os.cpp - platform/system/connectivity/wifilogd - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * 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
  *
  *      http://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.
  */

 #include <algorithm>
 #include <cerrno>
 #include <cstdint>
 #include <cstring>

 #include "android-base/logging.h"

 #include "wifilogd/local_utils.h"
 #include "wifilogd/os.h"

 namespace android {
 namespace wifilogd {

 using local_utils::GetMaxVal;

 namespace {
 constexpr auto kMaxNanoSeconds = 1000 * 1000 * 1000 - 1;
 }

 constexpr int Os::kInvalidFd;

 Os::Os() : raw_os_(new RawOs()) {}
 Os::Os(std::unique_ptr<RawOs> raw_os) : raw_os_(std::move(raw_os)) {}
 Os::~Os() {}

 std::tuple<int, Os::Errno> Os::GetControlSocket(
     const std::string& socket_name) {
   int sock_fd = raw_os_->GetControlSocket(socket_name.c_str());
   if (sock_fd < 0) {
     return {kInvalidFd, errno};
   } else {
     return {sock_fd, 0};
   }
 }

 Os::Timestamp Os::GetTimestamp(clockid_t clock_id) const {
   struct timespec now_timespec;
   int failed = raw_os_->ClockGettime(clock_id, &now_timespec);
   if (failed) {
     LOG(FATAL) << "Unexpected error: " << std::strerror(errno);
   }
   CHECK(now_timespec.tv_nsec <= kMaxNanoSeconds);

   Timestamp now_timestamp;
   now_timestamp.secs = SAFELY_CLAMP(
       now_timespec.tv_sec, uint32_t, 0,
       // The upper-bound comes from the source-type on 32-bit platforms,
       // and the dest-type on 64-bit platforms. Using min(), we can figure out
       // which type to use for the upper bound, without resorting to macros.
       std::min(static_cast<uintmax_t>(GetMaxVal(now_timestamp.secs)),
                static_cast<uintmax_t>(GetMaxVal(now_timespec.tv_sec))));
   now_timestamp.nsecs =
       SAFELY_CLAMP(now_timespec.tv_nsec, uint32_t, 0, kMaxNanoSeconds);
   return now_timestamp;
 }

 void Os::Nanosleep(uint32_t sleep_time_nsec) {
   struct timespec sleep_timespec = {
       0,  // tv_sec
       SAFELY_CLAMP(sleep_time_nsec, decltype(timespec::tv_nsec), 0, kMaxNanos)};

   int failed = 0;
   do {
     struct timespec remaining_timespec;
     failed = raw_os_->Nanosleep(&sleep_timespec, &remaining_timespec);
     sleep_timespec = remaining_timespec;
   } while (failed && errno == EINTR && sleep_timespec.tv_nsec > 0);

   if (failed && errno != EINTR) {
     // The only other documented errors for the underlying nanosleep() call are
     // EFAULT and EINVAL. But we always pass valid pointers, and the values in
     // |sleep_timespec| are always valid.
     LOG(FATAL) << "Unexpected error: " << std::strerror(errno);
   }
 }

 std::tuple<size_t, Os::Errno> Os::ReceiveDatagram(int fd, void* buf,
                                                   size_t buflen) {
   // recv() takes a size_t, but returns an ssize_t. That means that the largest
   // successful read that recv() can report is the maximal ssize_t. Passing a
   // larger |buflen| risks mistakenly reporting a truncated read.
   CHECK(buflen <= GetMaxVal<ssize_t>());

   const ssize_t res = raw_os_->Recv(fd, buf, buflen, MSG_TRUNC);
   if (res < 0) {
     return {0, errno};
   }

   // Due to the MSG_TRUNC flag, |res| may reasonably be larger than
   // |buflen|. In such cases, |res| indicates the full size of the datagram,
   // before being truncated to fit our buffer. Hence, we omit the
   // buffer-overflow CHECK that exists in Write().
   return {res, 0};
 }

 std::tuple<size_t, Os::Errno> Os::Write(int fd, const void* buf,
                                         size_t buflen) {
   // write() takes a size_t, but returns an ssize_t. That means that the
   // largest successful write that write() can report is the maximal ssize_t.
   // Passing a larger |buflen| risks mistakenly reporting a truncated write.
   CHECK(buflen <= GetMaxVal<ssize_t>());

   const ssize_t res = raw_os_->Write(fd, buf, buflen);
   if (res < 0) {
     return {0, errno};
   }

   CHECK(res <=
         SAFELY_CLAMP(buflen, ssize_t, 0,
                      GetMaxVal<ssize_t>()));  // Abort on buffer overflow.

   // Note that |res| may be less than buflen. However, a) a short write is
   // not an error, and b) |errno| may be stale, as |errno| is only guaranteed to
   // be set if an error occurred. Hence, we return Errno of 0 unconditionally.
   // See http://yarchive.net/comp/linux/write_error_return.html
   return {res, 0};
 }

 }  // namespace wifilogd
 }  // namespace android
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* 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
	*
	* http://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.
	*/

	#include <algorithm>
	#include <cerrno>
	#include <cstdint>
	#include <cstring>

	#include "android-base/logging.h"

	#include "wifilogd/local_utils.h"
	#include "wifilogd/os.h"

	namespace android {
	namespace wifilogd {

	using local_utils::GetMaxVal;

	namespace {
	constexpr auto kMaxNanoSeconds = 1000 * 1000 * 1000 - 1;
	}

	constexpr int Os::kInvalidFd;

	Os::Os() : raw_os_(new RawOs()) {}
	Os::Os(std::unique_ptr<RawOs> raw_os) : raw_os_(std::move(raw_os)) {}
	Os::~Os() {}

	std::tuple<int, Os::Errno> Os::GetControlSocket(
	const std::string& socket_name) {
	int sock_fd = raw_os_->GetControlSocket(socket_name.c_str());
	if (sock_fd < 0) {
	return {kInvalidFd, errno};
	} else {
	return {sock_fd, 0};
	}
	}

	Os::Timestamp Os::GetTimestamp(clockid_t clock_id) const {
	struct timespec now_timespec;
	int failed = raw_os_->ClockGettime(clock_id, &now_timespec);
	if (failed) {
	LOG(FATAL) << "Unexpected error: " << std::strerror(errno);
	}
	CHECK(now_timespec.tv_nsec <= kMaxNanoSeconds);

	Timestamp now_timestamp;
	now_timestamp.secs = SAFELY_CLAMP(
	now_timespec.tv_sec, uint32_t, 0,
	// The upper-bound comes from the source-type on 32-bit platforms,
	// and the dest-type on 64-bit platforms. Using min(), we can figure out
	// which type to use for the upper bound, without resorting to macros.
	std::min(static_cast<uintmax_t>(GetMaxVal(now_timestamp.secs)),
	static_cast<uintmax_t>(GetMaxVal(now_timespec.tv_sec))));
	now_timestamp.nsecs =
	SAFELY_CLAMP(now_timespec.tv_nsec, uint32_t, 0, kMaxNanoSeconds);
	return now_timestamp;
	}

	void Os::Nanosleep(uint32_t sleep_time_nsec) {
	struct timespec sleep_timespec = {
	0, // tv_sec
	SAFELY_CLAMP(sleep_time_nsec, decltype(timespec::tv_nsec), 0, kMaxNanos)};

	int failed = 0;
	do {
	struct timespec remaining_timespec;
	failed = raw_os_->Nanosleep(&sleep_timespec, &remaining_timespec);
	sleep_timespec = remaining_timespec;
	} while (failed && errno == EINTR && sleep_timespec.tv_nsec > 0);

	if (failed && errno != EINTR) {
	// The only other documented errors for the underlying nanosleep() call are
	// EFAULT and EINVAL. But we always pass valid pointers, and the values in
	// \|sleep_timespec\| are always valid.
	LOG(FATAL) << "Unexpected error: " << std::strerror(errno);
	}
	}

	std::tuple<size_t, Os::Errno> Os::ReceiveDatagram(int fd, void* buf,
	size_t buflen) {
	// recv() takes a size_t, but returns an ssize_t. That means that the largest
	// successful read that recv() can report is the maximal ssize_t. Passing a
	// larger \|buflen\| risks mistakenly reporting a truncated read.
	CHECK(buflen <= GetMaxVal<ssize_t>());

	const ssize_t res = raw_os_->Recv(fd, buf, buflen, MSG_TRUNC);
	if (res < 0) {
	return {0, errno};
	}

	// Due to the MSG_TRUNC flag, \|res\| may reasonably be larger than
	// \|buflen\|. In such cases, \|res\| indicates the full size of the datagram,
	// before being truncated to fit our buffer. Hence, we omit the
	// buffer-overflow CHECK that exists in Write().
	return {res, 0};
	}

	std::tuple<size_t, Os::Errno> Os::Write(int fd, const void* buf,
	size_t buflen) {
	// write() takes a size_t, but returns an ssize_t. That means that the
	// largest successful write that write() can report is the maximal ssize_t.
	// Passing a larger \|buflen\| risks mistakenly reporting a truncated write.
	CHECK(buflen <= GetMaxVal<ssize_t>());

	const ssize_t res = raw_os_->Write(fd, buf, buflen);
	if (res < 0) {
	return {0, errno};
	}

	CHECK(res <=
	SAFELY_CLAMP(buflen, ssize_t, 0,
	GetMaxVal<ssize_t>())); // Abort on buffer overflow.

	// Note that \|res\| may be less than buflen. However, a) a short write is
	// not an error, and b) \|errno\| may be stale, as \|errno\| is only guaranteed to
	// be set if an error occurred. Hence, we return Errno of 0 unconditionally.
	// See http://yarchive.net/comp/linux/write_error_return.html
	return {res, 0};
	}

	} // namespace wifilogd
	} // namespace android