#!/usr/bin/env python # Copyright 2019 Google LLC # # This source code is licensed under the BSD-style license found in the # LICENSE file in the root directory of this source tree. import argparse import codecs import math import os import re import sys import yaml sys.path.insert(0, os.path.dirname(os.path.abspath(__file__))) from primes import next_prime import xngen import xnncommon parser = argparse.ArgumentParser(description='MaxPool microkernel test generator') parser.add_argument("-s", "--spec", metavar="FILE", required=True, help="Specification (YAML) file") parser.add_argument("-o", "--output", metavar="FILE", required=True, help='Output (C++ source) file') parser.set_defaults(defines=list()) def split_ukernel_name(name): match = re.fullmatch(r"xnn_(s8|u8|s16|f16|f32)_maxpool(_(minmax))?_ukernel_(\d+)p(\d+)x__(.+)_c(\d+)", name) if match is None: raise ValueError("Unexpected microkernel name: " + name) primary_tile = int(match.group(4)) incremental_tile = int(match.group(5)) channel_tile = int(match.group(7)) arch, isa = xnncommon.parse_target_name(target_name=match.group(6)) return primary_tile, incremental_tile, channel_tile, arch, isa MAXPOOL_TEST_TEMPLATE = """\ TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .input_offset(${next_prime(CHANNEL_TILE+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_unipass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .input_offset(${next_prime(CHANNEL_TILE+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } $if CHANNEL_TILE > 1: TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*8)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_unipass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*8)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_unipass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*2)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_unipass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = 2; pooling_elements < ${PRIMARY_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*2)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .input_offset(${next_prime(CHANNEL_TILE+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_twopass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .input_offset(${next_prime(CHANNEL_TILE+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } $if CHANNEL_TILE > 1: TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*5)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_twopass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*8)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_twopass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_fulltile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_fulltile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*2)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_fulltile_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_fulltile_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(${PRIMARY_TILE+INCREMENTAL_TILE}) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_subtile) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_twopass_subtile_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+1}; pooling_elements < ${PRIMARY_TILE+INCREMENTAL_TILE}; pooling_elements++) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*2)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_multipass) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_multipass_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .input_offset(${next_prime(CHANNEL_TILE+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_multipass_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}_multipass_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } $if CHANNEL_TILE > 1: TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_multipass) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_multipass_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*8)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_multipass_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}_multipass_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*8}; channels += ${CHANNEL_TILE}) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_multipass) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_multipass_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${CHANNEL_TILE}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_multipass_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}_multipass_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_multipass) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_multipass_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*2)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_multipass_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}_multipass_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t pooling_elements = ${PRIMARY_TILE+INCREMENTAL_TILE+1}; pooling_elements <= ${PRIMARY_TILE+INCREMENTAL_TILE*3}; pooling_elements += 3) { for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) { MaxPoolMicrokernelTester() .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } } TEST(${TEST_NAME}, few_output_pixels) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } } TEST(${TEST_NAME}, few_output_pixels_with_input_offset) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .input_offset(${next_prime(CHANNEL_TILE*5+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } } TEST(${TEST_NAME}, few_output_pixels_with_qmin) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .qmin(${QMIN}) $if DATATYPE in ["s8", "u8"]: .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } } TEST(${TEST_NAME}, few_output_pixels_with_qmax) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(${QMAX}) .Test(${", ".join(TEST_ARGS)}); } } } } TEST(${TEST_NAME}, few_output_pixels_with_output_stride) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .channels(channels) .output_stride(${next_prime(CHANNEL_TILE*5+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } } TEST(${TEST_NAME}, few_output_pixels_with_step) { $if ISA_CHECK: ${ISA_CHECK}; for (size_t output_pixels = 2; output_pixels <= 5; output_pixels++) { for (size_t pooling_elements : std::vector{{2, ${PRIMARY_TILE}, ${PRIMARY_TILE+INCREMENTAL_TILE-1}}}) { for (size_t channels = 1; channels <= ${CHANNEL_TILE*5}; channels += ${max(1, CHANNEL_TILE-1)}) { for (size_t step = 2; step <= pooling_elements; step++) { MaxPoolMicrokernelTester() .output_pixels(output_pixels) .pooling_elements(pooling_elements) .pooling_tile(${PRIMARY_TILE}, ${INCREMENTAL_TILE}) .step(step) .channels(channels) .output_stride(${next_prime(CHANNEL_TILE*5+1)}) $if DATATYPE in ["s8", "u8"]: .qmin(std::numeric_limits<${CTYPE}>::min()) .qmax(std::numeric_limits<${CTYPE}>::max()) .Test(${", ".join(TEST_ARGS)}); } } } } } """ def generate_test_cases(ukernel, init_fn, primary_tile, incremental_tile, channel_tile, isa): """Generates all tests cases for a MAXPOOL micro-kernel. Args: ukernel: C name of the micro-kernel function. init_fn: C name of the function to initialize microkernel parameters. primary_tile: Number of rows (pixels) processed per one iteration of the primary outer loop of the micro-kernel. incremental_tile: Number of rows (pixels) processed per one iteration of the incremental outer loop of the micro-kernel. channel_tile: Number of channels processed per one iteration of the inner loops of the micro-kernel. isa: instruction set required to run the micro-kernel. Generated unit test will skip execution if the host processor doesn't support this ISA. Returns: Code for the test case. """ _, test_name = ukernel.split("_", 1) _, datatype, ukernel_type, _ = ukernel.split("_", 3) test_args = [ukernel, init_fn] return xngen.preprocess(MAXPOOL_TEST_TEMPLATE, { "TEST_NAME": test_name.upper().replace("UKERNEL_", ""), "TEST_ARGS": test_args, "DATATYPE": datatype, "CTYPE": {"s8": "int8_t", "u8": "uint8_t", "f16": "uint16_t", "f32": "int16_t"}[datatype], "QMIN": {"s8": -64, "u8": 64}.get(datatype, -16384), "QMAX": {"s8": 64, "u8": 192}.get(datatype, 16384), "PRIMARY_TILE": primary_tile, "INCREMENTAL_TILE": incremental_tile, "CHANNEL_TILE": channel_tile, "ISA_CHECK": xnncommon.generate_isa_check_macro(isa), "next_prime": next_prime, }) def main(args): options = parser.parse_args(args) with codecs.open(options.spec, "r", encoding="utf-8") as spec_file: spec_yaml = yaml.safe_load(spec_file) if not isinstance(spec_yaml, list): raise ValueError("expected a list of micro-kernels in the spec") tests = """\ // Copyright (c) Facebook, Inc. and its affiliates. // All rights reserved. // // Copyright 2019 Google LLC // // This source code is licensed under the BSD-style license found in the // LICENSE file in the root directory of this source tree. // // Auto-generated file. Do not edit! // Specification: {specification} // Generator: {generator} #include #include #include #include #include "maxpool-microkernel-tester.h" """.format(specification=options.spec, generator=sys.argv[0]) for ukernel_spec in spec_yaml: name = ukernel_spec["name"] init_fn = ukernel_spec["init"] primary_tile, incremental_tile, channel_tile, arch, isa = \ split_ukernel_name(name) # specification can override architecture arch = ukernel_spec.get("arch", arch) test_case = generate_test_cases(name, init_fn, primary_tile, incremental_tile, channel_tile, isa) tests += "\n\n" + xnncommon.postprocess_test_case(test_case, arch, isa) txt_changed = True if os.path.exists(options.output): with codecs.open(options.output, "r", encoding="utf-8") as output_file: txt_changed = output_file.read() != tests if txt_changed: with codecs.open(options.output, "w", encoding="utf-8") as output_file: output_file.write(tests) if __name__ == "__main__": main(sys.argv[1:])