tools/generate-bilinear-test.py - platform/external/XNNPACK - Git at Google

 #!/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 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='Bilinear 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.match(r"^xnn_(f16|f32)_bilinear_ukernel__(.+)_c(\d+)$", name)
   assert match is not None
   channel_tile = int(match.group(3))
   pixel_tile = 1

   arch, isa = xnncommon.parse_target_name(target_name=match.group(2))
   return channel_tile, pixel_tile, arch, isa


 BILINEAR_TEST_TEMPLATE = """\
 TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}) {
   $if ISA_CHECK:
     ${ISA_CHECK};
   BilinearMicrokernelTester()
     .pixels(${PIXEL_TILE})
     .channels(${CHANNEL_TILE})
     .Test(${TEST_FUNC});
 }

 $if CHANNEL_TILE > 1:
   TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}) {
     $if ISA_CHECK:
       ${ISA_CHECK};
     for (size_t channels = ${CHANNEL_TILE*2}; channels < ${CHANNEL_TILE*10}; channels += ${CHANNEL_TILE}) {
       BilinearMicrokernelTester()
         .pixels(${PIXEL_TILE})
         .channels(channels)
         .Test(${TEST_FUNC});
     }
   }

   TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}) {
     $if ISA_CHECK:
       ${ISA_CHECK};
     for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) {
       BilinearMicrokernelTester()
         .pixels(${PIXEL_TILE})
         .channels(channels)
         .Test(${TEST_FUNC});
     }
   }

 TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}) {
   $if ISA_CHECK:
     ${ISA_CHECK};
   for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) {
     BilinearMicrokernelTester()
       .pixels(${PIXEL_TILE})
       .channels(channels)
       .Test(${TEST_FUNC});
   }
 }

 $if PIXEL_TILE > 1:
   TEST(${TEST_NAME}, pixels_div_${PIXEL_TILE}) {
     $if ISA_CHECK:
       ${ISA_CHECK};
     for (size_t pixels = ${PIXEL_TILE*2}; pixels < ${PIXEL_TILE*10}; pixels += ${PIXEL_TILE}) {
       for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
         BilinearMicrokernelTester()
           .pixels(pixels)
           .channels(channels)
           .Test(${TEST_FUNC});
       }
     }
   }

   TEST(${TEST_NAME}, pixels_lt_${PIXEL_TILE}) {
     $if ISA_CHECK:
       ${ISA_CHECK};
     for (size_t pixels = 1; pixels < ${PIXEL_TILE}; pixels++) {
       for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
         BilinearMicrokernelTester()
           .pixels(pixels)
           .channels(channels)
           .Test(${TEST_FUNC});
       }
     }
   }

 TEST(${TEST_NAME}, pixels_gt_${PIXEL_TILE}) {
   $if ISA_CHECK:
     ${ISA_CHECK};
   for (size_t pixels = ${PIXEL_TILE+1}; pixels < ${max(PIXEL_TILE*2, 3)}; pixels++) {
     for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
       BilinearMicrokernelTester()
         .pixels(pixels)
         .channels(channels)
         .Test(${TEST_FUNC});
     }
   }
 }

 TEST(${TEST_NAME}, input_offset) {
   $if ISA_CHECK:
     ${ISA_CHECK};
   for (size_t pixels = 1; pixels < ${PIXEL_TILE * 5}; pixels += ${max(1, PIXEL_TILE - 1)}) {
     for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
       BilinearMicrokernelTester()
         .pixels(pixels)
         .channels(channels)
         .input_offset(${next_prime(CHANNEL_TILE * 5 + 1)})
         .Test(${TEST_FUNC});
     }
   }
 }
 TEST(${TEST_NAME}, output_stride) {
   $if ISA_CHECK:
     ${ISA_CHECK};
   for (size_t pixels = 1; pixels < ${PIXEL_TILE * 5}; pixels += ${max(1, PIXEL_TILE - 1)}) {
     for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
       BilinearMicrokernelTester()
         .pixels(pixels)
         .channels(channels)
         .output_stride(${next_prime(CHANNEL_TILE * 5 + 1)})
         .Test(${TEST_FUNC});
     }
   }
 }
 """


 def generate_test_cases(ukernel, channel_tile, pixel_tile, isa):
   """Generates all tests cases for a BILINEAR micro-kernel.

   Args:
     ukernel: C name of the micro-kernel function.
     channel_tile: Number of channels processed per one iteration of the inner
                   loop of the micro-kernel.
     pixel_tile: Number of pixels processed per one iteration of the outer loop
                 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]
   return xngen.preprocess(BILINEAR_TEST_TEMPLATE, {
       "TEST_NAME": test_name.upper().replace("UKERNEL_", ""),
       "TEST_FUNC": ukernel,
       "UKERNEL_TYPE": ukernel_type.upper(),
       "DATATYPE": datatype,
       "CHANNEL_TILE": channel_tile,
       "PIXEL_TILE": pixel_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 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/common.h>
 #include <xnnpack/isa-checks.h>

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

     for ukernel_spec in spec_yaml:
       name = ukernel_spec["name"]
       channel_tile, pixel_tile, arch, isa = split_ukernel_name(name)

       # specification can override architecture
       arch = ukernel_spec.get("arch", arch)

       test_case = generate_test_cases(name, channel_tile, pixel_tile, isa)
       tests += "\n\n" + xnncommon.postprocess_test_case(test_case, arch, isa)

     with codecs.open(options.output, "w", encoding="utf-8") as output_file:
       output_file.write(tests)


 if __name__ == "__main__":
   main(sys.argv[1:])
	#!/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 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='Bilinear 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.match(r"^xnn_(f16\|f32)_bilinear_ukernel__(.+)_c(\d+)$", name)
	assert match is not None
	channel_tile = int(match.group(3))
	pixel_tile = 1

	arch, isa = xnncommon.parse_target_name(target_name=match.group(2))
	return channel_tile, pixel_tile, arch, isa


	BILINEAR_TEST_TEMPLATE = """\
	TEST(${TEST_NAME}, channels_eq_${CHANNEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	BilinearMicrokernelTester()
	.pixels(${PIXEL_TILE})
	.channels(${CHANNEL_TILE})
	.Test(${TEST_FUNC});
	}

	$if CHANNEL_TILE > 1:
	TEST(${TEST_NAME}, channels_div_${CHANNEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t channels = ${CHANNEL_TILE2}; channels < ${CHANNEL_TILE10}; channels += ${CHANNEL_TILE}) {
	BilinearMicrokernelTester()
	.pixels(${PIXEL_TILE})
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}

	TEST(${TEST_NAME}, channels_lt_${CHANNEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t channels = 1; channels < ${CHANNEL_TILE}; channels++) {
	BilinearMicrokernelTester()
	.pixels(${PIXEL_TILE})
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}

	TEST(${TEST_NAME}, channels_gt_${CHANNEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t channels = ${CHANNEL_TILE+1}; channels < ${10 if CHANNEL_TILE == 1 else CHANNEL_TILE*2}; channels++) {
	BilinearMicrokernelTester()
	.pixels(${PIXEL_TILE})
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}

	$if PIXEL_TILE > 1:
	TEST(${TEST_NAME}, pixels_div_${PIXEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t pixels = ${PIXEL_TILE2}; pixels < ${PIXEL_TILE10}; pixels += ${PIXEL_TILE}) {
	for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
	BilinearMicrokernelTester()
	.pixels(pixels)
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}
	}

	TEST(${TEST_NAME}, pixels_lt_${PIXEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t pixels = 1; pixels < ${PIXEL_TILE}; pixels++) {
	for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
	BilinearMicrokernelTester()
	.pixels(pixels)
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}
	}

	TEST(${TEST_NAME}, pixels_gt_${PIXEL_TILE}) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t pixels = ${PIXEL_TILE+1}; pixels < ${max(PIXEL_TILE*2, 3)}; pixels++) {
	for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
	BilinearMicrokernelTester()
	.pixels(pixels)
	.channels(channels)
	.Test(${TEST_FUNC});
	}
	}
	}

	TEST(${TEST_NAME}, input_offset) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t pixels = 1; pixels < ${PIXEL_TILE * 5}; pixels += ${max(1, PIXEL_TILE - 1)}) {
	for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
	BilinearMicrokernelTester()
	.pixels(pixels)
	.channels(channels)
	.input_offset(${next_prime(CHANNEL_TILE * 5 + 1)})
	.Test(${TEST_FUNC});
	}
	}
	}
	TEST(${TEST_NAME}, output_stride) {
	$if ISA_CHECK:
	${ISA_CHECK};
	for (size_t pixels = 1; pixels < ${PIXEL_TILE * 5}; pixels += ${max(1, PIXEL_TILE - 1)}) {
	for (size_t channels = 1; channels <= ${CHANNEL_TILE * 5}; channels += ${max(1, CHANNEL_TILE - 1)}) {
	BilinearMicrokernelTester()
	.pixels(pixels)
	.channels(channels)
	.output_stride(${next_prime(CHANNEL_TILE * 5 + 1)})
	.Test(${TEST_FUNC});
	}
	}
	}
	"""


	def generate_test_cases(ukernel, channel_tile, pixel_tile, isa):
	"""Generates all tests cases for a BILINEAR micro-kernel.

	Args:
	ukernel: C name of the micro-kernel function.
	channel_tile: Number of channels processed per one iteration of the inner
	loop of the micro-kernel.
	pixel_tile: Number of pixels processed per one iteration of the outer loop
	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]
	return xngen.preprocess(BILINEAR_TEST_TEMPLATE, {
	"TEST_NAME": test_name.upper().replace("UKERNEL_", ""),
	"TEST_FUNC": ukernel,
	"UKERNEL_TYPE": ukernel_type.upper(),
	"DATATYPE": datatype,
	"CHANNEL_TILE": channel_tile,
	"PIXEL_TILE": pixel_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 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/common.h>
	#include <xnnpack/isa-checks.h>

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

	for ukernel_spec in spec_yaml:
	name = ukernel_spec["name"]
	channel_tile, pixel_tile, arch, isa = split_ukernel_name(name)

	# specification can override architecture
	arch = ukernel_spec.get("arch", arch)

	test_case = generate_test_cases(name, channel_tile, pixel_tile, isa)
	tests += "\n\n" + xnncommon.postprocess_test_case(test_case, arch, isa)

	with codecs.open(options.output, "w", encoding="utf-8") as output_file:
	output_file.write(tests)


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