#ifndef MIGRAPHX_GUARD_OPERATORS_ARGMIN_HPP #define MIGRAPHX_GUARD_OPERATORS_ARGMIN_HPP #include #include #include #include namespace migraphx { inline namespace MIGRAPHX_INLINE_NS { namespace op { struct argmin { int64_t axis = 0; template static auto reflect(Self& self, F f) { return pack(f(self.axis, "axis")); } std::string name() const { return "argmin"; } shape compute_shape(std::vector inputs) const { check_shapes{inputs, *this}.has(1).standard(); auto lens = inputs[0].lens(); int64_t n_dim = static_cast(lens.size()); if(axis >= n_dim || axis < 0) { MIGRAPHX_THROW("ARGMIN: axis is out of range."); } lens[axis] = 1; return {shape::int64_type, lens}; } template int64_t calc_argmin(T& input, std::vector& indices, size_t item_num) const { auto min_val = input(indices.begin(), indices.end()); int64_t min_index = 0; for(std::size_t i = 1; i < item_num; ++i) { indices[axis] = i; auto cur_val = input(indices.begin(), indices.end()); if(min_val > cur_val) { min_val = cur_val; min_index = i; } } return min_index; } argument compute(const shape& output_shape, std::vector args) const { argument result{output_shape}; std::size_t batch_item_num = args.front().get_shape().lens()[axis]; result.visit([&](auto output) { args[0].visit([&](auto input) { par_for(output_shape.elements(), [&](auto i) { auto data_idx = output_shape.multi(i); output[i] = this->calc_argmin(input, data_idx, batch_item_num); }); }); }); return result; } }; } // namespace op } // namespace MIGRAPHX_INLINE_NS } // namespace migraphx #endif