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1 /*
2  *  Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
3  *
4  *  Use of this source code is governed by a BSD-style license
5  *  that can be found in the LICENSE file in the root of the source
6  *  tree. An additional intellectual property rights grant can be found
7  *  in the file PATENTS.  All contributing project authors may
8  *  be found in the AUTHORS file in the root of the source tree.
9  */
10 
11 #include "webrtc/modules/rtp_rtcp/source/forward_error_correction_internal.h"
12 
13 #include <assert.h>
14 #include <string.h>
15 
16 #include "webrtc/modules/rtp_rtcp/source/fec_private_tables_bursty.h"
17 #include "webrtc/modules/rtp_rtcp/source/fec_private_tables_random.h"
18 
19 namespace {
20 using webrtc::fec_private_tables::kPacketMaskBurstyTbl;
21 using webrtc::fec_private_tables::kPacketMaskRandomTbl;
22 
23 // Allow for different modes of protection for packets in UEP case.
24 enum ProtectionMode {
25   kModeNoOverlap,
26   kModeOverlap,
27   kModeBiasFirstPacket,
28 };
29 
30 // Fits an input mask (sub_mask) to an output mask.
31 // The mask is a matrix where the rows are the FEC packets,
32 // and the columns are the source packets the FEC is applied to.
33 // Each row of the mask is represented by a number of mask bytes.
34 //
35 // \param[in]  num_mask_bytes     The number of mask bytes of output mask.
36 // \param[in]  num_sub_mask_bytes The number of mask bytes of input mask.
37 // \param[in]  num_rows           The number of rows of the input mask.
38 // \param[in]  sub_mask           A pointer to hold the input mask, of size
39 //                                [0, num_rows * num_sub_mask_bytes]
40 // \param[out] packet_mask        A pointer to hold the output mask, of size
41 //                                [0, x * num_mask_bytes], where x >= num_rows.
FitSubMask(int num_mask_bytes,int num_sub_mask_bytes,int num_rows,const uint8_t * sub_mask,uint8_t * packet_mask)42 void FitSubMask(int num_mask_bytes,
43                 int num_sub_mask_bytes,
44                 int num_rows,
45                 const uint8_t* sub_mask,
46                 uint8_t* packet_mask) {
47   if (num_mask_bytes == num_sub_mask_bytes) {
48     memcpy(packet_mask, sub_mask, num_rows * num_sub_mask_bytes);
49   } else {
50     for (int i = 0; i < num_rows; ++i) {
51       int pkt_mask_idx = i * num_mask_bytes;
52       int pkt_mask_idx2 = i * num_sub_mask_bytes;
53       for (int j = 0; j < num_sub_mask_bytes; ++j) {
54         packet_mask[pkt_mask_idx] = sub_mask[pkt_mask_idx2];
55         pkt_mask_idx++;
56         pkt_mask_idx2++;
57       }
58     }
59   }
60 }
61 
62 // Shifts a mask by number of columns (bits), and fits it to an output mask.
63 // The mask is a matrix where the rows are the FEC packets,
64 // and the columns are the source packets the FEC is applied to.
65 // Each row of the mask is represented by a number of mask bytes.
66 //
67 // \param[in]  num_mask_bytes     The number of mask bytes of output mask.
68 // \param[in]  num_sub_mask_bytes The number of mask bytes of input mask.
69 // \param[in]  num_column_shift   The number columns to be shifted, and
70 //                                the starting row for the output mask.
71 // \param[in]  end_row            The ending row for the output mask.
72 // \param[in]  sub_mask           A pointer to hold the input mask, of size
73 //                                [0, (end_row_fec - start_row_fec) *
74 //                                    num_sub_mask_bytes]
75 // \param[out] packet_mask        A pointer to hold the output mask, of size
76 //                                [0, x * num_mask_bytes],
77 //                                where x >= end_row_fec.
78 // TODO(marpan): This function is doing three things at the same time:
79 // shift within a byte, byte shift and resizing.
80 // Split up into subroutines.
ShiftFitSubMask(int num_mask_bytes,int res_mask_bytes,int num_column_shift,int end_row,const uint8_t * sub_mask,uint8_t * packet_mask)81 void ShiftFitSubMask(int num_mask_bytes,
82                      int res_mask_bytes,
83                      int num_column_shift,
84                      int end_row,
85                      const uint8_t* sub_mask,
86                      uint8_t* packet_mask) {
87   // Number of bit shifts within a byte
88   const int num_bit_shifts = (num_column_shift % 8);
89   const int num_byte_shifts = num_column_shift >> 3;
90 
91   // Modify new mask with sub-mask21.
92 
93   // Loop over the remaining FEC packets.
94   for (int i = num_column_shift; i < end_row; ++i) {
95     // Byte index of new mask, for row i and column res_mask_bytes,
96     // offset by the number of bytes shifts
97     int pkt_mask_idx =
98         i * num_mask_bytes + res_mask_bytes - 1 + num_byte_shifts;
99     // Byte index of sub_mask, for row i and column res_mask_bytes
100     int pkt_mask_idx2 =
101         (i - num_column_shift) * res_mask_bytes + res_mask_bytes - 1;
102 
103     uint8_t shift_right_curr_byte = 0;
104     uint8_t shift_left_prev_byte = 0;
105     uint8_t comb_new_byte = 0;
106 
107     // Handle case of num_mask_bytes > res_mask_bytes:
108     // For a given row, copy the rightmost "numBitShifts" bits
109     // of the last byte of sub_mask into output mask.
110     if (num_mask_bytes > res_mask_bytes) {
111       shift_left_prev_byte = (sub_mask[pkt_mask_idx2] << (8 - num_bit_shifts));
112       packet_mask[pkt_mask_idx + 1] = shift_left_prev_byte;
113     }
114 
115     // For each row i (FEC packet), shift the bit-mask of the sub_mask.
116     // Each row of the mask contains "resMaskBytes" of bytes.
117     // We start from the last byte of the sub_mask and move to first one.
118     for (int j = res_mask_bytes - 1; j > 0; j--) {
119       // Shift current byte of sub21 to the right by "numBitShifts".
120       shift_right_curr_byte = sub_mask[pkt_mask_idx2] >> num_bit_shifts;
121 
122       // Fill in shifted bits with bits from the previous (left) byte:
123       // First shift the previous byte to the left by "8-numBitShifts".
124       shift_left_prev_byte =
125           (sub_mask[pkt_mask_idx2 - 1] << (8 - num_bit_shifts));
126 
127       // Then combine both shifted bytes into new mask byte.
128       comb_new_byte = shift_right_curr_byte | shift_left_prev_byte;
129 
130       // Assign to new mask.
131       packet_mask[pkt_mask_idx] = comb_new_byte;
132       pkt_mask_idx--;
133       pkt_mask_idx2--;
134     }
135     // For the first byte in the row (j=0 case).
136     shift_right_curr_byte = sub_mask[pkt_mask_idx2] >> num_bit_shifts;
137     packet_mask[pkt_mask_idx] = shift_right_curr_byte;
138   }
139 }
140 }  // namespace
141 
142 namespace webrtc {
143 namespace internal {
144 
PacketMaskTable(FecMaskType fec_mask_type,int num_media_packets)145 PacketMaskTable::PacketMaskTable(FecMaskType fec_mask_type,
146                                  int num_media_packets)
147     : fec_mask_type_(InitMaskType(fec_mask_type, num_media_packets)),
148       fec_packet_mask_table_(InitMaskTable(fec_mask_type_)) {}
149 
150 // Sets |fec_mask_type_| to the type of packet mask selected. The type of
151 // packet mask selected is based on |fec_mask_type| and |num_media_packets|.
152 // If |num_media_packets| is larger than the maximum allowed by |fec_mask_type|
153 // for the bursty type, then the random type is selected.
InitMaskType(FecMaskType fec_mask_type,int num_media_packets)154 FecMaskType PacketMaskTable::InitMaskType(FecMaskType fec_mask_type,
155                                           int num_media_packets) {
156   // The mask should not be bigger than |packetMaskTbl|.
157   assert(num_media_packets <= static_cast<int>(sizeof(kPacketMaskRandomTbl) /
158                                                sizeof(*kPacketMaskRandomTbl)));
159   switch (fec_mask_type) {
160     case kFecMaskRandom: {
161       return kFecMaskRandom;
162     }
163     case kFecMaskBursty: {
164       int max_media_packets = static_cast<int>(sizeof(kPacketMaskBurstyTbl) /
165                                                sizeof(*kPacketMaskBurstyTbl));
166       if (num_media_packets > max_media_packets) {
167         return kFecMaskRandom;
168       } else {
169         return kFecMaskBursty;
170       }
171     }
172   }
173   assert(false);
174   return kFecMaskRandom;
175 }
176 
177 // Returns the pointer to the packet mask tables corresponding to type
178 // |fec_mask_type|.
InitMaskTable(FecMaskType fec_mask_type)179 const uint8_t*** PacketMaskTable::InitMaskTable(FecMaskType fec_mask_type) {
180   switch (fec_mask_type) {
181     case kFecMaskRandom: {
182       return kPacketMaskRandomTbl;
183     }
184     case kFecMaskBursty: {
185       return kPacketMaskBurstyTbl;
186     }
187   }
188   assert(false);
189   return kPacketMaskRandomTbl;
190 }
191 
192 // Remaining protection after important (first partition) packet protection
RemainingPacketProtection(int num_media_packets,int num_fec_remaining,int num_fec_for_imp_packets,int num_mask_bytes,ProtectionMode mode,uint8_t * packet_mask,const PacketMaskTable & mask_table)193 void RemainingPacketProtection(int num_media_packets,
194                                int num_fec_remaining,
195                                int num_fec_for_imp_packets,
196                                int num_mask_bytes,
197                                ProtectionMode mode,
198                                uint8_t* packet_mask,
199                                const PacketMaskTable& mask_table) {
200   if (mode == kModeNoOverlap) {
201     // sub_mask21
202 
203     const int l_bit =
204         (num_media_packets - num_fec_for_imp_packets) > 16 ? 1 : 0;
205 
206     const int res_mask_bytes =
207         (l_bit == 1) ? kMaskSizeLBitSet : kMaskSizeLBitClear;
208 
209     const uint8_t* packet_mask_sub_21 =
210         mask_table.fec_packet_mask_table()[num_media_packets -
211                                            num_fec_for_imp_packets -
212                                            1][num_fec_remaining - 1];
213 
214     ShiftFitSubMask(num_mask_bytes, res_mask_bytes, num_fec_for_imp_packets,
215                     (num_fec_for_imp_packets + num_fec_remaining),
216                     packet_mask_sub_21, packet_mask);
217 
218   } else if (mode == kModeOverlap || mode == kModeBiasFirstPacket) {
219     // sub_mask22
220 
221     const uint8_t* packet_mask_sub_22 =
222         mask_table.fec_packet_mask_table()[num_media_packets -
223                                            1][num_fec_remaining - 1];
224 
225     FitSubMask(num_mask_bytes, num_mask_bytes, num_fec_remaining,
226                packet_mask_sub_22,
227                &packet_mask[num_fec_for_imp_packets * num_mask_bytes]);
228 
229     if (mode == kModeBiasFirstPacket) {
230       for (int i = 0; i < num_fec_remaining; ++i) {
231         int pkt_mask_idx = i * num_mask_bytes;
232         packet_mask[pkt_mask_idx] = packet_mask[pkt_mask_idx] | (1 << 7);
233       }
234     }
235   } else {
236     assert(false);
237   }
238 }
239 
240 // Protection for important (first partition) packets
ImportantPacketProtection(int num_fec_for_imp_packets,int num_imp_packets,int num_mask_bytes,uint8_t * packet_mask,const PacketMaskTable & mask_table)241 void ImportantPacketProtection(int num_fec_for_imp_packets,
242                                int num_imp_packets,
243                                int num_mask_bytes,
244                                uint8_t* packet_mask,
245                                const PacketMaskTable& mask_table) {
246   const int l_bit = num_imp_packets > 16 ? 1 : 0;
247   const int num_imp_mask_bytes =
248       (l_bit == 1) ? kMaskSizeLBitSet : kMaskSizeLBitClear;
249 
250   // Get sub_mask1 from table
251   const uint8_t* packet_mask_sub_1 =
252       mask_table.fec_packet_mask_table()[num_imp_packets -
253                                          1][num_fec_for_imp_packets - 1];
254 
255   FitSubMask(num_mask_bytes, num_imp_mask_bytes, num_fec_for_imp_packets,
256              packet_mask_sub_1, packet_mask);
257 }
258 
259 // This function sets the protection allocation: i.e., how many FEC packets
260 // to use for num_imp (1st partition) packets, given the: number of media
261 // packets, number of FEC packets, and number of 1st partition packets.
SetProtectionAllocation(int num_media_packets,int num_fec_packets,int num_imp_packets)262 int SetProtectionAllocation(int num_media_packets,
263                             int num_fec_packets,
264                             int num_imp_packets) {
265   // TODO(marpan): test different cases for protection allocation:
266 
267   // Use at most (alloc_par * num_fec_packets) for important packets.
268   float alloc_par = 0.5;
269   int max_num_fec_for_imp = alloc_par * num_fec_packets;
270 
271   int num_fec_for_imp_packets = (num_imp_packets < max_num_fec_for_imp)
272                                     ? num_imp_packets
273                                     : max_num_fec_for_imp;
274 
275   // Fall back to equal protection in this case
276   if (num_fec_packets == 1 && (num_media_packets > 2 * num_imp_packets)) {
277     num_fec_for_imp_packets = 0;
278   }
279 
280   return num_fec_for_imp_packets;
281 }
282 
283 // Modification for UEP: reuse the off-line tables for the packet masks.
284 // Note: these masks were designed for equal packet protection case,
285 // assuming random packet loss.
286 
287 // Current version has 3 modes (options) to build UEP mask from existing ones.
288 // Various other combinations may be added in future versions.
289 // Longer-term, we may add another set of tables specifically for UEP cases.
290 // TODO(marpan): also consider modification of masks for bursty loss cases.
291 
292 // Mask is characterized as (#packets_to_protect, #fec_for_protection).
293 // Protection factor defined as: (#fec_for_protection / #packets_to_protect).
294 
295 // Let k=num_media_packets, n=total#packets, (n-k)=num_fec_packets,
296 // m=num_imp_packets.
297 
298 // For ProtectionMode 0 and 1:
299 // one mask (sub_mask1) is used for 1st partition packets,
300 // the other mask (sub_mask21/22, for 0/1) is for the remaining FEC packets.
301 
302 // In both mode 0 and 1, the packets of 1st partition (num_imp_packets) are
303 // treated equally important, and are afforded more protection than the
304 // residual partition packets.
305 
306 // For num_imp_packets:
307 // sub_mask1 = (m, t): protection = t/(m), where t=F(k,n-k,m).
308 // t=F(k,n-k,m) is the number of packets used to protect first partition in
309 // sub_mask1. This is determined from the function SetProtectionAllocation().
310 
311 // For the left-over protection:
312 // Mode 0: sub_mask21 = (k-m,n-k-t): protection = (n-k-t)/(k-m)
313 // mode 0 has no protection overlap between the two partitions.
314 // For mode 0, we would typically set t = min(m, n-k).
315 
316 // Mode 1: sub_mask22 = (k, n-k-t), with protection (n-k-t)/(k)
317 // mode 1 has protection overlap between the two partitions (preferred).
318 
319 // For ProtectionMode 2:
320 // This gives 1st packet of list (which is 1st packet of 1st partition) more
321 // protection. In mode 2, the equal protection mask (which is obtained from
322 // mode 1 for t=0) is modified (more "1s" added in 1st column of packet mask)
323 // to bias higher protection for the 1st source packet.
324 
325 // Protection Mode 2 may be extended for a sort of sliding protection
326 // (i.e., vary the number/density of "1s" across columns) across packets.
327 
UnequalProtectionMask(int num_media_packets,int num_fec_packets,int num_imp_packets,int num_mask_bytes,uint8_t * packet_mask,const PacketMaskTable & mask_table)328 void UnequalProtectionMask(int num_media_packets,
329                            int num_fec_packets,
330                            int num_imp_packets,
331                            int num_mask_bytes,
332                            uint8_t* packet_mask,
333                            const PacketMaskTable& mask_table) {
334   // Set Protection type and allocation
335   // TODO(marpan): test/update for best mode and some combinations thereof.
336 
337   ProtectionMode mode = kModeOverlap;
338   int num_fec_for_imp_packets = 0;
339 
340   if (mode != kModeBiasFirstPacket) {
341     num_fec_for_imp_packets = SetProtectionAllocation(
342         num_media_packets, num_fec_packets, num_imp_packets);
343   }
344 
345   int num_fec_remaining = num_fec_packets - num_fec_for_imp_packets;
346   // Done with setting protection type and allocation
347 
348   //
349   // Generate sub_mask1
350   //
351   if (num_fec_for_imp_packets > 0) {
352     ImportantPacketProtection(num_fec_for_imp_packets, num_imp_packets,
353                               num_mask_bytes, packet_mask, mask_table);
354   }
355 
356   //
357   // Generate sub_mask2
358   //
359   if (num_fec_remaining > 0) {
360     RemainingPacketProtection(num_media_packets, num_fec_remaining,
361                               num_fec_for_imp_packets, num_mask_bytes, mode,
362                               packet_mask, mask_table);
363   }
364 }
365 
GeneratePacketMasks(int num_media_packets,int num_fec_packets,int num_imp_packets,bool use_unequal_protection,const PacketMaskTable & mask_table,uint8_t * packet_mask)366 void GeneratePacketMasks(int num_media_packets,
367                          int num_fec_packets,
368                          int num_imp_packets,
369                          bool use_unequal_protection,
370                          const PacketMaskTable& mask_table,
371                          uint8_t* packet_mask) {
372   assert(num_media_packets > 0);
373   assert(num_fec_packets <= num_media_packets && num_fec_packets > 0);
374   assert(num_imp_packets <= num_media_packets && num_imp_packets >= 0);
375 
376   int l_bit = num_media_packets > 16 ? 1 : 0;
377   const int num_mask_bytes =
378       (l_bit == 1) ? kMaskSizeLBitSet : kMaskSizeLBitClear;
379 
380   // Equal-protection for these cases.
381   if (!use_unequal_protection || num_imp_packets == 0) {
382     // Retrieve corresponding mask table directly:for equal-protection case.
383     // Mask = (k,n-k), with protection factor = (n-k)/k,
384     // where k = num_media_packets, n=total#packets, (n-k)=num_fec_packets.
385     memcpy(packet_mask,
386            mask_table.fec_packet_mask_table()[num_media_packets -
387                                               1][num_fec_packets - 1],
388            num_fec_packets * num_mask_bytes);
389   } else {  // UEP case
390     UnequalProtectionMask(num_media_packets, num_fec_packets, num_imp_packets,
391                           num_mask_bytes, packet_mask, mask_table);
392   }  // End of UEP modification
393 }  // End of GetPacketMasks
394 
395 }  // namespace internal
396 }  // namespace webrtc
397