test/c/std/gzip.c - external/github.com/google/wuffs - Git at Google

 // Copyright 2018 The Wuffs Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    https://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 // ----------------

 /*
 This test program is typically run indirectly, by the "wuffs test" or "wuffs
 bench" commands. These commands take an optional "-mimic" flag to check that
 Wuffs' output mimics (i.e. exactly matches) other libraries' output, such as
 giflib for GIF, libpng for PNG, etc.

 To manually run this test:

 for CC in clang gcc; do
   $CC -std=c99 -Wall -Werror gzip.c && ./a.out
   rm -f a.out
 done

 Each edition should print "PASS", amongst other information, and exit(0).

 Add the "wuffs mimic cflags" (everything after the colon below) to the C
 compiler flags (after the .c file) to run the mimic tests.

 To manually run the benchmarks, replace "-Wall -Werror" with "-O3" and replace
 the first "./a.out" with "./a.out -bench". Combine these changes with the
 "wuffs mimic cflags" to run the mimic benchmarks.
 */

 // ¿ wuffs mimic cflags: -DWUFFS_MIMIC -ldeflate -lz

 // Wuffs ships as a "single file C library" or "header file library" as per
 // https://github.com/nothings/stb/blob/master/docs/stb_howto.txt
 //
 // To use that single file as a "foo.c"-like implementation, instead of a
 // "foo.h"-like header, #define WUFFS_IMPLEMENTATION before #include'ing or
 // compiling it.
 #define WUFFS_IMPLEMENTATION

 // Defining the WUFFS_CONFIG__MODULE* macros are optional, but it lets users of
 // release/c/etc.c choose which parts of Wuffs to build. That file contains the
 // entire Wuffs standard library, implementing a variety of codecs and file
 // formats. Without this macro definition, an optimizing compiler or linker may
 // very well discard Wuffs code for unused codecs, but listing the Wuffs
 // modules we use makes that process explicit. Preprocessing means that such
 // code simply isn't compiled.
 #define WUFFS_CONFIG__MODULES
 #define WUFFS_CONFIG__MODULE__BASE
 #define WUFFS_CONFIG__MODULE__CRC32
 #define WUFFS_CONFIG__MODULE__DEFLATE
 #define WUFFS_CONFIG__MODULE__GZIP

 // If building this program in an environment that doesn't easily accommodate
 // relative includes, you can use the script/inline-c-relative-includes.go
 // program to generate a stand-alone C file.
 #include "../../../release/c/wuffs-unsupported-snapshot.c"
 #include "../testlib/testlib.c"
 #ifdef WUFFS_MIMIC
 #include "../mimiclib/deflate-gzip-zlib.c"
 #endif

 // ---------------- Golden Tests

 golden_test g_gzip_midsummer_gt = {
     .want_filename = "test/data/midsummer.txt",
     .src_filename = "test/data/midsummer.txt.gz",
 };

 golden_test g_gzip_pi_gt = {
     .want_filename = "test/data/pi.txt",
     .src_filename = "test/data/pi.txt.gz",
 };

 // ---------------- Gzip Tests

 const char*  //
 test_wuffs_gzip_decode_interface() {
   CHECK_FOCUS(__func__);
   wuffs_gzip__decoder dec;
   CHECK_STATUS("initialize",
                wuffs_gzip__decoder__initialize(
                    &dec, sizeof dec, WUFFS_VERSION,
                    WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED));
   return do_test__wuffs_base__io_transformer(
       wuffs_gzip__decoder__upcast_as__wuffs_base__io_transformer(&dec),
       "test/data/romeo.txt.gz", 0, SIZE_MAX, 942, 0x0A);
 }

 const char*  //
 wuffs_gzip_decode(wuffs_base__io_buffer* dst,
                   wuffs_base__io_buffer* src,
                   uint32_t wuffs_initialize_flags,
                   uint64_t wlimit,
                   uint64_t rlimit) {
   wuffs_gzip__decoder dec;
   CHECK_STATUS("initialize",
                wuffs_gzip__decoder__initialize(&dec, sizeof dec, WUFFS_VERSION,
                                                wuffs_initialize_flags));

   while (true) {
     wuffs_base__io_buffer limited_dst = make_limited_writer(*dst, wlimit);
     wuffs_base__io_buffer limited_src = make_limited_reader(*src, rlimit);

     wuffs_base__status status = wuffs_gzip__decoder__transform_io(
         &dec, &limited_dst, &limited_src, g_work_slice_u8);

     dst->meta.wi += limited_dst.meta.wi;
     src->meta.ri += limited_src.meta.ri;

     if (((wlimit < UINT64_MAX) &&
          (status.repr == wuffs_base__suspension__short_write)) ||
         ((rlimit < UINT64_MAX) &&
          (status.repr == wuffs_base__suspension__short_read))) {
       continue;
     }
     return status.repr;
   }
 }

 const char*  //
 do_test_wuffs_gzip_checksum(bool ignore_checksum, uint32_t bad_checksum) {
   wuffs_base__io_buffer have = ((wuffs_base__io_buffer){
       .data = g_have_slice_u8,
   });
   wuffs_base__io_buffer src = ((wuffs_base__io_buffer){
       .data = g_src_slice_u8,
   });

   CHECK_STRING(read_file(&src, g_gzip_midsummer_gt.src_filename));

   // Flip a bit in the gzip checksum, which is in the last 8 bytes of the file.
   if (src.meta.wi < 8) {
     RETURN_FAIL("source file was too short");
   }
   if (bad_checksum) {
     src.data.ptr[src.meta.wi - 1 - (bad_checksum & 7)] ^= 1;
   }

   int end_limit;  // The rlimit, relative to the end of the data.
   for (end_limit = 0; end_limit < 10; end_limit++) {
     wuffs_gzip__decoder dec;
     CHECK_STATUS("initialize",
                  wuffs_gzip__decoder__initialize(
                      &dec, sizeof dec, WUFFS_VERSION,
                      WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED));
     wuffs_gzip__decoder__set_quirk_enabled(
         &dec, WUFFS_BASE__QUIRK_IGNORE_CHECKSUM, ignore_checksum);
     have.meta.wi = 0;
     src.meta.ri = 0;

     // Decode the src data in 1 or 2 chunks, depending on whether end_limit is
     // or isn't zero.
     int i;
     for (i = 0; i < 2; i++) {
       uint64_t rlimit = UINT64_MAX;
       const char* want_z = NULL;
       if (i == 0) {
         if (end_limit == 0) {
           continue;
         }
         if (src.meta.wi < end_limit) {
           RETURN_FAIL("end_limit=%d: not enough source data", end_limit);
         }
         rlimit = src.meta.wi - (uint64_t)(end_limit);
         want_z = wuffs_base__suspension__short_read;
       } else {
         want_z = (bad_checksum && !ignore_checksum)
                      ? wuffs_gzip__error__bad_checksum
                      : NULL;
       }

       wuffs_base__io_buffer limited_src = make_limited_reader(src, rlimit);
       wuffs_base__status have_z = wuffs_gzip__decoder__transform_io(
           &dec, &have, &limited_src, g_work_slice_u8);
       src.meta.ri += limited_src.meta.ri;
       if (have_z.repr != want_z) {
         RETURN_FAIL("end_limit=%d: have \"%s\", want \"%s\"", end_limit,
                     have_z.repr, want_z);
       }
     }
   }
   return NULL;
 }

 const char*  //
 test_wuffs_gzip_checksum_ignore() {
   CHECK_FOCUS(__func__);
   return do_test_wuffs_gzip_checksum(true, 8 | 0);
 }

 const char*  //
 test_wuffs_gzip_checksum_verify_bad0() {
   CHECK_FOCUS(__func__);
   return do_test_wuffs_gzip_checksum(false, 8 | 0);
 }

 const char*  //
 test_wuffs_gzip_checksum_verify_bad7() {
   CHECK_FOCUS(__func__);
   return do_test_wuffs_gzip_checksum(false, 8 | 7);
 }

 const char*  //
 test_wuffs_gzip_checksum_verify_good() {
   CHECK_FOCUS(__func__);
   return do_test_wuffs_gzip_checksum(false, 0);
 }

 const char*  //
 test_wuffs_gzip_decode_midsummer() {
   CHECK_FOCUS(__func__);
   return do_test_io_buffers(wuffs_gzip_decode, &g_gzip_midsummer_gt, UINT64_MAX,
                             UINT64_MAX);
 }

 const char*  //
 test_wuffs_gzip_decode_pi() {
   CHECK_FOCUS(__func__);
   return do_test_io_buffers(wuffs_gzip_decode, &g_gzip_pi_gt, UINT64_MAX,
                             UINT64_MAX);
 }

 // ---------------- Mimic Tests

 #ifdef WUFFS_MIMIC

 const char*  //
 test_mimic_gzip_decode_midsummer() {
   CHECK_FOCUS(__func__);
   return do_test_io_buffers(mimic_gzip_decode, &g_gzip_midsummer_gt, UINT64_MAX,
                             UINT64_MAX);
 }

 const char*  //
 test_mimic_gzip_decode_pi() {
   CHECK_FOCUS(__func__);
   return do_test_io_buffers(mimic_gzip_decode, &g_gzip_pi_gt, UINT64_MAX,
                             UINT64_MAX);
 }

 #endif  // WUFFS_MIMIC

 // ---------------- Gzip Benches

 const char*  //
 bench_wuffs_gzip_decode_10k() {
   CHECK_FOCUS(__func__);
   return do_bench_io_buffers(
       wuffs_gzip_decode, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED,
       tcounter_dst, &g_gzip_midsummer_gt, UINT64_MAX, UINT64_MAX, 300);
 }

 const char*  //
 bench_wuffs_gzip_decode_100k() {
   CHECK_FOCUS(__func__);
   return do_bench_io_buffers(
       wuffs_gzip_decode, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED,
       tcounter_dst, &g_gzip_pi_gt, UINT64_MAX, UINT64_MAX, 30);
 }

 // ---------------- Mimic Benches

 #ifdef WUFFS_MIMIC

 const char*  //
 bench_mimic_gzip_decode_10k() {
   CHECK_FOCUS(__func__);
   return do_bench_io_buffers(mimic_gzip_decode, 0, tcounter_dst,
                              &g_gzip_midsummer_gt, UINT64_MAX, UINT64_MAX, 300);
 }

 const char*  //
 bench_mimic_gzip_decode_100k() {
   CHECK_FOCUS(__func__);
   return do_bench_io_buffers(mimic_gzip_decode, 0, tcounter_dst, &g_gzip_pi_gt,
                              UINT64_MAX, UINT64_MAX, 30);
 }

 #endif  // WUFFS_MIMIC

 // ---------------- Manifest

 // Note that the gzip mimic tests and benches don't work with
 // WUFFS_MIMICLIB_USE_MINIZ_INSTEAD_OF_ZLIB.

 proc g_tests[] = {

     test_wuffs_gzip_checksum_ignore,
     test_wuffs_gzip_checksum_verify_bad0,
     test_wuffs_gzip_checksum_verify_bad7,
     test_wuffs_gzip_checksum_verify_good,
     test_wuffs_gzip_decode_interface,
     test_wuffs_gzip_decode_midsummer,
     test_wuffs_gzip_decode_pi,

 #ifdef WUFFS_MIMIC

     test_mimic_gzip_decode_midsummer,
     test_mimic_gzip_decode_pi,

 #endif  // WUFFS_MIMIC

     NULL,
 };

 proc g_benches[] = {

     bench_wuffs_gzip_decode_10k,
     bench_wuffs_gzip_decode_100k,

 #ifdef WUFFS_MIMIC

     bench_mimic_gzip_decode_10k,
     bench_mimic_gzip_decode_100k,

 #endif  // WUFFS_MIMIC

     NULL,
 };

 int  //
 main(int argc, char** argv) {
   g_proc_package_name = "std/gzip";
   return test_main(argc, argv, g_tests, g_benches);
 }
	// Copyright 2018 The Wuffs Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// https://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	// ----------------

	/*
	This test program is typically run indirectly, by the "wuffs test" or "wuffs
	bench" commands. These commands take an optional "-mimic" flag to check that
	Wuffs' output mimics (i.e. exactly matches) other libraries' output, such as
	giflib for GIF, libpng for PNG, etc.

	To manually run this test:

	for CC in clang gcc; do
	$CC -std=c99 -Wall -Werror gzip.c && ./a.out
	rm -f a.out
	done

	Each edition should print "PASS", amongst other information, and exit(0).

	Add the "wuffs mimic cflags" (everything after the colon below) to the C
	compiler flags (after the .c file) to run the mimic tests.

	To manually run the benchmarks, replace "-Wall -Werror" with "-O3" and replace
	the first "./a.out" with "./a.out -bench". Combine these changes with the
	"wuffs mimic cflags" to run the mimic benchmarks.
	*/

	// ¿ wuffs mimic cflags: -DWUFFS_MIMIC -ldeflate -lz

	// Wuffs ships as a "single file C library" or "header file library" as per
	// https://github.com/nothings/stb/blob/master/docs/stb_howto.txt
	//
	// To use that single file as a "foo.c"-like implementation, instead of a
	// "foo.h"-like header, #define WUFFS_IMPLEMENTATION before #include'ing or
	// compiling it.
	#define WUFFS_IMPLEMENTATION

	// Defining the WUFFS_CONFIG__MODULE* macros are optional, but it lets users of
	// release/c/etc.c choose which parts of Wuffs to build. That file contains the
	// entire Wuffs standard library, implementing a variety of codecs and file
	// formats. Without this macro definition, an optimizing compiler or linker may
	// very well discard Wuffs code for unused codecs, but listing the Wuffs
	// modules we use makes that process explicit. Preprocessing means that such
	// code simply isn't compiled.
	#define WUFFS_CONFIG__MODULES
	#define WUFFS_CONFIG__MODULE__BASE
	#define WUFFS_CONFIG__MODULE__CRC32
	#define WUFFS_CONFIG__MODULE__DEFLATE
	#define WUFFS_CONFIG__MODULE__GZIP

	// If building this program in an environment that doesn't easily accommodate
	// relative includes, you can use the script/inline-c-relative-includes.go
	// program to generate a stand-alone C file.
	#include "../../../release/c/wuffs-unsupported-snapshot.c"
	#include "../testlib/testlib.c"
	#ifdef WUFFS_MIMIC
	#include "../mimiclib/deflate-gzip-zlib.c"
	#endif

	// ---------------- Golden Tests

	golden_test g_gzip_midsummer_gt = {
	.want_filename = "test/data/midsummer.txt",
	.src_filename = "test/data/midsummer.txt.gz",
	};

	golden_test g_gzip_pi_gt = {
	.want_filename = "test/data/pi.txt",
	.src_filename = "test/data/pi.txt.gz",
	};

	// ---------------- Gzip Tests

	const char* //
	test_wuffs_gzip_decode_interface() {
	CHECK_FOCUS(__func__);
	wuffs_gzip__decoder dec;
	CHECK_STATUS("initialize",
	wuffs_gzip__decoder__initialize(
	&dec, sizeof dec, WUFFS_VERSION,
	WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED));
	return do_test__wuffs_base__io_transformer(
	wuffs_gzip__decoder__upcast_as__wuffs_base__io_transformer(&dec),
	"test/data/romeo.txt.gz", 0, SIZE_MAX, 942, 0x0A);
	}

	const char* //
	wuffs_gzip_decode(wuffs_base__io_buffer* dst,
	wuffs_base__io_buffer* src,
	uint32_t wuffs_initialize_flags,
	uint64_t wlimit,
	uint64_t rlimit) {
	wuffs_gzip__decoder dec;
	CHECK_STATUS("initialize",
	wuffs_gzip__decoder__initialize(&dec, sizeof dec, WUFFS_VERSION,
	wuffs_initialize_flags));

	while (true) {
	wuffs_base__io_buffer limited_dst = make_limited_writer(*dst, wlimit);
	wuffs_base__io_buffer limited_src = make_limited_reader(*src, rlimit);

	wuffs_base__status status = wuffs_gzip__decoder__transform_io(
	&dec, &limited_dst, &limited_src, g_work_slice_u8);

	dst->meta.wi += limited_dst.meta.wi;
	src->meta.ri += limited_src.meta.ri;

	if (((wlimit < UINT64_MAX) &&
	(status.repr == wuffs_base__suspension__short_write)) \|\|
	((rlimit < UINT64_MAX) &&
	(status.repr == wuffs_base__suspension__short_read))) {
	continue;
	}
	return status.repr;
	}
	}

	const char* //
	do_test_wuffs_gzip_checksum(bool ignore_checksum, uint32_t bad_checksum) {
	wuffs_base__io_buffer have = ((wuffs_base__io_buffer){
	.data = g_have_slice_u8,
	});
	wuffs_base__io_buffer src = ((wuffs_base__io_buffer){
	.data = g_src_slice_u8,
	});

	CHECK_STRING(read_file(&src, g_gzip_midsummer_gt.src_filename));

	// Flip a bit in the gzip checksum, which is in the last 8 bytes of the file.
	if (src.meta.wi < 8) {
	RETURN_FAIL("source file was too short");
	}
	if (bad_checksum) {
	src.data.ptr[src.meta.wi - 1 - (bad_checksum & 7)] ^= 1;
	}

	int end_limit; // The rlimit, relative to the end of the data.
	for (end_limit = 0; end_limit < 10; end_limit++) {
	wuffs_gzip__decoder dec;
	CHECK_STATUS("initialize",
	wuffs_gzip__decoder__initialize(
	&dec, sizeof dec, WUFFS_VERSION,
	WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED));
	wuffs_gzip__decoder__set_quirk_enabled(
	&dec, WUFFS_BASE__QUIRK_IGNORE_CHECKSUM, ignore_checksum);
	have.meta.wi = 0;
	src.meta.ri = 0;

	// Decode the src data in 1 or 2 chunks, depending on whether end_limit is
	// or isn't zero.
	int i;
	for (i = 0; i < 2; i++) {
	uint64_t rlimit = UINT64_MAX;
	const char* want_z = NULL;
	if (i == 0) {
	if (end_limit == 0) {
	continue;
	}
	if (src.meta.wi < end_limit) {
	RETURN_FAIL("end_limit=%d: not enough source data", end_limit);
	}
	rlimit = src.meta.wi - (uint64_t)(end_limit);
	want_z = wuffs_base__suspension__short_read;
	} else {
	want_z = (bad_checksum && !ignore_checksum)
	? wuffs_gzip__error__bad_checksum
	: NULL;
	}

	wuffs_base__io_buffer limited_src = make_limited_reader(src, rlimit);
	wuffs_base__status have_z = wuffs_gzip__decoder__transform_io(
	&dec, &have, &limited_src, g_work_slice_u8);
	src.meta.ri += limited_src.meta.ri;
	if (have_z.repr != want_z) {
	RETURN_FAIL("end_limit=%d: have \"%s\", want \"%s\"", end_limit,
	have_z.repr, want_z);
	}
	}
	}
	return NULL;
	}

	const char* //
	test_wuffs_gzip_checksum_ignore() {
	CHECK_FOCUS(__func__);
	return do_test_wuffs_gzip_checksum(true, 8 \| 0);
	}

	const char* //
	test_wuffs_gzip_checksum_verify_bad0() {
	CHECK_FOCUS(__func__);
	return do_test_wuffs_gzip_checksum(false, 8 \| 0);
	}

	const char* //
	test_wuffs_gzip_checksum_verify_bad7() {
	CHECK_FOCUS(__func__);
	return do_test_wuffs_gzip_checksum(false, 8 \| 7);
	}

	const char* //
	test_wuffs_gzip_checksum_verify_good() {
	CHECK_FOCUS(__func__);
	return do_test_wuffs_gzip_checksum(false, 0);
	}

	const char* //
	test_wuffs_gzip_decode_midsummer() {
	CHECK_FOCUS(__func__);
	return do_test_io_buffers(wuffs_gzip_decode, &g_gzip_midsummer_gt, UINT64_MAX,
	UINT64_MAX);
	}

	const char* //
	test_wuffs_gzip_decode_pi() {
	CHECK_FOCUS(__func__);
	return do_test_io_buffers(wuffs_gzip_decode, &g_gzip_pi_gt, UINT64_MAX,
	UINT64_MAX);
	}

	// ---------------- Mimic Tests

	#ifdef WUFFS_MIMIC

	const char* //
	test_mimic_gzip_decode_midsummer() {
	CHECK_FOCUS(__func__);
	return do_test_io_buffers(mimic_gzip_decode, &g_gzip_midsummer_gt, UINT64_MAX,
	UINT64_MAX);
	}

	const char* //
	test_mimic_gzip_decode_pi() {
	CHECK_FOCUS(__func__);
	return do_test_io_buffers(mimic_gzip_decode, &g_gzip_pi_gt, UINT64_MAX,
	UINT64_MAX);
	}

	#endif // WUFFS_MIMIC

	// ---------------- Gzip Benches

	const char* //
	bench_wuffs_gzip_decode_10k() {
	CHECK_FOCUS(__func__);
	return do_bench_io_buffers(
	wuffs_gzip_decode, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED,
	tcounter_dst, &g_gzip_midsummer_gt, UINT64_MAX, UINT64_MAX, 300);
	}

	const char* //
	bench_wuffs_gzip_decode_100k() {
	CHECK_FOCUS(__func__);
	return do_bench_io_buffers(
	wuffs_gzip_decode, WUFFS_INITIALIZE__LEAVE_INTERNAL_BUFFERS_UNINITIALIZED,
	tcounter_dst, &g_gzip_pi_gt, UINT64_MAX, UINT64_MAX, 30);
	}

	// ---------------- Mimic Benches

	#ifdef WUFFS_MIMIC

	const char* //
	bench_mimic_gzip_decode_10k() {
	CHECK_FOCUS(__func__);
	return do_bench_io_buffers(mimic_gzip_decode, 0, tcounter_dst,
	&g_gzip_midsummer_gt, UINT64_MAX, UINT64_MAX, 300);
	}

	const char* //
	bench_mimic_gzip_decode_100k() {
	CHECK_FOCUS(__func__);
	return do_bench_io_buffers(mimic_gzip_decode, 0, tcounter_dst, &g_gzip_pi_gt,
	UINT64_MAX, UINT64_MAX, 30);
	}

	#endif // WUFFS_MIMIC

	// ---------------- Manifest

	// Note that the gzip mimic tests and benches don't work with
	// WUFFS_MIMICLIB_USE_MINIZ_INSTEAD_OF_ZLIB.

	proc g_tests[] = {

	test_wuffs_gzip_checksum_ignore,
	test_wuffs_gzip_checksum_verify_bad0,
	test_wuffs_gzip_checksum_verify_bad7,
	test_wuffs_gzip_checksum_verify_good,
	test_wuffs_gzip_decode_interface,
	test_wuffs_gzip_decode_midsummer,
	test_wuffs_gzip_decode_pi,

	#ifdef WUFFS_MIMIC

	test_mimic_gzip_decode_midsummer,
	test_mimic_gzip_decode_pi,

	#endif // WUFFS_MIMIC

	NULL,
	};

	proc g_benches[] = {

	bench_wuffs_gzip_decode_10k,
	bench_wuffs_gzip_decode_100k,

	#ifdef WUFFS_MIMIC

	bench_mimic_gzip_decode_10k,
	bench_mimic_gzip_decode_100k,

	#endif // WUFFS_MIMIC

	NULL,
	};

	int //
	main(int argc, char** argv) {
	g_proc_package_name = "std/gzip";
	return test_main(argc, argv, g_tests, g_benches);
	}