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Rack/include/dsp/ringbuffer.hpp

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  1. #pragma once

  2. #ifndef RACK_SKIP_RINGBUFFER

  3. 

  4. #include <string.h>

  5. #include "util/common.hpp"

  6. 

  7. 

  8. namespace rack {

  9. 

  10. /** A simple cyclic buffer.

  11. S must be a power of 2.

  12. Thread-safe for single producers and consumers.

  13. */

  14. template <typename T, size_t S>

  15. struct RingBuffer {

  16. 	T data[S];

  17. 	size_t start = 0;

  18. 	size_t end = 0;

  19. 

  20. 	size_t mask(size_t i) const {

  21. 			return i & (S - 1);

  22. 	}

  23. 	void push(T t) {

  24. 		size_t i = mask(end++);

  25. 		data[i] = t;

  26. 	}

  27. 	void pushBuffer(const T *t, int n) {

  28. 		size_t i = mask(end);

  29. 		size_t e1 = i + n;

  30. 		size_t e2 = (e1 < S) ? e1 : S;

  31. 		memcpy(&data[i], t, sizeof(T) * (e2 - i));

  32. 		if (e1 > S) {

  33. 			memcpy(data, &t[S - i], sizeof(T) * (e1 - S));

  34. 		}

  35. 		end += n;

  36. 	}

  37. 	T shift() {

  38. 		return data[mask(start++)];

  39. 	}

  40. 	void shiftBuffer(T *t, size_t n) {

  41. 		size_t i = mask(start);

  42. 		size_t s1 = i + n;

  43. 		size_t s2 = (s1 < S) ? s1 : S;

  44. 		memcpy(t, &data[i], sizeof(T) * (s2 - i));

  45. 		if (s1 > S) {

  46. 			memcpy(&t[S - i], data, sizeof(T) * (s1 - S));

  47. 		}

  48. 		start += n;

  49. 	}

  50. 	void clear() {

  51. 		start = end;

  52. 	}

  53. 	bool empty() const {

  54. 		return start == end;

  55. 	}

  56. 	bool full() const {

  57. 		return end - start == S;

  58. 	}

  59. 	size_t size() const {

  60. 		return end - start;

  61. 	}

  62. 	size_t capacity() const {

  63. 		return S - size();

  64. 	}

  65. };

  66. 

  67. /** A cyclic buffer which maintains a valid linear array of size S by keeping a copy of the buffer in adjacent memory.

  68. S must be a power of 2.

  69. Thread-safe for single producers and consumers?

  70. */

  71. template <typename T, size_t S>

  72. struct DoubleRingBuffer {

  73. 	T data[S*2];

  74. 	size_t start = 0;

  75. 	size_t end = 0;

  76. 

  77. 	size_t mask(size_t i) const {

  78. 		return i & (S - 1);

  79. 	}

  80. 	void push(T t) {

  81. 		size_t i = mask(end++);

  82. 		data[i] = t;

  83. 		data[i + S] = t;

  84. 	}

  85. 	T shift() {

  86. 		return data[mask(start++)];

  87. 	}

  88. 	void clear() {

  89. 		start = end;

  90. 	}

  91. 	bool empty() const {

  92. 		return start == end;

  93. 	}

  94. 	bool full() const {

  95. 		return end - start == S;

  96. 	}

  97. 	size_t size() const {

  98. 		return end - start;

  99. 	}

  100. 	size_t capacity() const {

  101. 		return S - size();

  102. 	}

  103. 	/** Returns a pointer to S consecutive elements for appending.

  104. 	If any data is appended, you must call endIncr afterwards.

  105. 	Pointer is invalidated when any other method is called.

  106. 	*/

  107. 	T *endData() {

  108. 		return &data[mask(end)];

  109. 	}

  110. 	void endIncr(size_t n) {

  111. 		size_t e = mask(end);

  112. 		size_t e1 = e + n;

  113. 		size_t e2 = (e1 < S) ? e1 : S;

  114. 		// Copy data forward

  115. 		memcpy(&data[S + e], &data[e], sizeof(T) * (e2 - e));

  116. 

  117. 		if (e1 > S) {

  118. 			// Copy data backward from the doubled block to the main block

  119. 			memcpy(data, &data[S], sizeof(T) * (e1 - S));

  120. 		}

  121. 		end += n;

  122. 	}

  123. 	/** Returns a pointer to S consecutive elements for consumption

  124. 	If any data is consumed, call startIncr afterwards.

  125. 	*/

  126. 	const T *startData() const {

  127. 		return &data[mask(start)];

  128. 	}

  129. 	void startIncr(size_t n) {

  130. 		start += n;

  131. 	}

  132. };

  133. 

  134. /** A cyclic buffer which maintains a valid linear array of size S by sliding along a larger block of size N.

  135. The linear array of S elements are moved back to the start of the block once it outgrows past the end.

  136. This happens every N - S pushes, so the push() time is O(1 + S / (N - S)).

  137. For example, a float buffer of size 64 in a block of size 1024 is nearly as efficient as RingBuffer.

  138. Not thread-safe.

  139. */

  140. template <typename T, size_t S, size_t N>

  141. struct AppleRingBuffer {

  142. 	T data[N];

  143. 	size_t start = 0;

  144. 	size_t end = 0;

  145. 

  146. 	void returnBuffer() {

  147. 		// move end block to beginning

  148. 		// may overlap, but memmove handles that correctly

  149. 		size_t s = size();

  150. 		memmove(data, &data[start], sizeof(T) * s);

  151. 		start = 0;

  152. 		end = s;

  153. 	}

  154. 	void push(T t) {

  155. 		if (end + 1 > N) {

  156. 			returnBuffer();

  157. 		}

  158. 		data[end++] = t;

  159. 	}

  160. 	T shift() {

  161. 		return data[start++];

  162. 	}

  163. 	bool empty() const {

  164. 		return start == end;

  165. 	}

  166. 	bool full() const {

  167. 		return end - start == S;

  168. 	}

  169. 	size_t size() const {

  170. 		return end - start;

  171. 	}

  172. 	size_t capacity() const {

  173. 		return S - size();

  174. 	}

  175. 	/** Returns a pointer to S consecutive elements for appending, requesting to append n elements.

  176. 	*/

  177. 	T *endData(size_t n) {

  178. 		if (end + n > N) {

  179. 			returnBuffer();

  180. 		}

  181. 		return &data[end];

  182. 	}

  183. 	/** Actually increments the end position

  184. 	Must be called after endData(), and `n` must be at most the `n` passed to endData()

  185. 	*/

  186. 	void endIncr(size_t n) {

  187. 		end += n;

  188. 	}

  189. 	/** Returns a pointer to S consecutive elements for consumption

  190. 	If any data is consumed, call startIncr afterwards.

  191. 	*/

  192. 	const T *startData() const {

  193. 		return &data[start];

  194. 	}

  195. 	void startIncr(size_t n) {

  196. 		// This is valid as long as n < S

  197. 		start += n;

  198. 	}

  199. };

  200. 

  201. } // namespace rack

  202. #endif // RACK_SKIP_RINGBUFFER