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	#!/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 bisect
	import codecs
	import collections
	import os
	import sys
	import yaml
	import zlib

	sys.path.insert(0, os.path.dirname(os.path.abspath(__file__)))
	from primes import next_prime
	import xngen
	import xnncommon

	parser = argparse.ArgumentParser(description="XNNPACK generator")
	parser.add_argument(
	"-s", "--spec", metavar="FILE", required=True, help="Spec (YAML) file")
	parser.add_argument(
	"-o",
	"--output",
	action="append",
	metavar="FILE",
	required=True,
	help="Output (C++ source) file(s)")
	parser.set_defaults(defines=list())

	def split_ukernel_name(name):
	common_name, target_name = name.split("__", 1)
	common_parts = common_name.split("_")
	xw = "gemm_xw_" in common_name
	param_spec = common_parts[-1]
	if "s" in param_spec:
	param_spec, sr = param_spec.split("s", 1)
	sr = int(sr)
	else:
	sr = 1
	if "c" in param_spec:
	param_spec, kr = param_spec.split("c", 1)
	kr = int(kr)
	else:
	kr = 1
	mr, nr = map(int, param_spec.split("x"))
	arch, isa, assembly = xnncommon.parse_target_name(target_name)

	requantization = common_parts[-3]
	if requantization not in ["fp32", "rndnu"]:
	requantization = None

	return mr, nr, kr, sr, xw, requantization, arch, isa, assembly


	GEMM_TEST_CODE = """\
	TEST(${TEST_NAME}, k_eq_${KBLOCK}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	TEST(${TEST_NAME}, strided_cn) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.cn_stride(${next_prime(NR + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	$if UKERNEL_TYPE != "IGEMM":
	TEST(${TEST_NAME}, k_eq_${KBLOCK}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.a_stride(${next_prime(KBLOCK + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	TEST(${TEST_NAME}, k_eq_${KBLOCK}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(${KBLOCK})
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, k_eq_${KBLOCK}_subtile_m) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(${NR})
	.k(${KBLOCK})
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}


	TEST(${TEST_NAME}, k_eq_${KBLOCK}_subtile_n) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = 1; n <= ${NR}; n++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(${KBLOCK})
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if IS_PIPELINED:
	TEST(${TEST_NAME}, k_eq_${KBLOCK * 2}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK * 2})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	$if UKERNEL_TYPE != "IGEMM":
	TEST(${TEST_NAME}, k_eq_${KBLOCK * 2}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK * 2})
	.a_stride(${next_prime(KBLOCK * 2 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	TEST(${TEST_NAME}, k_eq_${KBLOCK * 2}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(${KBLOCK * 2})
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	$if KBLOCK > 1:
	TEST(${TEST_NAME}, k_lt_${ADJKBLOCK}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k < ${ADJKBLOCK}; k++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if UKERNEL_TYPE != "IGEMM":
	TEST(${TEST_NAME}, k_lt_${ADJKBLOCK}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k < ${ADJKBLOCK}; k++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.a_stride(${next_prime(ADJKBLOCK + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	TEST(${TEST_NAME}, k_lt_${ADJKBLOCK}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k < ${ADJKBLOCK}; k++) {
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	TEST(${TEST_NAME}, k_gt_${ADJKBLOCK}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + 1}; k < ${ADJKBLOCK * 10 if ADJKBLOCK == 1 else ADJKBLOCK * 2}; k++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if UKERNEL_TYPE.startswith("GEMM"):
	TEST(${TEST_NAME}, k_gt_${ADJKBLOCK}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + 1}; k < ${10 if ADJKBLOCK == 1 else ADJKBLOCK * 2}; k++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.a_stride(${next_prime(10 if ADJKBLOCK == 1 else ADJKBLOCK * 2 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	TEST(${TEST_NAME}, k_gt_${ADJKBLOCK}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + 1}; k < ${10 if ADJKBLOCK == 1 else ADJKBLOCK * 2}; k++) {
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	$if KBLOCK > 1:
	TEST(${TEST_NAME}, k_div_${KBLOCK}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + KBLOCK}; k <= ${KBLOCK * 10}; k += ${KBLOCK}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if UKERNEL_TYPE.startswith("GEMM"):
	TEST(${TEST_NAME}, k_div_${KBLOCK}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + KBLOCK}; k <= ${KBLOCK * 10}; k += ${KBLOCK}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.a_stride(${next_prime(KBLOCK * 10 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	TEST(${TEST_NAME}, k_div_${KBLOCK}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = ${ADJKBLOCK + KBLOCK}; k <= ${KBLOCK * 10}; k += ${KBLOCK}) {
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	TEST(${TEST_NAME}, n_gt_${NR}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${NR + 1}; n < ${NR * 2}; n++) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, n_gt_${NR}_strided_cn) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${NR + 1}; n < ${NR * 2}; n++) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.cn_stride(${next_prime(NR + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	$if UKERNEL_TYPE != "IGEMM":
	TEST(${TEST_NAME}, n_gt_${NR}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${NR + 1}; n < ${NR * 2}; n++) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.a_stride(${next_prime(KBLOCK * 5 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, n_gt_${NR}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${NR + 1}; n < ${NR * 2}; n++) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	TEST(${TEST_NAME}, n_div_${NR}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${2 * NR}; n <= ${3 * NR}; n += ${NR}) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, n_div_${NR}_strided_cn) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${2 * NR}; n <= ${3 * NR}; n += ${NR}) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.cn_stride(${next_prime(NR + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	$if UKERNEL_TYPE != "IGEMM":
	TEST(${TEST_NAME}, n_div_${NR}_strided_a) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${2 * NR}; n <= ${3 * NR}; n += ${NR}) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.a_stride(${next_prime(KBLOCK * 5 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, n_div_${NR}_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${2 * NR}; n <= ${3 * NR}; n += ${NR}) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	$if UKERNEL_TYPE.startswith("IGEMM"):
	TEST(${TEST_NAME}, small_kernel) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.ks(3)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	TEST(${TEST_NAME}, small_kernel_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.ks(3)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	TEST(${TEST_NAME}, n_gt_${NR}_small_kernel) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${NR + 1}; n < ${NR * 2}; n++) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.ks(3)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, n_div_${NR}_small_kernel) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t n = ${2 * NR}; n <= ${3 * NR}; n += ${NR}) {
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(n)
	.k(k)
	.ks(3)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	TEST(${TEST_NAME}, strided_cm_subtile) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	for (uint32_t n = 1; n <= ${NR}; n++) {
	for (uint32_t m = 1; m <= ${MR}; m++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(n)
	.k(k)
	.cm_stride(${next_prime(NR + 1)})
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	$if UKERNEL_TYPE.startswith("IGEMM"):
	TEST(${TEST_NAME}, a_offset) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.ks(3)
	.a_offset(${next_prime(MR * KBLOCK * 5 + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	TEST(${TEST_NAME}, zero) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	for (uint32_t mz = 0; mz < ${MR}; mz++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.ks(3)
	.a_offset(${next_prime(MR * KBLOCK * 5 + 1)})
	.zero_index(mz)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}

	$if ACTIVATION == "MINMAX":
	TEST(${TEST_NAME}, qmin) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.qmin(128)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	TEST(${TEST_NAME}, qmax) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.qmax(128)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	TEST(${TEST_NAME}, strided_cm) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.cm_stride(${next_prime(NR + 1)})
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}

	$if DATATYPE == "qu8":
	TEST(${TEST_NAME}, no_a_zero_point) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.a_zero_point(0)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if DATATYPE in ["qu8", "f32_qc4w"]:
	TEST(${TEST_NAME}, no_b_zero_point) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.b_zero_point(0)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if DATATYPE == "qu8":
	TEST(${TEST_NAME}, b_zero_point) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint16_t b_zero_point = 0; b_zero_point <= 255; ++b_zero_point) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.b_zero_point(b_zero_point)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if DATATYPE == "f32_qc4w":
	TEST(${TEST_NAME}, b_zero_point) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint8_t b_zero_point = 0; b_zero_point <= 15; ++b_zero_point) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.b_zero_point(b_zero_point)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if DATATYPE == "qu8":
	TEST(${TEST_NAME}, no_zero_point) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t k = 1; k <= ${KBLOCK * 5}; k += ${KBLOCK + 1}) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(k)
	.a_zero_point(0)
	.b_zero_point(0)
	.Test(${", ".join(TEST_ARGS)});
	}
	}

	$if TEST_NAME.startswith('GENERATE') and DATATYPE in ['f32', 'f16']:
	TEST(${TEST_NAME}, subtile_m_upto_mr) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (uint32_t max_mr = 1; max_mr <= ${MR}; max_mr++) {
	for (uint32_t m = 1; m <= max_mr; m++) {
	for (size_t k = 1; k <= ${KBLOCK * 2}; k += 1) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(max_mr)
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(m)
	.n(${NR})
	.k(k)
	.iterations(1)
	$if DATATYPE == 'f32_qc4w':
	.b_zero_point(7)
	.Test(${", ".join(TEST_ARGS)});
	}
	}
	}
	}

	$if TEST_NAME.startswith('GENERATE') and DATATYPE == 'f32' and POST_OP:
	TEST(${TEST_NAME}, hardswish) {
	$if ISA_CHECK:
	${ISA_CHECK};
	const std::vector<xnn_post_operation> fused_operators = { {xnn_post_operation_type_hardswish} };
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.Test(
	${", ".join(TEST_ARGS)},
	fused_operators);
	}
	$if MR > 1:
	TEST(${TEST_NAME}, hardswish_max_mr_lt_${MR}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	const std::vector<xnn_post_operation> fused_operators = { {xnn_post_operation_type_hardswish} };
	for (uint32_t max_mr = 1; max_mr < ${MR}; max_mr++) {
	GemmMicrokernelTester()
	$if EXTENDED_WEIGHTS:
	.extended_weights(true)
	.mr(max_mr)
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(max_mr)
	.n(${NR})
	.k(${KBLOCK})
	.Test(
	${", ".join(TEST_ARGS)},
	fused_operators);
	}
	}

	$if TEST_NAME.startswith('GENERATE') and DATATYPE in ['f32', 'f16'] and PROTOTYPE is not None:
	#if XNN_ENABLE_ASSEMBLY
	TEST(${TEST_NAME}, matches_assembly) {
	$if ISA_CHECK:
	${ISA_CHECK};
	GemmMicrokernelTester()
	.mr(${MR})
	.nr(${NR})
	.kr(${KR})
	.sr(${SR})
	.m(${MR})
	.n(${NR})
	.k(${KBLOCK})
	.Test(
	${", ".join(TEST_ARGS)},
	&${PROTOTYPE});
	}
	#endif // XNN_ENABLE_ASSEMBLY

	"""


	def generate_test_cases(ukernel, mr, nr, kr, sr, xw, k_block, init_fn,
	requantization, is_pipelined, isa, jit, prototype, post_op):
	"""Generates all tests cases for a GEMM micro-kernel.

	Args:
	ukernel: C name of the micro-kernel function.
	mr: MR parameter of the GEMM micro-kernel.
	nr: NR parameter of the GEMM micro-kernel.
	kr: KR parameter of the GEMM micro-kernel.
	sr: SR parameter of the GEMM micro-kernel.
	xw: boolean indicator for microkernel with extended weights.
	k_block: Number of K values processed per one iteration of the main loop of
	the micro-kernel.
	init_fn: C name of the function to initialize microkernel parameters.
	requantization: name of the requantization scheme used by the microkernel.
	is_pipelined: Indicates if the micro-kernel is implemented with software
	pipelining. Additional test cases are generated for software pipelined
	micro-kernels to separately test prologue + epiloque of the pipelined loop
	and iteration of the pipelined loop.
	isa: instruction set required to run the micro-kernel. Generated unit test
	will skip execution if the host processor doesn't support this ISA.
	jit: if we are generating test code for JIT codegen.
	post_op: if post operation is supported (only for JIT).

	Returns:
	Code for the test case.
	"""
	_, ukernel_name = ukernel.split("_", 1)

	if jit:
	_, _, datatype, ukernel_type, _ = ukernel.split("_", 4)
	activation = None
	else:
	_, datatype, ukernel_type, activation, _ = ukernel.split("_", 4)
	if datatype == "f32" and ukernel_type in ["qc8w", "qc4w"]:
	_, datatype, weighttype, ukernel_type, activation, _ = ukernel.split("_", 5)
	datatype = datatype + "_" + weighttype
	if activation == "ukernel":
	activation = "linear"
	if activation in ["qs8w"]:
	_, _, _, _, _, activation, _ = ukernel.split("_", 6)
	test_args = [ukernel]
	if init_fn:
	test_args.append(init_fn)
	if requantization:
	requantization_datatype = {"qc8": "qs8"}.get(datatype, datatype)
	test_args.append("xnn_%s_requantize_%s" % \
	(requantization_datatype, requantization))

	if jit:
	if "minmax" in init_fn:
	activation = "minmax"

	return xngen.preprocess(
	GEMM_TEST_CODE, {
	"TEST_NAME": ukernel_name.upper().replace("UKERNEL_", ""),
	"TEST_ARGS": test_args,
	"UKERNEL_TYPE": ukernel_type.upper(),
	"DATATYPE": datatype,
	"ACTIVATION": activation.upper(),
	"MR": mr,
	"NR": nr,
	"KR": kr,
	"SR": sr,
	"EXTENDED_WEIGHTS": xw,
	"KBLOCK": k_block,
	"ADJKBLOCK": 2 * k_block if is_pipelined else k_block,
	"IS_PIPELINED": is_pipelined,
	"ISA_CHECK": xnncommon.generate_isa_check_macro(isa),
	"next_prime": next_prime,
	"POST_OP": post_op,
	"PROTOTYPE": prototype,
	})


	def main(args):
	options = parser.parse_args(args)
	num_output_files = len(options.output)

	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 <gtest/gtest.h>

	#include <xnnpack/allocator.h>
	#include <xnnpack/common.h>
	#include <xnnpack/isa-checks.h>
	#include <xnnpack/microparams-init.h>

	#include <xnnpack/gemm.h>
	#include <xnnpack/igemm.h>
	#include <xnnpack/ppmm.h>
	#include "gemm-microkernel-tester.h"
	""".format(
	specification=options.spec, generator=sys.argv[0])

	outputs = collections.defaultdict(lambda: tests)

	for ukernel_spec in spec_yaml:
	name = ukernel_spec["name"]
	k_block = int(ukernel_spec["k-block"])
	init_fn = ukernel_spec.get("init")
	pipelined = bool(ukernel_spec.get("pipelined", False))
	jit = name.startswith("xnn_generate")
	prototype = ukernel_spec.get("prototype")
	post_op = ukernel_spec.get("post-op", True)
	mr, nr, kr, sr, xw, requantization, arch, isa, assembly = \
	split_ukernel_name(name)

	test_case = generate_test_cases(name, mr, nr, kr, sr, xw, k_block,
	init_fn, requantization, pipelined, isa,
	jit, prototype, post_op)

	# Hash the name of each microkernel and figure out which output file to
	# write it to.
	output_index = zlib.crc32(bytes(name, "utf-8")) % num_output_files
	outputs[options.
	output[output_index]] += "\n\n" + xnncommon.postprocess_test_case(
	test_case, arch, isa, assembly, jit)

	for output_name in options.output:
	txt_changed = True
	if os.path.exists(output_name):
	with codecs.open(output_name, "r", encoding="utf-8") as output_file:
	txt_changed = output_file.read() != outputs[output_name]

	if txt_changed:
	with codecs.open(output_name, "w", encoding="utf-8") as output_file:
	output_file.write(outputs[output_name])


	if __name__ == "__main__":
	main(sys.argv[1:])