Port Android relocation packer to chromium build
[chromium-blink-merge.git] / net / spdy / hpack_huffman_table.cc
blobd9cff25239a72e86c988dbc88f5b6204b30a05ab
1 // Copyright 2014 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #include "net/spdy/hpack_huffman_table.h"
7 #include <algorithm>
8 #include <cmath>
10 #include "base/logging.h"
11 #include "base/numerics/safe_conversions.h"
12 #include "net/spdy/hpack_input_stream.h"
13 #include "net/spdy/hpack_output_stream.h"
15 namespace net {
17 using base::StringPiece;
18 using std::string;
20 namespace {
22 // How many bits to index in the root decode table.
23 const uint8 kDecodeTableRootBits = 9;
24 // Maximum number of bits to index in successive decode tables.
25 const uint8 kDecodeTableBranchBits = 6;
27 bool SymbolLengthAndIdCompare(const HpackHuffmanSymbol& a,
28 const HpackHuffmanSymbol& b) {
29 if (a.length == b.length) {
30 return a.id < b.id;
32 return a.length < b.length;
34 bool SymbolIdCompare(const HpackHuffmanSymbol& a,
35 const HpackHuffmanSymbol& b) {
36 return a.id < b.id;
39 } // namespace
41 HpackHuffmanTable::DecodeEntry::DecodeEntry()
42 : next_table_index(0), length(0), symbol_id(0) {
44 HpackHuffmanTable::DecodeEntry::DecodeEntry(uint8 next_table_index,
45 uint8 length,
46 uint16 symbol_id)
47 : next_table_index(next_table_index), length(length), symbol_id(symbol_id) {
49 size_t HpackHuffmanTable::DecodeTable::size() const {
50 return size_t(1) << indexed_length;
53 HpackHuffmanTable::HpackHuffmanTable() {}
55 HpackHuffmanTable::~HpackHuffmanTable() {}
57 bool HpackHuffmanTable::Initialize(const HpackHuffmanSymbol* input_symbols,
58 size_t symbol_count) {
59 CHECK(!IsInitialized());
60 DCHECK(base::IsValueInRangeForNumericType<uint16>(symbol_count));
62 std::vector<Symbol> symbols(symbol_count);
63 // Validate symbol id sequence, and copy into |symbols|.
64 for (uint16 i = 0; i < symbol_count; i++) {
65 if (i != input_symbols[i].id) {
66 failed_symbol_id_ = i;
67 return false;
69 symbols[i] = input_symbols[i];
71 // Order on length and ID ascending, to verify symbol codes are canonical.
72 std::sort(symbols.begin(), symbols.end(), SymbolLengthAndIdCompare);
73 if (symbols[0].code != 0) {
74 failed_symbol_id_ = 0;
75 return false;
77 for (size_t i = 1; i != symbols.size(); i++) {
78 unsigned code_shift = 32 - symbols[i-1].length;
79 uint32 code = symbols[i-1].code + (1 << code_shift);
81 if (code != symbols[i].code) {
82 failed_symbol_id_ = symbols[i].id;
83 return false;
85 if (code < symbols[i-1].code) {
86 // An integer overflow occurred. This implies the input
87 // lengths do not represent a valid Huffman code.
88 failed_symbol_id_ = symbols[i].id;
89 return false;
92 if (symbols.back().length < 8) {
93 // At least one code (such as an EOS symbol) must be 8 bits or longer.
94 // Without this, some inputs will not be encodable in a whole number
95 // of bytes.
96 return false;
98 pad_bits_ = static_cast<uint8>(symbols.back().code >> 24);
100 BuildDecodeTables(symbols);
101 // Order on symbol ID ascending.
102 std::sort(symbols.begin(), symbols.end(), SymbolIdCompare);
103 BuildEncodeTable(symbols);
104 return true;
107 void HpackHuffmanTable::BuildEncodeTable(const std::vector<Symbol>& symbols) {
108 for (size_t i = 0; i != symbols.size(); i++) {
109 const Symbol& symbol = symbols[i];
110 CHECK_EQ(i, symbol.id);
111 code_by_id_.push_back(symbol.code);
112 length_by_id_.push_back(symbol.length);
116 void HpackHuffmanTable::BuildDecodeTables(const std::vector<Symbol>& symbols) {
117 AddDecodeTable(0, kDecodeTableRootBits);
118 // We wish to maximize the flatness of the DecodeTable hierarchy (subject to
119 // the |kDecodeTableBranchBits| constraint), and to minimize the size of
120 // child tables. To achieve this, we iterate in order of descending code
121 // length. This ensures that child tables are visited with their longest
122 // entry first, and that the child can therefore be minimally sized to hold
123 // that entry without fear of introducing unneccesary branches later.
124 for (std::vector<Symbol>::const_reverse_iterator it = symbols.rbegin();
125 it != symbols.rend(); ++it) {
126 uint8 table_index = 0;
127 while (true) {
128 const DecodeTable table = decode_tables_[table_index];
130 // Mask and shift the portion of the code being indexed into low bits.
131 uint32 index = (it->code << table.prefix_length);
132 index = index >> (32 - table.indexed_length);
134 CHECK_LT(index, table.size());
135 DecodeEntry entry = Entry(table, index);
137 uint8 total_indexed = table.prefix_length + table.indexed_length;
138 if (total_indexed >= it->length) {
139 // We're writing a terminal entry.
140 entry.length = it->length;
141 entry.symbol_id = it->id;
142 entry.next_table_index = table_index;
143 SetEntry(table, index, entry);
144 break;
147 if (entry.length == 0) {
148 // First visit to this placeholder. We need to create a new table.
149 CHECK_EQ(entry.next_table_index, 0);
150 entry.length = it->length;
151 entry.next_table_index = AddDecodeTable(
152 total_indexed, // Becomes the new table prefix.
153 std::min<uint8>(kDecodeTableBranchBits,
154 entry.length - total_indexed));
155 SetEntry(table, index, entry);
157 CHECK_NE(entry.next_table_index, table_index);
158 table_index = entry.next_table_index;
161 // Fill shorter table entries into the additional entry spots they map to.
162 for (size_t i = 0; i != decode_tables_.size(); i++) {
163 const DecodeTable& table = decode_tables_[i];
164 uint8 total_indexed = table.prefix_length + table.indexed_length;
166 size_t j = 0;
167 while (j != table.size()) {
168 const DecodeEntry& entry = Entry(table, j);
169 if (entry.length != 0 && entry.length < total_indexed) {
170 // The difference between entry & table bit counts tells us how
171 // many additional entries map to this one.
172 size_t fill_count = 1 << (total_indexed - entry.length);
173 CHECK_LE(j + fill_count, table.size());
175 for (size_t k = 1; k != fill_count; k++) {
176 CHECK_EQ(Entry(table, j + k).length, 0);
177 SetEntry(table, j + k, entry);
179 j += fill_count;
180 } else {
181 j++;
187 uint8 HpackHuffmanTable::AddDecodeTable(uint8 prefix, uint8 indexed) {
188 CHECK_LT(decode_tables_.size(), 255u);
190 DecodeTable table;
191 table.prefix_length = prefix;
192 table.indexed_length = indexed;
193 table.entries_offset = decode_entries_.size();
194 decode_tables_.push_back(table);
196 decode_entries_.resize(decode_entries_.size() + (size_t(1) << indexed));
197 return static_cast<uint8>(decode_tables_.size() - 1);
200 const HpackHuffmanTable::DecodeEntry& HpackHuffmanTable::Entry(
201 const DecodeTable& table,
202 uint32 index) const {
203 DCHECK_LT(index, table.size());
204 DCHECK_LT(table.entries_offset + index, decode_entries_.size());
205 return decode_entries_[table.entries_offset + index];
208 void HpackHuffmanTable::SetEntry(const DecodeTable& table,
209 uint32 index,
210 const DecodeEntry& entry) {
211 CHECK_LT(index, table.size());
212 CHECK_LT(table.entries_offset + index, decode_entries_.size());
213 decode_entries_[table.entries_offset + index] = entry;
216 bool HpackHuffmanTable::IsInitialized() const {
217 return !code_by_id_.empty();
220 void HpackHuffmanTable::EncodeString(StringPiece in,
221 HpackOutputStream* out) const {
222 size_t bit_remnant = 0;
223 for (size_t i = 0; i != in.size(); i++) {
224 uint16 symbol_id = static_cast<uint8>(in[i]);
225 CHECK_GT(code_by_id_.size(), symbol_id);
227 // Load, and shift code to low bits.
228 unsigned length = length_by_id_[symbol_id];
229 uint32 code = code_by_id_[symbol_id] >> (32 - length);
231 bit_remnant = (bit_remnant + length) % 8;
233 if (length > 24) {
234 out->AppendBits(static_cast<uint8>(code >> 24), length - 24);
235 length = 24;
237 if (length > 16) {
238 out->AppendBits(static_cast<uint8>(code >> 16), length - 16);
239 length = 16;
241 if (length > 8) {
242 out->AppendBits(static_cast<uint8>(code >> 8), length - 8);
243 length = 8;
245 out->AppendBits(static_cast<uint8>(code), length);
247 if (bit_remnant != 0) {
248 // Pad current byte as required.
249 out->AppendBits(pad_bits_ >> bit_remnant, 8 - bit_remnant);
253 size_t HpackHuffmanTable::EncodedSize(StringPiece in) const {
254 size_t bit_count = 0;
255 for (size_t i = 0; i != in.size(); i++) {
256 uint16 symbol_id = static_cast<uint8>(in[i]);
257 CHECK_GT(code_by_id_.size(), symbol_id);
259 bit_count += length_by_id_[symbol_id];
261 if (bit_count % 8 != 0) {
262 bit_count += 8 - bit_count % 8;
264 return bit_count / 8;
267 bool HpackHuffmanTable::DecodeString(HpackInputStream* in,
268 size_t out_capacity,
269 string* out) const {
270 // Number of decode iterations required for a 32-bit code.
271 const int kDecodeIterations = static_cast<int>(
272 std::ceil((32.f - kDecodeTableRootBits) / kDecodeTableBranchBits));
274 out->clear();
276 // Current input, stored in the high |bits_available| bits of |bits|.
277 uint32 bits = 0;
278 size_t bits_available = 0;
279 bool peeked_success = in->PeekBits(&bits_available, &bits);
281 while (true) {
282 const DecodeTable* table = &decode_tables_[0];
283 uint32 index = bits >> (32 - kDecodeTableRootBits);
285 for (int i = 0; i != kDecodeIterations; i++) {
286 DCHECK_LT(index, table->size());
287 DCHECK_LT(Entry(*table, index).next_table_index, decode_tables_.size());
289 table = &decode_tables_[Entry(*table, index).next_table_index];
290 // Mask and shift the portion of the code being indexed into low bits.
291 index = (bits << table->prefix_length) >> (32 - table->indexed_length);
293 const DecodeEntry& entry = Entry(*table, index);
295 if (entry.length > bits_available) {
296 if (!peeked_success) {
297 // Unable to read enough input for a match. If only a portion of
298 // the last byte remains, this is a successful EOF condition.
299 in->ConsumeByteRemainder();
300 return !in->HasMoreData();
302 } else if (entry.length == 0) {
303 // The input is an invalid prefix, larger than any prefix in the table.
304 return false;
305 } else {
306 if (out->size() == out_capacity) {
307 // This code would cause us to overflow |out_capacity|.
308 return false;
310 if (entry.symbol_id < 256) {
311 // Assume symbols >= 256 are used for padding.
312 out->push_back(static_cast<char>(entry.symbol_id));
315 in->ConsumeBits(entry.length);
316 bits = bits << entry.length;
317 bits_available -= entry.length;
319 peeked_success = in->PeekBits(&bits_available, &bits);
321 NOTREACHED();
322 return false;
325 } // namespace net