pmc(3): Correct some typos in event descriptions

- s/occured/occurred/
- s/the the/the/

MFC after:	3 days
This commit is contained in:
Gordon Bergling 2022-09-04 12:52:38 +02:00
parent b197d4b893
commit f0d4c2afd6
6 changed files with 10 additions and 10 deletions

View File

@ -624,7 +624,7 @@
"CounterHTOff": "0,1,2,3,4,5,6,7",
"EventCode": "0x87",
"EventName": "ILD_STALL.LCP",
"PublicDescription": "This event counts stalls occured due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"PublicDescription": "This event counts stalls occurred due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"SampleAfterValue": "2000003",
"UMask": "0x1"
},
@ -1377,4 +1377,4 @@
"SampleAfterValue": "2000003",
"UMask": "0x1"
}
]
]

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@ -624,7 +624,7 @@
"CounterHTOff": "0,1,2,3,4,5,6,7",
"EventCode": "0x87",
"EventName": "ILD_STALL.LCP",
"PublicDescription": "This event counts stalls occured due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"PublicDescription": "This event counts stalls occurred due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"SampleAfterValue": "2000003",
"UMask": "0x1"
},
@ -1378,4 +1378,4 @@
"SampleAfterValue": "2000003",
"UMask": "0x1"
}
]
]

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@ -624,7 +624,7 @@
"CounterHTOff": "0,1,2,3,4,5,6,7",
"EventCode": "0x87",
"EventName": "ILD_STALL.LCP",
"PublicDescription": "This event counts stalls occured due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"PublicDescription": "This event counts stalls occurred due to changing prefix length (66, 67 or REX.W when they change the length of the decoded instruction). Occurrences counting is proportional to the number of prefixes in a 16B-line. This may result in the following penalties: three-cycle penalty for each LCP in a 16-byte chunk.",
"SampleAfterValue": "2000003",
"UMask": "0x1"
},
@ -1377,4 +1377,4 @@
"SampleAfterValue": "2000003",
"UMask": "0x1"
}
]
]

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@ -1923,7 +1923,7 @@
"EventCode": "0x25",
"EventName": "UNC_UPI_RxL0P_POWER_CYCLES",
"PerPkg": "1",
"PublicDescription": "Counts cycles when the the receive side (Rx) of the Intel Ultra Path Interconnect(UPI) is in L0p power mode. L0p is a mode where we disable 60% of the UPI lanes, decreasing our bandwidth in order to save power.",
"PublicDescription": "Counts cycles when the receive side (Rx) of the Intel Ultra Path Interconnect(UPI) is in L0p power mode. L0p is a mode where we disable 60% of the UPI lanes, decreasing our bandwidth in order to save power.",
"Unit": "UPI LL"
},
{

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@ -257,7 +257,7 @@
"Counter": "0,1",
"EventCode": "0xCA",
"EventName": "NO_ALLOC_CYCLES.NOT_DELIVERED",
"PublicDescription": "The NO_ALLOC_CYCLES.NOT_DELIVERED event is used to measure front-end inefficiencies, i.e. when front-end of the machine is not delivering micro-ops to the back-end and the back-end is not stalled. This event can be used to identify if the machine is truly front-end bound. When this event occurs, it is an indication that the front-end of the machine is operating at less than its theoretical peak performance. Background: We can think of the processor pipeline as being divided into 2 broader parts: Front-end and Back-end. Front-end is responsible for fetching the instruction, decoding into micro-ops (uops) in machine understandable format and putting them into a micro-op queue to be consumed by back end. The back-end then takes these micro-ops, allocates the required resources. When all resources are ready, micro-ops are executed. If the back-end is not ready to accept micro-ops from the front-end, then we do not want to count these as front-end bottlenecks. However, whenever we have bottlenecks in the back-end, we will have allocation unit stalls and eventually forcing the front-end to wait until the back-end is ready to receive more UOPS. This event counts the cycles only when back-end is requesting more uops and front-end is not able to provide them. Some examples of conditions that cause front-end efficiencies are: Icache misses, ITLB misses, and decoder restrictions that limit the the front-end bandwidth.",
"PublicDescription": "The NO_ALLOC_CYCLES.NOT_DELIVERED event is used to measure front-end inefficiencies, i.e. when front-end of the machine is not delivering micro-ops to the back-end and the back-end is not stalled. This event can be used to identify if the machine is truly front-end bound. When this event occurs, it is an indication that the front-end of the machine is operating at less than its theoretical peak performance. Background: We can think of the processor pipeline as being divided into 2 broader parts: Front-end and Back-end. Front-end is responsible for fetching the instruction, decoding into micro-ops (uops) in machine understandable format and putting them into a micro-op queue to be consumed by back end. The back-end then takes these micro-ops, allocates the required resources. When all resources are ready, micro-ops are executed. If the back-end is not ready to accept micro-ops from the front-end, then we do not want to count these as front-end bottlenecks. However, whenever we have bottlenecks in the back-end, we will have allocation unit stalls and eventually forcing the front-end to wait until the back-end is ready to receive more UOPS. This event counts the cycles only when back-end is requesting more uops and front-end is not able to provide them. Some examples of conditions that cause front-end efficiencies are: Icache misses, ITLB misses, and decoder restrictions that limit the front-end bandwidth.",
"SampleAfterValue": "200003",
"UMask": "0x50"
},
@ -313,4 +313,4 @@
"SampleAfterValue": "2000003",
"UMask": "0x1"
}
]
]

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@ -1852,7 +1852,7 @@
"EventCode": "0x25",
"EventName": "UNC_UPI_RxL0P_POWER_CYCLES",
"PerPkg": "1",
"PublicDescription": "Counts cycles when the the receive side (Rx) of the Intel Ultra Path Interconnect(UPI) is in L0p power mode. L0p is a mode where we disable 60% of the UPI lanes, decreasing our bandwidth in order to save power.",
"PublicDescription": "Counts cycles when the receive side (Rx) of the Intel Ultra Path Interconnect(UPI) is in L0p power mode. L0p is a mode where we disable 60% of the UPI lanes, decreasing our bandwidth in order to save power.",
"Unit": "UPI LL"
},
{