annotate base/RingBuffer.h @ 47:bac8b14ab355

* Add menu for re-adding existing layers * Fix layer tree window so that it at least approximates correct * Add bundled operations in command history, for use with things like multiple consecutive changes to a parameter value * Disambiguate plugins that happen to have identical descriptions * Add spectral centroid plugin (could use some parameters!) * Some other fixes
author Chris Cannam
date Fri, 17 Mar 2006 17:38:28 +0000
parents 2fb933f88604
children 39ae3dee27b9
rev   line source
Chris@0 1 /* -*- c-basic-offset: 4 -*- vi:set ts=8 sts=4 sw=4: */
Chris@0 2
Chris@0 3 /*
Chris@0 4 A waveform viewer and audio annotation editor.
Chris@2 5 Chris Cannam, Queen Mary University of London, 2005-2006
Chris@0 6
Chris@0 7 This is experimental software. Not for distribution.
Chris@0 8 */
Chris@0 9
Chris@0 10 /*
Chris@0 11 This is a modified version of a source file from the
Chris@0 12 Rosegarden MIDI and audio sequencer and notation editor.
Chris@17 13 This file copyright 2000-2006 Chris Cannam.
Chris@0 14 */
Chris@0 15
Chris@0 16 #ifndef _RINGBUFFER_H_
Chris@0 17 #define _RINGBUFFER_H_
Chris@0 18
Chris@0 19 #include <sys/types.h>
Chris@0 20
Chris@0 21 #include "System.h"
Chris@0 22 #include "Scavenger.h"
Chris@0 23
Chris@0 24 //#define DEBUG_RINGBUFFER 1
Chris@0 25
Chris@0 26 #ifdef DEBUG_RINGBUFFER
Chris@0 27 #include <iostream>
Chris@0 28 #endif
Chris@0 29
Chris@0 30 /**
Chris@0 31 * RingBuffer implements a lock-free ring buffer for one writer and N
Chris@0 32 * readers, that is to be used to store a sample type T.
Chris@0 33 *
Chris@0 34 * For efficiency, RingBuffer frequently initialises samples by
Chris@0 35 * writing zeroes into their memory space, so T should normally be a
Chris@0 36 * simple type that can safely be set to zero using memset.
Chris@0 37 */
Chris@0 38
Chris@0 39 template <typename T, int N = 1>
Chris@0 40 class RingBuffer
Chris@0 41 {
Chris@0 42 public:
Chris@0 43 /**
Chris@0 44 * Create a ring buffer with room to write n samples.
Chris@0 45 *
Chris@0 46 * Note that the internal storage size will actually be n+1
Chris@0 47 * samples, as one element is unavailable for administrative
Chris@0 48 * reasons. Since the ring buffer performs best if its size is a
Chris@0 49 * power of two, this means n should ideally be some power of two
Chris@0 50 * minus one.
Chris@0 51 */
Chris@0 52 RingBuffer(size_t n);
Chris@0 53
Chris@0 54 virtual ~RingBuffer();
Chris@0 55
Chris@0 56 /**
Chris@0 57 * Return the total capacity of the ring buffer in samples.
Chris@0 58 * (This is the argument n passed to the constructor.)
Chris@0 59 */
Chris@0 60 size_t getSize() const;
Chris@0 61
Chris@0 62 /**
Chris@0 63 * Resize the ring buffer. This also empties it. Actually swaps
Chris@0 64 * in a new, larger buffer; the old buffer is scavenged after a
Chris@0 65 * seemly delay. Should be called from the write thread.
Chris@0 66 */
Chris@0 67 void resize(size_t newSize);
Chris@0 68
Chris@0 69 /**
Chris@0 70 * Lock the ring buffer into physical memory. Returns true
Chris@0 71 * for success.
Chris@0 72 */
Chris@0 73 bool mlock();
Chris@0 74
Chris@0 75 /**
Chris@0 76 * Reset read and write pointers, thus emptying the buffer.
Chris@0 77 * Should be called from the write thread.
Chris@0 78 */
Chris@0 79 void reset();
Chris@0 80
Chris@0 81 /**
Chris@0 82 * Return the amount of data available for reading by reader R, in
Chris@0 83 * samples.
Chris@0 84 */
Chris@0 85 size_t getReadSpace(int R = 0) const;
Chris@0 86
Chris@0 87 /**
Chris@0 88 * Return the amount of space available for writing, in samples.
Chris@0 89 */
Chris@0 90 size_t getWriteSpace() const;
Chris@0 91
Chris@0 92 /**
Chris@0 93 * Read n samples from the buffer, for reader R. If fewer than n
Chris@0 94 * are available, the remainder will be zeroed out. Returns the
Chris@0 95 * number of samples actually read.
Chris@0 96 */
Chris@0 97 size_t read(T *destination, size_t n, int R = 0);
Chris@0 98
Chris@0 99 /**
Chris@0 100 * Read n samples from the buffer, for reader R, adding them to
Chris@0 101 * the destination. If fewer than n are available, the remainder
Chris@0 102 * will be left alone. Returns the number of samples actually
Chris@0 103 * read.
Chris@0 104 */
Chris@0 105 size_t readAdding(T *destination, size_t n, int R = 0);
Chris@0 106
Chris@0 107 /**
Chris@0 108 * Read one sample from the buffer, for reader R. If no sample is
Chris@0 109 * available, this will silently return zero. Calling this
Chris@0 110 * repeatedly is obviously slower than calling read once, but it
Chris@0 111 * may be good enough if you don't want to allocate a buffer to
Chris@0 112 * read into.
Chris@0 113 */
Chris@0 114 T readOne(int R = 0);
Chris@0 115
Chris@0 116 /**
Chris@0 117 * Read n samples from the buffer, if available, for reader R,
Chris@0 118 * without advancing the read pointer -- i.e. a subsequent read()
Chris@0 119 * or skip() will be necessary to empty the buffer. If fewer than
Chris@0 120 * n are available, the remainder will be zeroed out. Returns the
Chris@0 121 * number of samples actually read.
Chris@0 122 */
Chris@0 123 size_t peek(T *destination, size_t n, int R = 0) const;
Chris@0 124
Chris@0 125 /**
Chris@0 126 * Read one sample from the buffer, if available, without
Chris@0 127 * advancing the read pointer -- i.e. a subsequent read() or
Chris@0 128 * skip() will be necessary to empty the buffer. Returns zero if
Chris@0 129 * no sample was available.
Chris@0 130 */
Chris@0 131 T peekOne(int R = 0) const;
Chris@0 132
Chris@0 133 /**
Chris@0 134 * Pretend to read n samples from the buffer, for reader R,
Chris@0 135 * without actually returning them (i.e. discard the next n
Chris@0 136 * samples). Returns the number of samples actually available for
Chris@0 137 * discarding.
Chris@0 138 */
Chris@0 139 size_t skip(size_t n, int R = 0);
Chris@0 140
Chris@0 141 /**
Chris@0 142 * Write n samples to the buffer. If insufficient space is
Chris@0 143 * available, not all samples may actually be written. Returns
Chris@0 144 * the number of samples actually written.
Chris@0 145 */
Chris@0 146 size_t write(const T *source, size_t n);
Chris@0 147
Chris@0 148 /**
Chris@0 149 * Write n zero-value samples to the buffer. If insufficient
Chris@0 150 * space is available, not all zeros may actually be written.
Chris@0 151 * Returns the number of zeroes actually written.
Chris@0 152 */
Chris@0 153 size_t zero(size_t n);
Chris@0 154
Chris@0 155 protected:
Chris@0 156 T *m_buffer;
Chris@0 157 volatile size_t m_writer;
Chris@0 158 volatile size_t m_readers[N];
Chris@0 159 size_t m_size;
Chris@0 160 bool m_mlocked;
Chris@0 161
Chris@0 162 static Scavenger<ScavengerArrayWrapper<T> > m_scavenger;
Chris@0 163
Chris@0 164 private:
Chris@0 165 RingBuffer(const RingBuffer &); // not provided
Chris@0 166 RingBuffer &operator=(const RingBuffer &); // not provided
Chris@0 167 };
Chris@0 168
Chris@0 169 template <typename T, int N>
Chris@0 170 Scavenger<ScavengerArrayWrapper<T> > RingBuffer<T, N>::m_scavenger;
Chris@0 171
Chris@0 172 template <typename T, int N>
Chris@0 173 RingBuffer<T, N>::RingBuffer(size_t n) :
Chris@0 174 m_buffer(new T[n + 1]),
Chris@0 175 m_writer(0),
Chris@0 176 m_size(n + 1),
Chris@0 177 m_mlocked(false)
Chris@0 178 {
Chris@0 179 #ifdef DEBUG_RINGBUFFER
Chris@0 180 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::RingBuffer(" << n << ")" << std::endl;
Chris@0 181 #endif
Chris@0 182
Chris@0 183 for (int i = 0; i < N; ++i) m_readers[i] = 0;
Chris@0 184
Chris@0 185 m_scavenger.scavenge();
Chris@0 186 }
Chris@0 187
Chris@0 188 template <typename T, int N>
Chris@0 189 RingBuffer<T, N>::~RingBuffer()
Chris@0 190 {
Chris@0 191 #ifdef DEBUG_RINGBUFFER
Chris@0 192 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::~RingBuffer" << std::endl;
Chris@0 193 #endif
Chris@0 194
Chris@0 195 if (m_mlocked) {
Chris@0 196 MUNLOCK((void *)m_buffer, m_size * sizeof(T));
Chris@0 197 }
Chris@0 198 delete[] m_buffer;
Chris@0 199
Chris@0 200 m_scavenger.scavenge();
Chris@0 201 }
Chris@0 202
Chris@0 203 template <typename T, int N>
Chris@0 204 size_t
Chris@0 205 RingBuffer<T, N>::getSize() const
Chris@0 206 {
Chris@0 207 #ifdef DEBUG_RINGBUFFER
Chris@0 208 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::getSize(): " << m_size-1 << std::endl;
Chris@0 209 #endif
Chris@0 210
Chris@0 211 return m_size - 1;
Chris@0 212 }
Chris@0 213
Chris@0 214 template <typename T, int N>
Chris@0 215 void
Chris@0 216 RingBuffer<T, N>::resize(size_t newSize)
Chris@0 217 {
Chris@0 218 #ifdef DEBUG_RINGBUFFER
Chris@0 219 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::resize(" << newSize << ")" << std::endl;
Chris@0 220 #endif
Chris@0 221
Chris@0 222 m_scavenger.scavenge();
Chris@0 223
Chris@0 224 if (m_mlocked) {
Chris@0 225 MUNLOCK((void *)m_buffer, m_size * sizeof(T));
Chris@0 226 }
Chris@0 227
Chris@0 228 m_scavenger.claim(new ScavengerArrayWrapper<T>(m_buffer));
Chris@0 229
Chris@0 230 reset();
Chris@0 231 m_buffer = new T[newSize + 1];
Chris@0 232 m_size = newSize + 1;
Chris@0 233
Chris@0 234 if (m_mlocked) {
Chris@0 235 if (MLOCK((void *)m_buffer, m_size * sizeof(T))) {
Chris@0 236 m_mlocked = false;
Chris@0 237 }
Chris@0 238 }
Chris@0 239 }
Chris@0 240
Chris@0 241 template <typename T, int N>
Chris@0 242 bool
Chris@0 243 RingBuffer<T, N>::mlock()
Chris@0 244 {
Chris@0 245 if (MLOCK((void *)m_buffer, m_size * sizeof(T))) return false;
Chris@0 246 m_mlocked = true;
Chris@0 247 return true;
Chris@0 248 }
Chris@0 249
Chris@0 250 template <typename T, int N>
Chris@0 251 void
Chris@0 252 RingBuffer<T, N>::reset()
Chris@0 253 {
Chris@0 254 #ifdef DEBUG_RINGBUFFER
Chris@0 255 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::reset" << std::endl;
Chris@0 256 #endif
Chris@0 257
Chris@0 258 m_writer = 0;
Chris@0 259 for (int i = 0; i < N; ++i) m_readers[i] = 0;
Chris@0 260 }
Chris@0 261
Chris@0 262 template <typename T, int N>
Chris@0 263 size_t
Chris@0 264 RingBuffer<T, N>::getReadSpace(int R) const
Chris@0 265 {
Chris@0 266 size_t writer = m_writer;
Chris@0 267 size_t reader = m_readers[R];
Chris@0 268 size_t space = 0;
Chris@0 269
Chris@0 270 if (writer > reader) space = writer - reader;
Chris@0 271 else space = ((writer + m_size) - reader) % m_size;
Chris@0 272
Chris@0 273 #ifdef DEBUG_RINGBUFFER
Chris@0 274 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::getReadSpace(" << R << "): " << space << std::endl;
Chris@0 275 #endif
Chris@0 276
Chris@0 277 return space;
Chris@0 278 }
Chris@0 279
Chris@0 280 template <typename T, int N>
Chris@0 281 size_t
Chris@0 282 RingBuffer<T, N>::getWriteSpace() const
Chris@0 283 {
Chris@0 284 size_t space = 0;
Chris@0 285 for (int i = 0; i < N; ++i) {
Chris@0 286 size_t here = (m_readers[i] + m_size - m_writer - 1) % m_size;
Chris@0 287 if (i == 0 || here < space) space = here;
Chris@0 288 }
Chris@0 289
Chris@0 290 #ifdef DEBUG_RINGBUFFER
Chris@0 291 size_t rs(getReadSpace()), rp(m_readers[0]);
Chris@0 292
Chris@0 293 std::cerr << "RingBuffer: write space " << space << ", read space "
Chris@0 294 << rs << ", total " << (space + rs) << ", m_size " << m_size << std::endl;
Chris@0 295 std::cerr << "RingBuffer: reader " << rp << ", writer " << m_writer << std::endl;
Chris@0 296 #endif
Chris@0 297
Chris@0 298 #ifdef DEBUG_RINGBUFFER
Chris@0 299 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::getWriteSpace(): " << space << std::endl;
Chris@0 300 #endif
Chris@0 301
Chris@0 302 return space;
Chris@0 303 }
Chris@0 304
Chris@0 305 template <typename T, int N>
Chris@0 306 size_t
Chris@0 307 RingBuffer<T, N>::read(T *destination, size_t n, int R)
Chris@0 308 {
Chris@0 309 #ifdef DEBUG_RINGBUFFER
Chris@0 310 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::read(dest, " << n << ", " << R << ")" << std::endl;
Chris@0 311 #endif
Chris@0 312
Chris@0 313 size_t available = getReadSpace(R);
Chris@0 314 if (n > available) {
Chris@0 315 #ifdef DEBUG_RINGBUFFER
Chris@0 316 std::cerr << "WARNING: Only " << available << " samples available"
Chris@0 317 << std::endl;
Chris@0 318 #endif
Chris@0 319 memset(destination + available, 0, (n - available) * sizeof(T));
Chris@0 320 n = available;
Chris@0 321 }
Chris@0 322 if (n == 0) return n;
Chris@0 323
Chris@0 324 size_t here = m_size - m_readers[R];
Chris@0 325 if (here >= n) {
Chris@0 326 memcpy(destination, m_buffer + m_readers[R], n * sizeof(T));
Chris@0 327 } else {
Chris@0 328 memcpy(destination, m_buffer + m_readers[R], here * sizeof(T));
Chris@0 329 memcpy(destination + here, m_buffer, (n - here) * sizeof(T));
Chris@0 330 }
Chris@0 331
Chris@0 332 m_readers[R] = (m_readers[R] + n) % m_size;
Chris@0 333
Chris@0 334 #ifdef DEBUG_RINGBUFFER
Chris@0 335 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::read: read " << n << ", reader now " << m_readers[R] << std::endl;
Chris@0 336 #endif
Chris@0 337
Chris@0 338 return n;
Chris@0 339 }
Chris@0 340
Chris@0 341 template <typename T, int N>
Chris@0 342 size_t
Chris@0 343 RingBuffer<T, N>::readAdding(T *destination, size_t n, int R)
Chris@0 344 {
Chris@0 345 #ifdef DEBUG_RINGBUFFER
Chris@0 346 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::readAdding(dest, " << n << ", " << R << ")" << std::endl;
Chris@0 347 #endif
Chris@0 348
Chris@0 349 size_t available = getReadSpace(R);
Chris@0 350 if (n > available) {
Chris@0 351 #ifdef DEBUG_RINGBUFFER
Chris@0 352 std::cerr << "WARNING: Only " << available << " samples available"
Chris@0 353 << std::endl;
Chris@0 354 #endif
Chris@0 355 n = available;
Chris@0 356 }
Chris@0 357 if (n == 0) return n;
Chris@0 358
Chris@0 359 size_t here = m_size - m_readers[R];
Chris@0 360
Chris@0 361 if (here >= n) {
Chris@0 362 for (size_t i = 0; i < n; ++i) {
Chris@0 363 destination[i] += (m_buffer + m_readers[R])[i];
Chris@0 364 }
Chris@0 365 } else {
Chris@0 366 for (size_t i = 0; i < here; ++i) {
Chris@0 367 destination[i] += (m_buffer + m_readers[R])[i];
Chris@0 368 }
Chris@0 369 for (size_t i = 0; i < (n - here); ++i) {
Chris@0 370 destination[i + here] += m_buffer[i];
Chris@0 371 }
Chris@0 372 }
Chris@0 373
Chris@0 374 m_readers[R] = (m_readers[R] + n) % m_size;
Chris@0 375 return n;
Chris@0 376 }
Chris@0 377
Chris@0 378 template <typename T, int N>
Chris@0 379 T
Chris@0 380 RingBuffer<T, N>::readOne(int R)
Chris@0 381 {
Chris@0 382 #ifdef DEBUG_RINGBUFFER
Chris@0 383 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::readOne(" << R << ")" << std::endl;
Chris@0 384 #endif
Chris@0 385
Chris@0 386 if (m_writer == m_readers[R]) {
Chris@0 387 #ifdef DEBUG_RINGBUFFER
Chris@0 388 std::cerr << "WARNING: No sample available"
Chris@0 389 << std::endl;
Chris@0 390 #endif
Chris@0 391 T t;
Chris@0 392 memset(&t, 0, sizeof(T));
Chris@0 393 return t;
Chris@0 394 }
Chris@0 395 T value = m_buffer[m_readers[R]];
Chris@0 396 if (++m_readers[R] == m_size) m_readers[R] = 0;
Chris@0 397 return value;
Chris@0 398 }
Chris@0 399
Chris@0 400 template <typename T, int N>
Chris@0 401 size_t
Chris@0 402 RingBuffer<T, N>::peek(T *destination, size_t n, int R) const
Chris@0 403 {
Chris@0 404 #ifdef DEBUG_RINGBUFFER
Chris@0 405 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::peek(dest, " << n << ", " << R << ")" << std::endl;
Chris@0 406 #endif
Chris@0 407
Chris@0 408 size_t available = getReadSpace(R);
Chris@0 409 if (n > available) {
Chris@0 410 #ifdef DEBUG_RINGBUFFER
Chris@0 411 std::cerr << "WARNING: Only " << available << " samples available"
Chris@0 412 << std::endl;
Chris@0 413 #endif
Chris@0 414 memset(destination + available, 0, (n - available) * sizeof(T));
Chris@0 415 n = available;
Chris@0 416 }
Chris@0 417 if (n == 0) return n;
Chris@0 418
Chris@0 419 size_t here = m_size - m_readers[R];
Chris@0 420 if (here >= n) {
Chris@0 421 memcpy(destination, m_buffer + m_readers[R], n * sizeof(T));
Chris@0 422 } else {
Chris@0 423 memcpy(destination, m_buffer + m_readers[R], here * sizeof(T));
Chris@0 424 memcpy(destination + here, m_buffer, (n - here) * sizeof(T));
Chris@0 425 }
Chris@0 426
Chris@0 427 #ifdef DEBUG_RINGBUFFER
Chris@0 428 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::peek: read " << n << std::endl;
Chris@0 429 #endif
Chris@0 430
Chris@0 431 return n;
Chris@0 432 }
Chris@0 433
Chris@0 434 template <typename T, int N>
Chris@0 435 T
Chris@0 436 RingBuffer<T, N>::peekOne(int R) const
Chris@0 437 {
Chris@0 438 #ifdef DEBUG_RINGBUFFER
Chris@0 439 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::peek(" << R << ")" << std::endl;
Chris@0 440 #endif
Chris@0 441
Chris@0 442 if (m_writer == m_readers[R]) {
Chris@0 443 #ifdef DEBUG_RINGBUFFER
Chris@0 444 std::cerr << "WARNING: No sample available"
Chris@0 445 << std::endl;
Chris@0 446 #endif
Chris@0 447 T t;
Chris@0 448 memset(&t, 0, sizeof(T));
Chris@0 449 return t;
Chris@0 450 }
Chris@0 451 T value = m_buffer[m_readers[R]];
Chris@0 452 return value;
Chris@0 453 }
Chris@0 454
Chris@0 455 template <typename T, int N>
Chris@0 456 size_t
Chris@0 457 RingBuffer<T, N>::skip(size_t n, int R)
Chris@0 458 {
Chris@0 459 #ifdef DEBUG_RINGBUFFER
Chris@0 460 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::skip(" << n << ", " << R << ")" << std::endl;
Chris@0 461 #endif
Chris@0 462
Chris@0 463 size_t available = getReadSpace(R);
Chris@0 464 if (n > available) {
Chris@0 465 #ifdef DEBUG_RINGBUFFER
Chris@0 466 std::cerr << "WARNING: Only " << available << " samples available"
Chris@0 467 << std::endl;
Chris@0 468 #endif
Chris@0 469 n = available;
Chris@0 470 }
Chris@0 471 if (n == 0) return n;
Chris@0 472 m_readers[R] = (m_readers[R] + n) % m_size;
Chris@0 473 return n;
Chris@0 474 }
Chris@0 475
Chris@0 476 template <typename T, int N>
Chris@0 477 size_t
Chris@0 478 RingBuffer<T, N>::write(const T *source, size_t n)
Chris@0 479 {
Chris@0 480 #ifdef DEBUG_RINGBUFFER
Chris@0 481 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::write(" << n << ")" << std::endl;
Chris@0 482 #endif
Chris@0 483
Chris@0 484 size_t available = getWriteSpace();
Chris@0 485 if (n > available) {
Chris@0 486 #ifdef DEBUG_RINGBUFFER
Chris@0 487 std::cerr << "WARNING: Only room for " << available << " samples"
Chris@0 488 << std::endl;
Chris@0 489 #endif
Chris@0 490 n = available;
Chris@0 491 }
Chris@0 492 if (n == 0) return n;
Chris@0 493
Chris@0 494 size_t here = m_size - m_writer;
Chris@0 495 if (here >= n) {
Chris@0 496 memcpy(m_buffer + m_writer, source, n * sizeof(T));
Chris@0 497 } else {
Chris@0 498 memcpy(m_buffer + m_writer, source, here * sizeof(T));
Chris@0 499 memcpy(m_buffer, source + here, (n - here) * sizeof(T));
Chris@0 500 }
Chris@0 501
Chris@0 502 m_writer = (m_writer + n) % m_size;
Chris@0 503
Chris@0 504 #ifdef DEBUG_RINGBUFFER
Chris@0 505 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::write: wrote " << n << ", writer now " << m_writer << std::endl;
Chris@0 506 #endif
Chris@0 507
Chris@0 508 return n;
Chris@0 509 }
Chris@0 510
Chris@0 511 template <typename T, int N>
Chris@0 512 size_t
Chris@0 513 RingBuffer<T, N>::zero(size_t n)
Chris@0 514 {
Chris@0 515 #ifdef DEBUG_RINGBUFFER
Chris@0 516 std::cerr << "RingBuffer<T," << N << ">[" << this << "]::zero(" << n << ")" << std::endl;
Chris@0 517 #endif
Chris@0 518
Chris@0 519 size_t available = getWriteSpace();
Chris@0 520 if (n > available) {
Chris@0 521 #ifdef DEBUG_RINGBUFFER
Chris@0 522 std::cerr << "WARNING: Only room for " << available << " samples"
Chris@0 523 << std::endl;
Chris@0 524 #endif
Chris@0 525 n = available;
Chris@0 526 }
Chris@0 527 if (n == 0) return n;
Chris@0 528
Chris@0 529 size_t here = m_size - m_writer;
Chris@0 530 if (here >= n) {
Chris@0 531 memset(m_buffer + m_writer, 0, n * sizeof(T));
Chris@0 532 } else {
Chris@0 533 memset(m_buffer + m_writer, 0, here * sizeof(T));
Chris@0 534 memset(m_buffer, 0, (n - here) * sizeof(T));
Chris@0 535 }
Chris@0 536
Chris@0 537 m_writer = (m_writer + n) % m_size;
Chris@0 538 return n;
Chris@0 539 }
Chris@0 540
Chris@0 541 #endif // _RINGBUFFER_H_