SPRZ491D december   2020  – june 2023 DRA821U , DRA821U-Q1

 

  1.   1
  2. 1Modules Affected
  3. 2Nomenclature, Package Symbolization, and Revision Identification
    1. 2.1 Device and Development-Support Tool Nomenclature
    2. 2.2 Devices Supported
    3. 2.3 Package Symbolization and Revision Identification
  4. 3Silicon Revision 1.0, 2.0 Usage Notes and Advisories
    1. 3.1 Silicon Revision 1.0, 2.0 Usage Notes
    2. 3.2 Silicon Revision 1.0, 2.0 Advisories
    3.     i2049
    4.     i2062
    5.     i2091
    6.     i2116
    7.     i2123
    8. 3.3 i2126
    9. 3.4 i2127
    10.     i2134
    11.     i2137
    12.     i2146
    13. 3.5 i2151
    14.     i2157
    15.     i2159
    16.     i2160
    17.     i2161
    18.     i2163
    19.     i2166
    20.     i2177
    21.     i2182
    22.     i2183
    23.     i2184
    24.     i2185
    25.     i2186
    26.     i2187
    27.     i2189
    28.     i2196
    29.     i2197
    30.     i2201
    31.     i2205
    32.     i2207
    33.     i2208
    34.     i2209
    35.     i2216
    36.     i2217
    37.     i2221
    38.     i2222
    39.     i2227
    40.     i2228
    41.     i2232
    42.     i2234
    43.     i2235
    44.     i2237
    45.     i2241
    46.     i2242
    47.     i2243
    48.     i2244
    49.     i2245
    50.     i2246
    51.     i2249
    52.     i2253
    53.     i2257
    54.     i2274
    55.     i2275
    56.     i2277
    57.     i2278
    58.     i2279
    59.     i2283
    60.     i2306
    61.     i2307
    62.     i2310
    63.     i2311
    64.     i2312
    65.     i2320
    66.     i2326
    67.     i2329
    68.     i2351
    69.     i2360
    70.     i2361
    71.     i2362
    72.     i2366
    73.     i2371
    74.     i2372
    75.     i2383
  5.   Trademarks
  6.   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 3-1 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.

GUID-D55FF7CD-AC3B-4E2D-8E59-F0A0210702B6-low.png Figure 3-1 Interrupt Aggregator Version 1.0

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