PMEVTYPER<n>_EL0, Performance Monitors Event Type Registers, n = 0 - 30

The PMEVTYPER<n>_EL0 characteristics are:

Purpose

Configures event counter n, where n is 0 to 30.

Configuration

AArch64 System register PMEVTYPER<n>_EL0 bits [31:0] are architecturally mapped to AArch32 System register PMEVTYPER<n>[31:0].

AArch64 System register PMEVTYPER<n>_EL0 bits [63:0] are architecturally mapped to External register PMEVTYPER<n>_EL0[63:0].

This register is present only when FEAT_PMUv3 is implemented. Otherwise, direct accesses to PMEVTYPER<n>_EL0 are UNDEFINED.

Attributes

PMEVTYPER<n>_EL0 is a 64-bit register.

Field descriptions

6362616059585756555453525150494847464544434241403938373635343332
313029282726252423222120191817161514131211109876543210
TCRES0TH
PUNSKNSUNSHMMTSHTRLKRLURLHRES0evtCount[15:10]evtCount[9:0]

TC, bits [63:61]
When FEAT_PMUv3_TH is implemented:

Threshold Control. Defines the threshold function. In the description of this field, the value V is the value the event specified by PMEVTYPER<n>_EL0 would increment the counter by on a processor cycle if the threshold function is disabled. Comparisons treat V and PMEVTYPER<n>_EL0.TH as unsigned integer values.

TCMeaning
0b000

Not-equal. The counter increments by V on each processor cycle when V is not equal to PMEVTYPER<n>_EL0.TH. If PMEVTYPER<n>_EL0.TH is zero, the threshold function is disabled.

0b001

Not-equal, count. The counter increments by 1 on each processor cycle when V is not equal to PMEVTYPER<n>_EL0.TH.

0b010

Equals. The counter increments by V on each processor cycle when V is equal to PMEVTYPER<n>_EL0.TH.

0b011

Equals, count. The counter increments by 1 on each processor cycle when V is equal to PMEVTYPER<n>_EL0.TH.

0b100

Greater-than-or-equal. The counter increments by V on each processor cycle when V is PMEVTYPER<n>_EL0.TH or more.

0b101

Greater-than-or-equal, count. The counter increments by 1 on each processor cycle when V is PMEVTYPER<n>_EL0.TH or more.

0b110

Less-than. The counter increments by V on each processor cycle when V is less than PMEVTYPER<n>_EL0.TH.

0b111

Less-than, count. The counter increments by 1 on each processor cycle when V is less than PMEVTYPER<n>_EL0.TH.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

Bits [60:44]

Reserved, RES0.

TH, bits [43:32]
When FEAT_PMUv3_TH is implemented:

Threshold value. Provides the unsigned value for the threshold function defined by PMEVTYPER<n>_EL0.TC.

If PMEVTYPER<n>_EL0.TC is 0b000 and PMEVTYPER<n>_EL0.TH is zero, then the threshold function is disabled.

If PMMIR_EL1.THWIDTH is less than 12, then bits PMEVTYPER<n>_EL0.TH[11:PMMIR_EL1.THWIDTH] are RES0. This accounts for the behavior when writing a value greater-than-or-equal-to 2(PMMIR_EL1.THWIDTH).

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

P, bit [31]

Privileged filtering bit. Controls counting in EL1.

If EL3 is implemented, then counting in Non-secure EL1 is further controlled by the PMEVTYPER<n>_EL0.NSK bit.

If FEAT_RME is implemented, then counting in Realm EL1 is further controlled by the PMEVTYPER<n>_EL0.RLK bit.

PMeaning
0b0

Count events in EL1.

0b1

Do not count events in EL1.

The reset behavior of this field is:

U, bit [30]

User filtering bit. Controls counting in EL0.

If EL3 is implemented, then counting in Non-secure EL0 is further controlled by the PMEVTYPER<n>_EL0.NSU bit.

If FEAT_RME is implemented, then counting in Realm EL0 is further controlled by the PMEVTYPER<n>_EL0.RLU bit.

UMeaning
0b0

Count events in EL0.

0b1

Do not count events in EL0.

The reset behavior of this field is:

NSK, bit [29]
When EL3 is implemented:

Non-secure EL1 (kernel) modes filtering bit. Controls counting in Non-secure EL1.

If the value of this bit is equal to the value of the PMEVTYPER<n>_EL0.P bit, events in Non-secure EL1 are counted.

Otherwise, events in Non-secure EL1 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

NSU, bit [28]
When EL3 is implemented:

Non-secure EL0 (Unprivileged) filtering bit. Controls counting in Non-secure EL0.

If the value of this bit is equal to the value of the PMEVTYPER<n>_EL0.U bit, events in Non-secure EL0 are counted.

Otherwise, events in Non-secure EL0 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

NSH, bit [27]
When EL2 is implemented:

EL2 (Hypervisor) filtering bit. Controls counting in EL2.

If Secure EL2 is implemented, and EL3 is implemented, counting in Secure EL2 is further controlled by the PMEVTYPER<n>_EL0.SH bit.

If FEAT_RME is implemented, then counting in Realm EL2 is further controlled by the PMEVTYPER<n>_EL0.RLH bit.

NSHMeaning
0b0

Do not count events in EL2.

0b1

Count events in EL2.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

M, bit [26]
When EL3 is implemented:

EL3 filtering bit.

If the value of this bit is equal to the value of the PMEVTYPER<n>_EL0.P bit, events in EL3 are counted.

Otherwise, events in EL3 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

MT, bit [25]
When FEAT_MTPMU is implemented or an IMPLEMENTATION DEFINED multi-threaded PMU extension is implemented:

Multithreading.

MTMeaning
0b0

Count events only on controlling PE.

0b1

Count events from any PE with the same affinity at level 1 and above as this PE.

From Armv8.6, the IMPLEMENTATION DEFINED multi-threaded PMU extension is not permitted, meaning if FEAT_MTPMU is not implemented, this field is RES0. See ID_AA64DFR0_EL1.MTPMU.

This field is ignored by the PE and treated as zero when FEAT_MTPMU is implemented and Disabled.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

SH, bit [24]
When FEAT_SEL2 is implemented and EL3 is implemented:

Secure EL2 filtering.

If the value of this bit is not equal to the value of the PMEVTYPER<n>_EL0.NSH bit, events in Secure EL2 are counted.

Otherwise, events in Secure EL2 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

T, bit [23]
When FEAT_TME is implemented:

Transactional state filtering bit. Controls counting in Transactional state.

TMeaning
0b0

This bit has no effect on the filtering of events.

0b1

Do not count events in Transactional state.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

RLK, bit [22]
When FEAT_RME is implemented:

Realm EL1 (kernel) filtering bit. Controls counting in Realm EL1.

If the value of this bit is equal to the value of the PMEVTYPER<n>_EL0.P bit, events in Realm EL1 are counted.

Otherwise, events in Realm EL1 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

RLU, bit [21]
When FEAT_RME is implemented:

Realm EL0 (unprivileged) filtering bit. Controls counting in Realm EL0.

If the value of this bit is equal to the value of the PMEVTYPER<n>_EL0.U bit, events in Realm EL0 are counted.

Otherwise, events in Realm EL0 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

RLH, bit [20]
When FEAT_RME is implemented:

Realm EL2 filtering bit. Controls counting in Realm EL2.

If the value of this bit is not equal to the value of the PMEVTYPER<n>_EL0.NSH bit, events in Realm EL2 are counted.

Otherwise, events in Realm EL2 are not counted.

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

Bits [19:16]

Reserved, RES0.

evtCount[15:10], bits [15:10]
When FEAT_PMUv3p1 is implemented:

Extension to evtCount[9:0]. For more information, see evtCount[9:0].

The reset behavior of this field is:


Otherwise:

Reserved, RES0.

evtCount[9:0], bits [9:0]

Event to count.

The event number of the event that is counted by event counter PMEVCNTR<n>_EL0.

The ranges of event numbers allocated to each type of event are shown in 'Allocation of the PMU event number space'.

If FEAT_PMUv3p8 is implemented and PMEVTYPER<n>_EL0.evtCount is programmed to an event that is reserved or not supported by the PE, no events are counted and the value returned by a direct or external read of the PMEVTYPER<n>_EL0.evtCount field is the value written to the field.

Note

Arm recommends this behavior for all implementations of FEAT_PMUv3.

Otherwise, if PMEVTYPER<n>_EL0.evtCount is programmed to an event that is reserved or not supported by the PE, the behavior depends on the value written:

Note

UNPREDICTABLE means the event must not expose privileged information.

The reset behavior of this field is:

Accessing PMEVTYPER<n>_EL0

PMEVTYPER<n>_EL0 can also be accessed by using PMXEVTYPER_EL0 with PMSELR_EL0.SEL set to n.

If FEAT_FGT is implemented and <n> is greater than or equal to the number of accessible event counters, then the behavior of permitted reads and writes of PMEVTYPER<n>_EL0 is as follows:

If FEAT_FGT is not implemented and <n> is greater than or equal to the number of accessible event counters, then reads and writes of PMEVTYPER<n>_EL0 are CONSTRAINED UNPREDICTABLE, and the following behaviors are permitted:

Note

In EL0, an access is permitted if it is enabled by PMUSERENR_EL0.EN.

If EL2 is implemented and enabled in the current Security state, in EL1 and EL0, MDCR_EL2.HPMN identifies the number of accessible event counters. Otherwise, the number of accessible event counters is the number of implemented event counters. For more information, see MDCR_EL2.HPMN.

Accesses to this register use the following encodings in the System register encoding space:

MRS <Xt>, PMEVTYPER<m>_EL0 ; Where m = 0-30

op0op1CRnCRmop2
0b110b0110b11100b11:m[4:3]m[2:0]

integer m = UInt(CRm<1:0>:op2<2:0>); if m >= NUM_PMU_COUNTERS then if IsFeatureImplemented(FEAT_FGT) then UNDEFINED; else ConstrainUnpredictableProcedure(Unpredictable_PMUEVENTCOUNTER); elsif PSTATE.EL == EL0 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif PMUSERENR_EL0.EN == '0' then if EL2Enabled() && HCR_EL2.TGE == '1' then AArch64.SystemAccessTrap(EL2, 0x18); else AArch64.SystemAccessTrap(EL1, 0x18); elsif EL2Enabled() && HCR_EL2.<E2H,TGE> != '11' && (!HaveEL(EL3) || SCR_EL3.FGTEn == '1') && HDFGRTR_EL2.PMEVTYPERn_EL0 == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && MDCR_EL2.TPM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && m >= AArch64.GetNumEventCountersAccessible() then AArch64.SystemAccessTrap(EL2, 0x18); elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else X[t, 64] = PMEVTYPER_EL0[m]; elsif PSTATE.EL == EL1 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif EL2Enabled() && (!HaveEL(EL3) || SCR_EL3.FGTEn == '1') && HDFGRTR_EL2.PMEVTYPERn_EL0 == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && MDCR_EL2.TPM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && m >= AArch64.GetNumEventCountersAccessible() then AArch64.SystemAccessTrap(EL2, 0x18); elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else X[t, 64] = PMEVTYPER_EL0[m]; elsif PSTATE.EL == EL2 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else X[t, 64] = PMEVTYPER_EL0[m]; elsif PSTATE.EL == EL3 then X[t, 64] = PMEVTYPER_EL0[m];

MSR PMEVTYPER<m>_EL0, <Xt> ; Where m = 0-30

op0op1CRnCRmop2
0b110b0110b11100b11:m[4:3]m[2:0]

integer m = UInt(CRm<1:0>:op2<2:0>); if m >= NUM_PMU_COUNTERS then if IsFeatureImplemented(FEAT_FGT) then UNDEFINED; else ConstrainUnpredictableProcedure(Unpredictable_PMUEVENTCOUNTER); elsif PSTATE.EL == EL0 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif PMUSERENR_EL0.EN == '0' then if EL2Enabled() && HCR_EL2.TGE == '1' then AArch64.SystemAccessTrap(EL2, 0x18); else AArch64.SystemAccessTrap(EL1, 0x18); elsif EL2Enabled() && HCR_EL2.<E2H,TGE> != '11' && (!HaveEL(EL3) || SCR_EL3.FGTEn == '1') && HDFGWTR_EL2.PMEVTYPERn_EL0 == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && MDCR_EL2.TPM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && m >= AArch64.GetNumEventCountersAccessible() then AArch64.SystemAccessTrap(EL2, 0x18); elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else PMEVTYPER_EL0[m] = X[t, 64]; elsif PSTATE.EL == EL1 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif EL2Enabled() && (!HaveEL(EL3) || SCR_EL3.FGTEn == '1') && HDFGWTR_EL2.PMEVTYPERn_EL0 == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && MDCR_EL2.TPM == '1' then AArch64.SystemAccessTrap(EL2, 0x18); elsif EL2Enabled() && m >= AArch64.GetNumEventCountersAccessible() then AArch64.SystemAccessTrap(EL2, 0x18); elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else PMEVTYPER_EL0[m] = X[t, 64]; elsif PSTATE.EL == EL2 then if Halted() && HaveEL(EL3) && EDSCR.SDD == '1' && boolean IMPLEMENTATION_DEFINED "EL3 trap priority when SDD == '1'" && MDCR_EL3.TPM == '1' then UNDEFINED; elsif HaveEL(EL3) && MDCR_EL3.TPM == '1' then if Halted() && EDSCR.SDD == '1' then UNDEFINED; else AArch64.SystemAccessTrap(EL3, 0x18); else PMEVTYPER_EL0[m] = X[t, 64]; elsif PSTATE.EL == EL3 then PMEVTYPER_EL0[m] = X[t, 64];


05/07/2022 17:08; b0421fa9a8865165f9b91af9b4a566111f866305

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