == "xy") {
        if (indexs.size() >= 2) {
            std::swap(indexs[0], indexs[1]);
        }
    } else {
        mgb_assert(op.indexing == "ij", "meshgrid only support \"ij\" or \"xy\"");
    }
    for (size_t ind = 0; ind < inputs.size(); ind++) {
        auto&& inp = inputs[indexs[ind]];
        mgb_assert(inp->layout().ndim <= 1);
        tshp[ind] = inp->layout().total_nr_elems();
        view_shp[ind] = 1;
    }
    SmallVector<TensorPtr> grids;
    for (size_t i = 0; i < inputs.size(); i++) {
        auto&& src = inputs[i];
        TensorLayout layout;
        view_shp[indexs[i]] = src->layout().total_nr_elems();
        mgb_assert(src->layout().try_reshape(layout, view_shp));
        layout = layout.broadcast(tshp);
        view_shp[indexs[i]] = 1;
        grids.push_back(Tensor::make(src->blob(), src->offset(), layout));
    }
    return grids;
 }
 OP_TRAIT_REG(MeshGrid, MeshGrid)
        .apply_on_var_node(apply_on_var_node)
        .infer_output_attrs_fallible(infer_output_attrs_fallible)
        .apply_on_physical_tensor(apply_on_physical_tensor)
        .get_input_layout_constraint(get_input_layout_constraint)
        .fallback();
 }  // namespace meshgrid
 namespace broadcast {
 std::shared_ptr<OpDef> make_from_op_node(cg::OperatorNodeBase* node_) {
@@ -211,7 +327,6 @@ SmallVector<TensorPtr> apply_on_physical_tensor(
                tshp, tshp_nd->get_value().proxy_to_default_cpu());
    }
    if (op.axis != opr::Reshape::Param::INVALID_AXIS) {
        mgb_assert(tshp[op.axis] == -1);
        tshp[op.axis] = 1;
        tshp[op.axis] = src->layout().total_nr_elems() / tshp.total_nr_elems();
    }
@@ -237,7 +352,6 @@ SmallVector<VarNode::LayoutConstraintCallback> get_input_layout_constraint(
                    tshp, inputs[1]->get_value().proxy_to_default_cpu());
        }
        if (op.axis != opr::Reshape::Param::INVALID_AXIS) {
            mgb_assert(tshp[op.axis] == -1);
            tshp[op.axis] = 1;
            tshp[op.axis] = layout.total_nr_elems() / tshp.total_nr_elems();
        }
@@ -250,7 +364,7 @@ SmallVector<VarNode::LayoutConstraintCallback> get_input_layout_constraint(
    return layout_checker;
 }
 OP_TRAIT_REG(Reshape, Reshape)
 OP_TRAIT_REG(Reshape, Reshape, opr::Reshape)
        .apply_on_var_node(apply_on_var_node)
        .infer_output_attrs_fallible(infer_output_attrs_fallible)
        .apply_on_physical_tensor(apply_on_physical_tensor)
--- a/imperative/tablegen/generated/hash.txt
+++ b/imperative/tablegen/generated/hash.txt
@@ -1,7 +1,7 @@
 905bdf78e5413b06873be64b4ba55db9  ../../dnn/scripts/opr_param_defs.py
 e35e13523f43b7bea4034a0bf75937b7  ../../src/core/include/megbrain/ir/ops.td
 240dccd6f8d42cadfd08c6ca90fe61b1  generated/opdef.h.inl
 a79a4058ff18ffd9593ee5db3deef6c4  generated/opdef.cpp.inl
 83c179ee7416824fbfab978a097cd4d3  generated/opdef.py.inl
 86f70b1052331130f5e4c0ca53e68423  generated/opdef.cpy.inl
 40708c56b1f05fdb7d06cc097a300330  ../../src/core/include/megbrain/ir/ops.td
 9f3af118c7fe8d0c9db433825d5ad77b  generated/opdef.h.inl
 4041e44a8ba3cca3b3affa1ed9ed44a2  generated/opdef.cpp.inl
 319e1d170c989fe793a4e9c45decefc4  generated/opdef.py.inl
 26a18a7593566128ecce76e8f74dcc5d  generated/opdef.cpy.inl
 71e1462bf4d882e2615c3c632cb671cc  generated/enum_macro.h
--- a/imperative/tablegen/generated/opdef.cpp.inl
+++ b/imperative/tablegen/generated/opdef.cpp.inl
@@ -4672,6 +4672,43 @@ OP_TRAIT_REG(MatrixMul, MatrixMul)
    .props(MatrixMul_props_impl)
    .make_name(MatrixMul_make_name_impl);
 MGB_DYN_TYPE_OBJ_FINAL_IMPL(MeshGrid);
 namespace {
 size_t MeshGrid_hash_impl(const OpDef& def_) {
    auto&& op_ = def_.cast_final_safe<MeshGrid>();
    static_cast<void>(op_);
    size_t val = mgb::hash(op_.dyn_typeinfo());
    val = mgb::hash_pair_combine(val, mgb::hash(op_.indexing));
    return val;
 }
 bool MeshGrid_is_same_st_impl(const OpDef& lhs_, const OpDef& rhs_) {
    auto &&a_ = lhs_.cast_final_safe<MeshGrid>(),
         &&b_ = rhs_.cast_final_safe<MeshGrid>();
    static_cast<void>(a_);
    static_cast<void>(b_);
    if (a_.indexing != b_.indexing) return false;
    return true;
 }
 std::vector<std::pair<const char*, std::string>> MeshGrid_props_impl(const OpDef& def_) {
    auto&& op_ = def_.cast_final_safe<MeshGrid>();
    static_cast<void>(op_);
    std::vector<std::pair<const char*, std::string>> props_;
    props_.emplace_back("indexing", op_.indexing);
    return props_;
 }
 std::string MeshGrid_make_name_impl(const OpDef& def_) {
    auto&& op_ = def_.cast_final_safe<MeshGrid>();
    static_cast<void>(op_);
    return "MeshGrid";
 }
 } // anonymous namespace
 OP_TRAIT_REG(MeshGrid, MeshGrid)
    .hash(MeshGrid_hash_impl)
    .is_same_st(MeshGrid_is_same_st_impl)
    .props(MeshGrid_props_impl)
    .make_name(MeshGrid_make_name_impl);
 MGB_DYN_TYPE_OBJ_FINAL_IMPL(MeshIndexing);
 namespace {
--- a/imperative/tablegen/generated/opdef.cpy.inl
+++ b/imperative/tablegen/generated/opdef.cpy.inl
@@ -12467,6 +12467,95 @@ void _init_py_MatrixMul(py::module m) {
    mgb_assert(PyOp(OpDef)::ctype2pytype.emplace(MatrixMul::typeinfo(), &py_type).second);
 }
 PyOpDefBegin(MeshGrid) // {
    static PyGetSetDef py_getsetters[];
    static PyMethodDef tp_methods[];
    static PyObject* getstate(PyObject* self, PyObject*) {
        auto& opdef = reinterpret_cast<PyOp(MeshGrid)*>(self)->inst();
        static_cast<void>(opdef);
        std::unordered_map<std::string, py::object> state {
            {"indexing", serialization<decltype(opdef.indexing)>::dump(opdef.indexing)}
        };
        return py::cast(state).release().ptr();
    }
    static PyObject* setstate(PyObject* self, PyObject* args) {
        PyObject* dict = PyTuple_GetItem(args, 0);
        if (!dict) return NULL;
        auto state = py::cast<std::unordered_map<std::string, py::object>>(dict);
        auto& opdef = reinterpret_cast<PyOp(MeshGrid)*>(self)->inst();
        static_cast<void>(opdef);
        {
        auto&& iter = state.find("indexing");
        if (iter != state.end()) {
            opdef.indexing = serialization<decltype(opdef.indexing)>::load(iter->second);
        }
        }
        Py_RETURN_NONE;
    }
    static int py_init(PyObject *self, PyObject *args, PyObject *kwds);
 // };
 PyOpDefEnd(MeshGrid)
 int PyOp(MeshGrid)::py_init(PyObject *self, PyObject *args, PyObject *kwds) {
    static const char* kwlist[] = {"indexing", "scope", NULL};
    PyObject *indexing = NULL, *scope = NULL;
    if (!PyArg_ParseTupleAndKeywords(args, kwds, "|OO", const_cast<char**>(kwlist), &indexing, &scope))
    return -1;
    if (indexing) {
        try {
            // TODO: remove this guard which is used for pybind11 implicit conversion
            py::detail::loader_life_support guard{};
            reinterpret_cast<PyOp(MeshGrid)*>(self)->inst().indexing =
                    py::cast<decltype(MeshGrid::indexing)>(py::handle(indexing));
        } CATCH_ALL(-1)
    }
    if (scope) {
        try {
            reinterpret_cast<PyOp(OpDef)*>(self)->op
                ->set_scope(py::cast<std::string>(py::handle(scope)));
        } CATCH_ALL(-1)
    }
    return 0;
 }
 PyGetSetDef PyOp(MeshGrid)::py_getsetters[] = {
    {const_cast<char*>("indexing"), py_get_generic(MeshGrid, indexing), py_set_generic(MeshGrid, indexing), const_cast<char*>("indexing"), NULL},
    {NULL}  /* Sentinel */
 };
    PyMethodDef PyOp(MeshGrid)::tp_methods[] = {
        {const_cast<char*>("__getstate__"), PyOp(MeshGrid)::getstate, METH_NOARGS, "MeshGrid getstate"},
    {const_cast<char*>("__setstate__"), PyOp(MeshGrid)::setstate, METH_VARARGS, "MeshGrid setstate"},
        {NULL}  /* Sentinel */
    };
 void _init_py_MeshGrid(py::module m) {
    using py_op = PyOp(MeshGrid);
    auto& py_type = PyOpType(MeshGrid);
    py_type = {PyVarObject_HEAD_INIT(NULL, 0)};
    py_type.tp_name = "megengine.core._imperative_rt.ops.MeshGrid";
    py_type.tp_basicsize = sizeof(PyOp(MeshGrid));
    py_type.tp_flags = Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE;
    py_type.tp_doc = "MeshGrid";
    py_type.tp_base = &PyOpType(OpDef);
    py_type.tp_dealloc = py_dealloc_generic<py_op>;
    py_type.tp_new = py_new_generic<py_op>;
    py_type.tp_init = py_op::py_init;
    py_type.tp_methods = py_op::tp_methods;
    py_type.tp_getset = py_op::py_getsetters;
    mgb_assert(PyType_Ready(&py_type) >= 0);
    PyType_Modified(&py_type);
    m.add_object("MeshGrid", reinterpret_cast<PyObject*>(&py_type));
    mgb_assert(PyOp(OpDef)::ctype2pytype.emplace(MeshGrid::typeinfo(), &py_type).second);
 }
 PyOpDefBegin(MeshIndexing) // {
    static PyGetSetDef py_getsetters[];
    static PyMethodDef tp_methods[];
@@ -18594,6 +18683,7 @@ void _init_py_WarpPerspectiveBackwardMat(py::module m) {
    _init_py_MagicMindRuntime(m); \
    _init_py_MatrixInverse(m); \
    _init_py_MatrixMul(m); \
    _init_py_MeshGrid(m); \
    _init_py_MeshIndexing(m); \
    _init_py_NMSKeep(m); \
    _init_py_NvOf(m); \
--- a/imperative/tablegen/generated/opdef.h.inl
+++ b/imperative/tablegen/generated/opdef.h.inl
@@ -1262,6 +1262,15 @@ public:
    }
 };
 class MeshGrid : public OpDefImplBase<MeshGrid> {
    MGB_DYN_TYPE_OBJ_FINAL_DECL;
 public:
    std::string indexing;
    MeshGrid() = default;
    MeshGrid(std::string indexing_, std::string scope_ = {}): indexing(indexing_) { set_scope(scope_); }
 };
 class MeshIndexing : public OpDefImplBase<MeshIndexing> {
    MGB_DYN_TYPE_OBJ_FINAL_DECL;
--- a/imperative/tablegen/generated/opdef.py.inl
+++ b/imperative/tablegen/generated/opdef.py.inl
@@ -1365,6 +1365,13 @@ MatrixMulInst
    .def_readwrite("dimA", &MatrixMul::dimA)
    .def_readwrite("dimB", &MatrixMul::dimB);
 py::class_<MeshGrid, std::shared_ptr<MeshGrid>, OpDef> MeshGridInst(m, "MeshGrid");
 MeshGridInst
    .def(py::init<std::string, std::string>(), py::arg("indexing"), py::arg("scope") = {})
    .def(py::init<>())
    .def_readwrite("indexing", &MeshGrid::indexing);
 py::class_<MeshIndexing, std::shared_ptr<MeshIndexing>, OpDef> MeshIndexingInst(m, "MeshIndexing");
 MeshIndexingInst
--- a/src/core/include/megbrain/ir/ops.td
+++ b/src/core/include/megbrain/ir/ops.td
@@ -515,4 +515,9 @@ def Dropout: MgbHashableOp<"Dropout", [DropoutParam]> {
  let cmpFunction = [{return $0.handle == $1.handle && $0.drop_prob == $1.drop_prob;}];
 }
 def MeshGrid: MgbHashableOp<"MeshGrid"> {
  let extraArguments = (ins
  MgbStringAttr:$indexing
  );
 }
 #endif // MGB_OPS