Event Name | Description | Additional Info |
---|---|---|
CORE | ||
INST_RETIRED.ANY | Counts the number of instructions retired - an Architectural PerfMon event. Counting continues during hardware interrupts, traps, and inside interrupt handlers. Notes: INST_RETIRED.ANY is counted by a designated fixed counter freeing up programmable counters to count other events. INST_RETIRED.ANY_P is counted by a programmable counter. | IA32_FIXED_CTR0 PEBS:[PreciseEventingIP] Architectural, Fixed, AtRetirement |
CPU_CLK_UNHALTED.THREAD | Counts the number of core cycles while the thread is not in a halt state. The thread enters the halt state when it is running the HLT instruction. This event is a component in many key event ratios. The core frequency may change from time to time due to transitions associated with Enhanced Intel SpeedStep Technology or TM2. For this reason this event may have a changing ratio with regards to time. When the core frequency is constant, this event can approximate elapsed time while the core was not in the halt state. It is counted on a dedicated fixed counter, leaving the eight programmable counters available for other events. | IA32_FIXED_CTR1 PEBS:[NonPreciseEventingIP] Architectural, Fixed, Speculative |
CPU_CLK_UNHALTED.REF_TSC | Counts the number of reference cycles when the core is not in a halt state. The core enters the halt state when it is running the HLT instruction or the MWAIT instruction. This event is not affected by core frequency changes (for example, P states, TM2 transitions) but has the same incrementing frequency as the time stamp counter. This event can approximate elapsed time while the core was not in a halt state. This event has a constant ratio with the CPU_CLK_UNHALTED.REF_XCLK event. It is counted on a dedicated fixed counter, leaving the eight programmable counters available for other events. Note: On all current platforms this event stops counting during 'throttling (TM)' states duty off periods the processor is 'halted'. The counter update is done at a lower clock rate then the core clock the overflow status bit for this counter may appear 'sticky'. After the counter has overflowed and software clears the overflow status bit and resets the counter to less than MAX. The reset value to the counter is not clocked immediately so the overflow status bit will flip 'high (1)' and generate another PMI (if enabled) after which the reset value gets clocked into the counter. Therefore, software will get the interrupt, read the overflow status bit '1 for bit 34 while the counter value is less than MAX. Software should ignore this case. | IA32_FIXED_CTR2 PEBS:[NonPreciseEventingIP] Architectural, Fixed, Speculative |
TOPDOWN.SLOTS | Number of available slots for an unhalted logical processor. The event increments by machine-width of the narrowest pipeline as employed by the Top-down Microarchitecture Analysis method (TMA). The count is distributed among unhalted logical processors (hyper-threads) who share the same physical core. Software can use this event as the denominator for the top-level metrics of the TMA method. This architectural event is counted on a designated fixed counter (Fixed Counter 3). | IA32_FIXED_CTR3 PEBS:[NonPreciseEventingIP] Architectural, Fixed, Speculative |
BR_INST_RETIRED.ALL_BRANCHES | Counts all branch instructions retired. | EventSel=C4H UMask=00H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, AtRetirement |
BR_MISP_RETIRED.ALL_BRANCHES | Counts all the retired branch instructions that were mispredicted by the processor. A branch misprediction occurs when the processor incorrectly predicts the destination of the branch. When the misprediction is discovered at execution, all the instructions executed in the wrong (speculative) path must be discarded, and the processor must start fetching from the correct path. | EventSel=C5H UMask=00H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, AtRetirement |
CPU_CLK_UNHALTED.REF_XCLK | Counts core crystal clock cycles when the thread is unhalted. | EventSel=3CH UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, Speculative |
CPU_CLK_UNHALTED.THREAD_P | This is an architectural event that counts the number of thread cycles while the thread is not in a halt state. The thread enters the halt state when it is running the HLT instruction. The core frequency may change from time to time due to power or thermal throttling. For this reason, this event may have a changing ratio with regards to wall clock time. | EventSel=3CH UMask=00H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, Speculative |
INST_RETIRED.ANY_P | Counts the number of instructions retired - an Architectural PerfMon event. Counting continues during hardware interrupts, traps, and inside interrupt handlers. Notes: INST_RETIRED.ANY is counted by a designated fixed counter freeing up programmable counters to count other events. INST_RETIRED.ANY_P is counted by a programmable counter. | EventSel=C0H UMask=00H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, AtRetirement |
LONGEST_LAT_CACHE.MISS | Counts core-originated cacheable requests that miss the L3 cache (Longest Latency cache). Requests include data and code reads, Reads-for-Ownership (RFOs), speculative accesses and hardware prefetches to the L1 and L2. It does not include hardware prefetches to the L3, and may not count other types of requests to the L3. | EventSel=2EH UMask=41H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, Speculative |
TOPDOWN.SLOTS_P | Counts the number of available slots for an unhalted logical processor. The event increments by machine-width of the narrowest pipeline as employed by the Top-down Microarchitecture Analysis method. The count is distributed among unhalted logical processors (hyper-threads) who share the same physical core. | EventSel=A4H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Architectural, Speculative |
ARITH.DIVIDER_ACTIVE | Counts cycles when divide unit is busy executing divide or square root operations. Accounts for integer and floating-point operations. | EventSel=14H UMask=09H CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
ASSISTS.ANY | Counts the number of occurrences where a microcode assist is invoked by hardware Examples include AD (page Access Dirty), FP and AVX related assists. | EventSel=C1H UMask=07H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
ASSISTS.FP | Counts all microcode Floating Point assists. | EventSel=C1H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
BACLEARS.ANY | Counts the number of times the front-end is resteered when it finds a branch instruction in a fetch line. This occurs for the first time a branch instruction is fetched or when the branch is not tracked by the BPU (Branch Prediction Unit) anymore. | EventSel=E6H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
BR_INST_RETIRED.COND | Counts conditional branch instructions retired. | EventSel=C4H UMask=11H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.COND_NTAKEN | Counts not taken branch instructions retired. | EventSel=C4H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.COND_TAKEN | Counts taken conditional branch instructions retired. | EventSel=C4H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.FAR_BRANCH | Counts far branch instructions retired. | EventSel=C4H UMask=40H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.INDIRECT | Counts near indirect branch instructions retired excluding returns. TSX abort is an indirect branch. | EventSel=C4H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.NEAR_CALL | Counts both direct and indirect near call instructions retired. | EventSel=C4H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.NEAR_RETURN | Counts return instructions retired. | EventSel=C4H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_INST_RETIRED.NEAR_TAKEN | Counts taken branch instructions retired. | EventSel=C4H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.COND | Counts mispredicted conditional branch instructions retired. | EventSel=C5H UMask=11H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.COND_NTAKEN | Counts the number of conditional branch instructions retired that were mispredicted and the branch direction was not taken. | EventSel=C5H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.COND_TAKEN | Counts taken conditional mispredicted branch instructions retired. | EventSel=C5H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.INDIRECT | Counts all miss-predicted indirect branch instructions retired (excluding RETs. TSX aborts is considered indirect branch). | EventSel=C5H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.INDIRECT_CALL | Counts retired mispredicted indirect (near taken) CALL instructions, including both register and memory indirect. | EventSel=C5H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.NEAR_TAKEN | Counts number of near branch instructions retired that were mispredicted and taken. | EventSel=C5H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
BR_MISP_RETIRED.RET | This is a non-precise version (that is, does not use PEBS) of the event that counts mispredicted return instructions retired. | EventSel=C5H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
CORE_POWER.LVL0_TURBO_LICENSE | Counts Core cycles where the core was running with power-delivery for baseline license level 0. This includes non-AVX codes, SSE, AVX 128-bit, and low-current AVX 256-bit codes. | EventSel=28H UMask=07H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CORE_POWER.LVL1_TURBO_LICENSE | Counts Core cycles where the core was running with power-delivery for license level 1. This includes high current AVX 256-bit instructions as well as low current AVX 512-bit instructions. | EventSel=28H UMask=18H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CORE_POWER.LVL2_TURBO_LICENSE | Core cycles where the core was running with power-delivery for license level 2 (introduced in Skylake Server microarchitecture). This includes high current AVX 512-bit instructions. | EventSel=28H UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CPU_CLK_UNHALTED.DISTRIBUTED | This event distributes cycle counts between active hyperthreads, i.e., those in C0. A hyperthread becomes inactive when it executes the HLT or MWAIT instructions. If all other hyperthreads are inactive (or disabled or do not exist), all counts are attributed to this hyperthread. To obtain the full count when the Core is active, sum the counts from each hyperthread. | EventSel=ECH UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
CPU_CLK_UNHALTED.ONE_THREAD_ACTIVE | Counts Core crystal clock cycles when current thread is unhalted and the other thread is halted. | EventSel=3CH UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
CPU_CLK_UNHALTED.REF_DISTRIBUTED | This event distributes Core crystal clock cycle counts between active hyperthreads, i.e., those in C0 sleep-state. A hyperthread becomes inactive when it executes the HLT or MWAIT instructions. If one thread is active in a core, all counts are attributed to this hyperthread. To obtain the full count when the Core is active, sum the counts from each hyperthread. | EventSel=3CH UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
CYCLE_ACTIVITY.CYCLES_L1D_MISS | Cycles while L1 cache miss demand load is outstanding. | EventSel=A3H UMask=08H CMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.CYCLES_L2_MISS | Cycles while L2 cache miss demand load is outstanding. | EventSel=A3H UMask=01H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.CYCLES_L3_MISS | Cycles while L3 cache miss demand load is outstanding. | EventSel=A3H UMask=02H CMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.CYCLES_MEM_ANY | Cycles while memory subsystem has an outstanding load. | EventSel=A3H UMask=10H CMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
CYCLE_ACTIVITY.STALLS_L1D_MISS | Execution stalls while L1 cache miss demand load is outstanding. | EventSel=A3H UMask=0CH CMask=0CH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.STALLS_L2_MISS | Execution stalls while L2 cache miss demand load is outstanding. | EventSel=A3H UMask=05H CMask=05H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.STALLS_L3_MISS | Execution stalls while L3 cache miss demand load is outstanding. | EventSel=A3H UMask=06H CMask=06H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
CYCLE_ACTIVITY.STALLS_MEM_ANY | Execution stalls while memory subsystem has an outstanding load. | EventSel=A3H UMask=14H CMask=14H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
CYCLE_ACTIVITY.STALLS_TOTAL | Total execution stalls. | EventSel=A3H UMask=04H CMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
DSB2MITE_SWITCHES.COUNT | Counts the number of Decode Stream Buffer (DSB a.k.a. Uop Cache)-to-MITE speculative transitions. | EventSel=ABH UMask=02H EdgeDetect=1 CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DSB2MITE_SWITCHES.PENALTY_CYCLES | Decode Stream Buffer (DSB) is a Uop-cache that holds translations of previously fetched instructions that were decoded by the legacy x86 decode pipeline (MITE). This event counts fetch penalty cycles when a transition occurs from DSB to MITE. | EventSel=ABH UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.STLB_HIT | Counts loads that miss the DTLB (Data TLB) and hit the STLB (Second level TLB). | EventSel=08H UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.WALK_ACTIVE | Counts cycles when at least one PMH (Page Miss Handler) is busy with a page walk for a demand load. | EventSel=08H UMask=10H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.WALK_COMPLETED | Counts completed page walks (all page sizes) caused by demand data loads. This implies it missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=08H UMask=0EH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.WALK_COMPLETED_2M_4M | Counts completed page walks (2M/4M sizes) caused by demand data loads. This implies address translations missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=08H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.WALK_COMPLETED_4K | Counts completed page walks (4K sizes) caused by demand data loads. This implies address translations missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=08H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_LOAD_MISSES.WALK_PENDING | Counts the number of page walks outstanding for a demand load in the PMH (Page Miss Handler) each cycle. | EventSel=08H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.STLB_HIT | Counts stores that miss the DTLB (Data TLB) and hit the STLB (2nd Level TLB). | EventSel=49H UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.WALK_ACTIVE | Counts cycles when at least one PMH (Page Miss Handler) is busy with a page walk for a store. | EventSel=49H UMask=10H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.WALK_COMPLETED | Counts completed page walks (all page sizes) caused by demand data stores. This implies it missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=49H UMask=0EH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.WALK_COMPLETED_2M_4M | Counts completed page walks (2M/4M sizes) caused by demand data stores. This implies address translations missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=49H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.WALK_COMPLETED_4K | Counts completed page walks (4K sizes) caused by demand data stores. This implies address translations missed in the DTLB and further levels of TLB. The page walk can end with or without a fault. | EventSel=49H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
DTLB_STORE_MISSES.WALK_PENDING | Counts the number of page walks outstanding for a store in the PMH (Page Miss Handler) each cycle. | EventSel=49H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
EXE_ACTIVITY.1_PORTS_UTIL | Counts cycles during which a total of 1 uop was executed on all ports and Reservation Station (RS) was not empty. | EventSel=A6H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
EXE_ACTIVITY.2_PORTS_UTIL | Counts cycles during which a total of 2 uops were executed on all ports and Reservation Station (RS) was not empty. | EventSel=A6H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
EXE_ACTIVITY.3_PORTS_UTIL | Cycles total of 3 uops are executed on all ports and Reservation Station (RS) was not empty. | EventSel=A6H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
EXE_ACTIVITY.4_PORTS_UTIL | Cycles total of 4 uops are executed on all ports and Reservation Station (RS) was not empty. | EventSel=A6H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
EXE_ACTIVITY.BOUND_ON_STORES | Counts cycles where the Store Buffer was full and no loads caused an execution stall. | EventSel=A6H UMask=40H CMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
FP_ARITH_INST_RETIRED.128B_PACKED_DOUBLE | Number of SSE/AVX computational 128-bit packed double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 2 computation operations, one for each element. Applies to SSE* and AVX* packed double precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX SQRT DPP FM(N)ADD/SUB. DPP and FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.128B_PACKED_SINGLE | Number of SSE/AVX computational 128-bit packed single precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 4 computation operations, one for each element. Applies to SSE* and AVX* packed single precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX SQRT RSQRT RCP DPP FM(N)ADD/SUB. DPP and FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.256B_PACKED_DOUBLE | Number of SSE/AVX computational 256-bit packed double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 4 computation operations, one for each element. Applies to SSE* and AVX* packed double precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX SQRT FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.256B_PACKED_SINGLE | Number of SSE/AVX computational 256-bit packed single precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 8 computation operations, one for each element. Applies to SSE* and AVX* packed single precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX SQRT RSQRT RCP DPP FM(N)ADD/SUB. DPP and FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.4_FLOPS | Number of SSE/AVX computational 128-bit packed single precision and 256-bit packed double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 2 or/and 4 computation operations, one for each element. Applies to SSE* and AVX* packed single precision floating-point and packed double precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX RCP14 RSQRT14 SQRT DPP FM(N)ADD/SUB. DPP and FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=18H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.512B_PACKED_DOUBLE | Number of SSE/AVX computational 512-bit packed double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 8 computation operations, one for each element. Applies to SSE* and AVX* packed double precision floating-point instructions: ADD SUB MUL DIV MIN MAX SQRT RSQRT14 RCP14 FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=40H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.512B_PACKED_SINGLE | Number of SSE/AVX computational 512-bit packed single precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 16 computation operations, one for each element. Applies to SSE* and AVX* packed single precision floating-point instructions: ADD SUB MUL DIV MIN MAX SQRT RSQRT14 RCP14 FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.8_FLOPS | Number of SSE/AVX computational 256-bit packed single precision and 512-bit packed double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 8 computation operations, one for each element. Applies to SSE* and AVX* packed single precision and double precision floating-point instructions: ADD SUB HADD HSUB SUBADD MUL DIV MIN MAX SQRT RSQRT RSQRT14 RCP RCP14 DPP FM(N)ADD/SUB. DPP and FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=60H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.SCALAR | Number of SSE/AVX computational scalar single precision and double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 1 computational operation. Applies to SSE* and AVX* scalar single precision floating-point instructions: ADD SUB MUL DIV MIN MAX SQRT RSQRT RCP FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=03H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.SCALAR_DOUBLE | Number of SSE/AVX computational scalar double precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 1 computational operation. Applies to SSE* and AVX* scalar double precision floating-point instructions: ADD SUB MUL DIV MIN MAX SQRT FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.SCALAR_SINGLE | Number of SSE/AVX computational scalar single precision floating-point instructions retired; some instructions will count twice as noted below. Each count represents 1 computational operation. Applies to SSE* and AVX* scalar single precision floating-point instructions: ADD SUB MUL DIV MIN MAX SQRT RSQRT RCP FM(N)ADD/SUB. FM(N)ADD/SUB instructions count twice as they perform 2 calculations per element. The DAZ and FTZ flags in the MXCSR register need to be set when using these events. | EventSel=C7H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FP_ARITH_INST_RETIRED.VECTOR | Number of any Vector retired FP arithmetic instructions | EventSel=C7H UMask=FCH Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.ANY_DSB_MISS | Counts retired Instructions that experienced DSB (Decode stream buffer i.e. the decoded instruction-cache) miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=01H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.DSB_MISS | Number of retired Instructions that experienced a critical DSB (Decode stream buffer i.e. the decoded instruction-cache) miss. Critical means stalls were exposed to the back-end as a result of the DSB miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=11H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.ITLB_MISS | Counts retired Instructions that experienced iTLB (Instruction TLB) true miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=14H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.L1I_MISS | Counts retired Instructions who experienced Instruction L1 Cache true miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=12H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.L2_MISS | Counts retired Instructions who experienced Instruction L2 Cache true miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=13H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_1 | Retired instructions that are fetched after an interval where the front-end delivered no uops for a period of at least 1 cycle which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=500106H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_128 | Counts retired instructions that are fetched after an interval where the front-end delivered no uops for a period of 128 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=508006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_16 | Counts retired instructions that are delivered to the back-end after a front-end stall of at least 16 cycles. During this period the front-end delivered no uops. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=501006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_2 | Retired instructions that are fetched after an interval where the front-end delivered no uops for a period of at least 2 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=500206H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_2_BUBBLES_GE_1 | Counts retired instructions that are delivered to the back-end after the front-end had at least 1 bubble-slot for a period of 2 cycles. A bubble-slot is an empty issue-pipeline slot while there was no RAT stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=100206H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_256 | Counts retired instructions that are fetched after an interval where the front-end delivered no uops for a period of 256 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=510006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_32 | Counts retired instructions that are delivered to the back-end after a front-end stall of at least 32 cycles. During this period the front-end delivered no uops. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=502006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_4 | Counts retired instructions that are fetched after an interval where the front-end delivered no uops for a period of 4 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=500406H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_512 | Counts retired instructions that are fetched after an interval where the front-end delivered no uops for a period of 512 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=520006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_64 | Counts retired instructions that are fetched after an interval where the front-end delivered no uops for a period of 64 cycles which was not interrupted by a back-end stall. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=504006H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.LATENCY_GE_8 | Counts retired instructions that are delivered to the back-end after a front-end stall of at least 8 cycles. During this period the front-end delivered no uops. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=500806H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
FRONTEND_RETIRED.STLB_MISS | Counts retired Instructions that experienced STLB (2nd level TLB) true miss. | EventSel=C6H UMask=01H MSR_PEBS_FRONTEND(3F7H)=15H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.ABORTED | Counts the number of times HLE abort was triggered. | EventSel=C8H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.ABORTED_EVENTS | Counts the number of times an HLE execution aborted due to unfriendly events (such as interrupts). | EventSel=C8H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.ABORTED_MEM | Counts the number of times an HLE execution aborted due to various memory events (e.g., read/write capacity and conflicts). | EventSel=C8H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.ABORTED_UNFRIENDLY | Counts the number of times an HLE execution aborted due to HLE-unfriendly instructions and certain unfriendly events (such as AD assists etc.). | EventSel=C8H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.COMMIT | Counts the number of times HLE commit succeeded. | EventSel=C8H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
HLE_RETIRED.START | Counts the number of times we entered an HLE region. Does not count nested transactions. | EventSel=C8H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
ICACHE_16B.IFDATA_STALL | Counts cycles where a code line fetch is stalled due to an L1 instruction cache miss. The legacy decode pipeline works at a 16 Byte granularity. | EventSel=80H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ICACHE_64B.IFTAG_HIT | Counts instruction fetch tag lookups that hit in the instruction cache (L1I). Counts at 64-byte cache-line granularity. Accounts for both cacheable and uncacheable accesses. | EventSel=83H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ICACHE_64B.IFTAG_MISS | Counts instruction fetch tag lookups that miss in the instruction cache (L1I). Counts at 64-byte cache-line granularity. Accounts for both cacheable and uncacheable accesses. | EventSel=83H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ICACHE_64B.IFTAG_STALL | Counts cycles where a code fetch is stalled due to L1 instruction cache tag miss. | EventSel=83H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.DSB_CYCLES_ANY | Counts the number of cycles uops were delivered to Instruction Decode Queue (IDQ) from the Decode Stream Buffer (DSB) path. | EventSel=79H UMask=08H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.DSB_CYCLES_OK | Counts the number of cycles where optimal number of uops was delivered to the Instruction Decode Queue (IDQ) from the DSB (Decode Stream Buffer) path. Count includes uops that may 'bypass' the IDQ. | EventSel=79H UMask=08H CMask=05H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.DSB_UOPS | Counts the number of uops delivered to Instruction Decode Queue (IDQ) from the Decode Stream Buffer (DSB) path. | EventSel=79H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MITE_CYCLES_ANY | Counts the number of cycles uops were delivered to the Instruction Decode Queue (IDQ) from the MITE (legacy decode pipeline) path. During these cycles uops are not being delivered from the Decode Stream Buffer (DSB). | EventSel=79H UMask=04H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MITE_CYCLES_OK | Counts the number of cycles where optimal number of uops was delivered to the Instruction Decode Queue (IDQ) from the MITE (legacy decode pipeline) path. During these cycles uops are not being delivered from the Decode Stream Buffer (DSB). | EventSel=79H UMask=04H CMask=05H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MITE_UOPS | Counts the number of uops delivered to Instruction Decode Queue (IDQ) from the MITE path. This also means that uops are not being delivered from the Decode Stream Buffer (DSB). | EventSel=79H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MS_CYCLES_ANY | Counts cycles during which uops are being delivered to Instruction Decode Queue (IDQ) while the Microcode Sequencer (MS) is busy. Uops maybe initiated by Decode Stream Buffer (DSB) or MITE. | EventSel=79H UMask=30H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MS_SWITCHES | Number of switches from DSB (Decode Stream Buffer) or MITE (legacy decode pipeline) to the Microcode Sequencer. | EventSel=79H UMask=30H EdgeDetect=1 CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ.MS_UOPS | Counts the total number of uops delivered by the Microcode Sequencer (MS). Any instruction over 4 uops will be delivered by the MS. Some instructions such as transcendentals may additionally generate uops from the MS. | EventSel=79H UMask=30H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
IDQ_UOPS_NOT_DELIVERED.CORE | Counts the number of uops not delivered to by the Instruction Decode Queue (IDQ) to the back-end of the pipeline when there was no back-end stalls. This event counts for one SMT thread in a given cycle. | EventSel=9CH UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
IDQ_UOPS_NOT_DELIVERED.CYCLES_0_UOPS_DELIV.CORE | Counts the number of cycles when no uops were delivered by the Instruction Decode Queue (IDQ) to the back-end of the pipeline when there was no back-end stalls. This event counts for one SMT thread in a given cycle. | EventSel=9CH UMask=01H CMask=05H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
IDQ_UOPS_NOT_DELIVERED.CYCLES_FE_WAS_OK | Counts the number of cycles when the optimal number of uops were delivered by the Instruction Decode Queue (IDQ) to the back-end of the pipeline when there was no back-end stalls. This event counts for one SMT thread in a given cycle. | EventSel=9CH UMask=01H Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
ILD_STALL.LCP | Counts cycles that the Instruction Length decoder (ILD) stalls occurred due to dynamically changing prefix length of the decoded instruction (by operand size prefix instruction 0x66, address size prefix instruction 0x67 or REX.W for Intel64). Count is proportional to the number of prefixes in a 16B-line. This may result in a three-cycle penalty for each LCP (Length changing prefix) in a 16-byte chunk. | EventSel=87H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
INST_DECODED.DECODERS | Number of decoders utilized in a cycle when the MITE (legacy decode pipeline) fetches instructions. | EventSel=55H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
INST_RETIRED.NOP | Number of all retired NOP instructions. | EventSel=C0H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
INST_RETIRED.PREC_DIST | A version of INST_RETIRED that allows for a more unbiased distribution of samples across instructions retired. It utilizes the Precise Distribution of Instructions Retired (PDIR) feature to mitigate some bias in how retired instructions get sampled. Use on Fixed Counter 0. | IA32_FIXED_CTR0 PEBS:[PreciseEventingIP] Fixed, AtRetirement |
INST_RETIRED.STALL_CYCLES | This event counts cycles without actually retired instructions. | EventSel=C0H UMask=01H Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
INT_MISC.ALL_RECOVERY_CYCLES | Counts cycles the Backend cluster is recovering after a miss-speculation or a Store Buffer or Load Buffer drain stall. | EventSel=0DH UMask=03H CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
INT_MISC.CLEAR_RESTEER_CYCLES | Cycles after recovery from a branch misprediction or machine clear till the first uop is issued from the resteered path. | EventSel=0DH UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
INT_MISC.CLEARS_COUNT | Counts the number of speculative clears due to any type of branch misprediction or machine clears | EventSel=0DH UMask=01H EdgeDetect=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
INT_MISC.RECOVERY_CYCLES | Counts core cycles when the Resource allocator was stalled due to recovery from an earlier branch misprediction or machine clear event. | EventSel=0DH UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
INT_MISC.UOP_DROPPING | Estimated number of Top-down Microarchitecture Analysis slots that got dropped due to non front-end reasons | EventSel=0DH UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
ITLB_MISSES.STLB_HIT | Counts instruction fetch requests that miss the ITLB (Instruction TLB) and hit the STLB (Second-level TLB). | EventSel=85H UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ITLB_MISSES.WALK_ACTIVE | Counts cycles when at least one PMH (Page Miss Handler) is busy with a page walk for a code (instruction fetch) request. | EventSel=85H UMask=10H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ITLB_MISSES.WALK_COMPLETED | Counts completed page walks (all page sizes) caused by a code fetch. This implies it missed in the ITLB (Instruction TLB) and further levels of TLB. The page walk can end with or without a fault. | EventSel=85H UMask=0EH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ITLB_MISSES.WALK_COMPLETED_2M_4M | Counts completed page walks (2M/4M page sizes) caused by a code fetch. This implies it missed in the ITLB (Instruction TLB) and further levels of TLB. The page walk can end with or without a fault. | EventSel=85H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ITLB_MISSES.WALK_COMPLETED_4K | Counts completed page walks (4K page sizes) caused by a code fetch. This implies it missed in the ITLB (Instruction TLB) and further levels of TLB. The page walk can end with or without a fault. | EventSel=85H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
ITLB_MISSES.WALK_PENDING | Counts the number of page walks outstanding for an outstanding code (instruction fetch) request in the PMH (Page Miss Handler) each cycle. | EventSel=85H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D.REPLACEMENT | Counts L1D data line replacements including opportunistic replacements, and replacements that require stall-for-replace or block-for-replace. | EventSel=51H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D_PEND_MISS.FB_FULL | Counts number of cycles a demand request has waited due to L1D Fill Buffer (FB) unavailability. Demand requests include cacheable/uncacheable demand load, store, lock or SW prefetch accesses. | EventSel=48H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D_PEND_MISS.FB_FULL_PERIODS | Counts number of phases a demand request has waited due to L1D Fill Buffer (FB) unavailability. Demand requests include cacheable/uncacheable demand load, store, lock or SW prefetch accesses. | EventSel=48H UMask=02H EdgeDetect=1 CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D_PEND_MISS.L2_STALL | Counts number of cycles a demand request has waited due to L1D due to lack of L2 resources. Demand requests include cacheable/uncacheable demand load, store, lock or SW prefetch accesses. | EventSel=48H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D_PEND_MISS.PENDING | Counts number of L1D misses that are outstanding in each cycle, that is each cycle the number of Fill Buffers (FB) outstanding required by Demand Reads. FB either is held by demand loads, or it is held by non-demand loads and gets hit at least once by demand. The valid outstanding interval is defined until the FB deallocation by one of the following ways: from FB allocation, if FB is allocated by demand from the demand Hit FB, if it is allocated by hardware or software prefetch. Note: In the L1D, a Demand Read contains cacheable or noncacheable demand loads, including ones causing cache-line splits and reads due to page walks resulted from any request type. | EventSel=48H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L1D_PEND_MISS.PENDING_CYCLES | Counts duration of L1D miss outstanding in cycles. | EventSel=48H UMask=01H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_LINES_IN.ALL | Counts the number of L2 cache lines filling the L2. Counting does not cover rejects. | EventSel=F1H UMask=1FH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_LINES_OUT.NON_SILENT | Counts the number of lines that are evicted by L2 cache when triggered by an L2 cache fill. Those lines are in Modified state. Modified lines are written back to L3 | EventSel=F2H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_LINES_OUT.SILENT | Counts the number of lines that are silently dropped by L2 cache when triggered by an L2 cache fill. These lines are typically in Shared or Exclusive state. A non-threaded event. | EventSel=F2H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_LINES_OUT.USELESS_HWPF | Counts the number of cache lines that have been prefetched by the L2 hardware prefetcher but not used by demand access when evicted from the L2 cache | EventSel=F2H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.ALL_CODE_RD | Counts the total number of L2 code requests. | EventSel=24H UMask=E4H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.ALL_DEMAND_DATA_RD | Counts the number of demand Data Read requests (including requests from L1D hardware prefetchers). These loads may hit or miss L2 cache. Only non rejected loads are counted. | EventSel=24H UMask=E1H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.ALL_DEMAND_MISS | Counts demand requests that miss L2 cache. | EventSel=24H UMask=27H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.ALL_DEMAND_REFERENCES | Counts demand requests to L2 cache. | EventSel=24H UMask=E7H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.ALL_RFO | Counts the total number of RFO (read for ownership) requests to L2 cache. L2 RFO requests include both L1D demand RFO misses as well as L1D RFO prefetches. | EventSel=24H UMask=E2H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.CODE_RD_HIT | Counts L2 cache hits when fetching instructions, code reads. | EventSel=24H UMask=C4H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.CODE_RD_MISS | Counts L2 cache misses when fetching instructions. | EventSel=24H UMask=24H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.DEMAND_DATA_RD_HIT | Counts the number of demand Data Read requests initiated by load instructions that hit L2 cache. | EventSel=24H UMask=C1H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.DEMAND_DATA_RD_MISS | Counts the number of demand Data Read requests that miss L2 cache. Only not rejected loads are counted. | EventSel=24H UMask=21H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.RFO_HIT | Counts the RFO (Read-for-Ownership) requests that hit L2 cache. | EventSel=24H UMask=C2H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.RFO_MISS | Counts the RFO (Read-for-Ownership) requests that miss L2 cache. | EventSel=24H UMask=22H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.SWPF_HIT | Counts Software prefetch requests that hit the L2 cache. Accounts for PREFETCHNTA and PREFETCHT0/1/2 instructions when FB is not full. | EventSel=24H UMask=C8H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_RQSTS.SWPF_MISS | Counts Software prefetch requests that miss the L2 cache. Accounts for PREFETCHNTA and PREFETCHT0/1/2 instructions when FB is not full. | EventSel=24H UMask=28H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
L2_TRANS.L2_WB | Counts L2 writebacks that access L2 cache. | EventSel=F0H UMask=40H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LD_BLOCKS.NO_SR | Counts the number of times that split load operations are temporarily blocked because all resources for handling the split accesses are in use. | EventSel=03H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LD_BLOCKS.STORE_FORWARD | Counts the number of times where store forwarding was prevented for a load operation. The most common case is a load blocked due to the address of memory access (partially) overlapping with a preceding uncompleted store. Note: See the table of not supported store forwards in the Optimization Guide. | EventSel=03H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LD_BLOCKS_PARTIAL.ADDRESS_ALIAS | Counts the number of times a load got blocked due to false dependencies due to partial compare on address. | EventSel=07H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LOAD_HIT_PREFETCH.SWPF | Counts all not software-prefetch load dispatches that hit the fill buffer (FB) allocated for the software prefetch. It can also be incremented by some lock instructions. So it should only be used with profiling so that the locks can be excluded by ASM (Assembly File) inspection of the nearby instructions. | EventSel=4CH UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LSD.CYCLES_ACTIVE | Counts the cycles when at least one uop is delivered by the LSD (Loop-stream detector). | EventSel=A8H UMask=01H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LSD.CYCLES_OK | Counts the cycles when optimal number of uops is delivered by the LSD (Loop-stream detector). | EventSel=A8H UMask=01H CMask=05H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
LSD.UOPS | Counts the number of uops delivered to the back-end by the LSD(Loop Stream Detector). | EventSel=A8H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
MACHINE_CLEARS.COUNT | Counts the number of machine clears (nukes) of any type. | EventSel=C3H UMask=01H EdgeDetect=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
MACHINE_CLEARS.MEMORY_ORDERING | Counts the number of Machine Clears detected dye to memory ordering. Memory Ordering Machine Clears may apply when a memory read may not conform to the memory ordering rules of the x86 architecture | EventSel=C3H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
MACHINE_CLEARS.SMC | Counts self-modifying code (SMC) detected, which causes a machine clear. | EventSel=C3H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
MEM_INST_RETIRED.ALL_LOADS | Counts all retired load instructions. This event accounts for SW prefetch instructions of PREFETCHNTA or PREFETCHT0/1/2 or PREFETCHW. | EventSel=D0H UMask=81H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.ALL_STORES | Counts all retired store instructions. | EventSel=D0H UMask=82H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.ANY | Counts all retired memory instructions - loads and stores. | EventSel=D0H UMask=83H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.LOCK_LOADS | Counts retired load instructions with locked access. | EventSel=D0H UMask=21H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.SPLIT_LOADS | Counts retired load instructions that split across a cacheline boundary. | EventSel=D0H UMask=41H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.SPLIT_STORES | Counts retired store instructions that split across a cacheline boundary. | EventSel=D0H UMask=42H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.STLB_MISS_LOADS | Number of retired load instructions that (start a) miss in the 2nd-level TLB (STLB). | EventSel=D0H UMask=11H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_INST_RETIRED.STLB_MISS_STORES | Number of retired store instructions that (start a) miss in the 2nd-level TLB (STLB). | EventSel=D0H UMask=12H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_L3_HIT_RETIRED.XSNP_HIT | Counts retired load instructions whose data sources were L3 and cross-core snoop hits in on-pkg core cache. | EventSel=D2H UMask=02H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_L3_HIT_RETIRED.XSNP_HITM | Counts retired load instructions whose data sources were HitM responses from shared L3. | EventSel=D2H UMask=04H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_L3_HIT_RETIRED.XSNP_MISS | Counts the retired load instructions whose data sources were L3 hit and cross-core snoop missed in on-pkg core cache. | EventSel=D2H UMask=01H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_L3_HIT_RETIRED.XSNP_NONE | Counts retired load instructions whose data sources were hits in L3 without snoops required. | EventSel=D2H UMask=08H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_MISC_RETIRED.UC | Retired instructions with at least one load to uncacheable memory-type, or at least one cache-line split locked access (Bus Lock). | EventSel=D4H UMask=04H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.FB_HIT | Counts retired load instructions with at least one uop was load missed in L1 but hit FB (Fill Buffers) due to preceding miss to the same cache line with data not ready. | EventSel=D1H UMask=40H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L1_HIT | Counts retired load instructions with at least one uop that hit in the L1 data cache. This event includes all SW prefetches and lock instructions regardless of the data source. | EventSel=D1H UMask=01H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L1_MISS | Counts retired load instructions with at least one uop that missed in the L1 cache. | EventSel=D1H UMask=08H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L2_HIT | Counts retired load instructions with L2 cache hits as data sources. | EventSel=D1H UMask=02H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L2_MISS | Counts retired load instructions missed L2 cache as data sources. | EventSel=D1H UMask=10H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L3_HIT | Counts retired load instructions with at least one uop that hit in the L3 cache. | EventSel=D1H UMask=04H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_LOAD_RETIRED.L3_MISS | Counts retired load instructions with at least one uop that missed in the L3 cache. | EventSel=D1H UMask=20H Counter=0,1,2,3 PEBS:[PreciseEventingIP, DataLinearAddress, Counter=0,1,2,3] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_128 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 128 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=80H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_16 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 16 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=10H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_256 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 256 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=100H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_32 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 32 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=20H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_4 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 4 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=04H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_512 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 512 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=200H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_64 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 64 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=40H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MEM_TRANS_RETIRED.LOAD_LATENCY_GT_8 | Counts randomly selected loads when the latency from first dispatch to completion is greater than 8 cycles. Reported latency may be longer than just the memory latency. | EventSel=CDH UMask=01H MSR_PEBS_LD_LAT_THRESHOLD(3F6H)=08H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, DataLinearAddress, Latency, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MISC_RETIRED.LBR_INSERTS | Increments when an entry is added to the Last Branch Record (LBR) array (or removed from the array in case of RETURNs in call stack mode). The event requires LBR to be enabled properly. | EventSel=CCH UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
MISC_RETIRED.PAUSE_INST | Counts number of retired PAUSE instructions. This event is not supported on first SKL and KBL products. | EventSel=CCH UMask=40H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP] AtRetirement |
OFFCORE_REQUESTS.ALL_DATA_RD | Counts the demand and prefetch data reads. All Core Data Reads include cacheable 'Demands' and L2 prefetchers (not L3 prefetchers). Counting also covers reads due to page walks resulted from any request type. | EventSel=B0H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS.ALL_REQUESTS | Counts memory transactions sent to the uncore including requests initiated by the core, all L3 prefetches, reads resulting from page walks, and snoop responses. | EventSel=B0H UMask=80H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS.DEMAND_DATA_RD | Counts the Demand Data Read requests sent to uncore. Use it in conjunction with OFFCORE_REQUESTS_OUTSTANDING to determine average latency in the uncore. | EventSel=B0H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS.DEMAND_RFO | Counts the demand RFO (read for ownership) requests including regular RFOs, locks, ItoM. | EventSel=B0H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS.L3_MISS_DEMAND_DATA_RD | Counts demand data read requests that miss the L3 cache. | EventSel=B0H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.ALL_DATA_RD | For every cycle, increments by the number of outstanding data read requests pending. Data read requests include cacheable demand reads and L2 prefetches, but do not include RFOs, code reads or prefetches to the L3. Reads due to page walks resulting from any request type will also be counted. Requests are considered outstanding from the time they miss the core's L2 cache until the transaction completion message is sent to the requestor. | EventSel=60H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.CYCLES_WITH_DATA_RD | Cycles where at least 1 outstanding data read request is pending. Data read requests include cacheable demand reads and L2 prefetches, but do not include RFOs, code reads or prefetches to the L3. Reads due to page walks resulting from any request type will also be counted. Requests are considered outstanding from the time they miss the core's L2 cache until the transaction completion message is sent to the requestor. | EventSel=60H UMask=08H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.CYCLES_WITH_DEMAND_RFO | Cycles where at least 1 outstanding Demand RFO request is pending. RFOs are initiated by a core as part of a data store operation. Demand RFO requests include RFOs, locks, and ItoM transactions. Requests are considered outstanding from the time they miss the core's L2 cache until the transaction completion message is sent to the requestor. | EventSel=60H UMask=04H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.CYCLES_WITH_L3_MISS_DEMAND_DATA_RD | Cycles where at least one demand data read request known to have missed the L3 cache is pending. Note that this does not capture all elapsed cycles while requests are outstanding - only cycles from when the requests were known to have missed the L3 cache. | EventSel=60H UMask=10H CMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.DEMAND_DATA_RD | For every cycle, increments by the number of outstanding demand data read requests pending. Requests are considered outstanding from the time they miss the core's L2 cache until the transaction completion message is sent to the requestor. | EventSel=60H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
OFFCORE_REQUESTS_OUTSTANDING.DEMAND_RFO | Counts the number of off-core outstanding read-for-ownership (RFO) store transactions every cycle. An RFO transaction is considered to be in the Off-core outstanding state between L2 cache miss and transaction completion. | EventSel=60H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
RESOURCE_STALLS.SB | Counts allocation stall cycles caused by the store buffer (SB) being full. This counts cycles that the pipeline back-end blocked uop delivery from the front-end. | EventSel=A2H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
RESOURCE_STALLS.SCOREBOARD | Counts cycles where the pipeline is stalled due to serializing operations. | EventSel=A2H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
RS_EVENTS.EMPTY_CYCLES | Counts cycles during which the reservation station (RS) is empty for this logical processor. This is usually caused when the front-end pipeline runs into starvation periods (e.g. branch mispredictions or i-cache misses) | EventSel=5EH UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
RS_EVENTS.EMPTY_END | Counts end of periods where the Reservation Station (RS) was empty. Could be useful to closely sample on front-end latency issues (see the FRONTEND_RETIRED event of designated precise events) | EventSel=5EH UMask=01H EdgeDetect=1 Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
RTM_RETIRED.ABORTED | Counts the number of times RTM abort was triggered. | EventSel=C9H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[PreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.ABORTED_EVENTS | Counts the number of times an RTM execution aborted due to none of the previous 3 categories (e.g. interrupt). | EventSel=C9H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.ABORTED_MEM | Counts the number of times an RTM execution aborted due to various memory events (e.g. read/write capacity and conflicts). | EventSel=C9H UMask=08H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.ABORTED_MEMTYPE | Counts the number of times an RTM execution aborted due to incompatible memory type. | EventSel=C9H UMask=40H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.ABORTED_UNFRIENDLY | Counts the number of times an RTM execution aborted due to HLE-unfriendly instructions. | EventSel=C9H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.COMMIT | Counts the number of times RTM commit succeeded. | EventSel=C9H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
RTM_RETIRED.START | Counts the number of times we entered an RTM region. Does not count nested transactions. | EventSel=C9H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
SQ_MISC.BUS_LOCK | Counts the more expensive bus lock needed to enforce cache coherency for certain memory accesses that need to be done atomically. Can be created by issuing an atomic instruction (via the LOCK prefix) which causes a cache line split or accesses uncacheable memory. | EventSel=F4H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SQ_MISC.SQ_FULL | Counts the cycles for which the thread is active and the queue waiting for responses from the uncore cannot take any more entries. | EventSel=F4H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SW_PREFETCH_ACCESS.ANY | Counts the number of PREFETCHNTA, PREFETCHW, PREFETCHT0, PREFETCHT1 or PREFETCHT2 instructions executed. | EventSel=32H UMask=0FH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SW_PREFETCH_ACCESS.NTA | Counts the number of PREFETCHNTA instructions executed. | EventSel=32H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SW_PREFETCH_ACCESS.PREFETCHW | Counts the number of PREFETCHW instructions executed. | EventSel=32H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SW_PREFETCH_ACCESS.T0 | Counts the number of PREFETCHT0 instructions executed. | EventSel=32H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
SW_PREFETCH_ACCESS.T1_T2 | Counts the number of PREFETCHT1 or PREFETCHT2 instructions executed. | EventSel=32H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TLB_FLUSH.DTLB_THREAD | Counts the number of DTLB flush attempts of the thread-specific entries. | EventSel=BDH UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TLB_FLUSH.STLB_ANY | Counts the number of any STLB flush attempts (such as entire, VPID, PCID, InvPage, CR3 write, etc.). | EventSel=BDH UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TOPDOWN.BACKEND_BOUND_SLOTS | Counts the number of Top-down Microarchitecture Analysis (TMA) method's slots where no micro-operations were being issued from front-end to back-end of the machine due to lack of back-end resources. | EventSel=A4H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
TX_EXEC.MISC2 | Counts Unfriendly TSX abort triggered by a vzeroupper instruction. | EventSel=5DH UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
TX_EXEC.MISC3 | Counts Unfriendly TSX abort triggered by a nest count that is too deep. | EventSel=5DH UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
TX_MEM.ABORT_CAPACITY_READ | Speculatively counts the number of Transactional Synchronization Extensions (TSX) aborts due to a data capacity limitation for transactional reads | EventSel=54H UMask=80H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_CAPACITY_WRITE | Speculatively counts the number of Transactional Synchronization Extensions (TSX) aborts due to a data capacity limitation for transactional writes. | EventSel=54H UMask=02H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_CONFLICT | Counts the number of times a TSX line had a cache conflict. | EventSel=54H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_HLE_ELISION_BUFFER_MISMATCH | Counts the number of times a TSX Abort was triggered due to release/commit but data and address mismatch. | EventSel=54H UMask=10H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_HLE_ELISION_BUFFER_NOT_EMPTY | Counts the number of times a TSX Abort was triggered due to commit but Lock Buffer not empty. | EventSel=54H UMask=08H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_HLE_ELISION_BUFFER_UNSUPPORTED_ALIGNMENT | Counts the number of times a TSX Abort was triggered due to attempting an unsupported alignment from Lock Buffer. | EventSel=54H UMask=20H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.ABORT_HLE_STORE_TO_ELIDED_LOCK | Counts the number of times a TSX Abort was triggered due to a non-release/commit store to lock. | EventSel=54H UMask=04H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
TX_MEM.HLE_ELISION_BUFFER_FULL | Counts the number of times we could not allocate Lock Buffer. | EventSel=54H UMask=40H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
UOPS_DECODED.DEC0 | Uops exclusively fetched by decoder 0 | EventSel=56H UMask=01H Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative |
UOPS_DISPATCHED.PORT_0 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to port 0. | EventSel=A1H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_1 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to port 1. | EventSel=A1H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_2_3 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to ports 2 and 3. | EventSel=A1H UMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_4_9 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to ports 5 and 9. | EventSel=A1H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_5 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to port 5. | EventSel=A1H UMask=20H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_6 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to port 6. | EventSel=A1H UMask=40H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_DISPATCHED.PORT_7_8 | Counts, on the per-thread basis, cycles during which at least one uop is dispatched from the Reservation Station (RS) to ports 7 and 8. | EventSel=A1H UMask=80H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CORE | Counts the number of uops executed from any thread. | EventSel=B1H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CORE_CYCLES_GE_1 | Counts cycles when at least 1 micro-op is executed from any thread on physical core. | EventSel=B1H UMask=02H CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CORE_CYCLES_GE_2 | Counts cycles when at least 2 micro-ops are executed from any thread on physical core. | EventSel=B1H UMask=02H CMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CORE_CYCLES_GE_3 | Counts cycles when at least 3 micro-ops are executed from any thread on physical core. | EventSel=B1H UMask=02H CMask=03H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CORE_CYCLES_GE_4 | Counts cycles when at least 4 micro-ops are executed from any thread on physical core. | EventSel=B1H UMask=02H CMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CYCLES_GE_1 | Cycles where at least 1 uop was executed per-thread. | EventSel=B1H UMask=01H CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CYCLES_GE_2 | Cycles where at least 2 uops were executed per-thread. | EventSel=B1H UMask=01H CMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CYCLES_GE_3 | Cycles where at least 3 uops were executed per-thread. | EventSel=B1H UMask=01H CMask=03H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.CYCLES_GE_4 | Cycles where at least 4 uops were executed per-thread. | EventSel=B1H UMask=01H CMask=04H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.STALL_CYCLES | Counts cycles during which no uops were dispatched from the Reservation Station (RS) per thread. | EventSel=B1H UMask=01H Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.THREAD | Counts the number of uops to be executed per-thread each cycle. | EventSel=B1H UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_EXECUTED.X87 | Counts the number of x87 uops executed. | EventSel=B1H UMask=10H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_ISSUED.ANY | Counts the number of uops that the Resource Allocation Table (RAT) issues to the Reservation Station (RS). | EventSel=0EH UMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_ISSUED.STALL_CYCLES | Counts cycles during which the Resource Allocation Table (RAT) does not issue any Uops to the reservation station (RS) for the current thread. | EventSel=0EH UMask=01H Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_ISSUED.VECTOR_WIDTH_MISMATCH | Counts the number of Blend Uops issued by the Resource Allocation Table (RAT) to the reservation station (RS) in order to preserve upper bits of vector registers. Starting with the Skylake microarchitecture, these Blend uops are needed since every Intel SSE instruction executed in Dirty Upper State needs to preserve bits 128-255 of the destination register. For more information, refer to 'Mixing Intel AVX and Intel SSE Code' section of the Optimization Guide. | EventSel=0EH UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_RETIRED.SLOTS | Counts the retirement slots used each cycle. | EventSel=C2H UMask=02H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
UOPS_RETIRED.STALL_CYCLES | This event counts cycles without actually retired uops. | EventSel=C2H UMask=02H Invert=1 CMask=01H Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] Speculative |
UOPS_RETIRED.TOTAL_CYCLES | Counts the number of cycles using always true condition (uops_ret < 16) applied to non PEBS uops retired event. | EventSel=C2H UMask=02H Invert=1 CMask=0AH Counter=0,1,2,3,4,5,6,7 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3,4,5,6,7] AtRetirement |
L2_RQSTS.MISS | This event is deprecated. | EventSel=24H UMask=3FH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative, Deprecated |
L2_RQSTS.REFERENCES | This event is deprecated. | EventSel=24H UMask=FFH Counter=0,1,2,3 PEBS:[NonPreciseEventingIP, Counter=0,1,2,3] Speculative, Deprecated |
UNCORE | ||
UNC_CLOCK.SOCKET | UNC_CLOCK.SOCKET | MSR_UNC_PERF_FIXED_CTR Fixed |
UNC_ARB_COH_TRK_REQUESTS.ALL | Number of entries allocated. Account for Any type: e.g. Snoop, etc. | EventSel=84H UMask=01H Counter=1 |
UNC_ARB_TRK_REQUESTS.ALL | Total number of all outgoing entries allocated. Accounts for Coherent and non-coherent traffic. | EventSel=81H UMask=01H Counter=1 |
OFFCORE | ||
OCR.DEMAND_DATA_RD.L3_HIT.SNOOP_NOT_NEEDED | Counts demand data reads that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0001H |
OCR.DEMAND_DATA_RD.L3_HIT.SNOOP_MISS | Counts demand data reads that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0001H |
OCR.DEMAND_DATA_RD.L3_HIT.SNOOP_HIT_NO_FWD | Counts demand data reads that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C0001H |
OCR.DEMAND_DATA_RD.L3_HIT.SNOOP_HITM | Counts demand data reads that hit a cacheline in the L3 where a snoop hit in another cores caches, data forwarding is required as the data is modified. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10003C0001H |
OCR.DEMAND_DATA_RD.L3_HIT.ANY | Counts demand data reads that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0001H |
OCR.DEMAND_RFO.L3_HIT.SNOOP_NOT_NEEDED | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0002H |
OCR.DEMAND_RFO.L3_HIT.SNOOP_MISS | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0002H |
OCR.DEMAND_RFO.L3_HIT.SNOOP_HIT_NO_FWD | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C0002H |
OCR.DEMAND_RFO.L3_HIT.SNOOP_HITM | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop hit in another cores caches, data forwarding is required as the data is modified. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10003C0002H |
OCR.DEMAND_RFO.L3_HIT.ANY | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0002H |
OCR.DEMAND_CODE_RD.L3_HIT.SNOOP_NOT_NEEDED | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0004H |
OCR.DEMAND_CODE_RD.L3_HIT.SNOOP_MISS | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0004H |
OCR.DEMAND_CODE_RD.L3_HIT.SNOOP_HIT_NO_FWD | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C0004H |
OCR.DEMAND_CODE_RD.L3_HIT.SNOOP_HITM | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop hit in another cores caches, data forwarding is required as the data is modified. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10003C0004H |
OCR.DEMAND_CODE_RD.L3_HIT.ANY | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0004H |
OCR.HWPF_L2_DATA_RD.L3_HIT.SNOOP_NOT_NEEDED | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0010H |
OCR.HWPF_L2_DATA_RD.L3_HIT.SNOOP_MISS | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0010H |
OCR.HWPF_L2_DATA_RD.L3_HIT.SNOOP_HIT_NO_FWD | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C0010H |
OCR.HWPF_L2_DATA_RD.L3_HIT.SNOOP_HITM | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop hit in another cores caches, data forwarding is required as the data is modified. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10003C0010H |
OCR.HWPF_L2_DATA_RD.L3_HIT.ANY | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0010H |
OCR.HWPF_L2_RFO.L3_HIT.SNOOP_NOT_NEEDED | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0020H |
OCR.HWPF_L2_RFO.L3_HIT.SNOOP_MISS | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0020H |
OCR.HWPF_L2_RFO.L3_HIT.SNOOP_HIT_NO_FWD | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C0020H |
OCR.HWPF_L2_RFO.L3_HIT.SNOOP_HITM | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop hit in another cores caches, data forwarding is required as the data is modified. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10003C0020H |
OCR.HWPF_L2_RFO.L3_HIT.ANY | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0020H |
OCR.HWPF_L1D_AND_SWPF.L3_HIT.SNOOP_NOT_NEEDED | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C0400H |
OCR.HWPF_L1D_AND_SWPF.L3_HIT.SNOOP_MISS | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C0400H |
OCR.HWPF_L1D_AND_SWPF.L3_HIT.ANY | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0400H |
OCR.STREAMING_WR.L3_HIT.ANY | Counts streaming stores that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C0800H |
OCR.OTHER.L3_HIT.SNOOP_NOT_NEEDED | Counts miscellaneous requests, such as I/O and un-cacheable accesses that hit a cacheline in the L3 where a snoop was not needed to satisfy the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1003C8000H |
OCR.OTHER.L3_HIT.SNOOP_MISS | Counts miscellaneous requests, such as I/O and un-cacheable accesses that hit a cacheline in the L3 where a snoop was sent but no other cores had the data. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=2003C8000H |
OCR.OTHER.L3_HIT.SNOOP_HIT_NO_FWD | Counts miscellaneous requests, such as I/O and un-cacheable accesses that hit a cacheline in the L3 where a snoop hit in another core, data forwarding is not required. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=4003C8000H |
OCR.HWPF_L3.L3_HIT.ANY | Counts hardware prefetches to the L3 only that hit a cacheline in the L3 where a snoop was sent or not. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FC03C2380H |
OCR.DEMAND_DATA_RD.ANY_RESPONSE | Counts demand data reads that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10001H |
OCR.DEMAND_RFO.ANY_RESPONSE | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10002H |
OCR.DEMAND_CODE_RD.ANY_RESPONSE | Counts demand instruction fetches and L1 instruction cache prefetches that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10004H |
OCR.HWPF_L2_DATA_RD.ANY_RESPONSE | Counts hardware prefetch data reads (which bring data to L2) that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10010H |
OCR.HWPF_L2_RFO.ANY_RESPONSE | Counts hardware prefetch RFOs (which bring data to L2) that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10020H |
OCR.HWPF_L1D_AND_SWPF.ANY_RESPONSE | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10400H |
OCR.STREAMING_WR.ANY_RESPONSE | Counts streaming stores that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=10800H |
OCR.OTHER.ANY_RESPONSE | Counts miscellaneous requests, such as I/O and un-cacheable accesses that have any type of response. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=18000H |
OCR.DEMAND_DATA_RD.L3_HIT.SNOOP_SENT | Counts demand data reads that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C0001H |
OCR.DEMAND_RFO.L3_HIT.SNOOP_SENT | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C0002H |
OCR.DEMAND_CODE_RD.L3_HIT.SNOOP_SENT | Counts demand instruction fetches and L1 instruction cache prefetches that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C0004H |
OCR.HWPF_L2_DATA_RD.L3_HIT.SNOOP_SENT | Counts hardware prefetch data reads (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C0010H |
OCR.HWPF_L2_RFO.L3_HIT.SNOOP_SENT | Counts hardware prefetch RFOs (which bring data to L2) that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C0020H |
OCR.OTHER.L3_HIT.SNOOP_SENT | Counts miscellaneous requests, such as I/O and un-cacheable accesses that hit a cacheline in the L3 where a snoop was sent. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=1E003C8000H |
OCR.DEMAND_DATA_RD.DRAM | Counts demand data reads that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000001H |
OCR.DEMAND_RFO.DRAM | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000002H |
OCR.DEMAND_CODE_RD.DRAM | Counts demand instruction fetches and L1 instruction cache prefetches that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000004H |
OCR.HWPF_L2_DATA_RD.DRAM | Counts hardware prefetch data reads (which bring data to L2) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000010H |
OCR.HWPF_L2_RFO.DRAM | Counts hardware prefetch RFOs (which bring data to L2) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000020H |
OCR.HWPF_L1D_AND_SWPF.DRAM | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000400H |
OCR.STREAMING_WR.DRAM | Counts streaming stores that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000800H |
OCR.OTHER.DRAM | Counts miscellaneous requests, such as I/O and un-cacheable accesses that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184008000H |
OCR.DEMAND_DATA_RD.L3_MISS | Counts demand data reads that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00001H |
OCR.DEMAND_RFO.L3_MISS | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00002H |
OCR.DEMAND_CODE_RD.L3_MISS | Counts demand instruction fetches and L1 instruction cache prefetches that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00004H |
OCR.HWPF_L2_DATA_RD.L3_MISS | Counts hardware prefetch data reads (which bring data to L2) that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00010H |
OCR.HWPF_L2_RFO.L3_MISS | Counts hardware prefetch RFOs (which bring data to L2) that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00020H |
OCR.HWPF_L1D_AND_SWPF.L3_MISS | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00400H |
OCR.STREAMING_WR.L3_MISS | Counts streaming stores that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC00800H |
OCR.OTHER.L3_MISS | Counts miscellaneous requests, such as I/O and un-cacheable accesses that was not supplied by the L3 cache. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=3FFFC08000H |
OCR.DEMAND_DATA_RD.LOCAL_DRAM | Counts demand data reads that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000001H |
OCR.DEMAND_RFO.LOCAL_DRAM | Counts demand reads for ownership (RFO) requests and software prefetches for exclusive ownership (PREFETCHW) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000002H |
OCR.DEMAND_CODE_RD.LOCAL_DRAM | Counts demand instruction fetches and L1 instruction cache prefetches that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000004H |
OCR.HWPF_L2_DATA_RD.LOCAL_DRAM | Counts hardware prefetch data reads (which bring data to L2) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000010H |
OCR.HWPF_L2_RFO.LOCAL_DRAM | Counts hardware prefetch RFOs (which bring data to L2) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000020H |
OCR.HWPF_L1D_AND_SWPF.LOCAL_DRAM | Counts L1 data cache prefetch requests and software prefetches (except PREFETCHW) that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000400H |
OCR.STREAMING_WR.LOCAL_DRAM | Counts streaming stores that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184000800H |
OCR.OTHER.LOCAL_DRAM | Counts miscellaneous requests, such as I/O and un-cacheable accesses that DRAM supplied the request. | EventSel={B7H,BBH} UMask=01H MSR_OFFCORE_RSPx{1A6H,1A7H}=184008000H |