// Copyright (c) 2006-2008 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "chrome/common/file_descriptor_set_posix.h" #include "base/eintr_wrapper.h" #include "base/logging.h" FileDescriptorSet::FileDescriptorSet() : consumed_descriptor_highwater_(0) { } FileDescriptorSet::~FileDescriptorSet() { if (consumed_descriptor_highwater_ == descriptors_.size()) return; LOG(WARNING) << "FileDescriptorSet destroyed with unconsumed descriptors"; // We close all the descriptors where the close flag is set. If this // message should have been transmitted, then closing those with close // flags set mirrors the expected behaviour. // // If this message was received with more descriptors than expected // (which could a DOS against the browser by a rogue renderer) then all // the descriptors have their close flag set and we free all the extra // kernel resources. for (unsigned i = consumed_descriptor_highwater_; i < descriptors_.size(); ++i) { if (descriptors_[i].auto_close) HANDLE_EINTR(close(descriptors_[i].fd)); } } bool FileDescriptorSet::Add(int fd) { if (descriptors_.size() == MAX_DESCRIPTORS_PER_MESSAGE) return false; struct base::FileDescriptor sd; sd.fd = fd; sd.auto_close = false; descriptors_.push_back(sd); return true; } bool FileDescriptorSet::AddAndAutoClose(int fd) { if (descriptors_.size() == MAX_DESCRIPTORS_PER_MESSAGE) return false; struct base::FileDescriptor sd; sd.fd = fd; sd.auto_close = true; descriptors_.push_back(sd); DCHECK(descriptors_.size() <= MAX_DESCRIPTORS_PER_MESSAGE); return true; } int FileDescriptorSet::GetDescriptorAt(unsigned index) const { if (index >= descriptors_.size()) return -1; // We should always walk the descriptors in order, so it's reasonable to // enforce this. Consider the case where a compromised renderer sends us // the following message: // // ExampleMsg: // num_fds:2 msg:FD(index = 1) control:SCM_RIGHTS {n, m} // // Here the renderer sent us a message which should have a descriptor, but // actually sent two in an attempt to fill our fd table and kill us. By // setting the index of the descriptor in the message to 1 (it should be // 0), we would record a highwater of 1 and then consider all the // descriptors to have been used. // // So we can either track of the use of each descriptor in a bitset, or we // can enforce that we walk the indexes strictly in order. // // There's one more wrinkle: When logging messages, we may reparse them. So // we have an exception: When the consumed_descriptor_highwater_ is at the // end of the array and index 0 is requested, we reset the highwater value. if (index == 0 && consumed_descriptor_highwater_ == descriptors_.size()) consumed_descriptor_highwater_ = 0; if (index != consumed_descriptor_highwater_) return -1; consumed_descriptor_highwater_ = index + 1; return descriptors_[index].fd; } void FileDescriptorSet::GetDescriptors(int* buffer) const { for (std::vector::const_iterator i = descriptors_.begin(); i != descriptors_.end(); ++i) { *(buffer++) = i->fd; } } void FileDescriptorSet::CommitAll() { for (std::vector::iterator i = descriptors_.begin(); i != descriptors_.end(); ++i) { if (i->auto_close) HANDLE_EINTR(close(i->fd)); } descriptors_.clear(); consumed_descriptor_highwater_ = 0; } void FileDescriptorSet::SetDescriptors(const int* buffer, unsigned count) { DCHECK_LE(count, MAX_DESCRIPTORS_PER_MESSAGE); DCHECK_EQ(descriptors_.size(), 0u); DCHECK_EQ(consumed_descriptor_highwater_, 0u); descriptors_.reserve(count); for (unsigned i = 0; i < count; ++i) { struct base::FileDescriptor sd; sd.fd = buffer[i]; sd.auto_close = true; descriptors_.push_back(sd); } }