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doc/rtio: sync() visualization
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@ -52,7 +52,7 @@ The :meth:`artiq.coredevice.ttl.TTLOut.on` method places an rising edge on the t
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Then the cursor is moved forward 2 µs and a falling edge event is placed at the new cursor position.
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Then the cursor is moved forward 2 µs and a falling edge event is placed at the new cursor position.
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Then later, when the wall clock reaches the respective timestamps the RTIO gateware executes the two events.
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Then later, when the wall clock reaches the respective timestamps the RTIO gateware executes the two events.
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The following diagram shows what is going on at the different levels of the software and gateware stack:
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The following diagram shows what is going on at the different levels of the software and gateware stack (assuming one machine unit of time is 1 ns):
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.. wavedrom::
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.. wavedrom::
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{
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{
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@ -144,13 +144,33 @@ This is demonstrated in the following example where a pulse is split across two
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``kernel1()`` exits leaving the cursor one second after the rising edge and ``kernel2()`` then submits a falling edge at that position.
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``kernel1()`` exits leaving the cursor one second after the rising edge and ``kernel2()`` then submits a falling edge at that position.
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RTIO reset
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Synchronization
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-----------
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---------------
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The seamless handover of the timeline (cursor and events) across kernels and experiments implies that a kernel can exit long before the events it has submitted have been executed.
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The seamless handover of the timeline (cursor and events) across kernels and experiments implies that a kernel can exit long before the events it has submitted have been executed.
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If a previous kernel sets timeline cursor far in the future this effectively locks the system.
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If a previous kernel sets timeline cursor far in the future this effectively locks the system.
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It also means that a kernel is not guaranteed to always be executed with positive slack.
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When a kernel should wait until all the events on a particular channel have been executed, use the :meth:`artiq.coredevice.ttl.TTLOut.sync` method of a channel:
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.. wavedrom::
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{
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signal: [
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{name: 'kernel', wave: 'x2x.|2.|x', data: ['on()', 'sync()'], node: '..A.....Y'},
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{name: 'now_mu', wave: '2..', data: ['7000'], node: '..P'},
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{},
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{},
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{name: 'rtio_counter', wave: 'x2x.|..2x', data: ['2000', '7000'], node: ' ....V'},
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{name: 'ttl', wave: 'x1', node: ' R', phase: -6.5},
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],
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edge: [
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'A~>R', 'P~>R', 'V~>R', 'V~>Y'
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],
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}
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RTIO reset
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-----------
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The seamless handover also means that a kernel is not guaranteed to always be executed with positive slack.
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An experiment can face any of these circumstances (large positive slack, full FIFOs, or negative slack).
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Therefore, when switching experiments it can be adequate to clear the RTIO FIFOs and initialize the timeline cursor to "sometime in the near future" using :meth:`artiq.coredevice.core.Core.reset`.
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Therefore, when switching experiments it can be adequate to clear the RTIO FIFOs and initialize the timeline cursor to "sometime in the near future" using :meth:`artiq.coredevice.core.Core.reset`.
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The example idle kernel implements this mechanism.
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The example idle kernel implements this mechanism.
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Since it never waits for any input, it will rapidly fill the output FIFOs and would produce a large positive slack.
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Since it never waits for any input, it will rapidly fill the output FIFOs and would produce a large positive slack.
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