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1 | ================ |
2 | CIRCULAR BUFFERS | |
3 | ================ | |
4 | ||
5 | By: David Howells <dhowells@redhat.com> | |
6 | Paul E. McKenney <paulmck@linux.vnet.ibm.com> | |
7 | ||
8 | ||
9 | Linux provides a number of features that can be used to implement circular | |
10 | buffering. There are two sets of such features: | |
11 | ||
12 | (1) Convenience functions for determining information about power-of-2 sized | |
13 | buffers. | |
14 | ||
15 | (2) Memory barriers for when the producer and the consumer of objects in the | |
16 | buffer don't want to share a lock. | |
17 | ||
18 | To use these facilities, as discussed below, there needs to be just one | |
19 | producer and just one consumer. It is possible to handle multiple producers by | |
20 | serialising them, and to handle multiple consumers by serialising them. | |
21 | ||
22 | ||
23 | Contents: | |
24 | ||
25 | (*) What is a circular buffer? | |
26 | ||
27 | (*) Measuring power-of-2 buffers. | |
28 | ||
29 | (*) Using memory barriers with circular buffers. | |
30 | - The producer. | |
31 | - The consumer. | |
32 | ||
33 | ||
34 | ========================== | |
35 | WHAT IS A CIRCULAR BUFFER? | |
36 | ========================== | |
37 | ||
38 | First of all, what is a circular buffer? A circular buffer is a buffer of | |
39 | fixed, finite size into which there are two indices: | |
40 | ||
41 | (1) A 'head' index - the point at which the producer inserts items into the | |
42 | buffer. | |
43 | ||
44 | (2) A 'tail' index - the point at which the consumer finds the next item in | |
45 | the buffer. | |
46 | ||
47 | Typically when the tail pointer is equal to the head pointer, the buffer is | |
48 | empty; and the buffer is full when the head pointer is one less than the tail | |
49 | pointer. | |
50 | ||
51 | The head index is incremented when items are added, and the tail index when | |
52 | items are removed. The tail index should never jump the head index, and both | |
53 | indices should be wrapped to 0 when they reach the end of the buffer, thus | |
54 | allowing an infinite amount of data to flow through the buffer. | |
55 | ||
56 | Typically, items will all be of the same unit size, but this isn't strictly | |
57 | required to use the techniques below. The indices can be increased by more | |
58 | than 1 if multiple items or variable-sized items are to be included in the | |
59 | buffer, provided that neither index overtakes the other. The implementer must | |
60 | be careful, however, as a region more than one unit in size may wrap the end of | |
61 | the buffer and be broken into two segments. | |
62 | ||
63 | ||
64 | ============================ | |
65 | MEASURING POWER-OF-2 BUFFERS | |
66 | ============================ | |
67 | ||
68 | Calculation of the occupancy or the remaining capacity of an arbitrarily sized | |
69 | circular buffer would normally be a slow operation, requiring the use of a | |
70 | modulus (divide) instruction. However, if the buffer is of a power-of-2 size, | |
71 | then a much quicker bitwise-AND instruction can be used instead. | |
72 | ||
73 | Linux provides a set of macros for handling power-of-2 circular buffers. These | |
74 | can be made use of by: | |
75 | ||
76 | #include <linux/circ_buf.h> | |
77 | ||
78 | The macros are: | |
79 | ||
80 | (*) Measure the remaining capacity of a buffer: | |
81 | ||
82 | CIRC_SPACE(head_index, tail_index, buffer_size); | |
83 | ||
84 | This returns the amount of space left in the buffer[1] into which items | |
85 | can be inserted. | |
86 | ||
87 | ||
88 | (*) Measure the maximum consecutive immediate space in a buffer: | |
89 | ||
90 | CIRC_SPACE_TO_END(head_index, tail_index, buffer_size); | |
91 | ||
92 | This returns the amount of consecutive space left in the buffer[1] into | |
93 | which items can be immediately inserted without having to wrap back to the | |
94 | beginning of the buffer. | |
95 | ||
96 | ||
97 | (*) Measure the occupancy of a buffer: | |
98 | ||
99 | CIRC_CNT(head_index, tail_index, buffer_size); | |
100 | ||
101 | This returns the number of items currently occupying a buffer[2]. | |
102 | ||
103 | ||
104 | (*) Measure the non-wrapping occupancy of a buffer: | |
105 | ||
106 | CIRC_CNT_TO_END(head_index, tail_index, buffer_size); | |
107 | ||
108 | This returns the number of consecutive items[2] that can be extracted from | |
109 | the buffer without having to wrap back to the beginning of the buffer. | |
110 | ||
111 | ||
112 | Each of these macros will nominally return a value between 0 and buffer_size-1, | |
113 | however: | |
114 | ||
115 | [1] CIRC_SPACE*() are intended to be used in the producer. To the producer | |
116 | they will return a lower bound as the producer controls the head index, | |
117 | but the consumer may still be depleting the buffer on another CPU and | |
118 | moving the tail index. | |
119 | ||
120 | To the consumer it will show an upper bound as the producer may be busy | |
121 | depleting the space. | |
122 | ||
123 | [2] CIRC_CNT*() are intended to be used in the consumer. To the consumer they | |
124 | will return a lower bound as the consumer controls the tail index, but the | |
125 | producer may still be filling the buffer on another CPU and moving the | |
126 | head index. | |
127 | ||
128 | To the producer it will show an upper bound as the consumer may be busy | |
129 | emptying the buffer. | |
130 | ||
131 | [3] To a third party, the order in which the writes to the indices by the | |
132 | producer and consumer become visible cannot be guaranteed as they are | |
133 | independent and may be made on different CPUs - so the result in such a | |
134 | situation will merely be a guess, and may even be negative. | |
135 | ||
136 | ||
137 | =========================================== | |
138 | USING MEMORY BARRIERS WITH CIRCULAR BUFFERS | |
139 | =========================================== | |
140 | ||
141 | By using memory barriers in conjunction with circular buffers, you can avoid | |
142 | the need to: | |
143 | ||
144 | (1) use a single lock to govern access to both ends of the buffer, thus | |
145 | allowing the buffer to be filled and emptied at the same time; and | |
146 | ||
147 | (2) use atomic counter operations. | |
148 | ||
149 | There are two sides to this: the producer that fills the buffer, and the | |
150 | consumer that empties it. Only one thing should be filling a buffer at any one | |
151 | time, and only one thing should be emptying a buffer at any one time, but the | |
152 | two sides can operate simultaneously. | |
153 | ||
154 | ||
155 | THE PRODUCER | |
156 | ------------ | |
157 | ||
158 | The producer will look something like this: | |
159 | ||
160 | spin_lock(&producer_lock); | |
161 | ||
162 | unsigned long head = buffer->head; | |
163 | unsigned long tail = ACCESS_ONCE(buffer->tail); | |
164 | ||
165 | if (CIRC_SPACE(head, tail, buffer->size) >= 1) { | |
166 | /* insert one item into the buffer */ | |
167 | struct item *item = buffer[head]; | |
168 | ||
169 | produce_item(item); | |
170 | ||
171 | smp_wmb(); /* commit the item before incrementing the head */ | |
172 | ||
173 | buffer->head = (head + 1) & (buffer->size - 1); | |
174 | ||
175 | /* wake_up() will make sure that the head is committed before | |
176 | * waking anyone up */ | |
177 | wake_up(consumer); | |
178 | } | |
179 | ||
180 | spin_unlock(&producer_lock); | |
181 | ||
182 | This will instruct the CPU that the contents of the new item must be written | |
183 | before the head index makes it available to the consumer and then instructs the | |
184 | CPU that the revised head index must be written before the consumer is woken. | |
185 | ||
186 | Note that wake_up() doesn't have to be the exact mechanism used, but whatever | |
187 | is used must guarantee a (write) memory barrier between the update of the head | |
188 | index and the change of state of the consumer, if a change of state occurs. | |
189 | ||
190 | ||
191 | THE CONSUMER | |
192 | ------------ | |
193 | ||
194 | The consumer will look something like this: | |
195 | ||
196 | spin_lock(&consumer_lock); | |
197 | ||
198 | unsigned long head = ACCESS_ONCE(buffer->head); | |
199 | unsigned long tail = buffer->tail; | |
200 | ||
201 | if (CIRC_CNT(head, tail, buffer->size) >= 1) { | |
202 | /* read index before reading contents at that index */ | |
203 | smp_read_barrier_depends(); | |
204 | ||
205 | /* extract one item from the buffer */ | |
206 | struct item *item = buffer[tail]; | |
207 | ||
208 | consume_item(item); | |
209 | ||
210 | smp_mb(); /* finish reading descriptor before incrementing tail */ | |
211 | ||
212 | buffer->tail = (tail + 1) & (buffer->size - 1); | |
213 | } | |
214 | ||
215 | spin_unlock(&consumer_lock); | |
216 | ||
217 | This will instruct the CPU to make sure the index is up to date before reading | |
218 | the new item, and then it shall make sure the CPU has finished reading the item | |
219 | before it writes the new tail pointer, which will erase the item. | |
220 | ||
221 | ||
222 | Note the use of ACCESS_ONCE() in both algorithms to read the opposition index. | |
223 | This prevents the compiler from discarding and reloading its cached value - | |
224 | which some compilers will do across smp_read_barrier_depends(). This isn't | |
225 | strictly needed if you can be sure that the opposition index will _only_ be | |
226 | used the once. | |
227 | ||
228 | ||
229 | =============== | |
230 | FURTHER READING | |
231 | =============== | |
232 | ||
233 | See also Documentation/memory-barriers.txt for a description of Linux's memory | |
234 | barrier facilities. |