fix typo
[lttv.git] / doc / developer / lttng-synthetic-tsc-msb.txt
1
2 LTTng synthetic TSC MSB
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4 Mathieu Desnoyers, Mars 1, 2006
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6 A problem found on some architectures is that the TSC is limited to 32 bits,
7 which induces a wrap-around every 8 seconds or so.
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9 The wraps arounds are detectable by the use of a heartbeat timer, which
10 generates an event in each trace at periodic interval. It makes reading the
11 trace sequentially possible.
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13 What causes problem is fast time seek in the trace : it uses the buffer
14 boundary timestamps (64 bits) to seek to the right block in O(log(n)). It
15 cannot, however, read the trace sequentially.
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17 So the problem posed is the following : we want to generate a per cpu 64 bits
18 TSC from the available 32 bits with the 32 MSB generated synthetically. I should
19 be readable by the buffer switch event.
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21 The idea is the following : we keep a 32 bits previous_tsc value per cpu. It
22 helps detect the wrap around. Each time a heartbeat fires or a buffer switch
23 happens, the previous_tsc is read, and then written to the new value. If a wrap
24 around is detected, the msb_tsc for the cpu is atomically incremented.
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26 We are sure that there is only one heartbeat at a given time because they are
27 fired at fixed interval : typically 10 times per 32bit TSC wrap around. Even
28 better, as they are launched by a worker thread, it can only be queued once in
29 the worker queue.
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31 Now with buffer switch vs heartbeat concurrency. Worse case : a heartbeat is
32 happenning : one CPU is in process context (worker thread), the other ones are
33 in interrupt context (IPI). On one CPU in IPI, we have an NMI triggered that
34 generates a buffer switch.
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36 What is sure is that the heartbeat needs to read and write the previous_tsc. It
37 also needs to increment atomically the msb_tsc. However, the buffer switch only
38 needs to read the previous_tsc, compare it to the current tsc and read the
39 msb_tsc.
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41 Another race case is that the buffer switch can be interrupted by the heartbeat.
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43 So what we need is to have an atomic write. As the architecture does not support
44 64 bits cmpxchg, we will need this little data structure to overcome this
45 problem :
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47 An array of two 64 bits elements. Elements are updated in two memory writes, but
48 the element switch (current element) is made atomically. As there is only one
49 writer, this has no locking problem.
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51 We make sure the synthetic tcs reader does not sleep by disabling preemption. We
52 do the same for the writer.
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