// 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. // The rules for header parsing were borrowed from Firefox: // http://lxr.mozilla.org/seamonkey/source/netwerk/protocol/http/src/nsHttpResponseHead.cpp // The rules for parsing content-types were also borrowed from Firefox: // http://lxr.mozilla.org/mozilla/source/netwerk/base/src/nsURLHelper.cpp#834 #include "net/http/http_response_headers.h" #include #include #include #include #include "base/format_macros.h" #include "base/logging.h" #include "base/metrics/histogram_macros.h" #include "base/pickle.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_piece.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/time/time.h" #include "base/values.h" #include "net/base/escape.h" #include "net/base/parse_number.h" #include "net/http/http_byte_range.h" #include "net/http/http_log_util.h" #include "net/http/http_util.h" #include "net/log/net_log_capture_mode.h" using base::StringPiece; using base::Time; using base::TimeDelta; namespace net { //----------------------------------------------------------------------------- namespace { // These headers are RFC 2616 hop-by-hop headers; // not to be stored by caches. const char* const kHopByHopResponseHeaders[] = { "connection", "proxy-connection", "keep-alive", "trailer", "transfer-encoding", "upgrade" }; // These headers are challenge response headers; // not to be stored by caches. const char* const kChallengeResponseHeaders[] = { "www-authenticate", "proxy-authenticate" }; // These headers are cookie setting headers; // not to be stored by caches or disclosed otherwise. const char* const kCookieResponseHeaders[] = { "set-cookie", "set-cookie2", "clear-site-data", }; // By default, do not cache Strict-Transport-Security or Public-Key-Pins. // This avoids erroneously re-processing them on page loads from cache --- // they are defined to be valid only on live and error-free HTTPS // connections. const char* const kSecurityStateHeaders[] = { "strict-transport-security", "public-key-pins" }; // These response headers are not copied from a 304/206 response to the cached // response headers. This list is based on Mozilla's nsHttpResponseHead.cpp. const char* const kNonUpdatedHeaders[] = { "connection", "proxy-connection", "keep-alive", "www-authenticate", "proxy-authenticate", "trailer", "transfer-encoding", "upgrade", "etag", "x-frame-options", "x-xss-protection", }; // Some header prefixes mean "Don't copy this header from a 304 response.". // Rather than listing all the relevant headers, we can consolidate them into // this list: const char* const kNonUpdatedHeaderPrefixes[] = { "content-", "x-content-", "x-webkit-" }; bool ShouldUpdateHeader(base::StringPiece name) { for (size_t i = 0; i < arraysize(kNonUpdatedHeaders); ++i) { if (base::LowerCaseEqualsASCII(name, kNonUpdatedHeaders[i])) return false; } for (size_t i = 0; i < arraysize(kNonUpdatedHeaderPrefixes); ++i) { if (base::StartsWith(name, kNonUpdatedHeaderPrefixes[i], base::CompareCase::INSENSITIVE_ASCII)) return false; } return true; } void CheckDoesNotHaveEmbededNulls(const std::string& str) { // Care needs to be taken when adding values to the raw headers string to // make sure it does not contain embeded NULLs. Any embeded '\0' may be // understood as line terminators and change how header lines get tokenized. CHECK(str.find('\0') == std::string::npos); } } // namespace const char HttpResponseHeaders::kContentRange[] = "Content-Range"; struct HttpResponseHeaders::ParsedHeader { // A header "continuation" contains only a subsequent value for the // preceding header. (Header values are comma separated.) bool is_continuation() const { return name_begin == name_end; } std::string::const_iterator name_begin; std::string::const_iterator name_end; std::string::const_iterator value_begin; std::string::const_iterator value_end; }; //----------------------------------------------------------------------------- HttpResponseHeaders::HttpResponseHeaders(const std::string& raw_input) : response_code_(-1) { Parse(raw_input); // The most important thing to do with this histogram is find out // the existence of unusual HTTP status codes. As it happens // right now, there aren't double-constructions of response headers // using this constructor, so our counts should also be accurate, // without instantiating the histogram in two places. It is also // important that this histogram not collect data in the other // constructor, which rebuilds an histogram from a pickle, since // that would actually create a double call between the original // HttpResponseHeader that was serialized, and initialization of the // new object from that pickle. UMA_HISTOGRAM_CUSTOM_ENUMERATION("Net.HttpResponseCode", HttpUtil::MapStatusCodeForHistogram( response_code_), // Note the third argument is only // evaluated once, see macro // definition for details. HttpUtil::GetStatusCodesForHistogram()); } HttpResponseHeaders::HttpResponseHeaders(base::PickleIterator* iter) : response_code_(-1) { std::string raw_input; if (iter->ReadString(&raw_input)) Parse(raw_input); } void HttpResponseHeaders::Persist(base::Pickle* pickle, PersistOptions options) { if (options == PERSIST_RAW) { pickle->WriteString(raw_headers_); return; // Done. } HeaderSet filter_headers; // Construct set of headers to filter out based on options. if ((options & PERSIST_SANS_NON_CACHEABLE) == PERSIST_SANS_NON_CACHEABLE) AddNonCacheableHeaders(&filter_headers); if ((options & PERSIST_SANS_COOKIES) == PERSIST_SANS_COOKIES) AddCookieHeaders(&filter_headers); if ((options & PERSIST_SANS_CHALLENGES) == PERSIST_SANS_CHALLENGES) AddChallengeHeaders(&filter_headers); if ((options & PERSIST_SANS_HOP_BY_HOP) == PERSIST_SANS_HOP_BY_HOP) AddHopByHopHeaders(&filter_headers); if ((options & PERSIST_SANS_RANGES) == PERSIST_SANS_RANGES) AddHopContentRangeHeaders(&filter_headers); if ((options & PERSIST_SANS_SECURITY_STATE) == PERSIST_SANS_SECURITY_STATE) AddSecurityStateHeaders(&filter_headers); std::string blob; blob.reserve(raw_headers_.size()); // This copies the status line w/ terminator null. // Note raw_headers_ has embedded nulls instead of \n, // so this just copies the first header line. blob.assign(raw_headers_.c_str(), strlen(raw_headers_.c_str()) + 1); for (size_t i = 0; i < parsed_.size(); ++i) { DCHECK(!parsed_[i].is_continuation()); // Locate the start of the next header. size_t k = i; while (++k < parsed_.size() && parsed_[k].is_continuation()) {} --k; std::string header_name = base::ToLowerASCII( base::StringPiece(parsed_[i].name_begin, parsed_[i].name_end)); if (filter_headers.find(header_name) == filter_headers.end()) { // Make sure there is a null after the value. blob.append(parsed_[i].name_begin, parsed_[k].value_end); blob.push_back('\0'); } i = k; } blob.push_back('\0'); pickle->WriteString(blob); } void HttpResponseHeaders::Update(const HttpResponseHeaders& new_headers) { DCHECK(new_headers.response_code() == 304 || new_headers.response_code() == 206); // Copy up to the null byte. This just copies the status line. std::string new_raw_headers(raw_headers_.c_str()); new_raw_headers.push_back('\0'); HeaderSet updated_headers; // NOTE: we write the new headers then the old headers for convenience. The // order should not matter. // Figure out which headers we want to take from new_headers: for (size_t i = 0; i < new_headers.parsed_.size(); ++i) { const HeaderList& new_parsed = new_headers.parsed_; DCHECK(!new_parsed[i].is_continuation()); // Locate the start of the next header. size_t k = i; while (++k < new_parsed.size() && new_parsed[k].is_continuation()) {} --k; base::StringPiece name(new_parsed[i].name_begin, new_parsed[i].name_end); if (ShouldUpdateHeader(name)) { std::string name_lower = base::ToLowerASCII(name); updated_headers.insert(name_lower); // Preserve this header line in the merged result, making sure there is // a null after the value. new_raw_headers.append(new_parsed[i].name_begin, new_parsed[k].value_end); new_raw_headers.push_back('\0'); } i = k; } // Now, build the new raw headers. MergeWithHeaders(new_raw_headers, updated_headers); } void HttpResponseHeaders::MergeWithHeaders(const std::string& raw_headers, const HeaderSet& headers_to_remove) { std::string new_raw_headers(raw_headers); for (size_t i = 0; i < parsed_.size(); ++i) { DCHECK(!parsed_[i].is_continuation()); // Locate the start of the next header. size_t k = i; while (++k < parsed_.size() && parsed_[k].is_continuation()) {} --k; std::string name = base::ToLowerASCII( base::StringPiece(parsed_[i].name_begin, parsed_[i].name_end)); if (headers_to_remove.find(name) == headers_to_remove.end()) { // It's ok to preserve this header in the final result. new_raw_headers.append(parsed_[i].name_begin, parsed_[k].value_end); new_raw_headers.push_back('\0'); } i = k; } new_raw_headers.push_back('\0'); // Make this object hold the new data. raw_headers_.clear(); parsed_.clear(); Parse(new_raw_headers); } void HttpResponseHeaders::RemoveHeader(const std::string& name) { // Copy up to the null byte. This just copies the status line. std::string new_raw_headers(raw_headers_.c_str()); new_raw_headers.push_back('\0'); std::string lowercase_name = base::ToLowerASCII(name); HeaderSet to_remove; to_remove.insert(lowercase_name); MergeWithHeaders(new_raw_headers, to_remove); } void HttpResponseHeaders::RemoveHeaders( const std::unordered_set& header_names) { // Copy up to the null byte. This just copies the status line. std::string new_raw_headers(raw_headers_.c_str()); new_raw_headers.push_back('\0'); HeaderSet to_remove; for (const auto& header_name : header_names) { to_remove.insert(base::ToLowerASCII(header_name)); } MergeWithHeaders(new_raw_headers, to_remove); } void HttpResponseHeaders::RemoveHeaderLine(const std::string& name, const std::string& value) { std::string name_lowercase = base::ToLowerASCII(name); std::string new_raw_headers(GetStatusLine()); new_raw_headers.push_back('\0'); new_raw_headers.reserve(raw_headers_.size()); size_t iter = 0; std::string old_header_name; std::string old_header_value; while (EnumerateHeaderLines(&iter, &old_header_name, &old_header_value)) { std::string old_header_name_lowercase = base::ToLowerASCII(old_header_name); if (name_lowercase == old_header_name_lowercase && value == old_header_value) continue; new_raw_headers.append(old_header_name); new_raw_headers.push_back(':'); new_raw_headers.push_back(' '); new_raw_headers.append(old_header_value); new_raw_headers.push_back('\0'); } new_raw_headers.push_back('\0'); // Make this object hold the new data. raw_headers_.clear(); parsed_.clear(); Parse(new_raw_headers); } void HttpResponseHeaders::AddHeader(const std::string& header) { CheckDoesNotHaveEmbededNulls(header); DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 2]); DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 1]); // Don't copy the last null. std::string new_raw_headers(raw_headers_, 0, raw_headers_.size() - 1); new_raw_headers.append(header); new_raw_headers.push_back('\0'); new_raw_headers.push_back('\0'); // Make this object hold the new data. raw_headers_.clear(); parsed_.clear(); Parse(new_raw_headers); } void HttpResponseHeaders::AddCookie(const std::string& cookie_string) { AddHeader("Set-Cookie: " + cookie_string); } void HttpResponseHeaders::ReplaceStatusLine(const std::string& new_status) { CheckDoesNotHaveEmbededNulls(new_status); // Copy up to the null byte. This just copies the status line. std::string new_raw_headers(new_status); new_raw_headers.push_back('\0'); HeaderSet empty_to_remove; MergeWithHeaders(new_raw_headers, empty_to_remove); } void HttpResponseHeaders::UpdateWithNewRange(const HttpByteRange& byte_range, int64_t resource_size, bool replace_status_line) { DCHECK(byte_range.IsValid()); DCHECK(byte_range.HasFirstBytePosition()); DCHECK(byte_range.HasLastBytePosition()); const char kLengthHeader[] = "Content-Length"; const char kRangeHeader[] = "Content-Range"; RemoveHeader(kLengthHeader); RemoveHeader(kRangeHeader); int64_t start = byte_range.first_byte_position(); int64_t end = byte_range.last_byte_position(); int64_t range_len = end - start + 1; if (replace_status_line) ReplaceStatusLine("HTTP/1.1 206 Partial Content"); AddHeader(base::StringPrintf("%s: bytes %" PRId64 "-%" PRId64 "/%" PRId64, kRangeHeader, start, end, resource_size)); AddHeader(base::StringPrintf("%s: %" PRId64, kLengthHeader, range_len)); } void HttpResponseHeaders::Parse(const std::string& raw_input) { raw_headers_.reserve(raw_input.size()); // ParseStatusLine adds a normalized status line to raw_headers_ std::string::const_iterator line_begin = raw_input.begin(); std::string::const_iterator line_end = std::find(line_begin, raw_input.end(), '\0'); // has_headers = true, if there is any data following the status line. // Used by ParseStatusLine() to decide if a HTTP/0.9 is really a HTTP/1.0. bool has_headers = (line_end != raw_input.end() && (line_end + 1) != raw_input.end() && *(line_end + 1) != '\0'); ParseStatusLine(line_begin, line_end, has_headers); raw_headers_.push_back('\0'); // Terminate status line with a null. if (line_end == raw_input.end()) { raw_headers_.push_back('\0'); // Ensure the headers end with a double null. DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 2]); DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 1]); return; } // Including a terminating null byte. size_t status_line_len = raw_headers_.size(); // Now, we add the rest of the raw headers to raw_headers_, and begin parsing // it (to populate our parsed_ vector). raw_headers_.append(line_end + 1, raw_input.end()); // Ensure the headers end with a double null. while (raw_headers_.size() < 2 || raw_headers_[raw_headers_.size() - 2] != '\0' || raw_headers_[raw_headers_.size() - 1] != '\0') { raw_headers_.push_back('\0'); } // Adjust to point at the null byte following the status line line_end = raw_headers_.begin() + status_line_len - 1; HttpUtil::HeadersIterator headers(line_end + 1, raw_headers_.end(), std::string(1, '\0')); while (headers.GetNext()) { AddHeader(headers.name_begin(), headers.name_end(), headers.values_begin(), headers.values_end()); } DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 2]); DCHECK_EQ('\0', raw_headers_[raw_headers_.size() - 1]); } bool HttpResponseHeaders::GetNormalizedHeader(const std::string& name, std::string* value) const { // If you hit this assertion, please use EnumerateHeader instead! DCHECK(!HttpUtil::IsNonCoalescingHeader(name)); value->clear(); bool found = false; size_t i = 0; while (i < parsed_.size()) { i = FindHeader(i, name); if (i == std::string::npos) break; found = true; if (!value->empty()) value->append(", "); std::string::const_iterator value_begin = parsed_[i].value_begin; std::string::const_iterator value_end = parsed_[i].value_end; while (++i < parsed_.size() && parsed_[i].is_continuation()) value_end = parsed_[i].value_end; value->append(value_begin, value_end); } return found; } std::string HttpResponseHeaders::GetStatusLine() const { // copy up to the null byte. return std::string(raw_headers_.c_str()); } std::string HttpResponseHeaders::GetStatusText() const { // GetStatusLine() is already normalized, so it has the format: // ' SP ' or // ' SP SP '. std::string status_text = GetStatusLine(); std::string::const_iterator begin = status_text.begin(); std::string::const_iterator end = status_text.end(); // Seek to beginning of . begin = std::find(begin, end, ' '); CHECK(begin != end); ++begin; CHECK(begin != end); // See if there is another space. begin = std::find(begin, end, ' '); if (begin == end) return std::string(); ++begin; CHECK(begin != end); return std::string(begin, end); } bool HttpResponseHeaders::EnumerateHeaderLines(size_t* iter, std::string* name, std::string* value) const { size_t i = *iter; if (i == parsed_.size()) return false; DCHECK(!parsed_[i].is_continuation()); name->assign(parsed_[i].name_begin, parsed_[i].name_end); std::string::const_iterator value_begin = parsed_[i].value_begin; std::string::const_iterator value_end = parsed_[i].value_end; while (++i < parsed_.size() && parsed_[i].is_continuation()) value_end = parsed_[i].value_end; value->assign(value_begin, value_end); *iter = i; return true; } bool HttpResponseHeaders::EnumerateHeader(size_t* iter, const base::StringPiece& name, std::string* value) const { size_t i; if (!iter || !*iter) { i = FindHeader(0, name); } else { i = *iter; if (i >= parsed_.size()) { i = std::string::npos; } else if (!parsed_[i].is_continuation()) { i = FindHeader(i, name); } } if (i == std::string::npos) { value->clear(); return false; } if (iter) *iter = i + 1; value->assign(parsed_[i].value_begin, parsed_[i].value_end); return true; } bool HttpResponseHeaders::HasHeaderValue(const base::StringPiece& name, const base::StringPiece& value) const { // The value has to be an exact match. This is important since // 'cache-control: no-cache' != 'cache-control: no-cache="foo"' size_t iter = 0; std::string temp; while (EnumerateHeader(&iter, name, &temp)) { if (base::EqualsCaseInsensitiveASCII(value, temp)) return true; } return false; } bool HttpResponseHeaders::HasHeader(const base::StringPiece& name) const { return FindHeader(0, name) != std::string::npos; } HttpResponseHeaders::~HttpResponseHeaders() { } // Note: this implementation implicitly assumes that line_end points at a valid // sentinel character (such as '\0'). // static HttpVersion HttpResponseHeaders::ParseVersion( std::string::const_iterator line_begin, std::string::const_iterator line_end) { std::string::const_iterator p = line_begin; // RFC2616 sec 3.1: HTTP-Version = "HTTP" "/" 1*DIGIT "." 1*DIGIT // TODO: (1*DIGIT apparently means one or more digits, but we only handle 1). // TODO: handle leading zeros, which is allowed by the rfc1616 sec 3.1. if (!base::StartsWith(base::StringPiece(line_begin, line_end), "http", base::CompareCase::INSENSITIVE_ASCII)) { DVLOG(1) << "missing status line"; return HttpVersion(); } p += 4; if (p >= line_end || *p != '/') { DVLOG(1) << "missing version"; return HttpVersion(); } std::string::const_iterator dot = std::find(p, line_end, '.'); if (dot == line_end) { DVLOG(1) << "malformed version"; return HttpVersion(); } ++p; // from / to first digit. ++dot; // from . to second digit. if (!(base::IsAsciiDigit(*p) && base::IsAsciiDigit(*dot))) { DVLOG(1) << "malformed version number"; return HttpVersion(); } uint16_t major = *p - '0'; uint16_t minor = *dot - '0'; return HttpVersion(major, minor); } // Note: this implementation implicitly assumes that line_end points at a valid // sentinel character (such as '\0'). void HttpResponseHeaders::ParseStatusLine( std::string::const_iterator line_begin, std::string::const_iterator line_end, bool has_headers) { // Extract the version number HttpVersion parsed_http_version = ParseVersion(line_begin, line_end); // Clamp the version number to one of: {0.9, 1.0, 1.1, 2.0} if (parsed_http_version == HttpVersion(0, 9) && !has_headers) { http_version_ = HttpVersion(0, 9); raw_headers_ = "HTTP/0.9"; } else if (parsed_http_version == HttpVersion(2, 0)) { http_version_ = HttpVersion(2, 0); raw_headers_ = "HTTP/2.0"; } else if (parsed_http_version >= HttpVersion(1, 1)) { http_version_ = HttpVersion(1, 1); raw_headers_ = "HTTP/1.1"; } else { // Treat everything else like HTTP 1.0 http_version_ = HttpVersion(1, 0); raw_headers_ = "HTTP/1.0"; } if (parsed_http_version != http_version_) { DVLOG(1) << "assuming HTTP/" << http_version_.major_value() << "." << http_version_.minor_value(); } // TODO(eroman): this doesn't make sense if ParseVersion failed. std::string::const_iterator p = std::find(line_begin, line_end, ' '); if (p == line_end) { DVLOG(1) << "missing response status; assuming 200 OK"; raw_headers_.append(" 200 OK"); response_code_ = 200; return; } // Skip whitespace. while (p < line_end && *p == ' ') ++p; std::string::const_iterator code = p; while (p < line_end && base::IsAsciiDigit(*p)) ++p; if (p == code) { DVLOG(1) << "missing response status number; assuming 200"; raw_headers_.append(" 200"); response_code_ = 200; return; } raw_headers_.push_back(' '); raw_headers_.append(code, p); base::StringToInt(StringPiece(code, p), &response_code_); // Skip whitespace. while (p < line_end && *p == ' ') ++p; // Trim trailing whitespace. while (line_end > p && line_end[-1] == ' ') --line_end; if (p == line_end) return; raw_headers_.push_back(' '); raw_headers_.append(p, line_end); } size_t HttpResponseHeaders::FindHeader(size_t from, const base::StringPiece& search) const { for (size_t i = from; i < parsed_.size(); ++i) { if (parsed_[i].is_continuation()) continue; base::StringPiece name(parsed_[i].name_begin, parsed_[i].name_end); if (base::EqualsCaseInsensitiveASCII(search, name)) return i; } return std::string::npos; } bool HttpResponseHeaders::GetCacheControlDirective(const StringPiece& directive, TimeDelta* result) const { StringPiece name("cache-control"); std::string value; size_t directive_size = directive.size(); size_t iter = 0; while (EnumerateHeader(&iter, name, &value)) { if (value.size() > directive_size + 1 && base::StartsWith(value, directive, base::CompareCase::INSENSITIVE_ASCII) && value[directive_size] == '=') { int64_t seconds; base::StringToInt64( StringPiece(value.begin() + directive_size + 1, value.end()), &seconds); *result = TimeDelta::FromSeconds(seconds); return true; } } return false; } void HttpResponseHeaders::AddHeader(std::string::const_iterator name_begin, std::string::const_iterator name_end, std::string::const_iterator values_begin, std::string::const_iterator values_end) { // If the header can be coalesced, then we should split it up. if (values_begin == values_end || HttpUtil::IsNonCoalescingHeader(name_begin, name_end)) { AddToParsed(name_begin, name_end, values_begin, values_end); } else { HttpUtil::ValuesIterator it(values_begin, values_end, ','); while (it.GetNext()) { AddToParsed(name_begin, name_end, it.value_begin(), it.value_end()); // clobber these so that subsequent values are treated as continuations name_begin = name_end = raw_headers_.end(); } } } void HttpResponseHeaders::AddToParsed(std::string::const_iterator name_begin, std::string::const_iterator name_end, std::string::const_iterator value_begin, std::string::const_iterator value_end) { ParsedHeader header; header.name_begin = name_begin; header.name_end = name_end; header.value_begin = value_begin; header.value_end = value_end; parsed_.push_back(header); } void HttpResponseHeaders::AddNonCacheableHeaders(HeaderSet* result) const { // Add server specified transients. Any 'cache-control: no-cache="foo,bar"' // headers present in the response specify additional headers that we should // not store in the cache. const char kCacheControl[] = "cache-control"; const char kPrefix[] = "no-cache=\""; const size_t kPrefixLen = sizeof(kPrefix) - 1; std::string value; size_t iter = 0; while (EnumerateHeader(&iter, kCacheControl, &value)) { // If the value is smaller than the prefix and a terminal quote, skip // it. if (value.size() <= kPrefixLen || value.compare(0, kPrefixLen, kPrefix) != 0) { continue; } // if it doesn't end with a quote, then treat as malformed if (value[value.size()-1] != '\"') continue; // process the value as a comma-separated list of items. Each // item can be wrapped by linear white space. std::string::const_iterator item = value.begin() + kPrefixLen; std::string::const_iterator end = value.end() - 1; while (item != end) { // Find the comma to compute the length of the current item, // and the position of the next one. std::string::const_iterator item_next = std::find(item, end, ','); std::string::const_iterator item_end = end; if (item_next != end) { // Skip over comma for next position. item_end = item_next; item_next++; } // trim off leading and trailing whitespace in this item. HttpUtil::TrimLWS(&item, &item_end); // assuming the header is not empty, lowercase and insert into set if (item_end > item) { result->insert( base::ToLowerASCII(base::StringPiece(&*item, item_end - item))); } // Continue to next item. item = item_next; } } } void HttpResponseHeaders::AddHopByHopHeaders(HeaderSet* result) { for (size_t i = 0; i < arraysize(kHopByHopResponseHeaders); ++i) result->insert(std::string(kHopByHopResponseHeaders[i])); } void HttpResponseHeaders::AddCookieHeaders(HeaderSet* result) { for (size_t i = 0; i < arraysize(kCookieResponseHeaders); ++i) result->insert(std::string(kCookieResponseHeaders[i])); } void HttpResponseHeaders::AddChallengeHeaders(HeaderSet* result) { for (size_t i = 0; i < arraysize(kChallengeResponseHeaders); ++i) result->insert(std::string(kChallengeResponseHeaders[i])); } void HttpResponseHeaders::AddHopContentRangeHeaders(HeaderSet* result) { result->insert(kContentRange); } void HttpResponseHeaders::AddSecurityStateHeaders(HeaderSet* result) { for (size_t i = 0; i < arraysize(kSecurityStateHeaders); ++i) result->insert(std::string(kSecurityStateHeaders[i])); } void HttpResponseHeaders::GetMimeTypeAndCharset(std::string* mime_type, std::string* charset) const { mime_type->clear(); charset->clear(); std::string name = "content-type"; std::string value; bool had_charset = false; size_t iter = 0; while (EnumerateHeader(&iter, name, &value)) HttpUtil::ParseContentType(value, mime_type, charset, &had_charset, NULL); } bool HttpResponseHeaders::GetMimeType(std::string* mime_type) const { std::string unused; GetMimeTypeAndCharset(mime_type, &unused); return !mime_type->empty(); } bool HttpResponseHeaders::GetCharset(std::string* charset) const { std::string unused; GetMimeTypeAndCharset(&unused, charset); return !charset->empty(); } bool HttpResponseHeaders::IsRedirect(std::string* location) const { if (!IsRedirectResponseCode(response_code_)) return false; // If we lack a Location header, then we can't treat this as a redirect. // We assume that the first non-empty location value is the target URL that // we want to follow. TODO(darin): Is this consistent with other browsers? size_t i = std::string::npos; do { i = FindHeader(++i, "location"); if (i == std::string::npos) return false; // If the location value is empty, then it doesn't count. } while (parsed_[i].value_begin == parsed_[i].value_end); if (location) { // Escape any non-ASCII characters to preserve them. The server should // only be returning ASCII here, but for compat we need to do this. *location = EscapeNonASCII( std::string(parsed_[i].value_begin, parsed_[i].value_end)); } return true; } // static bool HttpResponseHeaders::IsRedirectResponseCode(int response_code) { // Users probably want to see 300 (multiple choice) pages, so we don't count // them as redirects that need to be followed. return (response_code == 301 || response_code == 302 || response_code == 303 || response_code == 307 || response_code == 308); } // From RFC 2616 section 13.2.4: // // The calculation to determine if a response has expired is quite simple: // // response_is_fresh = (freshness_lifetime > current_age) // // Of course, there are other factors that can force a response to always be // validated or re-fetched. // bool HttpResponseHeaders::RequiresValidation(const Time& request_time, const Time& response_time, const Time& current_time) const { FreshnessLifetimes lifetimes = GetFreshnessLifetimes(response_time); if (lifetimes.freshness.is_zero()) return true; return lifetimes.freshness <= GetCurrentAge(request_time, response_time, current_time); } // From RFC 2616 section 13.2.4: // // The max-age directive takes priority over Expires, so if max-age is present // in a response, the calculation is simply: // // freshness_lifetime = max_age_value // // Otherwise, if Expires is present in the response, the calculation is: // // freshness_lifetime = expires_value - date_value // // Note that neither of these calculations is vulnerable to clock skew, since // all of the information comes from the origin server. // // Also, if the response does have a Last-Modified time, the heuristic // expiration value SHOULD be no more than some fraction of the interval since // that time. A typical setting of this fraction might be 10%: // // freshness_lifetime = (date_value - last_modified_value) * 0.10 // HttpResponseHeaders::FreshnessLifetimes HttpResponseHeaders::GetFreshnessLifetimes(const Time& response_time) const { FreshnessLifetimes lifetimes; // Check for headers that force a response to never be fresh. For backwards // compat, we treat "Pragma: no-cache" as a synonym for "Cache-Control: // no-cache" even though RFC 2616 does not specify it. if (HasHeaderValue("cache-control", "no-cache") || HasHeaderValue("cache-control", "no-store") || HasHeaderValue("pragma", "no-cache") || // Vary: * is never usable: see RFC 2616 section 13.6. HasHeaderValue("vary", "*")) { return lifetimes; } // NOTE: "Cache-Control: max-age" overrides Expires, so we only check the // Expires header after checking for max-age in GetFreshnessLifetimes. This // is important since "Expires: " means not fresh, but // it should not trump a max-age value. if (GetMaxAgeValue(&lifetimes.freshness)) return lifetimes; // If there is no Date header, then assume that the server response was // generated at the time when we received the response. Time date_value; if (!GetDateValue(&date_value)) date_value = response_time; Time expires_value; if (GetExpiresValue(&expires_value)) { // The expires value can be a date in the past! if (expires_value > date_value) { lifetimes.freshness = expires_value - date_value; return lifetimes; } DCHECK_EQ(TimeDelta(), lifetimes.freshness); return lifetimes; } // From RFC 2616 section 13.4: // // A response received with a status code of 200, 203, 206, 300, 301 or 410 // MAY be stored by a cache and used in reply to a subsequent request, // subject to the expiration mechanism, unless a cache-control directive // prohibits caching. // ... // A response received with any other status code (e.g. status codes 302 // and 307) MUST NOT be returned in a reply to a subsequent request unless // there are cache-control directives or another header(s) that explicitly // allow it. // // From RFC 2616 section 14.9.4: // // When the must-revalidate directive is present in a response received by // a cache, that cache MUST NOT use the entry after it becomes stale to // respond to a subsequent request without first revalidating it with the // origin server. (I.e., the cache MUST do an end-to-end revalidation every // time, if, based solely on the origin server's Expires or max-age value, // the cached response is stale.) // // https://datatracker.ietf.org/doc/draft-reschke-http-status-308/ is an // experimental RFC that adds 308 permanent redirect as well, for which "any // future references ... SHOULD use one of the returned URIs." if ((response_code_ == 200 || response_code_ == 203 || response_code_ == 206) && !HasHeaderValue("cache-control", "must-revalidate")) { // TODO(darin): Implement a smarter heuristic. Time last_modified_value; if (GetLastModifiedValue(&last_modified_value)) { // The last-modified value can be a date in the future! if (last_modified_value <= date_value) { lifetimes.freshness = (date_value - last_modified_value) / 10; return lifetimes; } } } // These responses are implicitly fresh (unless otherwise overruled): if (response_code_ == 300 || response_code_ == 301 || response_code_ == 308 || response_code_ == 410) { lifetimes.freshness = TimeDelta::Max(); return lifetimes; } // Our heuristic freshness estimate for this resource is 0 seconds, in // accordance with common browser behaviour. DCHECK_EQ(TimeDelta(), lifetimes.freshness); return lifetimes; } // From RFC 7234 section 4.2.3: // // The following data is used for the age calculation: // // age_value // // The term "age_value" denotes the value of the Age header field // (Section 5.1), in a form appropriate for arithmetic operation; or // 0, if not available. // // date_value // // The term "date_value" denotes the value of the Date header field, // in a form appropriate for arithmetic operations. See Section // 7.1.1.2 of [RFC7231] for the definition of the Date header field, // and for requirements regarding responses without it. // // now // // The term "now" means "the current value of the clock at the host // performing the calculation". A host ought to use NTP ([RFC5905]) // or some similar protocol to synchronize its clocks to Coordinated // Universal Time. // // request_time // // The current value of the clock at the host at the time the request // resulting in the stored response was made. // // response_time // // The current value of the clock at the host at the time the // response was received. // // The age is then calculated as // // apparent_age = max(0, response_time - date_value); // response_delay = response_time - request_time; // corrected_age_value = age_value + response_delay; // corrected_initial_age = max(apparent_age, corrected_age_value); // resident_time = now - response_time; // current_age = corrected_initial_age + resident_time; // TimeDelta HttpResponseHeaders::GetCurrentAge(const Time& request_time, const Time& response_time, const Time& current_time) const { // If there is no Date header, then assume that the server response was // generated at the time when we received the response. Time date_value; if (!GetDateValue(&date_value)) date_value = response_time; // If there is no Age header, then assume age is zero. GetAgeValue does not // modify its out param if the value does not exist. TimeDelta age_value; GetAgeValue(&age_value); TimeDelta apparent_age = std::max(TimeDelta(), response_time - date_value); TimeDelta response_delay = response_time - request_time; TimeDelta corrected_age_value = age_value + response_delay; TimeDelta corrected_initial_age = std::max(apparent_age, corrected_age_value); TimeDelta resident_time = current_time - response_time; TimeDelta current_age = corrected_initial_age + resident_time; return current_age; } bool HttpResponseHeaders::GetMaxAgeValue(TimeDelta* result) const { return GetCacheControlDirective("max-age", result); } bool HttpResponseHeaders::GetAgeValue(TimeDelta* result) const { std::string value; if (!EnumerateHeader(nullptr, "Age", &value)) return false; // Parse the delta-seconds as 1*DIGIT. uint32_t seconds; ParseIntError error; if (!ParseUint32(value, &seconds, &error)) { if (error == ParseIntError::FAILED_OVERFLOW) { // If the Age value cannot fit in a uint32_t, saturate it to a maximum // value. This is similar to what RFC 2616 says in section 14.6 for how // caches should transmit values that overflow. seconds = std::numeric_limits::max(); } else { return false; } } *result = TimeDelta::FromSeconds(seconds); return true; } bool HttpResponseHeaders::GetDateValue(Time* result) const { return GetTimeValuedHeader("Date", result); } bool HttpResponseHeaders::GetLastModifiedValue(Time* result) const { return GetTimeValuedHeader("Last-Modified", result); } bool HttpResponseHeaders::GetExpiresValue(Time* result) const { return GetTimeValuedHeader("Expires", result); } bool HttpResponseHeaders::GetTimeValuedHeader(const std::string& name, Time* result) const { std::string value; if (!EnumerateHeader(nullptr, name, &value)) return false; // When parsing HTTP dates it's beneficial to default to GMT because: // 1. RFC2616 3.3.1 says times should always be specified in GMT // 2. Only counter-example incorrectly appended "UTC" (crbug.com/153759) // 3. When adjusting cookie expiration times for clock skew // (crbug.com/135131) this better matches our cookie expiration // time parser which ignores timezone specifiers and assumes GMT. // 4. This is exactly what Firefox does. // TODO(pauljensen): The ideal solution would be to return false if the // timezone could not be understood so as to avoid makeing other calculations // based on an incorrect time. This would require modifying the time // library or duplicating the code. (http://crbug.com/158327) return Time::FromUTCString(value.c_str(), result); } // We accept the first value of "close" or "keep-alive" in a Connection or // Proxy-Connection header, in that order. Obeying "keep-alive" in HTTP/1.1 or // "close" in 1.0 is not strictly standards-compliant, but we'd like to // avoid looking at the Proxy-Connection header whenever it is reasonable to do // so. // TODO(ricea): Measure real-world usage of the "Proxy-Connection" header, // with a view to reducing support for it in order to make our Connection header // handling more RFC 7230 compliant. bool HttpResponseHeaders::IsKeepAlive() const { // NOTE: It is perhaps risky to assume that a Proxy-Connection header is // meaningful when we don't know that this response was from a proxy, but // Mozilla also does this, so we'll do the same. static const char* const kConnectionHeaders[] = { "connection", "proxy-connection"}; struct KeepAliveToken { const char* const token; bool keep_alive; }; static const KeepAliveToken kKeepAliveTokens[] = {{"keep-alive", true}, {"close", false}}; if (http_version_ < HttpVersion(1, 0)) return false; for (const char* header : kConnectionHeaders) { size_t iterator = 0; std::string token; while (EnumerateHeader(&iterator, header, &token)) { for (const KeepAliveToken& keep_alive_token : kKeepAliveTokens) { if (base::LowerCaseEqualsASCII(token, keep_alive_token.token)) return keep_alive_token.keep_alive; } } } return http_version_ != HttpVersion(1, 0); } bool HttpResponseHeaders::HasStrongValidators() const { std::string etag_header; EnumerateHeader(nullptr, "etag", &etag_header); std::string last_modified_header; EnumerateHeader(nullptr, "Last-Modified", &last_modified_header); std::string date_header; EnumerateHeader(nullptr, "Date", &date_header); return HttpUtil::HasStrongValidators(GetHttpVersion(), etag_header, last_modified_header, date_header); } bool HttpResponseHeaders::HasValidators() const { std::string etag_header; EnumerateHeader(NULL, "etag", &etag_header); std::string last_modified_header; EnumerateHeader(NULL, "Last-Modified", &last_modified_header); return HttpUtil::HasValidators(GetHttpVersion(), etag_header, last_modified_header); } // From RFC 2616: // Content-Length = "Content-Length" ":" 1*DIGIT int64_t HttpResponseHeaders::GetContentLength() const { return GetInt64HeaderValue("content-length"); } int64_t HttpResponseHeaders::GetInt64HeaderValue( const std::string& header) const { size_t iter = 0; std::string content_length_val; if (!EnumerateHeader(&iter, header, &content_length_val)) return -1; if (content_length_val.empty()) return -1; if (content_length_val[0] == '+') return -1; int64_t result; bool ok = base::StringToInt64(content_length_val, &result); if (!ok || result < 0) return -1; return result; } bool HttpResponseHeaders::GetContentRangeFor206( int64_t* first_byte_position, int64_t* last_byte_position, int64_t* instance_length) const { size_t iter = 0; std::string content_range_spec; if (!EnumerateHeader(&iter, kContentRange, &content_range_spec)) { *first_byte_position = *last_byte_position = *instance_length = -1; return false; } return HttpUtil::ParseContentRangeHeaderFor206( content_range_spec, first_byte_position, last_byte_position, instance_length); } std::unique_ptr HttpResponseHeaders::NetLogCallback( NetLogCaptureMode capture_mode) const { auto dict = std::make_unique(); auto headers = std::make_unique(); headers->AppendString(EscapeNonASCII(GetStatusLine())); size_t iterator = 0; std::string name; std::string value; while (EnumerateHeaderLines(&iterator, &name, &value)) { std::string log_value = ElideHeaderValueForNetLog(capture_mode, name, value); std::string escaped_name = EscapeNonASCII(name); std::string escaped_value = EscapeNonASCII(log_value); headers->AppendString(base::StringPrintf("%s: %s", escaped_name.c_str(), escaped_value.c_str())); } dict->Set("headers", std::move(headers)); return std::move(dict); } bool HttpResponseHeaders::IsChunkEncoded() const { // Ignore spurious chunked responses from HTTP/1.0 servers and proxies. return GetHttpVersion() >= HttpVersion(1, 1) && HasHeaderValue("Transfer-Encoding", "chunked"); } } // namespace net