nac3/nac3core/irrt/irrt_numpy_ndarray.hpp

#pragma once

#include "irrt_utils.hpp"
#include "irrt_typedefs.hpp"
#include "irrt_slice.hpp"

/*
    NDArray-related implementations.
`*/

// NDArray indices are always `uint32_t`.
using NDIndex = uint32_t;

namespace {
    namespace ndarray_util {
        // Compute the strides of an ndarray given an ndarray `shape`
        // and assuming that the ndarray is *fully C-contagious*.
        //
        // You might want to read up on https://ajcr.net/stride-guide-part-1/.
        template <typename SizeT>
        static void set_strides_by_shape(SizeT ndims, SizeT* dst_strides, const SizeT* shape) {
            SizeT stride_product = 1;
            for (SizeT i = 0; i < ndims; i++) {
                int dim_i = ndims - i - 1;
                dst_strides[dim_i] = stride_product;
                stride_product *= shape[dim_i];
            }
        }

        // Compute the size/# of elements of an ndarray given its shape
        template <typename SizeT>
        static SizeT calc_size_from_shape(SizeT ndims, const SizeT* shape) {
            SizeT size = 1;
            for (SizeT dim_i = 0; dim_i < ndims; dim_i++) size *= shape[dim_i];
            return size;
        }
    }

    typedef uint8_t NDSliceType;
    extern "C" {
        const NDSliceType INPUT_SLICE_TYPE_INTEGER = 0;
        const NDSliceType INPUT_SLICE_TYPE_SLICE = 1;
    }

    struct NDSlice {
        NDSliceType type;

        /*
            type = INPUT_SLICE_TYPE_INTEGER => `slice` points to a single `SizeT`
            type = INPUT_SLICE_TYPE_SLICE => `slice` points to a single `NDSliceRange`
        */
        uint8_t *slice;
    };

    template<typename SizeT>
    SizeT deduce_ndims_after_slicing(SizeT ndims, const SizeT num_slices, const NDSlice *slices) {
        nac3_assert(num_slices <= ndims);

        SizeT final_ndims = ndims;
        for (SizeT i = 0; i < num_slices; i++) {
            if (slices[i].type == INPUT_SLICE_TYPE_INTEGER) {
                final_ndims--; // An integer slice demotes the rank by 1
            }
        }
        return final_ndims;
    }

    template <typename SizeT>
    struct NDArrayIndicesIter {
        SizeT ndims;
        const SizeT *shape;
        SizeT *indices;

        void set_indices_zero() {
            __builtin_memset(indices, 0, sizeof(SizeT) * ndims);
        }

        void next() {
            for (SizeT i = 0; i < ndims; i++) {
                SizeT dim_i = ndims - i - 1;

                indices[dim_i]++;
                if (indices[dim_i] < shape[dim_i]) {
                    break;
                } else {
                    indices[dim_i] = 0;
                }
            }
        }
    };

    // The NDArray object. `SizeT` is the *signed* size type of this ndarray.
    //
    // NOTE: The order of fields is IMPORTANT. DON'T TOUCH IT
    //
    // Some resources you might find helpful:
    // - The official numpy implementations:
    //   - https://github.com/numpy/numpy/blob/735a477f0bc2b5b84d0e72d92f224bde78d4e069/doc/source/reference/c-api/types-and-structures.rst
    // - On strides (about reshaping, slicing, C-contagiousness, etc)
    //   - https://ajcr.net/stride-guide-part-1/.
    //   - https://ajcr.net/stride-guide-part-2/.
    //   - https://ajcr.net/stride-guide-part-3/.
    template <typename SizeT>
    struct NDArray {
        // The underlying data this `ndarray` is pointing to.
        //
        // NOTE: Formally this should be of type `void *`, but clang
        // translates `void *` to `i8 *` when run with `-S -emit-llvm`,
        // so we will put `uint8_t *` here for clarity.
        uint8_t *data;

        // The number of bytes of a single element in `data`.
        //
        // The `SizeT` is treated as `unsigned`.
        SizeT itemsize;

        // The number of dimensions of this shape.
        //
        // The `SizeT` is treated as `unsigned`.
        SizeT ndims;

        // Array shape, with length equal to `ndims`.
        //
        // The `SizeT` is treated as `unsigned`.
        //
        // NOTE: `shape` can contain 0.
        //   (those appear when the user makes an out of bounds slice into an ndarray, e.g., `np.zeros((3, 3))[400:].shape == (0, 3)`)
        SizeT *shape;

        // Array strides (stride value is in number of bytes, NOT number of elements), with length equal to `ndims`.
        //
        // The `SizeT` is treated as `signed`.
        //
        // NOTE: `strides` can have negative numbers.
        //   (those appear when there is a slice with a negative step, e.g., `my_array[::-1]`)
        SizeT *strides;

        // Calculate the size/# of elements of an `ndarray`.
        // This function corresponds to `np.size(<ndarray>)` or `ndarray.size`
        SizeT size() {
            return ndarray_util::calc_size_from_shape(ndims, shape);
        }

        // Calculate the number of bytes of its content of an `ndarray` *in its view*.
        // This function corresponds to `ndarray.nbytes`
        SizeT nbytes() {
            return this->size() * itemsize;
        }

        void set_value_at_pelement(uint8_t* pelement, uint8_t* pvalue) {
            __builtin_memcpy(pelement, pvalue, itemsize);
        }

        uint8_t* get_pelement(SizeT *indices) {
            uint8_t* element = data;
            for (SizeT dim_i = 0; dim_i < ndims; dim_i++)
                element += indices[dim_i] * strides[dim_i] * itemsize;
            return element;
        }

        // Is the given `indices` valid/in-bounds?
        bool in_bounds(SizeT *indices) {
            for (SizeT dim_i = 0; dim_i < ndims; dim_i++) {
                bool dim_ok = indices[dim_i] < shape[dim_i];
                if (!dim_ok) return false;
            }
            return true;
        }

        // Fill the ndarray with a value
        void fill_generic(uint8_t* pvalue) {
            NDArrayIndicesIter<SizeT> iter;
            iter.ndims = this->ndims;
            iter.shape = this->shape;
            iter.indices = (SizeT*) __builtin_alloca(sizeof(SizeT) * ndims);
            iter.set_indices_zero();

            for (SizeT i = 0; i < this->size(); i++, iter.next()) {
                uint8_t* pelement = get_pelement(iter.indices);
                set_value_at_pelement(pelement, pvalue);
            }
        }

        // Set the strides of the ndarray with `ndarray_util::set_strides_by_shape`
        void set_strides_by_shape() {
            ndarray_util::set_strides_by_shape(ndims, strides, shape);
        }

        // https://numpy.org/doc/stable/reference/generated/numpy.eye.html
        void set_to_eye(SizeT k, uint8_t* zero_pvalue, uint8_t* one_pvalue) {
            __builtin_assume(ndims == 2);

            // TODO: Better implementation

            fill_generic(zero_pvalue);
            for (SizeT i = 0; i < min(shape[0], shape[1]); i++) {
                SizeT row = i;
                SizeT col = i + k;
                SizeT indices[2] = { row, col };

                if (!in_bounds(indices)) continue;

                uint8_t* pelement = get_pelement(indices);
                set_value_at_pelement(pelement, one_pvalue);
            }
        }

        // To support numpy complex slices (e.g., `my_array[:50:2,4,:2:-1]`)
        void slice(SizeT num_slices, NDSlice* slices, NDArray<SizeT>*dst_ndarray) {
            // It is assumed that `dst_ndarray` is allocated by the caller and
            // has the correct `ndims`.
            nac3_assert(dst_ndarray->ndims == deduce_ndims_after_slicing(this->ndims, num_slices, slices));

            SizeT this_axis = 0;
            SizeT guest_axis = 0;
            // for () {
            // }
        }
    };
}

extern "C" {
    uint32_t __nac3_ndarray_size(NDArray<int32_t>* ndarray) {
        return ndarray->size();
    }

    uint64_t __nac3_ndarray_size64(NDArray<int64_t>* ndarray) {
        return ndarray->size();
    }

    void __nac3_ndarray_fill_generic(NDArray<int32_t>* ndarray, uint8_t* pvalue) {
        ndarray->fill_generic(pvalue);
    }

    void __nac3_ndarray_fill_generic64(NDArray<int64_t>* ndarray, uint8_t* pvalue) {
        ndarray->fill_generic(pvalue);
    }

    // void __nac3_ndarray_slice(NDArray<int32_t>* ndarray, int32_t num_slices, NDSlice<int32_t> *slices, NDArray<int32_t> *dst_ndarray) {
    //     // ndarray->slice(num_slices, slices, dst_ndarray);
    // }
}
core: more irrt 2024-07-10 11:56:31 +08:00			`#pragma once`

			`#include "irrt_utils.hpp"`
			`#include "irrt_typedefs.hpp"`
			`#include "irrt_slice.hpp"`

			`/*`
			`NDArray-related implementations.`
			`*/

			// NDArray indices are always `uint32_t`.
			`using NDIndex = uint32_t;`

			`namespace {`
			`namespace ndarray_util {`
			// Compute the strides of an ndarray given an ndarray `shape`
			`// and assuming that the ndarray is fully C-contagious.`
			`//`
			`// You might want to read up on https://ajcr.net/stride-guide-part-1/.`
			`template <typename SizeT>`
			`static void set_strides_by_shape(SizeT ndims, SizeT* dst_strides, const SizeT* shape) {`
			`SizeT stride_product = 1;`
			`for (SizeT i = 0; i < ndims; i++) {`
			`int dim_i = ndims - i - 1;`
			`dst_strides[dim_i] = stride_product;`
			`stride_product *= shape[dim_i];`
			`}`
			`}`

			`// Compute the size/# of elements of an ndarray given its shape`
			`template <typename SizeT>`
			`static SizeT calc_size_from_shape(SizeT ndims, const SizeT* shape) {`
			`SizeT size = 1;`
			`for (SizeT dim_i = 0; dim_i < ndims; dim_i++) size *= shape[dim_i];`
			`return size;`
			`}`
			`}`

			`typedef uint8_t NDSliceType;`
			`extern "C" {`
			`const NDSliceType INPUT_SLICE_TYPE_INTEGER = 0;`
			`const NDSliceType INPUT_SLICE_TYPE_SLICE = 1;`
			`}`

			`struct NDSlice {`
			`NDSliceType type;`

			`/*`
			type = INPUT_SLICE_TYPE_INTEGER => `slice` points to a single `SizeT`
			type = INPUT_SLICE_TYPE_SLICE => `slice` points to a single `NDSliceRange`
			`*/`
			`uint8_t *slice;`
			`};`

			`template<typename SizeT>`
			`SizeT deduce_ndims_after_slicing(SizeT ndims, const SizeT num_slices, const NDSlice *slices) {`
			`nac3_assert(num_slices <= ndims);`

			`SizeT final_ndims = ndims;`
			`for (SizeT i = 0; i < num_slices; i++) {`
			`if (slices[i].type == INPUT_SLICE_TYPE_INTEGER) {`
			`final_ndims--; // An integer slice demotes the rank by 1`
			`}`
			`}`
			`return final_ndims;`
			`}`

			`template <typename SizeT>`
			`struct NDArrayIndicesIter {`
			`SizeT ndims;`
			`const SizeT *shape;`
			`SizeT *indices;`

			`void set_indices_zero() {`
			`__builtin_memset(indices, 0, sizeof(SizeT) * ndims);`
			`}`

			`void next() {`
			`for (SizeT i = 0; i < ndims; i++) {`
			`SizeT dim_i = ndims - i - 1;`

			`indices[dim_i]++;`
			`if (indices[dim_i] < shape[dim_i]) {`
			`break;`
			`} else {`
			`indices[dim_i] = 0;`
			`}`
			`}`
			`}`
			`};`

			// The NDArray object. `SizeT` is the signed size type of this ndarray.
			`//`
			`// NOTE: The order of fields is IMPORTANT. DON'T TOUCH IT`
			`//`
			`// Some resources you might find helpful:`
			`// - The official numpy implementations:`
			`// - https://github.com/numpy/numpy/blob/735a477f0bc2b5b84d0e72d92f224bde78d4e069/doc/source/reference/c-api/types-and-structures.rst`
			`// - On strides (about reshaping, slicing, C-contagiousness, etc)`
			`// - https://ajcr.net/stride-guide-part-1/.`
			`// - https://ajcr.net/stride-guide-part-2/.`
			`// - https://ajcr.net/stride-guide-part-3/.`
			`template <typename SizeT>`
			`struct NDArray {`
			// The underlying data this `ndarray` is pointing to.
			`//`
			// NOTE: Formally this should be of type `void *`, but clang
			// translates `void ` to `i8 ` when run with `-S -emit-llvm`,
			// so we will put `uint8_t *` here for clarity.
			`uint8_t *data;`

			// The number of bytes of a single element in `data`.
			`//`
			// The `SizeT` is treated as `unsigned`.
			`SizeT itemsize;`

			`// The number of dimensions of this shape.`
			`//`
			// The `SizeT` is treated as `unsigned`.
			`SizeT ndims;`

			// Array shape, with length equal to `ndims`.
			`//`
			// The `SizeT` is treated as `unsigned`.
			`//`
			// NOTE: `shape` can contain 0.
			// (those appear when the user makes an out of bounds slice into an ndarray, e.g., `np.zeros((3, 3))[400:].shape == (0, 3)`)
			`SizeT *shape;`

			// Array strides (stride value is in number of bytes, NOT number of elements), with length equal to `ndims`.
			`//`
			// The `SizeT` is treated as `signed`.
			`//`
			// NOTE: `strides` can have negative numbers.
			// (those appear when there is a slice with a negative step, e.g., `my_array[::-1]`)
			`SizeT *strides;`

			// Calculate the size/# of elements of an `ndarray`.
			// This function corresponds to `np.size(<ndarray>)` or `ndarray.size`
			`SizeT size() {`
			`return ndarray_util::calc_size_from_shape(ndims, shape);`
			`}`

			// Calculate the number of bytes of its content of an `ndarray` in its view.
			// This function corresponds to `ndarray.nbytes`
			`SizeT nbytes() {`
			`return this->size() * itemsize;`
			`}`

			`void set_value_at_pelement(uint8_t* pelement, uint8_t* pvalue) {`
			`__builtin_memcpy(pelement, pvalue, itemsize);`
			`}`

			`uint8_t* get_pelement(SizeT *indices) {`
			`uint8_t* element = data;`
			`for (SizeT dim_i = 0; dim_i < ndims; dim_i++)`
			`element += indices[dim_i] * strides[dim_i] * itemsize;`
			`return element;`
			`}`

			// Is the given `indices` valid/in-bounds?
			`bool in_bounds(SizeT *indices) {`
			`for (SizeT dim_i = 0; dim_i < ndims; dim_i++) {`
			`bool dim_ok = indices[dim_i] < shape[dim_i];`
			`if (!dim_ok) return false;`
			`}`
			`return true;`
			`}`

			`// Fill the ndarray with a value`
			`void fill_generic(uint8_t* pvalue) {`
			`NDArrayIndicesIter<SizeT> iter;`
			`iter.ndims = this->ndims;`
			`iter.shape = this->shape;`
			`iter.indices = (SizeT) __builtin_alloca(sizeof(SizeT) ndims);`
			`iter.set_indices_zero();`

			`for (SizeT i = 0; i < this->size(); i++, iter.next()) {`
			`uint8_t* pelement = get_pelement(iter.indices);`
			`set_value_at_pelement(pelement, pvalue);`
			`}`
			`}`

			// Set the strides of the ndarray with `ndarray_util::set_strides_by_shape`
			`void set_strides_by_shape() {`
			`ndarray_util::set_strides_by_shape(ndims, strides, shape);`
			`}`

			`// https://numpy.org/doc/stable/reference/generated/numpy.eye.html`
			`void set_to_eye(SizeT k, uint8_t* zero_pvalue, uint8_t* one_pvalue) {`
			`__builtin_assume(ndims == 2);`

			`// TODO: Better implementation`

			`fill_generic(zero_pvalue);`
			`for (SizeT i = 0; i < min(shape[0], shape[1]); i++) {`
			`SizeT row = i;`
			`SizeT col = i + k;`
			`SizeT indices[2] = { row, col };`

			`if (!in_bounds(indices)) continue;`

			`uint8_t* pelement = get_pelement(indices);`
			`set_value_at_pelement(pelement, one_pvalue);`
			`}`
			`}`

			// To support numpy complex slices (e.g., `my_array[:50:2,4,:2:-1]`)
			`void slice(SizeT num_slices, NDSlice* slices, NDArray<SizeT>*dst_ndarray) {`
			// It is assumed that `dst_ndarray` is allocated by the caller and
			// has the correct `ndims`.
			`nac3_assert(dst_ndarray->ndims == deduce_ndims_after_slicing(this->ndims, num_slices, slices));`

			`SizeT this_axis = 0;`
			`SizeT guest_axis = 0;`
			`// for () {`
			`// }`
			`}`
			`};`
			`}`

			`extern "C" {`
			`uint32_t __nac3_ndarray_size(NDArray<int32_t>* ndarray) {`
			`return ndarray->size();`
			`}`

			`uint64_t __nac3_ndarray_size64(NDArray<int64_t>* ndarray) {`
			`return ndarray->size();`
			`}`

			`void __nac3_ndarray_fill_generic(NDArray<int32_t>* ndarray, uint8_t* pvalue) {`
			`ndarray->fill_generic(pvalue);`
			`}`

			`void __nac3_ndarray_fill_generic64(NDArray<int64_t>* ndarray, uint8_t* pvalue) {`
			`ndarray->fill_generic(pvalue);`
			`}`

			`// void __nac3_ndarray_slice(NDArray<int32_t>* ndarray, int32_t num_slices, NDSlice<int32_t> slices, NDArray<int32_t> dst_ndarray) {`
			`// // ndarray->slice(num_slices, slices, dst_ndarray);`
			`// }`
			`}`