Module: TensorStream::OpenCLHelpers::MathOps

Included in:

Evaluator::OpenclEvaluator

Defined in:

lib/tensor_stream/opencl/math_ops.rb

Overview

Collection of math functions for interfacing with OpenCL kernels

Class Method Summary

• .included(klass) ⇒ Object

Class Method Details

.included(klass) ⇒ Object

# File 'lib/tensor_stream/opencl/math_ops.rb', line 5

def MathOps.included(klass)
  klass.class_eval do
    %i[max min add real_div div sub floor_mod mod mul pow sigmoid_grad squared_difference].each do |op|
      register_op op do |_context, tensor, inputs|
        execute_2_operand_func(op.to_s, tensor, inputs[0], inputs[1])
      end
    end

    register_op :add_n do |_context, tensor, inputs|
      if inputs.size == 1
        inputs[0]
      else
        work_group = if inputs[0].shape.size > 2
                       [ inputs[0].shape.reduce(:*) / inputs[0].shape.last, inputs[0].shape.last]
                     else
                       m, n = inputs[0].shape
                       [m || 1, n || 1]
                     end

        cl_m = OpenCL::Int1.new(work_group[0])
        cl_n = OpenCL::Int1.new(work_group[1])
        cl_switch = OpenCL::Int1.new(0)
        dtype = tensor.data_type

        output_buffer = _create_result_buffer(tensor.data_type, inputs[0].shape, "out_#{tensor.name}")
        inputs_queue = inputs.dup
        a = inputs_queue.pop
        until inputs_queue.empty?
          b = inputs_queue.pop
          event_wait_list = build_event_wait_list([a, b])
          method_call = :"add_#{a.data_type}_#{b.data_type}"
          event = _cl_program('add', a: a.data_type, b: b.data_type, dtype: dtype).send(method_call, _opencl_queue, work_group, cl_m, cl_n, cl_switch, a.cl_buffer, b.cl_buffer, output_buffer.cl_buffer, event_wait_list: event_wait_list)
          a = output_buffer
          a.op = event
        end

        output_buffer.op = a.op
        output_buffer
      end
    end

    register_op :floor_div do |context, tensor, inputs|
      if fp_type?(tensor.data_type)
        execute_2_operand_func('floor_div', tensor, inputs[0], inputs[1])
      else
        execute_2_operand_func('div', tensor, inputs[0], inputs[1])
      end
    end

    register_op :mat_mul do |_context, tensor, inputs|
      a, b = inputs

      a_matrix_shape = a.shape.dup
      b_matrix_shape = b.shape.dup

      k = a_matrix_shape.pop
      m = a_matrix_shape.pop
      n = b_matrix_shape.pop
      v = b_matrix_shape.pop

      if tensor.options[:transpose_a]
        m, k = k, m
      end

      if tensor.options[:transpose_b]
        n, v = v, n
      end

      result_shape = [a_matrix_shape.first, m, n].compact
      work_group = [a_matrix_shape.first || 1, m, n]

      raise "#{tensor.inputs[0].name} rank must be greater than 1" if a.shape.size < 2
      raise "#{tensor.inputs[1].name} rank must be greater than 1" if b.shape.size < 2
      raise "#{tensor.inputs[0].name} unsupported rank" if b.shape.size > 3 || a.shape.size > 3
      raise "incompatible shape sizes for matrix multiplication (#{a.shape[1]} != #{b.shape[0]}) #{a.shape} vs #{b.shape}" if k != v

      dtype = tensor.data_type
      a, b = auto_type_cast(a, b, name: "#{tensor.name}/cast_#{a.name}_#{b.data_type}")
      output_buffer = _create_result_buffer(a.data_type, result_shape, tensor.name)

      cl_m = OpenCL::Int1.new(m)
      cl_n = OpenCL::Int1.new(n)
      cl_k = OpenCL::Int1.new(k)

      event_wait_list = build_event_wait_list([a, b])
      output_buffer.op = _cl_program('gemm', ta: !!tensor.options[:transpose_a], tb: !!tensor.options[:transpose_b], n: m * n, n_a: m * k, n_b: n * v, dtype: dtype).send(:"gemm_#{dtype}", _opencl_queue, work_group, cl_m, cl_n, cl_k, a.cl_buffer, b.cl_buffer, output_buffer.cl_buffer, event_wait_list: event_wait_list)

      output_buffer
    end

    register_op :bias_add do |context, tensor, inputs|
      value, bias = inputs
      output_buffer = _create_result_buffer(value.data_type, value.shape, tensor.name)
      result_shape = value.shape.dup
      bias_length = result_shape.pop
      work_group = [result_shape.reduce(:*)]
      event_wait_list = build_event_wait_list([value, bias])
      dtype = tensor.data_type
      output_buffer.op = _cl_program('bias_add', n: bias_length, dtype: dtype)
        .send(:"bias_add_#{dtype}", _opencl_queue, work_group, value.cl_buffer,
              bias.cl_buffer, output_buffer.cl_buffer, event_wait_list: event_wait_list)
      output_buffer
    end

    register_op :bias_add_grad do |context, tensor, inputs|
      received_grad = inputs[0]
      bias_size = received_grad.shape.last
      output_buffer = _create_result_buffer(received_grad.data_type, [bias_size], tensor.name)
      work_group = [bias_size]

      received_grad_shape = received_grad.shape.dup
      received_grad_shape.pop
      item_rows = received_grad_shape.reduce(:*)
      dtype = tensor.data_type
      output_buffer.op = _cl_program('bias_add_grad', n: bias_size, rows: item_rows, dtype: dtype)
        .send(:"bias_add_grad_#{dtype}", _opencl_queue, work_group, received_grad.cl_buffer,
              output_buffer.cl_buffer, event_wait_list: build_event_wait_list([received_grad]))
      output_buffer
    end

    %i[sign exp tan acos asin sin cos abs sqrt negate square reciprocal tanh tanh_grad sigmoid log1p round floor ceil log].each do |op|
      register_op op, noop: true do |context, tensor, inputs|
        execute_func(op.to_s, tensor, inputs[0], context)
      end
    end

    %i[sum mean].each do |op|
      register_op op do |context, tensor, inputs|
        reduction(context, tensor, inputs[0], inputs[1], op.to_sym)
      end
    end

    register_op :prod do |context, tensor, inputs|
      if inputs[0].shape == [0]
        convert_to_opencl([1.0], [], data_type: inputs[0].data_type, name: tensor.name)
      else
        reduction(context, tensor, inputs[0], inputs[1], :prod)
      end
    end

    %i[argmin argmax].each do |op|
      register_op op do |context, tensor, inputs|
        value, axis = inputs
        rank = value.shape.size
        axis = 0 if axis.nil?

        axis = axis.is_a?(OpenCLBuffer) ? read_final_result(axis) : axis
        raise TensorStream::InvalidArgumentError, "Expected dimension in the range [#{-rank},#{rank}) but got #{axis}" if axis < -rank || axis >= rank

        reduce_multi_axis(context, tensor, value, axis, 'arg', op.to_sym)
       end
    end

    def reduction(child_context, tensor, value, axis, func)
      if axis.nil?
        value = _run(value, child_context)
        size = value.shape.reduce(:*) || 1
        if value.shape.empty? # for scalars, just return as is
          value
        else
          reduction_threads = 32
          items_per_thread_threshold = 4

          output_buffer = _create_result_buffer(value.data_type, [], tensor.name)
          event_wait_list = build_event_wait_list([value])

          if (size > reduction_threads) && ((size / reduction_threads) > items_per_thread_threshold)
            items_per_thread = size / reduction_threads
            extra_items = size % reduction_threads
            intermediate_output_buffer = _create_result_buffer(value.data_type, [reduction_threads], tensor.name)

            temp_values = if extra_items.zero?
                            _cl_program(func, dtype: value.data_type, index: 0, n: items_per_thread, w: items_per_thread).
                              send(:"#{func}_#{value.data_type}", _opencl_queue, [reduction_threads], value.cl_buffer, intermediate_output_buffer.cl_buffer, event_wait_list: event_wait_list)
                          else
                            [_cl_program(func, dtype: value.data_type, index: 0, n: items_per_thread, w: items_per_thread).
                              send(:"#{func}_#{value.data_type}", _opencl_queue, [reduction_threads - 1], value.cl_buffer, intermediate_output_buffer.cl_buffer, event_wait_list: event_wait_list),
                            _cl_program(func, dtype: value.data_type, index: reduction_threads - 1, n: items_per_thread + extra_items,  w: items_per_thread).send(:"#{func}_#{value.data_type}", _opencl_queue, [1], value.cl_buffer, intermediate_output_buffer.cl_buffer, event_wait_list: event_wait_list)]
                          end
            output_buffer.op = _cl_program(func, dtype: value.data_type, n: reduction_threads, index: 0, w: 0).send(:"#{func}_#{value.data_type}", _opencl_queue, [1], value.cl_buffer, output_buffer.cl_buffer, event_wait_list: temp_values)
            output_buffer
          else
            output_buffer.op = _cl_program(func, dtype: value.data_type, n: size, index: 0, w: 0).send(:"#{func}_#{value.data_type}", _opencl_queue, [1], value.cl_buffer, output_buffer.cl_buffer, event_wait_list: event_wait_list)
            output_buffer
          end
         end
      else
        reduce_multi_axis(child_context, tensor, value, axis, 'reduce', func)
      end
    end

    def reduce_multi_axis(child_context, tensor, value, axis, prog, func)
      return value if value.shape.empty?

      rank = value.shape.size

      axis = axis.is_a?(OpenCLBuffer) ? read_final_result(axis) : axis
      axis = [axis] unless axis.is_a?(Array)
      return value if axis.empty?
      # remap negative values
      axis.map! { |axis| axis < 0 ? rank - axis.abs : axis }

      new_shape = value.shape.collect.with_index { |v, index| axis.include?(index) ? nil : v }.compact

      buffer_shape = tensor.options[:keepdims] ? _reduced_shape(value.shape.dup, axis) : new_shape
      output_buffer = _create_result_buffer(tensor.options[:output_type] || tensor.data_type, buffer_shape, tensor.name)

      work_group = new_shape.empty? ? [1] : new_shape
      dtype = value.data_type

      output_buffer.op = _cl_program("#{prog}_axis", f: func, axis: axis, shape: value.shape, o_shape: new_shape, dtype: dtype, out_dtype: tensor.options[:output_type])
          .send("#{prog}_axis_#{dtype}", _opencl_queue, work_group, value.cl_buffer,
                output_buffer.cl_buffer, event_wait_list: build_event_wait_list([value]))

      output_buffer
    end
  end
end