/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* vim:set ts=4 sw=4 sts=4 et cin: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ // HttpLog.h should generally be included first #include "HttpLog.h" #include "nsHttp.h" #include "CacheControlParser.h" #include "PLDHashTable.h" #include "mozilla/Mutex.h" #include "mozilla/HashFunctions.h" #include "nsCRT.h" #include "nsHttpRequestHead.h" #include "nsHttpResponseHead.h" #include "nsHttpHandler.h" #include "nsICacheEntry.h" #include "nsIRequest.h" #include #include namespace mozilla { namespace net { // define storage for all atoms namespace nsHttp { #define HTTP_ATOM(_name, _value) nsHttpAtom _name = { _value }; #include "nsHttpAtomList.h" #undef HTTP_ATOM } // find out how many atoms we have #define HTTP_ATOM(_name, _value) Unused_ ## _name, enum { #include "nsHttpAtomList.h" NUM_HTTP_ATOMS }; #undef HTTP_ATOM // we keep a linked list of atoms allocated on the heap for easy clean up when // the atom table is destroyed. The structure and value string are allocated // as one contiguous block. struct HttpHeapAtom { struct HttpHeapAtom *next; char value[1]; }; static PLDHashTable *sAtomTable; static struct HttpHeapAtom *sHeapAtoms = nullptr; static Mutex *sLock = nullptr; HttpHeapAtom * NewHeapAtom(const char *value) { int len = strlen(value); HttpHeapAtom *a = reinterpret_cast(malloc(sizeof(*a) + len)); if (!a) return nullptr; memcpy(a->value, value, len + 1); // add this heap atom to the list of all heap atoms a->next = sHeapAtoms; sHeapAtoms = a; return a; } // Hash string ignore case, based on PL_HashString static PLDHashNumber StringHash(const void *key) { PLDHashNumber h = 0; for (const char *s = reinterpret_cast(key); *s; ++s) h = AddToHash(h, nsCRT::ToLower(*s)); return h; } static bool StringCompare(const PLDHashEntryHdr *entry, const void *testKey) { const void *entryKey = reinterpret_cast(entry)->key; return PL_strcasecmp(reinterpret_cast(entryKey), reinterpret_cast(testKey)) == 0; } static const PLDHashTableOps ops = { StringHash, StringCompare, PLDHashTable::MoveEntryStub, PLDHashTable::ClearEntryStub, nullptr }; // We put the atoms in a hash table for speedy lookup.. see ResolveAtom. namespace nsHttp { nsresult CreateAtomTable() { MOZ_ASSERT(!sAtomTable, "atom table already initialized"); if (!sLock) { sLock = new Mutex("nsHttp.sLock"); } // The initial length for this table is a value greater than the number of // known atoms (NUM_HTTP_ATOMS) because we expect to encounter a few random // headers right off the bat. sAtomTable = new PLDHashTable(&ops, sizeof(PLDHashEntryStub), NUM_HTTP_ATOMS + 10); // fill the table with our known atoms const char *const atoms[] = { #define HTTP_ATOM(_name, _value) _name._val, #include "nsHttpAtomList.h" #undef HTTP_ATOM nullptr }; for (int i = 0; atoms[i]; ++i) { auto stub = static_cast (sAtomTable->Add(atoms[i], fallible)); if (!stub) return NS_ERROR_OUT_OF_MEMORY; MOZ_ASSERT(!stub->key, "duplicate static atom"); stub->key = atoms[i]; } return NS_OK; } void DestroyAtomTable() { delete sAtomTable; sAtomTable = nullptr; while (sHeapAtoms) { HttpHeapAtom *next = sHeapAtoms->next; free(sHeapAtoms); sHeapAtoms = next; } delete sLock; sLock = nullptr; } Mutex * GetLock() { return sLock; } // this function may be called from multiple threads nsHttpAtom ResolveAtom(const char *str) { nsHttpAtom atom = { nullptr }; if (!str || !sAtomTable) return atom; MutexAutoLock lock(*sLock); auto stub = static_cast(sAtomTable->Add(str, fallible)); if (!stub) return atom; // out of memory if (stub->key) { atom._val = reinterpret_cast(stub->key); return atom; } // if the atom could not be found in the atom table, then we'll go // and allocate a new atom on the heap. HttpHeapAtom *heapAtom = NewHeapAtom(str); if (!heapAtom) return atom; // out of memory stub->key = atom._val = heapAtom->value; return atom; } // // From section 2.2 of RFC 2616, a token is defined as: // // token = 1* // CHAR = // separators = "(" | ")" | "<" | ">" | "@" // | "," | ";" | ":" | "\" | <"> // | "/" | "[" | "]" | "?" | "=" // | "{" | "}" | SP | HT // CTL = // SP = // HT = // static const char kValidTokenMap[128] = { 0, 0, 0, 0, 0, 0, 0, 0, // 0 0, 0, 0, 0, 0, 0, 0, 0, // 8 0, 0, 0, 0, 0, 0, 0, 0, // 16 0, 0, 0, 0, 0, 0, 0, 0, // 24 0, 1, 0, 1, 1, 1, 1, 1, // 32 0, 0, 1, 1, 0, 1, 1, 0, // 40 1, 1, 1, 1, 1, 1, 1, 1, // 48 1, 1, 0, 0, 0, 0, 0, 0, // 56 0, 1, 1, 1, 1, 1, 1, 1, // 64 1, 1, 1, 1, 1, 1, 1, 1, // 72 1, 1, 1, 1, 1, 1, 1, 1, // 80 1, 1, 1, 0, 0, 0, 1, 1, // 88 1, 1, 1, 1, 1, 1, 1, 1, // 96 1, 1, 1, 1, 1, 1, 1, 1, // 104 1, 1, 1, 1, 1, 1, 1, 1, // 112 1, 1, 1, 0, 1, 0, 1, 0 // 120 }; bool IsValidToken(const char *start, const char *end) { if (start == end) return false; for (; start != end; ++start) { const unsigned char idx = *start; if (idx > 127 || !kValidTokenMap[idx]) return false; } return true; } const char* GetProtocolVersion(uint32_t pv) { switch (pv) { case HTTP_VERSION_2: case NS_HTTP_VERSION_2_0: return "h2"; case NS_HTTP_VERSION_1_0: return "http/1.0"; case NS_HTTP_VERSION_1_1: return "http/1.1"; default: NS_WARNING(nsPrintfCString("Unkown protocol version: 0x%X. " "Please file a bug", pv).get()); return "http/1.1"; } } // static void TrimHTTPWhitespace(const nsACString& aSource, nsACString& aDest) { nsAutoCString str(aSource); // HTTP whitespace 0x09: '\t', 0x0A: '\n', 0x0D: '\r', 0x20: ' ' static const char kHTTPWhitespace[] = "\t\n\r "; str.Trim(kHTTPWhitespace); aDest.Assign(str); } // static bool IsReasonableHeaderValue(const nsACString &s) { // Header values MUST NOT contain line-breaks. RFC 2616 technically // permits CTL characters, including CR and LF, in header values provided // they are quoted. However, this can lead to problems if servers do not // interpret quoted strings properly. Disallowing CR and LF here seems // reasonable and keeps things simple. We also disallow a null byte. const nsACString::char_type* end = s.EndReading(); for (const nsACString::char_type* i = s.BeginReading(); i != end; ++i) { if (*i == '\r' || *i == '\n' || *i == '\0') { return false; } } return true; } const char * FindToken(const char *input, const char *token, const char *seps) { if (!input) return nullptr; int inputLen = strlen(input); int tokenLen = strlen(token); if (inputLen < tokenLen) return nullptr; const char *inputTop = input; const char *inputEnd = input + inputLen - tokenLen; for (; input <= inputEnd; ++input) { if (PL_strncasecmp(input, token, tokenLen) == 0) { if (input > inputTop && !strchr(seps, *(input - 1))) continue; if (input < inputEnd && !strchr(seps, *(input + tokenLen))) continue; return input; } } return nullptr; } bool ParseInt64(const char *input, const char **next, int64_t *r) { MOZ_ASSERT(input); MOZ_ASSERT(r); char *end = nullptr; errno = 0; // Clear errno to make sure its value is set by strtoll int64_t value = strtoll(input, &end, /* base */ 10); // Fail if: - the parsed number overflows. // - the end points to the start of the input string. // - we parsed a negative value. Consumers don't expect that. if (errno != 0 || end == input || value < 0) { LOG(("nsHttp::ParseInt64 value=%" PRId64 " errno=%d", value, errno)); return false; } if (next) { *next = end; } *r = value; return true; } bool IsPermanentRedirect(uint32_t httpStatus) { return httpStatus == 301 || httpStatus == 308; } bool ValidationRequired(bool isForcedValid, nsHttpResponseHead *cachedResponseHead, uint32_t loadFlags, bool allowStaleCacheContent, bool isImmutable, bool customConditionalRequest, nsHttpRequestHead &requestHead, nsICacheEntry *entry, CacheControlParser &cacheControlRequest, bool fromPreviousSession) { // Check isForcedValid to see if it is possible to skip validation. // Don't skip validation if we have serious reason to believe that this // content is invalid (it's expired). // See netwerk/cache2/nsICacheEntry.idl for details if (isForcedValid && (!cachedResponseHead->ExpiresInPast() || !cachedResponseHead->MustValidateIfExpired())) { LOG(("NOT validating based on isForcedValid being true.\n")); return false; } // If the LOAD_FROM_CACHE flag is set, any cached data can simply be used if (loadFlags & nsIRequest::LOAD_FROM_CACHE || allowStaleCacheContent) { LOG(("NOT validating based on LOAD_FROM_CACHE load flag\n")); return false; } // If the VALIDATE_ALWAYS flag is set, any cached data won't be used until // it's revalidated with the server. if ((loadFlags & nsIRequest::VALIDATE_ALWAYS) && !isImmutable) { LOG(("Validating based on VALIDATE_ALWAYS load flag\n")); return true; } // Even if the VALIDATE_NEVER flag is set, there are still some cases in // which we must validate the cached response with the server. if (loadFlags & nsIRequest::VALIDATE_NEVER) { LOG(("VALIDATE_NEVER set\n")); // if no-store validate cached response (see bug 112564) if (cachedResponseHead->NoStore()) { LOG(("Validating based on no-store logic\n")); return true; } else { LOG(("NOT validating based on VALIDATE_NEVER load flag\n")); return false; } } // check if validation is strictly required... if (cachedResponseHead->MustValidate()) { LOG(("Validating based on MustValidate() returning TRUE\n")); return true; } // possibly serve from cache for a custom If-Match/If-Unmodified-Since // conditional request if (customConditionalRequest && !requestHead.HasHeader(nsHttp::If_Match) && !requestHead.HasHeader(nsHttp::If_Unmodified_Since)) { LOG(("Validating based on a custom conditional request\n")); return true; } // previously we also checked for a query-url w/out expiration // and didn't do heuristic on it. but defacto that is allowed now. // // Check if the cache entry has expired... bool doValidation = true; uint32_t now = NowInSeconds(); uint32_t age = 0; nsresult rv = cachedResponseHead->ComputeCurrentAge(now, now, &age); if (NS_FAILED(rv)) { return true; } uint32_t freshness = 0; rv = cachedResponseHead->ComputeFreshnessLifetime(&freshness); if (NS_FAILED(rv)) { return true; } uint32_t expiration = 0; rv = entry->GetExpirationTime(&expiration); if (NS_FAILED(rv)) { return true; } uint32_t maxAgeRequest, maxStaleRequest, minFreshRequest; LOG((" NowInSeconds()=%u, expiration time=%u, freshness lifetime=%u, age=%u", now, expiration, freshness, age)); if (cacheControlRequest.NoCache()) { LOG((" validating, no-cache request")); doValidation = true; } else if (cacheControlRequest.MaxStale(&maxStaleRequest)) { uint32_t staleTime = age > freshness ? age - freshness : 0; doValidation = staleTime > maxStaleRequest; LOG((" validating=%d, max-stale=%u requested", doValidation, maxStaleRequest)); } else if (cacheControlRequest.MaxAge(&maxAgeRequest)) { doValidation = age > maxAgeRequest; LOG((" validating=%d, max-age=%u requested", doValidation, maxAgeRequest)); } else if (cacheControlRequest.MinFresh(&minFreshRequest)) { uint32_t freshTime = freshness > age ? freshness - age : 0; doValidation = freshTime < minFreshRequest; LOG((" validating=%d, min-fresh=%u requested", doValidation, minFreshRequest)); } else if (now <= expiration) { doValidation = false; LOG((" not validating, expire time not in the past")); } else if (cachedResponseHead->MustValidateIfExpired()) { doValidation = true; } else if (loadFlags & nsIRequest::VALIDATE_ONCE_PER_SESSION) { // If the cached response does not include expiration infor- // mation, then we must validate the response, despite whether // or not this is the first access this session. This behavior // is consistent with existing browsers and is generally expected // by web authors. if (freshness == 0) doValidation = true; else doValidation = fromPreviousSession; } else { doValidation = true; } LOG(("%salidating based on expiration time\n", doValidation ? "V" : "Not v")); return doValidation; } nsresult GetHttpResponseHeadFromCacheEntry(nsICacheEntry *entry, nsHttpResponseHead *cachedResponseHead) { nsCString buf; // A "original-response-headers" metadata element holds network original headers, // i.e. the headers in the form as they arrieved from the network. // We need to get the network original headers first, because we need to keep them // in order. nsresult rv = entry->GetMetaDataElement("original-response-headers", getter_Copies(buf)); if (NS_SUCCEEDED(rv)) { rv = cachedResponseHead->ParseCachedOriginalHeaders((char *) buf.get()); if (NS_FAILED(rv)) { LOG((" failed to parse original-response-headers\n")); } } buf.Adopt(0); // A "response-head" metadata element holds response head, e.g. response status // line and headers in the form Firefox uses them internally (no dupicate // headers, etc.). rv = entry->GetMetaDataElement("response-head", getter_Copies(buf)); NS_ENSURE_SUCCESS(rv, rv); // Parse string stored in a "response-head" metadata element. // These response headers will be merged with the orignal headers (i.e. the // headers stored in a "original-response-headers" metadata element). rv = cachedResponseHead->ParseCachedHead(buf.get()); NS_ENSURE_SUCCESS(rv, rv); buf.Adopt(0); return NS_OK; } nsresult CheckPartial(nsICacheEntry* aEntry, int64_t *aSize, int64_t *aContentLength, nsHttpResponseHead *responseHead) { nsresult rv; rv = aEntry->GetDataSize(aSize); if (NS_ERROR_IN_PROGRESS == rv) { *aSize = -1; rv = NS_OK; } NS_ENSURE_SUCCESS(rv, rv); if (!responseHead) { return NS_ERROR_UNEXPECTED; } *aContentLength = responseHead->ContentLength(); return NS_OK; } void DetermineFramingAndImmutability(nsICacheEntry *entry, nsHttpResponseHead *responseHead, bool isHttps, bool *weaklyFramed, bool *isImmutable) { nsCString framedBuf; nsresult rv = entry->GetMetaDataElement("strongly-framed", getter_Copies(framedBuf)); // describe this in terms of explicitly weakly framed so as to be backwards // compatible with old cache contents which dont have strongly-framed makers *weaklyFramed = NS_SUCCEEDED(rv) && framedBuf.EqualsLiteral("0"); *isImmutable = !*weaklyFramed && isHttps && responseHead->Immutable(); } bool IsBeforeLastActiveTabLoadOptimization(TimeStamp const & when) { return gHttpHandler && gHttpHandler->IsBeforeLastActiveTabLoadOptimization(when); } void NotifyActiveTabLoadOptimization() { if (gHttpHandler) { gHttpHandler->NotifyActiveTabLoadOptimization(); } } TimeStamp const GetLastActiveTabLoadOptimizationHit() { return gHttpHandler ? gHttpHandler->GetLastActiveTabLoadOptimizationHit() : TimeStamp(); } void SetLastActiveTabLoadOptimizationHit(TimeStamp const &when) { if (gHttpHandler) { gHttpHandler->SetLastActiveTabLoadOptimizationHit(when); } } } // namespace nsHttp template void localEnsureBuffer(UniquePtr &buf, uint32_t newSize, uint32_t preserve, uint32_t &objSize) { if (objSize >= newSize) return; // Leave a little slop on the new allocation - add 2KB to // what we need and then round the result up to a 4KB (page) // boundary. objSize = (newSize + 2048 + 4095) & ~4095; static_assert(sizeof(T) == 1, "sizeof(T) must be 1"); auto tmp = MakeUnique(objSize); if (preserve) { memcpy(tmp.get(), buf.get(), preserve); } buf = Move(tmp); } void EnsureBuffer(UniquePtr &buf, uint32_t newSize, uint32_t preserve, uint32_t &objSize) { localEnsureBuffer (buf, newSize, preserve, objSize); } void EnsureBuffer(UniquePtr &buf, uint32_t newSize, uint32_t preserve, uint32_t &objSize) { localEnsureBuffer (buf, newSize, preserve, objSize); } static bool IsTokenSymbol(signed char chr) { if (chr < 33 || chr == 127 || chr == '(' || chr == ')' || chr == '<' || chr == '>' || chr == '@' || chr == ',' || chr == ';' || chr == ':' || chr == '"' || chr == '/' || chr == '[' || chr == ']' || chr == '?' || chr == '=' || chr == '{' || chr == '}' || chr == '\\') { return false; } return true; } ParsedHeaderPair::ParsedHeaderPair(const char *name, int32_t nameLen, const char *val, int32_t valLen, bool isQuotedValue) : mName(nsDependentCSubstring(nullptr, 0u)) , mValue(nsDependentCSubstring(nullptr, 0u)) , mIsQuotedValue(isQuotedValue) { if (nameLen > 0) { mName.Rebind(name, name + nameLen); } if (valLen > 0) { if (mIsQuotedValue) { RemoveQuotedStringEscapes(val, valLen); mValue.Rebind(mUnquotedValue.BeginWriting(), mUnquotedValue.Length()); } else { mValue.Rebind(val, val + valLen); } } } void ParsedHeaderPair::RemoveQuotedStringEscapes(const char *val, int32_t valLen) { mUnquotedValue.Truncate(); const char *c = val; for (int32_t i = 0; i < valLen; ++i) { if (c[i] == '\\' && c[i + 1]) { ++i; } mUnquotedValue.Append(c[i]); } } static void Tokenize(const char *input, uint32_t inputLen, const char token, const std::function& consumer) { auto trimWhitespace = [] (const char *in, uint32_t inLen, const char **out, uint32_t *outLen) { *out = in; *outLen = inLen; if (inLen == 0) { return; } // Trim leading space while (nsCRT::IsAsciiSpace(**out)) { (*out)++; --(*outLen); } // Trim tailing space for (const char *i = *out + *outLen - 1; i >= *out; --i) { if (!nsCRT::IsAsciiSpace(*i)) { break; } --(*outLen); } }; const char *first = input; bool inQuote = false; const char *result = nullptr; uint32_t resultLen = 0; for (uint32_t index = 0; index < inputLen; ++index) { if (inQuote && input[index] == '\\' && input[index + 1]) { index++; continue; } if (input[index] == '"') { inQuote = !inQuote; continue; } if (inQuote) { continue; } if (input[index] == token) { trimWhitespace(first, (input + index) - first, &result, &resultLen); consumer(result, resultLen); first = input + index + 1; } } trimWhitespace(first, (input + inputLen) - first, &result, &resultLen); consumer(result, resultLen); } ParsedHeaderValueList::ParsedHeaderValueList(const char *t, uint32_t len, bool allowInvalidValue) { if (!len) { return; } ParsedHeaderValueList *self = this; auto consumer = [=] (const char *output, uint32_t outputLength) { self->ParseNameAndValue(output, allowInvalidValue); }; Tokenize(t, len, ';', consumer); } void ParsedHeaderValueList::ParseNameAndValue(const char *input, bool allowInvalidValue) { const char *nameStart = input; const char *nameEnd = nullptr; const char *valueStart = input; const char *valueEnd = nullptr; bool isQuotedString = false; bool invalidValue = false; for (; *input && *input != ';' && *input != ',' && !nsCRT::IsAsciiSpace(*input) && *input != '='; input++) ; nameEnd = input; if (!(nameEnd - nameStart)) { return; } // Check whether param name is a valid token. for (const char *c = nameStart; c < nameEnd; c++) { if (!IsTokenSymbol(*c)) { nameEnd = c; break; } } if (!(nameEnd - nameStart)) { return; } while (nsCRT::IsAsciiSpace(*input)) { ++input; } if (!*input || *input++ != '=') { mValues.AppendElement(ParsedHeaderPair(nameStart, nameEnd - nameStart, nullptr, 0, false)); return; } while (nsCRT::IsAsciiSpace(*input)) { ++input; } if (*input != '"') { // The value is a token, not a quoted string. valueStart = input; for (valueEnd = input; *valueEnd && !nsCRT::IsAsciiSpace (*valueEnd) && *valueEnd != ';' && *valueEnd != ','; valueEnd++) ; input = valueEnd; if (!allowInvalidValue) { for (const char *c = valueStart; c < valueEnd; c++) { if (!IsTokenSymbol(*c)) { valueEnd = c; break; } } } } else { bool foundQuotedEnd = false; isQuotedString = true; ++input; valueStart = input; for (valueEnd = input; *valueEnd; ++valueEnd) { if (*valueEnd == '\\' && *(valueEnd + 1)) { ++valueEnd; } else if (*valueEnd == '"') { foundQuotedEnd = true; break; } } if (!foundQuotedEnd) { invalidValue = true; } input = valueEnd; // *valueEnd != null means that *valueEnd is quote character. if (*valueEnd) { input++; } } if (invalidValue) { valueEnd = valueStart; } mValues.AppendElement(ParsedHeaderPair(nameStart, nameEnd - nameStart, valueStart, valueEnd - valueStart, isQuotedString)); } ParsedHeaderValueListList::ParsedHeaderValueListList(const nsCString &fullHeader, bool allowInvalidValue) : mFull(fullHeader) { auto &values = mValues; auto consumer = [&values, allowInvalidValue] (const char *output, uint32_t outputLength) { values.AppendElement(ParsedHeaderValueList(output, outputLength, allowInvalidValue)); }; Tokenize(mFull.BeginReading(), mFull.Length(), ',', consumer); } } // namespace net } // namespace mozilla