SPRZ487F May   2022  – December 2024 AM620-Q1 , AM623 , AM625 , AM625-Q1 , AM625SIP

 

  1.   1
  2. 1Usage Notes and Advisories Matrices
    1. 1.1 Devices Supported
  3. 2Silicon Usage Notes and Advisories
    1. 2.1 Silicon Usage Notes
      1.      i2351
      2.      i2372
      3.      i2424
    2. 2.2 Silicon Advisories
      1.      i2049
      2.      i2062
      3.      i2097
      4.      i2103
      5.      i2134
      6.      i2189
      7.      i2196
      8.      i2232
      9.      i2244
      10.      i2310
      11.      i2311
      12.      i2327
      13.      i2328
      14.      i2279
      15.      i2307
      16.      i2320
      17.      i2329
      18.      i2208
      19.      i2249
      20.      i2278
      21.      i2312
      22.      i2366
      23.      i2371
      24.      i2253
      25.      i2283
      26.      i2383
      27.      i2401
      28.      i2407
      29.      i2409
      30.      i2410
      31.      i2413
      32.      i2414
      33.      i2415
      34.      i2416
      35.      i2417
      36.      i2418
      37.      i2419
      38.      i2420
      39.      i2421
      40.      i2422
      41.      i2423
      42.      i2435
      43.      i2431
  4.   Trademarks
  5.   Revision History

i2196

IA: Potential deadlock scenarios in IA

Details:

The interrupt Aggregator (IA) has one main function, which is to convert events arriving on the Event Transport Lane (ETL) bus, can convert them to interrupt status bits which are used to generate level interrupts. The block that performed this function in IA version 1.0 was called the status event block.

In addition to the status event block, there are two other main processing blocks; the multicast event block, and the counted event block. The multicast block really functions as an event splitter. For every event it takes in, it can generate two output events. The counted event block is used to convert high frequency events into a readable count. It counts input events and generates output events on count transitions to/from 0 to/from non-zero count values. Unlike the status event block, the multicast and counted event blocks generate output ETL events that are then mapped to other processing blocks.

An issue was found after design that could cause the IA to deadlock. The issue occurs when event “loops” occur between these three processing blocks. It is possible to create a situation where a processing block can not output an event because the path is blocked, and since it can not output an event, it can not take any new input events. This inability to take input events prevents the output path from being able to unwind, and thus both paths remain blocked.

Workaround(s):

Figure 2-3 shows the conceptual block diagram of IA 1.0. Potential loops are avoided by adopting the policy of not allowing the counted event block to send events to the multicast block. This method was chosen because it is more common to split an event first, and then count one while sending the other elsewhere. With this path blocked by convention, it is not possible for a single event to visit any block more than once and thus not possible for paths to become blocked so long as the outputs remain unblocked.

 Interrupt Aggregator Version 1.0 Figure 2-3 Interrupt Aggregator Version 1.0

By following the conventions outlined here, the system is safe from looping hazards that can create a deadlock scenario.