naiveproxy/net/http/partial_data.cc
2018-08-11 05:35:24 +00:00

470 lines
15 KiB
C++

// Copyright (c) 2012 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 "net/http/partial_data.h"
#include <limits>
#include "base/bind.h"
#include "base/bind_helpers.h"
#include "base/callback_helpers.h"
#include "base/format_macros.h"
#include "base/logging.h"
#include "base/strings/string_number_conversions.h"
#include "base/strings/string_util.h"
#include "base/strings/stringprintf.h"
#include "net/base/net_errors.h"
#include "net/disk_cache/disk_cache.h"
#include "net/http/http_response_headers.h"
#include "net/http/http_util.h"
namespace net {
namespace {
// The headers that we have to process.
const char kLengthHeader[] = "Content-Length";
const char kRangeHeader[] = "Content-Range";
const int kDataStream = 1;
} // namespace
PartialData::PartialData()
: current_range_start_(0),
current_range_end_(0),
cached_start_(0),
cached_min_len_(0),
resource_size_(0),
range_present_(false),
final_range_(false),
sparse_entry_(true),
truncated_(false),
initial_validation_(false),
weak_factory_(this) {}
PartialData::~PartialData() = default;
bool PartialData::Init(const HttpRequestHeaders& headers) {
std::string range_header;
if (!headers.GetHeader(HttpRequestHeaders::kRange, &range_header))
return false;
std::vector<HttpByteRange> ranges;
if (!HttpUtil::ParseRangeHeader(range_header, &ranges) || ranges.size() != 1)
return false;
// We can handle this range request.
byte_range_ = ranges[0];
if (!byte_range_.IsValid())
return false;
current_range_start_ = byte_range_.first_byte_position();
DVLOG(1) << "Range start: " << current_range_start_ << " end: " <<
byte_range_.last_byte_position();
return true;
}
void PartialData::SetHeaders(const HttpRequestHeaders& headers) {
DCHECK(extra_headers_.IsEmpty());
extra_headers_.CopyFrom(headers);
}
void PartialData::RestoreHeaders(HttpRequestHeaders* headers) const {
DCHECK(current_range_start_ >= 0 || byte_range_.IsSuffixByteRange());
int64_t end = byte_range_.IsSuffixByteRange()
? byte_range_.suffix_length()
: byte_range_.last_byte_position();
headers->CopyFrom(extra_headers_);
if (truncated_ || !byte_range_.IsValid())
return;
if (current_range_start_ < 0) {
headers->SetHeader(HttpRequestHeaders::kRange,
HttpByteRange::Suffix(end).GetHeaderValue());
} else {
headers->SetHeader(HttpRequestHeaders::kRange,
HttpByteRange::Bounded(
current_range_start_, end).GetHeaderValue());
}
}
int PartialData::ShouldValidateCache(disk_cache::Entry* entry,
const CompletionCallback& callback) {
DCHECK_GE(current_range_start_, 0);
// Scan the disk cache for the first cached portion within this range.
int len = GetNextRangeLen();
if (!len)
return 0;
DVLOG(3) << "ShouldValidateCache len: " << len;
if (sparse_entry_) {
DCHECK(callback_.is_null());
int64_t* start = new int64_t;
// This callback now owns "start". We make sure to keep it
// in a local variable since we want to use it later.
CompletionCallback cb =
base::Bind(&PartialData::GetAvailableRangeCompleted,
weak_factory_.GetWeakPtr(), base::Owned(start));
cached_min_len_ =
entry->GetAvailableRange(current_range_start_, len, start, cb);
if (cached_min_len_ == ERR_IO_PENDING) {
callback_ = callback;
return ERR_IO_PENDING;
} else {
cached_start_ = *start;
}
} else if (!truncated_) {
if (byte_range_.HasFirstBytePosition() &&
byte_range_.first_byte_position() >= resource_size_) {
// The caller should take care of this condition because we should have
// failed IsRequestedRangeOK(), but it's better to be consistent here.
len = 0;
}
cached_min_len_ = len;
cached_start_ = current_range_start_;
}
if (cached_min_len_ < 0)
return cached_min_len_;
// Return a positive number to indicate success (versus error or finished).
return 1;
}
void PartialData::PrepareCacheValidation(disk_cache::Entry* entry,
HttpRequestHeaders* headers) {
DCHECK_GE(current_range_start_, 0);
DCHECK_GE(cached_min_len_, 0);
int len = GetNextRangeLen();
DCHECK_NE(0, len);
range_present_ = false;
headers->CopyFrom(extra_headers_);
if (!cached_min_len_) {
// We don't have anything else stored.
final_range_ = true;
cached_start_ =
byte_range_.HasLastBytePosition() ? current_range_start_ + len : 0;
}
if (current_range_start_ == cached_start_) {
// The data lives in the cache.
range_present_ = true;
current_range_end_ = cached_start_ + cached_min_len_ - 1;
if (len == cached_min_len_)
final_range_ = true;
} else {
// This range is not in the cache.
current_range_end_ = cached_start_ - 1;
}
headers->SetHeader(
HttpRequestHeaders::kRange,
HttpByteRange::Bounded(current_range_start_, current_range_end_)
.GetHeaderValue());
}
bool PartialData::IsCurrentRangeCached() const {
return range_present_;
}
bool PartialData::IsLastRange() const {
return final_range_;
}
bool PartialData::UpdateFromStoredHeaders(const HttpResponseHeaders* headers,
disk_cache::Entry* entry,
bool truncated,
bool writing_in_progress) {
resource_size_ = 0;
if (truncated) {
DCHECK_EQ(headers->response_code(), 200);
// We don't have the real length and the user may be trying to create a
// sparse entry so let's not write to this entry.
if (byte_range_.IsValid())
return false;
if (!headers->HasStrongValidators())
return false;
// Now we avoid resume if there is no content length, but that was not
// always the case so double check here.
int64_t total_length = headers->GetContentLength();
if (total_length <= 0)
return false;
// In case we see a truncated entry, we first send a network request for
// 1 byte range with If-Range: to probe server support for resumption.
// The setting of |current_range_start_| and |cached_start_| below (with any
// positive value of |cached_min_len_|) results in that.
//
// Setting |initial_validation_| to true is how this communicates to
// HttpCache::Transaction that we're doing that (and that it's not the user
// asking for one byte), so if it sees a 206 with that flag set it will call
// SetRangeToStartDownload(), and then restart the process looking for the
// entire file (which is what the user wanted), with the cache handling
// the previous portion, and then a second network request for the entire
// rest of the range. A 200 in response to the probe request can be simply
// returned directly to the user.
truncated_ = true;
initial_validation_ = true;
sparse_entry_ = false;
int current_len = entry->GetDataSize(kDataStream);
byte_range_.set_first_byte_position(current_len);
resource_size_ = total_length;
current_range_start_ = current_len;
cached_min_len_ = current_len;
cached_start_ = current_len + 1;
return true;
}
sparse_entry_ = (headers->response_code() == 206);
if (writing_in_progress || sparse_entry_) {
// |writing_in_progress| means another Transaction is still fetching the
// body, so the only way we can see the length is if the server sent it
// in Content-Length -- GetDataSize would just return what got written
// thus far.
//
// |sparse_entry_| means a 206, and for those FixContentLength arranges it
// so that Content-Length written to the cache has the full length (on wire
// it's for a particular range only); while GetDataSize would be unusable
// since the data is stored using WriteSparseData, and not in the usual data
// stream.
resource_size_ = headers->GetContentLength();
if (resource_size_ <= 0)
return false;
} else {
// If we can safely use GetDataSize, it's preferrable since it's usable for
// things w/o Content-Length, such as chunked content.
resource_size_ = entry->GetDataSize(kDataStream);
}
DVLOG(2) << "UpdateFromStoredHeaders size: " << resource_size_;
if (sparse_entry_) {
// If our previous is a 206, we need strong validators as we may be
// stiching the cached data and network data together.
if (!headers->HasStrongValidators())
return false;
// Make sure that this is really a sparse entry.
return entry->CouldBeSparse();
}
return true;
}
void PartialData::SetRangeToStartDownload() {
DCHECK(truncated_);
DCHECK(!sparse_entry_);
current_range_start_ = 0;
cached_start_ = 0;
initial_validation_ = false;
}
bool PartialData::IsRequestedRangeOK() {
if (byte_range_.IsValid()) {
if (!byte_range_.ComputeBounds(resource_size_))
return false;
if (truncated_)
return true;
if (current_range_start_ < 0)
current_range_start_ = byte_range_.first_byte_position();
} else {
// This is not a range request but we have partial data stored.
current_range_start_ = 0;
byte_range_.set_last_byte_position(resource_size_ - 1);
}
bool rv = current_range_start_ >= 0;
if (!rv)
current_range_start_ = 0;
return rv;
}
bool PartialData::ResponseHeadersOK(const HttpResponseHeaders* headers) {
if (headers->response_code() == 304) {
if (!byte_range_.IsValid() || truncated_)
return true;
// We must have a complete range here.
return byte_range_.HasFirstBytePosition() &&
byte_range_.HasLastBytePosition();
}
int64_t start, end, total_length;
if (!headers->GetContentRangeFor206(&start, &end, &total_length))
return false;
if (total_length <= 0)
return false;
DCHECK_EQ(headers->response_code(), 206);
// A server should return a valid content length with a 206 (per the standard)
// but relax the requirement because some servers don't do that.
int64_t content_length = headers->GetContentLength();
if (content_length > 0 && content_length != end - start + 1)
return false;
if (!resource_size_) {
// First response. Update our values with the ones provided by the server.
resource_size_ = total_length;
if (!byte_range_.HasFirstBytePosition()) {
byte_range_.set_first_byte_position(start);
current_range_start_ = start;
}
if (!byte_range_.HasLastBytePosition())
byte_range_.set_last_byte_position(end);
} else if (resource_size_ != total_length) {
return false;
}
if (truncated_) {
if (!byte_range_.HasLastBytePosition())
byte_range_.set_last_byte_position(end);
}
if (start != current_range_start_)
return false;
if (!current_range_end_) {
// There is nothing in the cache.
DCHECK(byte_range_.HasLastBytePosition());
current_range_end_ = byte_range_.last_byte_position();
if (current_range_end_ >= resource_size_) {
// We didn't know the real file size, and the server is saying that the
// requested range goes beyond the size. Fix it.
current_range_end_ = end;
byte_range_.set_last_byte_position(end);
}
}
// If we received a range, but it's not exactly the range we asked for, avoid
// trouble and signal an error.
if (end != current_range_end_)
return false;
return true;
}
// We are making multiple requests to complete the range requested by the user.
// Just assume that everything is fine and say that we are returning what was
// requested.
void PartialData::FixResponseHeaders(HttpResponseHeaders* headers,
bool success) {
if (truncated_)
return;
if (byte_range_.IsValid() && success) {
headers->UpdateWithNewRange(byte_range_, resource_size_, !sparse_entry_);
return;
}
headers->RemoveHeader(kLengthHeader);
headers->RemoveHeader(kRangeHeader);
if (byte_range_.IsValid()) {
headers->ReplaceStatusLine("HTTP/1.1 416 Requested Range Not Satisfiable");
headers->AddHeader(base::StringPrintf("%s: bytes 0-0/%" PRId64,
kRangeHeader, resource_size_));
headers->AddHeader(base::StringPrintf("%s: 0", kLengthHeader));
} else {
// TODO(rvargas): Is it safe to change the protocol version?
headers->ReplaceStatusLine("HTTP/1.1 200 OK");
DCHECK_NE(resource_size_, 0);
headers->AddHeader(base::StringPrintf("%s: %" PRId64, kLengthHeader,
resource_size_));
}
}
void PartialData::FixContentLength(HttpResponseHeaders* headers) {
headers->RemoveHeader(kLengthHeader);
headers->AddHeader(base::StringPrintf("%s: %" PRId64, kLengthHeader,
resource_size_));
}
int PartialData::CacheRead(disk_cache::Entry* entry,
IOBuffer* data,
int data_len,
const CompletionCallback& callback) {
int read_len = std::min(data_len, cached_min_len_);
if (!read_len)
return 0;
int rv = 0;
if (sparse_entry_) {
rv = entry->ReadSparseData(current_range_start_, data, read_len,
callback);
} else {
if (current_range_start_ > std::numeric_limits<int32_t>::max())
return ERR_INVALID_ARGUMENT;
rv = entry->ReadData(kDataStream, static_cast<int>(current_range_start_),
data, read_len, callback);
}
return rv;
}
int PartialData::CacheWrite(disk_cache::Entry* entry,
IOBuffer* data,
int data_len,
const CompletionCallback& callback) {
DVLOG(3) << "To write: " << data_len;
if (sparse_entry_) {
return entry->WriteSparseData(
current_range_start_, data, data_len, callback);
} else {
if (current_range_start_ > std::numeric_limits<int32_t>::max())
return ERR_INVALID_ARGUMENT;
return entry->WriteData(kDataStream, static_cast<int>(current_range_start_),
data, data_len, callback, true);
}
}
void PartialData::OnCacheReadCompleted(int result) {
DVLOG(3) << "Read: " << result;
if (result > 0) {
current_range_start_ += result;
cached_min_len_ -= result;
DCHECK_GE(cached_min_len_, 0);
}
}
void PartialData::OnNetworkReadCompleted(int result) {
if (result > 0)
current_range_start_ += result;
}
int PartialData::GetNextRangeLen() {
int64_t range_len =
byte_range_.HasLastBytePosition()
? byte_range_.last_byte_position() - current_range_start_ + 1
: std::numeric_limits<int32_t>::max();
if (range_len > std::numeric_limits<int32_t>::max())
range_len = std::numeric_limits<int32_t>::max();
return static_cast<int32_t>(range_len);
}
void PartialData::GetAvailableRangeCompleted(int64_t* start, int result) {
DCHECK(!callback_.is_null());
DCHECK_NE(ERR_IO_PENDING, result);
cached_start_ = *start;
cached_min_len_ = result;
if (result >= 0)
result = 1; // Return success, go ahead and validate the entry.
base::ResetAndReturn(&callback_).Run(result);
}
} // namespace net