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linux/arch/x86/events/intel/ds.c
Linus Torvalds 785cdec46e Core x86 updates for v6.16: 
Boot code changes:
 
  - A large series of changes to reorganize the x86 boot code into a better isolated
    and easier to maintain base of PIC early startup code in arch/x86/boot/startup/,
    by Ard Biesheuvel.
 
    Motivation & background:
 
 	| Since commit
 	|
 	|    c88d71508e ("x86/boot/64: Rewrite startup_64() in C")
 	|
 	| dated Jun 6 2017, we have been using C code on the boot path in a way
 	| that is not supported by the toolchain, i.e., to execute non-PIC C
 	| code from a mapping of memory that is different from the one provided
 	| to the linker. It should have been obvious at the time that this was a
 	| bad idea, given the need to sprinkle fixup_pointer() calls left and
 	| right to manipulate global variables (including non-pointer variables)
 	| without crashing.
 	|
 	| This C startup code has been expanding, and in particular, the SEV-SNP
 	| startup code has been expanding over the past couple of years, and
 	| grown many of these warts, where the C code needs to use special
 	| annotations or helpers to access global objects.
 
    This tree includes the first phase of this work-in-progress x86 boot code
    reorganization.
 
 Scalability enhancements and micro-optimizations:
 
  - Improve code-patching scalability (Eric Dumazet)
  - Remove MFENCEs for X86_BUG_CLFLUSH_MONITOR (Andrew Cooper)
 
 CPU features enumeration updates:
 
  - Thorough reorganization and cleanup of CPUID parsing APIs (Ahmed S. Darwish)
  - Fix, refactor and clean up the cacheinfo code (Ahmed S. Darwish, Thomas Gleixner)
  - Update CPUID bitfields to x86-cpuid-db v2.3 (Ahmed S. Darwish)
 
 Memory management changes:
 
  - Allow temporary MMs when IRQs are on (Andy Lutomirski)
  - Opt-in to IRQs-off activate_mm() (Andy Lutomirski)
  - Simplify choose_new_asid() and generate better code (Borislav Petkov)
  - Simplify 32-bit PAE page table handling (Dave Hansen)
  - Always use dynamic memory layout (Kirill A. Shutemov)
  - Make SPARSEMEM_VMEMMAP the only memory model (Kirill A. Shutemov)
  - Make 5-level paging support unconditional (Kirill A. Shutemov)
  - Stop prefetching current->mm->mmap_lock on page faults (Mateusz Guzik)
  - Predict valid_user_address() returning true (Mateusz Guzik)
  - Consolidate initmem_init() (Mike Rapoport)
 
 FPU support and vector computing:
 
  - Enable Intel APX support (Chang S. Bae)
  - Reorgnize and clean up the xstate code (Chang S. Bae)
  - Make task_struct::thread constant size (Ingo Molnar)
  - Restore fpu_thread_struct_whitelist() to fix CONFIG_HARDENED_USERCOPY=y
    (Kees Cook)
  - Simplify the switch_fpu_prepare() + switch_fpu_finish() logic (Oleg Nesterov)
  - Always preserve non-user xfeatures/flags in __state_perm (Sean Christopherson)
 
 Microcode loader changes:
 
  - Help users notice when running old Intel microcode (Dave Hansen)
  - AMD: Do not return error when microcode update is not necessary (Annie Li)
  - AMD: Clean the cache if update did not load microcode (Boris Ostrovsky)
 
 Code patching (alternatives) changes:
 
  - Simplify, reorganize and clean up the x86 text-patching code (Ingo Molnar)
  - Make smp_text_poke_batch_process() subsume smp_text_poke_batch_finish()
    (Nikolay Borisov)
  - Refactor the {,un}use_temporary_mm() code (Peter Zijlstra)
 
 Debugging support:
 
  - Add early IDT and GDT loading to debug relocate_kernel() bugs (David Woodhouse)
  - Print the reason for the last reset on modern AMD CPUs (Yazen Ghannam)
  - Add AMD Zen debugging document (Mario Limonciello)
  - Fix opcode map (!REX2) superscript tags (Masami Hiramatsu)
  - Stop decoding i64 instructions in x86-64 mode at opcode (Masami Hiramatsu)
 
 CPU bugs and bug mitigations:
 
  - Remove X86_BUG_MMIO_UNKNOWN (Borislav Petkov)
  - Fix SRSO reporting on Zen1/2 with SMT disabled (Borislav Petkov)
  - Restructure and harmonize the various CPU bug mitigation methods
    (David Kaplan)
  - Fix spectre_v2 mitigation default on Intel (Pawan Gupta)
 
 MSR API:
 
  - Large MSR code and API cleanup (Xin Li)
  - In-kernel MSR API type cleanups and renames (Ingo Molnar)
 
 PKEYS:
 
  - Simplify PKRU update in signal frame (Chang S. Bae)
 
 NMI handling code:
 
  - Clean up, refactor and simplify the NMI handling code (Sohil Mehta)
  - Improve NMI duration console printouts (Sohil Mehta)
 
 Paravirt guests interface:
 
  - Restrict PARAVIRT_XXL to 64-bit only (Kirill A. Shutemov)
 
 SEV support:
 
  - Share the sev_secrets_pa value again (Tom Lendacky)
 
 x86 platform changes:
 
  - Introduce the <asm/amd/> header namespace (Ingo Molnar)
  - i2c: piix4, x86/platform: Move the SB800 PIIX4 FCH definitions to <asm/amd/fch.h>
    (Mario Limonciello)
 
 Fixes and cleanups:
 
  - x86 assembly code cleanups and fixes (Uros Bizjak)
 
  - Misc fixes and cleanups (Andi Kleen, Andy Lutomirski, Andy Shevchenko,
    Ard Biesheuvel, Bagas Sanjaya, Baoquan He, Borislav Petkov, Chang S. Bae,
    Chao Gao, Dan Williams, Dave Hansen, David Kaplan, David Woodhouse,
    Eric Biggers, Ingo Molnar, Josh Poimboeuf, Juergen Gross, Malaya Kumar Rout,
    Mario Limonciello, Nathan Chancellor, Oleg Nesterov, Pawan Gupta,
    Peter Zijlstra, Shivank Garg, Sohil Mehta, Thomas Gleixner, Uros Bizjak,
    Xin Li)
 
 Signed-off-by: Ingo Molnar <mingo@kernel.org>
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Merge tag 'x86-core-2025-05-25' of git://git.kernel.org/pub/scm/linux/kernel/git/tip/tip

Pull core x86 updates from Ingo Molnar:
 "Boot code changes:

   - A large series of changes to reorganize the x86 boot code into a
     better isolated and easier to maintain base of PIC early startup
     code in arch/x86/boot/startup/, by Ard Biesheuvel.

     Motivation & background:

  	| Since commit
  	|
  	|    c88d71508e ("x86/boot/64: Rewrite startup_64() in C")
  	|
  	| dated Jun 6 2017, we have been using C code on the boot path in a way
  	| that is not supported by the toolchain, i.e., to execute non-PIC C
  	| code from a mapping of memory that is different from the one provided
  	| to the linker. It should have been obvious at the time that this was a
  	| bad idea, given the need to sprinkle fixup_pointer() calls left and
  	| right to manipulate global variables (including non-pointer variables)
  	| without crashing.
  	|
  	| This C startup code has been expanding, and in particular, the SEV-SNP
  	| startup code has been expanding over the past couple of years, and
  	| grown many of these warts, where the C code needs to use special
  	| annotations or helpers to access global objects.

     This tree includes the first phase of this work-in-progress x86
     boot code reorganization.

  Scalability enhancements and micro-optimizations:

   - Improve code-patching scalability (Eric Dumazet)

   - Remove MFENCEs for X86_BUG_CLFLUSH_MONITOR (Andrew Cooper)

  CPU features enumeration updates:

   - Thorough reorganization and cleanup of CPUID parsing APIs (Ahmed S.
     Darwish)

   - Fix, refactor and clean up the cacheinfo code (Ahmed S. Darwish,
     Thomas Gleixner)

   - Update CPUID bitfields to x86-cpuid-db v2.3 (Ahmed S. Darwish)

  Memory management changes:

   - Allow temporary MMs when IRQs are on (Andy Lutomirski)

   - Opt-in to IRQs-off activate_mm() (Andy Lutomirski)

   - Simplify choose_new_asid() and generate better code (Borislav
     Petkov)

   - Simplify 32-bit PAE page table handling (Dave Hansen)

   - Always use dynamic memory layout (Kirill A. Shutemov)

   - Make SPARSEMEM_VMEMMAP the only memory model (Kirill A. Shutemov)

   - Make 5-level paging support unconditional (Kirill A. Shutemov)

   - Stop prefetching current->mm->mmap_lock on page faults (Mateusz
     Guzik)

   - Predict valid_user_address() returning true (Mateusz Guzik)

   - Consolidate initmem_init() (Mike Rapoport)

  FPU support and vector computing:

   - Enable Intel APX support (Chang S. Bae)

   - Reorgnize and clean up the xstate code (Chang S. Bae)

   - Make task_struct::thread constant size (Ingo Molnar)

   - Restore fpu_thread_struct_whitelist() to fix
     CONFIG_HARDENED_USERCOPY=y (Kees Cook)

   - Simplify the switch_fpu_prepare() + switch_fpu_finish() logic (Oleg
     Nesterov)

   - Always preserve non-user xfeatures/flags in __state_perm (Sean
     Christopherson)

  Microcode loader changes:

   - Help users notice when running old Intel microcode (Dave Hansen)

   - AMD: Do not return error when microcode update is not necessary
     (Annie Li)

   - AMD: Clean the cache if update did not load microcode (Boris
     Ostrovsky)

  Code patching (alternatives) changes:

   - Simplify, reorganize and clean up the x86 text-patching code (Ingo
     Molnar)

   - Make smp_text_poke_batch_process() subsume
     smp_text_poke_batch_finish() (Nikolay Borisov)

   - Refactor the {,un}use_temporary_mm() code (Peter Zijlstra)

  Debugging support:

   - Add early IDT and GDT loading to debug relocate_kernel() bugs
     (David Woodhouse)

   - Print the reason for the last reset on modern AMD CPUs (Yazen
     Ghannam)

   - Add AMD Zen debugging document (Mario Limonciello)

   - Fix opcode map (!REX2) superscript tags (Masami Hiramatsu)

   - Stop decoding i64 instructions in x86-64 mode at opcode (Masami
     Hiramatsu)

  CPU bugs and bug mitigations:

   - Remove X86_BUG_MMIO_UNKNOWN (Borislav Petkov)

   - Fix SRSO reporting on Zen1/2 with SMT disabled (Borislav Petkov)

   - Restructure and harmonize the various CPU bug mitigation methods
     (David Kaplan)

   - Fix spectre_v2 mitigation default on Intel (Pawan Gupta)

  MSR API:

   - Large MSR code and API cleanup (Xin Li)

   - In-kernel MSR API type cleanups and renames (Ingo Molnar)

  PKEYS:

   - Simplify PKRU update in signal frame (Chang S. Bae)

  NMI handling code:

   - Clean up, refactor and simplify the NMI handling code (Sohil Mehta)

   - Improve NMI duration console printouts (Sohil Mehta)

  Paravirt guests interface:

   - Restrict PARAVIRT_XXL to 64-bit only (Kirill A. Shutemov)

  SEV support:

   - Share the sev_secrets_pa value again (Tom Lendacky)

  x86 platform changes:

   - Introduce the <asm/amd/> header namespace (Ingo Molnar)

   - i2c: piix4, x86/platform: Move the SB800 PIIX4 FCH definitions to
     <asm/amd/fch.h> (Mario Limonciello)

  Fixes and cleanups:

   - x86 assembly code cleanups and fixes (Uros Bizjak)

   - Misc fixes and cleanups (Andi Kleen, Andy Lutomirski, Andy
     Shevchenko, Ard Biesheuvel, Bagas Sanjaya, Baoquan He, Borislav
     Petkov, Chang S. Bae, Chao Gao, Dan Williams, Dave Hansen, David
     Kaplan, David Woodhouse, Eric Biggers, Ingo Molnar, Josh Poimboeuf,
     Juergen Gross, Malaya Kumar Rout, Mario Limonciello, Nathan
     Chancellor, Oleg Nesterov, Pawan Gupta, Peter Zijlstra, Shivank
     Garg, Sohil Mehta, Thomas Gleixner, Uros Bizjak, Xin Li)"

* tag 'x86-core-2025-05-25' of git://git.kernel.org/pub/scm/linux/kernel/git/tip/tip: (331 commits)
  x86/bugs: Fix spectre_v2 mitigation default on Intel
  x86/bugs: Restructure ITS mitigation
  x86/xen/msr: Fix uninitialized variable 'err'
  x86/msr: Remove a superfluous inclusion of <asm/asm.h>
  x86/paravirt: Restrict PARAVIRT_XXL to 64-bit only
  x86/mm/64: Make 5-level paging support unconditional
  x86/mm/64: Make SPARSEMEM_VMEMMAP the only memory model
  x86/mm/64: Always use dynamic memory layout
  x86/bugs: Fix indentation due to ITS merge
  x86/cpuid: Rename hypervisor_cpuid_base()/for_each_possible_hypervisor_cpuid_base() to cpuid_base_hypervisor()/for_each_possible_cpuid_base_hypervisor()
  x86/cpu/intel: Rename CPUID(0x2) descriptors iterator parameter
  x86/cacheinfo: Rename CPUID(0x2) descriptors iterator parameter
  x86/cpuid: Rename cpuid_get_leaf_0x2_regs() to cpuid_leaf_0x2()
  x86/cpuid: Rename have_cpuid_p() to cpuid_feature()
  x86/cpuid: Set <asm/cpuid/api.h> as the main CPUID header
  x86/cpuid: Move CPUID(0x2) APIs into <cpuid/api.h>
  x86/msr: Add rdmsrl_on_cpu() compatibility wrapper
  x86/mm: Fix kernel-doc descriptions of various pgtable methods
  x86/asm-offsets: Export certain 'struct cpuinfo_x86' fields for 64-bit asm use too
  x86/boot: Defer initialization of VM space related global variables
  ...
2025-05-26 16:04:17 -07:00

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// SPDX-License-Identifier: GPL-2.0
#include <linux/bitops.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <linux/sched/clock.h>
#include <asm/cpu_entry_area.h>
#include <asm/debugreg.h>
#include <asm/perf_event.h>
#include <asm/tlbflush.h>
#include <asm/insn.h>
#include <asm/io.h>
#include <asm/msr.h>
#include <asm/timer.h>
#include "../perf_event.h"
/* Waste a full page so it can be mapped into the cpu_entry_area */
DEFINE_PER_CPU_PAGE_ALIGNED(struct debug_store, cpu_debug_store);
/* The size of a BTS record in bytes: */
#define BTS_RECORD_SIZE 24
#define PEBS_FIXUP_SIZE PAGE_SIZE
/*
* pebs_record_32 for p4 and core not supported
struct pebs_record_32 {
u32 flags, ip;
u32 ax, bc, cx, dx;
u32 si, di, bp, sp;
};
*/
union intel_x86_pebs_dse {
u64 val;
struct {
unsigned int ld_dse:4;
unsigned int ld_stlb_miss:1;
unsigned int ld_locked:1;
unsigned int ld_data_blk:1;
unsigned int ld_addr_blk:1;
unsigned int ld_reserved:24;
};
struct {
unsigned int st_l1d_hit:1;
unsigned int st_reserved1:3;
unsigned int st_stlb_miss:1;
unsigned int st_locked:1;
unsigned int st_reserved2:26;
};
struct {
unsigned int st_lat_dse:4;
unsigned int st_lat_stlb_miss:1;
unsigned int st_lat_locked:1;
unsigned int ld_reserved3:26;
};
struct {
unsigned int mtl_dse:5;
unsigned int mtl_locked:1;
unsigned int mtl_stlb_miss:1;
unsigned int mtl_fwd_blk:1;
unsigned int ld_reserved4:24;
};
struct {
unsigned int lnc_dse:8;
unsigned int ld_reserved5:2;
unsigned int lnc_stlb_miss:1;
unsigned int lnc_locked:1;
unsigned int lnc_data_blk:1;
unsigned int lnc_addr_blk:1;
unsigned int ld_reserved6:18;
};
};
/*
* Map PEBS Load Latency Data Source encodings to generic
* memory data source information
*/
#define P(a, b) PERF_MEM_S(a, b)
#define OP_LH (P(OP, LOAD) | P(LVL, HIT))
#define LEVEL(x) P(LVLNUM, x)
#define REM P(REMOTE, REMOTE)
#define SNOOP_NONE_MISS (P(SNOOP, NONE) | P(SNOOP, MISS))
/* Version for Sandy Bridge and later */
static u64 pebs_data_source[PERF_PEBS_DATA_SOURCE_MAX] = {
P(OP, LOAD) | P(LVL, MISS) | LEVEL(L3) | P(SNOOP, NA),/* 0x00:ukn L3 */
OP_LH | P(LVL, L1) | LEVEL(L1) | P(SNOOP, NONE), /* 0x01: L1 local */
OP_LH | P(LVL, LFB) | LEVEL(LFB) | P(SNOOP, NONE), /* 0x02: LFB hit */
OP_LH | P(LVL, L2) | LEVEL(L2) | P(SNOOP, NONE), /* 0x03: L2 hit */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, NONE), /* 0x04: L3 hit */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, MISS), /* 0x05: L3 hit, snoop miss */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HIT), /* 0x06: L3 hit, snoop hit */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM), /* 0x07: L3 hit, snoop hitm */
OP_LH | P(LVL, REM_CCE1) | REM | LEVEL(L3) | P(SNOOP, HIT), /* 0x08: L3 miss snoop hit */
OP_LH | P(LVL, REM_CCE1) | REM | LEVEL(L3) | P(SNOOP, HITM), /* 0x09: L3 miss snoop hitm*/
OP_LH | P(LVL, LOC_RAM) | LEVEL(RAM) | P(SNOOP, HIT), /* 0x0a: L3 miss, shared */
OP_LH | P(LVL, REM_RAM1) | REM | LEVEL(L3) | P(SNOOP, HIT), /* 0x0b: L3 miss, shared */
OP_LH | P(LVL, LOC_RAM) | LEVEL(RAM) | SNOOP_NONE_MISS, /* 0x0c: L3 miss, excl */
OP_LH | P(LVL, REM_RAM1) | LEVEL(RAM) | REM | SNOOP_NONE_MISS, /* 0x0d: L3 miss, excl */
OP_LH | P(LVL, IO) | LEVEL(NA) | P(SNOOP, NONE), /* 0x0e: I/O */
OP_LH | P(LVL, UNC) | LEVEL(NA) | P(SNOOP, NONE), /* 0x0f: uncached */
};
/* Patch up minor differences in the bits */
void __init intel_pmu_pebs_data_source_nhm(void)
{
pebs_data_source[0x05] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HIT);
pebs_data_source[0x06] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM);
pebs_data_source[0x07] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM);
}
static void __init __intel_pmu_pebs_data_source_skl(bool pmem, u64 *data_source)
{
u64 pmem_or_l4 = pmem ? LEVEL(PMEM) : LEVEL(L4);
data_source[0x08] = OP_LH | pmem_or_l4 | P(SNOOP, HIT);
data_source[0x09] = OP_LH | pmem_or_l4 | REM | P(SNOOP, HIT);
data_source[0x0b] = OP_LH | LEVEL(RAM) | REM | P(SNOOP, NONE);
data_source[0x0c] = OP_LH | LEVEL(ANY_CACHE) | REM | P(SNOOPX, FWD);
data_source[0x0d] = OP_LH | LEVEL(ANY_CACHE) | REM | P(SNOOP, HITM);
}
void __init intel_pmu_pebs_data_source_skl(bool pmem)
{
__intel_pmu_pebs_data_source_skl(pmem, pebs_data_source);
}
static void __init __intel_pmu_pebs_data_source_grt(u64 *data_source)
{
data_source[0x05] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HIT);
data_source[0x06] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM);
data_source[0x08] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOPX, FWD);
}
void __init intel_pmu_pebs_data_source_grt(void)
{
__intel_pmu_pebs_data_source_grt(pebs_data_source);
}
void __init intel_pmu_pebs_data_source_adl(void)
{
u64 *data_source;
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_CORE_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_skl(false, data_source);
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_ATOM_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_grt(data_source);
}
static void __init __intel_pmu_pebs_data_source_cmt(u64 *data_source)
{
data_source[0x07] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOPX, FWD);
data_source[0x08] = OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM);
data_source[0x0a] = OP_LH | P(LVL, LOC_RAM) | LEVEL(RAM) | P(SNOOP, NONE);
data_source[0x0b] = OP_LH | LEVEL(RAM) | REM | P(SNOOP, NONE);
data_source[0x0c] = OP_LH | LEVEL(RAM) | REM | P(SNOOPX, FWD);
data_source[0x0d] = OP_LH | LEVEL(RAM) | REM | P(SNOOP, HITM);
}
void __init intel_pmu_pebs_data_source_mtl(void)
{
u64 *data_source;
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_CORE_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_skl(false, data_source);
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_ATOM_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_cmt(data_source);
}
void __init intel_pmu_pebs_data_source_arl_h(void)
{
u64 *data_source;
intel_pmu_pebs_data_source_lnl();
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_TINY_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_cmt(data_source);
}
void __init intel_pmu_pebs_data_source_cmt(void)
{
__intel_pmu_pebs_data_source_cmt(pebs_data_source);
}
/* Version for Lion Cove and later */
static u64 lnc_pebs_data_source[PERF_PEBS_DATA_SOURCE_MAX] = {
P(OP, LOAD) | P(LVL, MISS) | LEVEL(L3) | P(SNOOP, NA), /* 0x00: ukn L3 */
OP_LH | P(LVL, L1) | LEVEL(L1) | P(SNOOP, NONE), /* 0x01: L1 hit */
OP_LH | P(LVL, L1) | LEVEL(L1) | P(SNOOP, NONE), /* 0x02: L1 hit */
OP_LH | P(LVL, LFB) | LEVEL(LFB) | P(SNOOP, NONE), /* 0x03: LFB/L1 Miss Handling Buffer hit */
0, /* 0x04: Reserved */
OP_LH | P(LVL, L2) | LEVEL(L2) | P(SNOOP, NONE), /* 0x05: L2 Hit */
OP_LH | LEVEL(L2_MHB) | P(SNOOP, NONE), /* 0x06: L2 Miss Handling Buffer Hit */
0, /* 0x07: Reserved */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, NONE), /* 0x08: L3 Hit */
0, /* 0x09: Reserved */
0, /* 0x0a: Reserved */
0, /* 0x0b: Reserved */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOPX, FWD), /* 0x0c: L3 Hit Snoop Fwd */
OP_LH | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM), /* 0x0d: L3 Hit Snoop HitM */
0, /* 0x0e: Reserved */
P(OP, LOAD) | P(LVL, MISS) | P(LVL, L3) | LEVEL(L3) | P(SNOOP, HITM), /* 0x0f: L3 Miss Snoop HitM */
OP_LH | LEVEL(MSC) | P(SNOOP, NONE), /* 0x10: Memory-side Cache Hit */
OP_LH | P(LVL, LOC_RAM) | LEVEL(RAM) | P(SNOOP, NONE), /* 0x11: Local Memory Hit */
};
void __init intel_pmu_pebs_data_source_lnl(void)
{
u64 *data_source;
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_CORE_IDX].pebs_data_source;
memcpy(data_source, lnc_pebs_data_source, sizeof(lnc_pebs_data_source));
data_source = x86_pmu.hybrid_pmu[X86_HYBRID_PMU_ATOM_IDX].pebs_data_source;
memcpy(data_source, pebs_data_source, sizeof(pebs_data_source));
__intel_pmu_pebs_data_source_cmt(data_source);
}
static u64 precise_store_data(u64 status)
{
union intel_x86_pebs_dse dse;
u64 val = P(OP, STORE) | P(SNOOP, NA) | P(LVL, L1) | P(TLB, L2);
dse.val = status;
/*
* bit 4: TLB access
* 1 = stored missed 2nd level TLB
*
* so it either hit the walker or the OS
* otherwise hit 2nd level TLB
*/
if (dse.st_stlb_miss)
val |= P(TLB, MISS);
else
val |= P(TLB, HIT);
/*
* bit 0: hit L1 data cache
* if not set, then all we know is that
* it missed L1D
*/
if (dse.st_l1d_hit)
val |= P(LVL, HIT);
else
val |= P(LVL, MISS);
/*
* bit 5: Locked prefix
*/
if (dse.st_locked)
val |= P(LOCK, LOCKED);
return val;
}
static u64 precise_datala_hsw(struct perf_event *event, u64 status)
{
union perf_mem_data_src dse;
dse.val = PERF_MEM_NA;
if (event->hw.flags & PERF_X86_EVENT_PEBS_ST_HSW)
dse.mem_op = PERF_MEM_OP_STORE;
else if (event->hw.flags & PERF_X86_EVENT_PEBS_LD_HSW)
dse.mem_op = PERF_MEM_OP_LOAD;
/*
* L1 info only valid for following events:
*
* MEM_UOPS_RETIRED.STLB_MISS_STORES
* MEM_UOPS_RETIRED.LOCK_STORES
* MEM_UOPS_RETIRED.SPLIT_STORES
* MEM_UOPS_RETIRED.ALL_STORES
*/
if (event->hw.flags & PERF_X86_EVENT_PEBS_ST_HSW) {
if (status & 1)
dse.mem_lvl = PERF_MEM_LVL_L1 | PERF_MEM_LVL_HIT;
else
dse.mem_lvl = PERF_MEM_LVL_L1 | PERF_MEM_LVL_MISS;
}
return dse.val;
}
static inline void pebs_set_tlb_lock(u64 *val, bool tlb, bool lock)
{
/*
* TLB access
* 0 = did not miss 2nd level TLB
* 1 = missed 2nd level TLB
*/
if (tlb)
*val |= P(TLB, MISS) | P(TLB, L2);
else
*val |= P(TLB, HIT) | P(TLB, L1) | P(TLB, L2);
/* locked prefix */
if (lock)
*val |= P(LOCK, LOCKED);
}
/* Retrieve the latency data for e-core of ADL */
static u64 __grt_latency_data(struct perf_event *event, u64 status,
u8 dse, bool tlb, bool lock, bool blk)
{
u64 val;
WARN_ON_ONCE(hybrid_pmu(event->pmu)->pmu_type == hybrid_big);
dse &= PERF_PEBS_DATA_SOURCE_GRT_MASK;
val = hybrid_var(event->pmu, pebs_data_source)[dse];
pebs_set_tlb_lock(&val, tlb, lock);
if (blk)
val |= P(BLK, DATA);
else
val |= P(BLK, NA);
return val;
}
u64 grt_latency_data(struct perf_event *event, u64 status)
{
union intel_x86_pebs_dse dse;
dse.val = status;
return __grt_latency_data(event, status, dse.ld_dse,
dse.ld_locked, dse.ld_stlb_miss,
dse.ld_data_blk);
}
/* Retrieve the latency data for e-core of MTL */
u64 cmt_latency_data(struct perf_event *event, u64 status)
{
union intel_x86_pebs_dse dse;
dse.val = status;
return __grt_latency_data(event, status, dse.mtl_dse,
dse.mtl_stlb_miss, dse.mtl_locked,
dse.mtl_fwd_blk);
}
static u64 lnc_latency_data(struct perf_event *event, u64 status)
{
union intel_x86_pebs_dse dse;
union perf_mem_data_src src;
u64 val;
dse.val = status;
/* LNC core latency data */
val = hybrid_var(event->pmu, pebs_data_source)[status & PERF_PEBS_DATA_SOURCE_MASK];
if (!val)
val = P(OP, LOAD) | LEVEL(NA) | P(SNOOP, NA);
if (dse.lnc_stlb_miss)
val |= P(TLB, MISS) | P(TLB, L2);
else
val |= P(TLB, HIT) | P(TLB, L1) | P(TLB, L2);
if (dse.lnc_locked)
val |= P(LOCK, LOCKED);
if (dse.lnc_data_blk)
val |= P(BLK, DATA);
if (dse.lnc_addr_blk)
val |= P(BLK, ADDR);
if (!dse.lnc_data_blk && !dse.lnc_addr_blk)
val |= P(BLK, NA);
src.val = val;
if (event->hw.flags & PERF_X86_EVENT_PEBS_ST_HSW)
src.mem_op = P(OP, STORE);
return src.val;
}
u64 lnl_latency_data(struct perf_event *event, u64 status)
{
struct x86_hybrid_pmu *pmu = hybrid_pmu(event->pmu);
if (pmu->pmu_type == hybrid_small)
return cmt_latency_data(event, status);
return lnc_latency_data(event, status);
}
u64 arl_h_latency_data(struct perf_event *event, u64 status)
{
struct x86_hybrid_pmu *pmu = hybrid_pmu(event->pmu);
if (pmu->pmu_type == hybrid_tiny)
return cmt_latency_data(event, status);
return lnl_latency_data(event, status);
}
static u64 load_latency_data(struct perf_event *event, u64 status)
{
union intel_x86_pebs_dse dse;
u64 val;
dse.val = status;
/*
* use the mapping table for bit 0-3
*/
val = hybrid_var(event->pmu, pebs_data_source)[dse.ld_dse];
/*
* Nehalem models do not support TLB, Lock infos
*/
if (x86_pmu.pebs_no_tlb) {
val |= P(TLB, NA) | P(LOCK, NA);
return val;
}
pebs_set_tlb_lock(&val, dse.ld_stlb_miss, dse.ld_locked);
/*
* Ice Lake and earlier models do not support block infos.
*/
if (!x86_pmu.pebs_block) {
val |= P(BLK, NA);
return val;
}
/*
* bit 6: load was blocked since its data could not be forwarded
* from a preceding store
*/
if (dse.ld_data_blk)
val |= P(BLK, DATA);
/*
* bit 7: load was blocked due to potential address conflict with
* a preceding store
*/
if (dse.ld_addr_blk)
val |= P(BLK, ADDR);
if (!dse.ld_data_blk && !dse.ld_addr_blk)
val |= P(BLK, NA);
return val;
}
static u64 store_latency_data(struct perf_event *event, u64 status)
{
union intel_x86_pebs_dse dse;
union perf_mem_data_src src;
u64 val;
dse.val = status;
/*
* use the mapping table for bit 0-3
*/
val = hybrid_var(event->pmu, pebs_data_source)[dse.st_lat_dse];
pebs_set_tlb_lock(&val, dse.st_lat_stlb_miss, dse.st_lat_locked);
val |= P(BLK, NA);
/*
* the pebs_data_source table is only for loads
* so override the mem_op to say STORE instead
*/
src.val = val;
src.mem_op = P(OP,STORE);
return src.val;
}
struct pebs_record_core {
u64 flags, ip;
u64 ax, bx, cx, dx;
u64 si, di, bp, sp;
u64 r8, r9, r10, r11;
u64 r12, r13, r14, r15;
};
struct pebs_record_nhm {
u64 flags, ip;
u64 ax, bx, cx, dx;
u64 si, di, bp, sp;
u64 r8, r9, r10, r11;
u64 r12, r13, r14, r15;
u64 status, dla, dse, lat;
};
/*
* Same as pebs_record_nhm, with two additional fields.
*/
struct pebs_record_hsw {
u64 flags, ip;
u64 ax, bx, cx, dx;
u64 si, di, bp, sp;
u64 r8, r9, r10, r11;
u64 r12, r13, r14, r15;
u64 status, dla, dse, lat;
u64 real_ip, tsx_tuning;
};
union hsw_tsx_tuning {
struct {
u32 cycles_last_block : 32,
hle_abort : 1,
rtm_abort : 1,
instruction_abort : 1,
non_instruction_abort : 1,
retry : 1,
data_conflict : 1,
capacity_writes : 1,
capacity_reads : 1;
};
u64 value;
};
#define PEBS_HSW_TSX_FLAGS 0xff00000000ULL
/* Same as HSW, plus TSC */
struct pebs_record_skl {
u64 flags, ip;
u64 ax, bx, cx, dx;
u64 si, di, bp, sp;
u64 r8, r9, r10, r11;
u64 r12, r13, r14, r15;
u64 status, dla, dse, lat;
u64 real_ip, tsx_tuning;
u64 tsc;
};
void init_debug_store_on_cpu(int cpu)
{
struct debug_store *ds = per_cpu(cpu_hw_events, cpu).ds;
if (!ds)
return;
wrmsr_on_cpu(cpu, MSR_IA32_DS_AREA,
(u32)((u64)(unsigned long)ds),
(u32)((u64)(unsigned long)ds >> 32));
}
void fini_debug_store_on_cpu(int cpu)
{
if (!per_cpu(cpu_hw_events, cpu).ds)
return;
wrmsr_on_cpu(cpu, MSR_IA32_DS_AREA, 0, 0);
}
static DEFINE_PER_CPU(void *, insn_buffer);
static void ds_update_cea(void *cea, void *addr, size_t size, pgprot_t prot)
{
unsigned long start = (unsigned long)cea;
phys_addr_t pa;
size_t msz = 0;
pa = virt_to_phys(addr);
preempt_disable();
for (; msz < size; msz += PAGE_SIZE, pa += PAGE_SIZE, cea += PAGE_SIZE)
cea_set_pte(cea, pa, prot);
/*
* This is a cross-CPU update of the cpu_entry_area, we must shoot down
* all TLB entries for it.
*/
flush_tlb_kernel_range(start, start + size);
preempt_enable();
}
static void ds_clear_cea(void *cea, size_t size)
{
unsigned long start = (unsigned long)cea;
size_t msz = 0;
preempt_disable();
for (; msz < size; msz += PAGE_SIZE, cea += PAGE_SIZE)
cea_set_pte(cea, 0, PAGE_NONE);
flush_tlb_kernel_range(start, start + size);
preempt_enable();
}
static void *dsalloc_pages(size_t size, gfp_t flags, int cpu)
{
unsigned int order = get_order(size);
int node = cpu_to_node(cpu);
struct page *page;
page = __alloc_pages_node(node, flags | __GFP_ZERO, order);
return page ? page_address(page) : NULL;
}
static void dsfree_pages(const void *buffer, size_t size)
{
if (buffer)
free_pages((unsigned long)buffer, get_order(size));
}
static int alloc_pebs_buffer(int cpu)
{
struct cpu_hw_events *hwev = per_cpu_ptr(&cpu_hw_events, cpu);
struct debug_store *ds = hwev->ds;
size_t bsiz = x86_pmu.pebs_buffer_size;
int max, node = cpu_to_node(cpu);
void *buffer, *insn_buff, *cea;
if (!x86_pmu.ds_pebs)
return 0;
buffer = dsalloc_pages(bsiz, GFP_KERNEL, cpu);
if (unlikely(!buffer))
return -ENOMEM;
/*
* HSW+ already provides us the eventing ip; no need to allocate this
* buffer then.
*/
if (x86_pmu.intel_cap.pebs_format < 2) {
insn_buff = kzalloc_node(PEBS_FIXUP_SIZE, GFP_KERNEL, node);
if (!insn_buff) {
dsfree_pages(buffer, bsiz);
return -ENOMEM;
}
per_cpu(insn_buffer, cpu) = insn_buff;
}
hwev->ds_pebs_vaddr = buffer;
/* Update the cpu entry area mapping */
cea = &get_cpu_entry_area(cpu)->cpu_debug_buffers.pebs_buffer;
ds->pebs_buffer_base = (unsigned long) cea;
ds_update_cea(cea, buffer, bsiz, PAGE_KERNEL);
ds->pebs_index = ds->pebs_buffer_base;
max = x86_pmu.pebs_record_size * (bsiz / x86_pmu.pebs_record_size);
ds->pebs_absolute_maximum = ds->pebs_buffer_base + max;
return 0;
}
static void release_pebs_buffer(int cpu)
{
struct cpu_hw_events *hwev = per_cpu_ptr(&cpu_hw_events, cpu);
void *cea;
if (!x86_pmu.ds_pebs)
return;
kfree(per_cpu(insn_buffer, cpu));
per_cpu(insn_buffer, cpu) = NULL;
/* Clear the fixmap */
cea = &get_cpu_entry_area(cpu)->cpu_debug_buffers.pebs_buffer;
ds_clear_cea(cea, x86_pmu.pebs_buffer_size);
dsfree_pages(hwev->ds_pebs_vaddr, x86_pmu.pebs_buffer_size);
hwev->ds_pebs_vaddr = NULL;
}
static int alloc_bts_buffer(int cpu)
{
struct cpu_hw_events *hwev = per_cpu_ptr(&cpu_hw_events, cpu);
struct debug_store *ds = hwev->ds;
void *buffer, *cea;
int max;
if (!x86_pmu.bts)
return 0;
buffer = dsalloc_pages(BTS_BUFFER_SIZE, GFP_KERNEL | __GFP_NOWARN, cpu);
if (unlikely(!buffer)) {
WARN_ONCE(1, "%s: BTS buffer allocation failure\n", __func__);
return -ENOMEM;
}
hwev->ds_bts_vaddr = buffer;
/* Update the fixmap */
cea = &get_cpu_entry_area(cpu)->cpu_debug_buffers.bts_buffer;
ds->bts_buffer_base = (unsigned long) cea;
ds_update_cea(cea, buffer, BTS_BUFFER_SIZE, PAGE_KERNEL);
ds->bts_index = ds->bts_buffer_base;
max = BTS_BUFFER_SIZE / BTS_RECORD_SIZE;
ds->bts_absolute_maximum = ds->bts_buffer_base +
max * BTS_RECORD_SIZE;
ds->bts_interrupt_threshold = ds->bts_absolute_maximum -
(max / 16) * BTS_RECORD_SIZE;
return 0;
}
static void release_bts_buffer(int cpu)
{
struct cpu_hw_events *hwev = per_cpu_ptr(&cpu_hw_events, cpu);
void *cea;
if (!x86_pmu.bts)
return;
/* Clear the fixmap */
cea = &get_cpu_entry_area(cpu)->cpu_debug_buffers.bts_buffer;
ds_clear_cea(cea, BTS_BUFFER_SIZE);
dsfree_pages(hwev->ds_bts_vaddr, BTS_BUFFER_SIZE);
hwev->ds_bts_vaddr = NULL;
}
static int alloc_ds_buffer(int cpu)
{
struct debug_store *ds = &get_cpu_entry_area(cpu)->cpu_debug_store;
memset(ds, 0, sizeof(*ds));
per_cpu(cpu_hw_events, cpu).ds = ds;
return 0;
}
static void release_ds_buffer(int cpu)
{
per_cpu(cpu_hw_events, cpu).ds = NULL;
}
void release_ds_buffers(void)
{
int cpu;
if (!x86_pmu.bts && !x86_pmu.ds_pebs)
return;
for_each_possible_cpu(cpu)
release_ds_buffer(cpu);
for_each_possible_cpu(cpu) {
/*
* Again, ignore errors from offline CPUs, they will no longer
* observe cpu_hw_events.ds and not program the DS_AREA when
* they come up.
*/
fini_debug_store_on_cpu(cpu);
}
for_each_possible_cpu(cpu) {
if (x86_pmu.ds_pebs)
release_pebs_buffer(cpu);
release_bts_buffer(cpu);
}
}
void reserve_ds_buffers(void)
{
int bts_err = 0, pebs_err = 0;
int cpu;
x86_pmu.bts_active = 0;
if (x86_pmu.ds_pebs)
x86_pmu.pebs_active = 0;
if (!x86_pmu.bts && !x86_pmu.ds_pebs)
return;
if (!x86_pmu.bts)
bts_err = 1;
if (!x86_pmu.ds_pebs)
pebs_err = 1;
for_each_possible_cpu(cpu) {
if (alloc_ds_buffer(cpu)) {
bts_err = 1;
pebs_err = 1;
}
if (!bts_err && alloc_bts_buffer(cpu))
bts_err = 1;
if (x86_pmu.ds_pebs && !pebs_err &&
alloc_pebs_buffer(cpu))
pebs_err = 1;
if (bts_err && pebs_err)
break;
}
if (bts_err) {
for_each_possible_cpu(cpu)
release_bts_buffer(cpu);
}
if (x86_pmu.ds_pebs && pebs_err) {
for_each_possible_cpu(cpu)
release_pebs_buffer(cpu);
}
if (bts_err && pebs_err) {
for_each_possible_cpu(cpu)
release_ds_buffer(cpu);
} else {
if (x86_pmu.bts && !bts_err)
x86_pmu.bts_active = 1;
if (x86_pmu.ds_pebs && !pebs_err)
x86_pmu.pebs_active = 1;
for_each_possible_cpu(cpu) {
/*
* Ignores wrmsr_on_cpu() errors for offline CPUs they
* will get this call through intel_pmu_cpu_starting().
*/
init_debug_store_on_cpu(cpu);
}
}
}
/*
* BTS
*/
struct event_constraint bts_constraint =
EVENT_CONSTRAINT(0, 1ULL << INTEL_PMC_IDX_FIXED_BTS, 0);
void intel_pmu_enable_bts(u64 config)
{
unsigned long debugctlmsr;
debugctlmsr = get_debugctlmsr();
debugctlmsr |= DEBUGCTLMSR_TR;
debugctlmsr |= DEBUGCTLMSR_BTS;
if (config & ARCH_PERFMON_EVENTSEL_INT)
debugctlmsr |= DEBUGCTLMSR_BTINT;
if (!(config & ARCH_PERFMON_EVENTSEL_OS))
debugctlmsr |= DEBUGCTLMSR_BTS_OFF_OS;
if (!(config & ARCH_PERFMON_EVENTSEL_USR))
debugctlmsr |= DEBUGCTLMSR_BTS_OFF_USR;
update_debugctlmsr(debugctlmsr);
}
void intel_pmu_disable_bts(void)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
unsigned long debugctlmsr;
if (!cpuc->ds)
return;
debugctlmsr = get_debugctlmsr();
debugctlmsr &=
~(DEBUGCTLMSR_TR | DEBUGCTLMSR_BTS | DEBUGCTLMSR_BTINT |
DEBUGCTLMSR_BTS_OFF_OS | DEBUGCTLMSR_BTS_OFF_USR);
update_debugctlmsr(debugctlmsr);
}
int intel_pmu_drain_bts_buffer(void)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct debug_store *ds = cpuc->ds;
struct bts_record {
u64 from;
u64 to;
u64 flags;
};
struct perf_event *event = cpuc->events[INTEL_PMC_IDX_FIXED_BTS];
struct bts_record *at, *base, *top;
struct perf_output_handle handle;
struct perf_event_header header;
struct perf_sample_data data;
unsigned long skip = 0;
struct pt_regs regs;
if (!event)
return 0;
if (!x86_pmu.bts_active)
return 0;
base = (struct bts_record *)(unsigned long)ds->bts_buffer_base;
top = (struct bts_record *)(unsigned long)ds->bts_index;
if (top <= base)
return 0;
memset(&regs, 0, sizeof(regs));
ds->bts_index = ds->bts_buffer_base;
perf_sample_data_init(&data, 0, event->hw.last_period);
/*
* BTS leaks kernel addresses in branches across the cpl boundary,
* such as traps or system calls, so unless the user is asking for
* kernel tracing (and right now it's not possible), we'd need to
* filter them out. But first we need to count how many of those we
* have in the current batch. This is an extra O(n) pass, however,
* it's much faster than the other one especially considering that
* n <= 2560 (BTS_BUFFER_SIZE / BTS_RECORD_SIZE * 15/16; see the
* alloc_bts_buffer()).
*/
for (at = base; at < top; at++) {
/*
* Note that right now *this* BTS code only works if
* attr::exclude_kernel is set, but let's keep this extra
* check here in case that changes.
*/
if (event->attr.exclude_kernel &&
(kernel_ip(at->from) || kernel_ip(at->to)))
skip++;
}
/*
* Prepare a generic sample, i.e. fill in the invariant fields.
* We will overwrite the from and to address before we output
* the sample.
*/
rcu_read_lock();
perf_prepare_sample(&data, event, &regs);
perf_prepare_header(&header, &data, event, &regs);
if (perf_output_begin(&handle, &data, event,
header.size * (top - base - skip)))
goto unlock;
for (at = base; at < top; at++) {
/* Filter out any records that contain kernel addresses. */
if (event->attr.exclude_kernel &&
(kernel_ip(at->from) || kernel_ip(at->to)))
continue;
data.ip = at->from;
data.addr = at->to;
perf_output_sample(&handle, &header, &data, event);
}
perf_output_end(&handle);
/* There's new data available. */
event->hw.interrupts++;
event->pending_kill = POLL_IN;
unlock:
rcu_read_unlock();
return 1;
}
void intel_pmu_drain_pebs_buffer(void)
{
struct perf_sample_data data;
static_call(x86_pmu_drain_pebs)(NULL, &data);
}
/*
* PEBS
*/
struct event_constraint intel_core2_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x00c0, 0x1), /* INST_RETIRED.ANY */
INTEL_FLAGS_UEVENT_CONSTRAINT(0xfec1, 0x1), /* X87_OPS_RETIRED.ANY */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x00c5, 0x1), /* BR_INST_RETIRED.MISPRED */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x1fc7, 0x1), /* SIMD_INST_RETURED.ANY */
INTEL_FLAGS_EVENT_CONSTRAINT(0xcb, 0x1), /* MEM_LOAD_RETIRED.* */
/* INST_RETIRED.ANY_P, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x01),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_atom_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x00c0, 0x1), /* INST_RETIRED.ANY */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x00c5, 0x1), /* MISPREDICTED_BRANCH_RETIRED */
INTEL_FLAGS_EVENT_CONSTRAINT(0xcb, 0x1), /* MEM_LOAD_RETIRED.* */
/* INST_RETIRED.ANY_P, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x01),
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0x1),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_slm_pebs_event_constraints[] = {
/* INST_RETIRED.ANY_P, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x1),
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0x1),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_glm_pebs_event_constraints[] = {
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0x1),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_grt_pebs_event_constraints[] = {
/* Allow all events as PEBS with no flags */
INTEL_HYBRID_LAT_CONSTRAINT(0x5d0, 0x3),
INTEL_HYBRID_LAT_CONSTRAINT(0x6d0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_nehalem_pebs_event_constraints[] = {
INTEL_PLD_CONSTRAINT(0x100b, 0xf), /* MEM_INST_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0x0f, 0xf), /* MEM_UNCORE_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x010c, 0xf), /* MEM_STORE_RETIRED.DTLB_MISS */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc0, 0xf), /* INST_RETIRED.ANY */
INTEL_EVENT_CONSTRAINT(0xc2, 0xf), /* UOPS_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc4, 0xf), /* BR_INST_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x02c5, 0xf), /* BR_MISP_RETIRED.NEAR_CALL */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc7, 0xf), /* SSEX_UOPS_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x20c8, 0xf), /* ITLB_MISS_RETIRED */
INTEL_FLAGS_EVENT_CONSTRAINT(0xcb, 0xf), /* MEM_LOAD_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xf7, 0xf), /* FP_ASSIST.* */
/* INST_RETIRED.ANY_P, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x0f),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_westmere_pebs_event_constraints[] = {
INTEL_PLD_CONSTRAINT(0x100b, 0xf), /* MEM_INST_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0x0f, 0xf), /* MEM_UNCORE_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x010c, 0xf), /* MEM_STORE_RETIRED.DTLB_MISS */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc0, 0xf), /* INSTR_RETIRED.* */
INTEL_EVENT_CONSTRAINT(0xc2, 0xf), /* UOPS_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc4, 0xf), /* BR_INST_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc5, 0xf), /* BR_MISP_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xc7, 0xf), /* SSEX_UOPS_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x20c8, 0xf), /* ITLB_MISS_RETIRED */
INTEL_FLAGS_EVENT_CONSTRAINT(0xcb, 0xf), /* MEM_LOAD_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xf7, 0xf), /* FP_ASSIST.* */
/* INST_RETIRED.ANY_P, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x0f),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_snb_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x01c0, 0x2), /* INST_RETIRED.PRECDIST */
INTEL_PLD_CONSTRAINT(0x01cd, 0x8), /* MEM_TRANS_RETIRED.LAT_ABOVE_THR */
INTEL_PST_CONSTRAINT(0x02cd, 0x8), /* MEM_TRANS_RETIRED.PRECISE_STORES */
/* UOPS_RETIRED.ALL, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c2, 0xf),
INTEL_EXCLEVT_CONSTRAINT(0xd0, 0xf), /* MEM_UOP_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd1, 0xf), /* MEM_LOAD_UOPS_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd2, 0xf), /* MEM_LOAD_UOPS_LLC_HIT_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd3, 0xf), /* MEM_LOAD_UOPS_LLC_MISS_RETIRED.* */
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_ivb_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x01c0, 0x2), /* INST_RETIRED.PRECDIST */
INTEL_PLD_CONSTRAINT(0x01cd, 0x8), /* MEM_TRANS_RETIRED.LAT_ABOVE_THR */
INTEL_PST_CONSTRAINT(0x02cd, 0x8), /* MEM_TRANS_RETIRED.PRECISE_STORES */
/* UOPS_RETIRED.ALL, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c2, 0xf),
/* INST_RETIRED.PREC_DIST, inv=1, cmask=16 (cycles:ppp). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c0, 0x2),
INTEL_EXCLEVT_CONSTRAINT(0xd0, 0xf), /* MEM_UOP_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd1, 0xf), /* MEM_LOAD_UOPS_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd2, 0xf), /* MEM_LOAD_UOPS_LLC_HIT_RETIRED.* */
INTEL_EXCLEVT_CONSTRAINT(0xd3, 0xf), /* MEM_LOAD_UOPS_LLC_MISS_RETIRED.* */
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_hsw_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x01c0, 0x2), /* INST_RETIRED.PRECDIST */
INTEL_PLD_CONSTRAINT(0x01cd, 0xf), /* MEM_TRANS_RETIRED.* */
/* UOPS_RETIRED.ALL, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c2, 0xf),
/* INST_RETIRED.PREC_DIST, inv=1, cmask=16 (cycles:ppp). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c0, 0x2),
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_NA(0x01c2, 0xf), /* UOPS_RETIRED.ALL */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XLD(0x11d0, 0xf), /* MEM_UOPS_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XLD(0x21d0, 0xf), /* MEM_UOPS_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XLD(0x41d0, 0xf), /* MEM_UOPS_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XLD(0x81d0, 0xf), /* MEM_UOPS_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XST(0x12d0, 0xf), /* MEM_UOPS_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XST(0x42d0, 0xf), /* MEM_UOPS_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_XST(0x82d0, 0xf), /* MEM_UOPS_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_XLD(0xd1, 0xf), /* MEM_LOAD_UOPS_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_XLD(0xd2, 0xf), /* MEM_LOAD_UOPS_L3_HIT_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_XLD(0xd3, 0xf), /* MEM_LOAD_UOPS_L3_MISS_RETIRED.* */
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_bdw_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x01c0, 0x2), /* INST_RETIRED.PRECDIST */
INTEL_PLD_CONSTRAINT(0x01cd, 0xf), /* MEM_TRANS_RETIRED.* */
/* UOPS_RETIRED.ALL, inv=1, cmask=16 (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c2, 0xf),
/* INST_RETIRED.PREC_DIST, inv=1, cmask=16 (cycles:ppp). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c0, 0x2),
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_NA(0x01c2, 0xf), /* UOPS_RETIRED.ALL */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x11d0, 0xf), /* MEM_UOPS_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x21d0, 0xf), /* MEM_UOPS_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x41d0, 0xf), /* MEM_UOPS_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x81d0, 0xf), /* MEM_UOPS_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x12d0, 0xf), /* MEM_UOPS_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x42d0, 0xf), /* MEM_UOPS_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x82d0, 0xf), /* MEM_UOPS_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd1, 0xf), /* MEM_LOAD_UOPS_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd2, 0xf), /* MEM_LOAD_UOPS_L3_HIT_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd3, 0xf), /* MEM_LOAD_UOPS_L3_MISS_RETIRED.* */
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_skl_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x1c0, 0x2), /* INST_RETIRED.PREC_DIST */
/* INST_RETIRED.PREC_DIST, inv=1, cmask=16 (cycles:ppp). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108001c0, 0x2),
/* INST_RETIRED.TOTAL_CYCLES_PS (inv=1, cmask=16) (cycles:p). */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x108000c0, 0x0f),
INTEL_PLD_CONSTRAINT(0x1cd, 0xf), /* MEM_TRANS_RETIRED.* */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x11d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x12d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x21d0, 0xf), /* MEM_INST_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x22d0, 0xf), /* MEM_INST_RETIRED.LOCK_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x41d0, 0xf), /* MEM_INST_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x42d0, 0xf), /* MEM_INST_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x81d0, 0xf), /* MEM_INST_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x82d0, 0xf), /* MEM_INST_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd1, 0xf), /* MEM_LOAD_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd2, 0xf), /* MEM_LOAD_L3_HIT_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD(0xd3, 0xf), /* MEM_LOAD_L3_MISS_RETIRED.* */
/* Allow all events as PEBS with no flags */
INTEL_ALL_EVENT_CONSTRAINT(0, 0xf),
EVENT_CONSTRAINT_END
};
struct event_constraint intel_icl_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x01c0, 0x100000000ULL), /* old INST_RETIRED.PREC_DIST */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x0100, 0x100000000ULL), /* INST_RETIRED.PREC_DIST */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x0400, 0x800000000ULL), /* SLOTS */
INTEL_PLD_CONSTRAINT(0x1cd, 0xff), /* MEM_TRANS_RETIRED.LOAD_LATENCY */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x11d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x12d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x21d0, 0xf), /* MEM_INST_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x41d0, 0xf), /* MEM_INST_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x42d0, 0xf), /* MEM_INST_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x81d0, 0xf), /* MEM_INST_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x82d0, 0xf), /* MEM_INST_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD_RANGE(0xd1, 0xd4, 0xf), /* MEM_LOAD_*_RETIRED.* */
INTEL_FLAGS_EVENT_CONSTRAINT(0xd0, 0xf), /* MEM_INST_RETIRED.* */
/*
* Everything else is handled by PMU_FL_PEBS_ALL, because we
* need the full constraints from the main table.
*/
EVENT_CONSTRAINT_END
};
struct event_constraint intel_glc_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x100, 0x100000000ULL), /* INST_RETIRED.PREC_DIST */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x0400, 0x800000000ULL),
INTEL_FLAGS_EVENT_CONSTRAINT(0xc0, 0xfe),
INTEL_PLD_CONSTRAINT(0x1cd, 0xfe),
INTEL_PSD_CONSTRAINT(0x2cd, 0x1),
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x11d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x12d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x21d0, 0xf), /* MEM_INST_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x41d0, 0xf), /* MEM_INST_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x42d0, 0xf), /* MEM_INST_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x81d0, 0xf), /* MEM_INST_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x82d0, 0xf), /* MEM_INST_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD_RANGE(0xd1, 0xd4, 0xf),
INTEL_FLAGS_EVENT_CONSTRAINT(0xd0, 0xf),
/*
* Everything else is handled by PMU_FL_PEBS_ALL, because we
* need the full constraints from the main table.
*/
EVENT_CONSTRAINT_END
};
struct event_constraint intel_lnc_pebs_event_constraints[] = {
INTEL_FLAGS_UEVENT_CONSTRAINT(0x100, 0x100000000ULL), /* INST_RETIRED.PREC_DIST */
INTEL_FLAGS_UEVENT_CONSTRAINT(0x0400, 0x800000000ULL),
INTEL_HYBRID_LDLAT_CONSTRAINT(0x1cd, 0x3fc),
INTEL_HYBRID_STLAT_CONSTRAINT(0x2cd, 0x3),
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x11d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x12d0, 0xf), /* MEM_INST_RETIRED.STLB_MISS_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x21d0, 0xf), /* MEM_INST_RETIRED.LOCK_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x41d0, 0xf), /* MEM_INST_RETIRED.SPLIT_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x42d0, 0xf), /* MEM_INST_RETIRED.SPLIT_STORES */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_LD(0x81d0, 0xf), /* MEM_INST_RETIRED.ALL_LOADS */
INTEL_FLAGS_UEVENT_CONSTRAINT_DATALA_ST(0x82d0, 0xf), /* MEM_INST_RETIRED.ALL_STORES */
INTEL_FLAGS_EVENT_CONSTRAINT_DATALA_LD_RANGE(0xd1, 0xd4, 0xf),
INTEL_FLAGS_EVENT_CONSTRAINT(0xd0, 0xf),
/*
* Everything else is handled by PMU_FL_PEBS_ALL, because we
* need the full constraints from the main table.
*/
EVENT_CONSTRAINT_END
};
struct event_constraint *intel_pebs_constraints(struct perf_event *event)
{
struct event_constraint *pebs_constraints = hybrid(event->pmu, pebs_constraints);
struct event_constraint *c;
if (!event->attr.precise_ip)
return NULL;
if (pebs_constraints) {
for_each_event_constraint(c, pebs_constraints) {
if (constraint_match(c, event->hw.config)) {
event->hw.flags |= c->flags;
return c;
}
}
}
/*
* Extended PEBS support
* Makes the PEBS code search the normal constraints.
*/
if (x86_pmu.flags & PMU_FL_PEBS_ALL)
return NULL;
return &emptyconstraint;
}
/*
* We need the sched_task callback even for per-cpu events when we use
* the large interrupt threshold, such that we can provide PID and TID
* to PEBS samples.
*/
static inline bool pebs_needs_sched_cb(struct cpu_hw_events *cpuc)
{
if (cpuc->n_pebs == cpuc->n_pebs_via_pt)
return false;
return cpuc->n_pebs && (cpuc->n_pebs == cpuc->n_large_pebs);
}
void intel_pmu_pebs_sched_task(struct perf_event_pmu_context *pmu_ctx, bool sched_in)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
if (!sched_in && pebs_needs_sched_cb(cpuc))
intel_pmu_drain_pebs_buffer();
}
static inline void pebs_update_threshold(struct cpu_hw_events *cpuc)
{
struct debug_store *ds = cpuc->ds;
int max_pebs_events = intel_pmu_max_num_pebs(cpuc->pmu);
u64 threshold;
int reserved;
if (cpuc->n_pebs_via_pt)
return;
if (x86_pmu.flags & PMU_FL_PEBS_ALL)
reserved = max_pebs_events + x86_pmu_max_num_counters_fixed(cpuc->pmu);
else
reserved = max_pebs_events;
if (cpuc->n_pebs == cpuc->n_large_pebs) {
threshold = ds->pebs_absolute_maximum -
reserved * cpuc->pebs_record_size;
} else {
threshold = ds->pebs_buffer_base + cpuc->pebs_record_size;
}
ds->pebs_interrupt_threshold = threshold;
}
#define PEBS_DATACFG_CNTRS(x) \
((x >> PEBS_DATACFG_CNTR_SHIFT) & PEBS_DATACFG_CNTR_MASK)
#define PEBS_DATACFG_CNTR_BIT(x) \
(((1ULL << x) & PEBS_DATACFG_CNTR_MASK) << PEBS_DATACFG_CNTR_SHIFT)
#define PEBS_DATACFG_FIX(x) \
((x >> PEBS_DATACFG_FIX_SHIFT) & PEBS_DATACFG_FIX_MASK)
#define PEBS_DATACFG_FIX_BIT(x) \
(((1ULL << (x)) & PEBS_DATACFG_FIX_MASK) \
<< PEBS_DATACFG_FIX_SHIFT)
static void adaptive_pebs_record_size_update(void)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
u64 pebs_data_cfg = cpuc->pebs_data_cfg;
int sz = sizeof(struct pebs_basic);
if (pebs_data_cfg & PEBS_DATACFG_MEMINFO)
sz += sizeof(struct pebs_meminfo);
if (pebs_data_cfg & PEBS_DATACFG_GP)
sz += sizeof(struct pebs_gprs);
if (pebs_data_cfg & PEBS_DATACFG_XMMS)
sz += sizeof(struct pebs_xmm);
if (pebs_data_cfg & PEBS_DATACFG_LBRS)
sz += x86_pmu.lbr_nr * sizeof(struct lbr_entry);
if (pebs_data_cfg & (PEBS_DATACFG_METRICS | PEBS_DATACFG_CNTR)) {
sz += sizeof(struct pebs_cntr_header);
/* Metrics base and Metrics Data */
if (pebs_data_cfg & PEBS_DATACFG_METRICS)
sz += 2 * sizeof(u64);
if (pebs_data_cfg & PEBS_DATACFG_CNTR) {
sz += (hweight64(PEBS_DATACFG_CNTRS(pebs_data_cfg)) +
hweight64(PEBS_DATACFG_FIX(pebs_data_cfg))) *
sizeof(u64);
}
}
cpuc->pebs_record_size = sz;
}
static void __intel_pmu_pebs_update_cfg(struct perf_event *event,
int idx, u64 *pebs_data_cfg)
{
if (is_metric_event(event)) {
*pebs_data_cfg |= PEBS_DATACFG_METRICS;
return;
}
*pebs_data_cfg |= PEBS_DATACFG_CNTR;
if (idx >= INTEL_PMC_IDX_FIXED)
*pebs_data_cfg |= PEBS_DATACFG_FIX_BIT(idx - INTEL_PMC_IDX_FIXED);
else
*pebs_data_cfg |= PEBS_DATACFG_CNTR_BIT(idx);
}
void intel_pmu_pebs_late_setup(struct cpu_hw_events *cpuc)
{
struct perf_event *event;
u64 pebs_data_cfg = 0;
int i;
for (i = 0; i < cpuc->n_events; i++) {
event = cpuc->event_list[i];
if (!is_pebs_counter_event_group(event))
continue;
__intel_pmu_pebs_update_cfg(event, cpuc->assign[i], &pebs_data_cfg);
}
if (pebs_data_cfg & ~cpuc->pebs_data_cfg)
cpuc->pebs_data_cfg |= pebs_data_cfg | PEBS_UPDATE_DS_SW;
}
#define PERF_PEBS_MEMINFO_TYPE (PERF_SAMPLE_ADDR | PERF_SAMPLE_DATA_SRC | \
PERF_SAMPLE_PHYS_ADDR | \
PERF_SAMPLE_WEIGHT_TYPE | \
PERF_SAMPLE_TRANSACTION | \
PERF_SAMPLE_DATA_PAGE_SIZE)
static u64 pebs_update_adaptive_cfg(struct perf_event *event)
{
struct perf_event_attr *attr = &event->attr;
u64 sample_type = attr->sample_type;
u64 pebs_data_cfg = 0;
bool gprs, tsx_weight;
if (!(sample_type & ~(PERF_SAMPLE_IP|PERF_SAMPLE_TIME)) &&
attr->precise_ip > 1)
return pebs_data_cfg;
if (sample_type & PERF_PEBS_MEMINFO_TYPE)
pebs_data_cfg |= PEBS_DATACFG_MEMINFO;
/*
* We need GPRs when:
* + user requested them
* + precise_ip < 2 for the non event IP
* + For RTM TSX weight we need GPRs for the abort code.
*/
gprs = ((sample_type & PERF_SAMPLE_REGS_INTR) &&
(attr->sample_regs_intr & PEBS_GP_REGS)) ||
((sample_type & PERF_SAMPLE_REGS_USER) &&
(attr->sample_regs_user & PEBS_GP_REGS));
tsx_weight = (sample_type & PERF_SAMPLE_WEIGHT_TYPE) &&
((attr->config & INTEL_ARCH_EVENT_MASK) ==
x86_pmu.rtm_abort_event);
if (gprs || (attr->precise_ip < 2) || tsx_weight)
pebs_data_cfg |= PEBS_DATACFG_GP;
if ((sample_type & PERF_SAMPLE_REGS_INTR) &&
(attr->sample_regs_intr & PERF_REG_EXTENDED_MASK))
pebs_data_cfg |= PEBS_DATACFG_XMMS;
if (sample_type & PERF_SAMPLE_BRANCH_STACK) {
/*
* For now always log all LBRs. Could configure this
* later.
*/
pebs_data_cfg |= PEBS_DATACFG_LBRS |
((x86_pmu.lbr_nr-1) << PEBS_DATACFG_LBR_SHIFT);
}
return pebs_data_cfg;
}
static void
pebs_update_state(bool needed_cb, struct cpu_hw_events *cpuc,
struct perf_event *event, bool add)
{
struct pmu *pmu = event->pmu;
/*
* Make sure we get updated with the first PEBS event.
* During removal, ->pebs_data_cfg is still valid for
* the last PEBS event. Don't clear it.
*/
if ((cpuc->n_pebs == 1) && add)
cpuc->pebs_data_cfg = PEBS_UPDATE_DS_SW;
if (needed_cb != pebs_needs_sched_cb(cpuc)) {
if (!needed_cb)
perf_sched_cb_inc(pmu);
else
perf_sched_cb_dec(pmu);
cpuc->pebs_data_cfg |= PEBS_UPDATE_DS_SW;
}
/*
* The PEBS record doesn't shrink on pmu::del(). Doing so would require
* iterating all remaining PEBS events to reconstruct the config.
*/
if (x86_pmu.intel_cap.pebs_baseline && add) {
u64 pebs_data_cfg;
pebs_data_cfg = pebs_update_adaptive_cfg(event);
/*
* Be sure to update the thresholds when we change the record.
*/
if (pebs_data_cfg & ~cpuc->pebs_data_cfg)
cpuc->pebs_data_cfg |= pebs_data_cfg | PEBS_UPDATE_DS_SW;
}
}
void intel_pmu_pebs_add(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct hw_perf_event *hwc = &event->hw;
bool needed_cb = pebs_needs_sched_cb(cpuc);
cpuc->n_pebs++;
if (hwc->flags & PERF_X86_EVENT_LARGE_PEBS)
cpuc->n_large_pebs++;
if (hwc->flags & PERF_X86_EVENT_PEBS_VIA_PT)
cpuc->n_pebs_via_pt++;
pebs_update_state(needed_cb, cpuc, event, true);
}
static void intel_pmu_pebs_via_pt_disable(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
if (!is_pebs_pt(event))
return;
if (!(cpuc->pebs_enabled & ~PEBS_VIA_PT_MASK))
cpuc->pebs_enabled &= ~PEBS_VIA_PT_MASK;
}
static void intel_pmu_pebs_via_pt_enable(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct hw_perf_event *hwc = &event->hw;
struct debug_store *ds = cpuc->ds;
u64 value = ds->pebs_event_reset[hwc->idx];
u32 base = MSR_RELOAD_PMC0;
unsigned int idx = hwc->idx;
if (!is_pebs_pt(event))
return;
if (!(event->hw.flags & PERF_X86_EVENT_LARGE_PEBS))
cpuc->pebs_enabled |= PEBS_PMI_AFTER_EACH_RECORD;
cpuc->pebs_enabled |= PEBS_OUTPUT_PT;
if (hwc->idx >= INTEL_PMC_IDX_FIXED) {
base = MSR_RELOAD_FIXED_CTR0;
idx = hwc->idx - INTEL_PMC_IDX_FIXED;
if (x86_pmu.intel_cap.pebs_format < 5)
value = ds->pebs_event_reset[MAX_PEBS_EVENTS_FMT4 + idx];
else
value = ds->pebs_event_reset[MAX_PEBS_EVENTS + idx];
}
wrmsrq(base + idx, value);
}
static inline void intel_pmu_drain_large_pebs(struct cpu_hw_events *cpuc)
{
if (cpuc->n_pebs == cpuc->n_large_pebs &&
cpuc->n_pebs != cpuc->n_pebs_via_pt)
intel_pmu_drain_pebs_buffer();
}
void intel_pmu_pebs_enable(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
u64 pebs_data_cfg = cpuc->pebs_data_cfg & ~PEBS_UPDATE_DS_SW;
struct hw_perf_event *hwc = &event->hw;
struct debug_store *ds = cpuc->ds;
unsigned int idx = hwc->idx;
hwc->config &= ~ARCH_PERFMON_EVENTSEL_INT;
cpuc->pebs_enabled |= 1ULL << hwc->idx;
if ((event->hw.flags & PERF_X86_EVENT_PEBS_LDLAT) && (x86_pmu.version < 5))
cpuc->pebs_enabled |= 1ULL << (hwc->idx + 32);
else if (event->hw.flags & PERF_X86_EVENT_PEBS_ST)
cpuc->pebs_enabled |= 1ULL << 63;
if (x86_pmu.intel_cap.pebs_baseline) {
hwc->config |= ICL_EVENTSEL_ADAPTIVE;
if (pebs_data_cfg != cpuc->active_pebs_data_cfg) {
/*
* drain_pebs() assumes uniform record size;
* hence we need to drain when changing said
* size.
*/
intel_pmu_drain_pebs_buffer();
adaptive_pebs_record_size_update();
wrmsrq(MSR_PEBS_DATA_CFG, pebs_data_cfg);
cpuc->active_pebs_data_cfg = pebs_data_cfg;
}
}
if (cpuc->pebs_data_cfg & PEBS_UPDATE_DS_SW) {
cpuc->pebs_data_cfg = pebs_data_cfg;
pebs_update_threshold(cpuc);
}
if (idx >= INTEL_PMC_IDX_FIXED) {
if (x86_pmu.intel_cap.pebs_format < 5)
idx = MAX_PEBS_EVENTS_FMT4 + (idx - INTEL_PMC_IDX_FIXED);
else
idx = MAX_PEBS_EVENTS + (idx - INTEL_PMC_IDX_FIXED);
}
/*
* Use auto-reload if possible to save a MSR write in the PMI.
* This must be done in pmu::start(), because PERF_EVENT_IOC_PERIOD.
*/
if (hwc->flags & PERF_X86_EVENT_AUTO_RELOAD) {
ds->pebs_event_reset[idx] =
(u64)(-hwc->sample_period) & x86_pmu.cntval_mask;
} else {
ds->pebs_event_reset[idx] = 0;
}
intel_pmu_pebs_via_pt_enable(event);
}
void intel_pmu_pebs_del(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct hw_perf_event *hwc = &event->hw;
bool needed_cb = pebs_needs_sched_cb(cpuc);
cpuc->n_pebs--;
if (hwc->flags & PERF_X86_EVENT_LARGE_PEBS)
cpuc->n_large_pebs--;
if (hwc->flags & PERF_X86_EVENT_PEBS_VIA_PT)
cpuc->n_pebs_via_pt--;
pebs_update_state(needed_cb, cpuc, event, false);
}
void intel_pmu_pebs_disable(struct perf_event *event)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct hw_perf_event *hwc = &event->hw;
intel_pmu_drain_large_pebs(cpuc);
cpuc->pebs_enabled &= ~(1ULL << hwc->idx);
if ((event->hw.flags & PERF_X86_EVENT_PEBS_LDLAT) &&
(x86_pmu.version < 5))
cpuc->pebs_enabled &= ~(1ULL << (hwc->idx + 32));
else if (event->hw.flags & PERF_X86_EVENT_PEBS_ST)
cpuc->pebs_enabled &= ~(1ULL << 63);
intel_pmu_pebs_via_pt_disable(event);
if (cpuc->enabled)
wrmsrq(MSR_IA32_PEBS_ENABLE, cpuc->pebs_enabled);
hwc->config |= ARCH_PERFMON_EVENTSEL_INT;
}
void intel_pmu_pebs_enable_all(void)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
if (cpuc->pebs_enabled)
wrmsrq(MSR_IA32_PEBS_ENABLE, cpuc->pebs_enabled);
}
void intel_pmu_pebs_disable_all(void)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
if (cpuc->pebs_enabled)
__intel_pmu_pebs_disable_all();
}
static int intel_pmu_pebs_fixup_ip(struct pt_regs *regs)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
unsigned long from = cpuc->lbr_entries[0].from;
unsigned long old_to, to = cpuc->lbr_entries[0].to;
unsigned long ip = regs->ip;
int is_64bit = 0;
void *kaddr;
int size;
/*
* We don't need to fixup if the PEBS assist is fault like
*/
if (!x86_pmu.intel_cap.pebs_trap)
return 1;
/*
* No LBR entry, no basic block, no rewinding
*/
if (!cpuc->lbr_stack.nr || !from || !to)
return 0;
/*
* Basic blocks should never cross user/kernel boundaries
*/
if (kernel_ip(ip) != kernel_ip(to))
return 0;
/*
* unsigned math, either ip is before the start (impossible) or
* the basic block is larger than 1 page (sanity)
*/
if ((ip - to) > PEBS_FIXUP_SIZE)
return 0;
/*
* We sampled a branch insn, rewind using the LBR stack
*/
if (ip == to) {
set_linear_ip(regs, from);
return 1;
}
size = ip - to;
if (!kernel_ip(ip)) {
int bytes;
u8 *buf = this_cpu_read(insn_buffer);
/* 'size' must fit our buffer, see above */
bytes = copy_from_user_nmi(buf, (void __user *)to, size);
if (bytes != 0)
return 0;
kaddr = buf;
} else {
kaddr = (void *)to;
}
do {
struct insn insn;
old_to = to;
#ifdef CONFIG_X86_64
is_64bit = kernel_ip(to) || any_64bit_mode(regs);
#endif
insn_init(&insn, kaddr, size, is_64bit);
/*
* Make sure there was not a problem decoding the instruction.
* This is doubly important because we have an infinite loop if
* insn.length=0.
*/
if (insn_get_length(&insn))
break;
to += insn.length;
kaddr += insn.length;
size -= insn.length;
} while (to < ip);
if (to == ip) {
set_linear_ip(regs, old_to);
return 1;
}
/*
* Even though we decoded the basic block, the instruction stream
* never matched the given IP, either the TO or the IP got corrupted.
*/
return 0;
}
static inline u64 intel_get_tsx_weight(u64 tsx_tuning)
{
if (tsx_tuning) {
union hsw_tsx_tuning tsx = { .value = tsx_tuning };
return tsx.cycles_last_block;
}
return 0;
}
static inline u64 intel_get_tsx_transaction(u64 tsx_tuning, u64 ax)
{
u64 txn = (tsx_tuning & PEBS_HSW_TSX_FLAGS) >> 32;
/* For RTM XABORTs also log the abort code from AX */
if ((txn & PERF_TXN_TRANSACTION) && (ax & 1))
txn |= ((ax >> 24) & 0xff) << PERF_TXN_ABORT_SHIFT;
return txn;
}
static inline u64 get_pebs_status(void *n)
{
if (x86_pmu.intel_cap.pebs_format < 4)
return ((struct pebs_record_nhm *)n)->status;
return ((struct pebs_basic *)n)->applicable_counters;
}
#define PERF_X86_EVENT_PEBS_HSW_PREC \
(PERF_X86_EVENT_PEBS_ST_HSW | \
PERF_X86_EVENT_PEBS_LD_HSW | \
PERF_X86_EVENT_PEBS_NA_HSW)
static u64 get_data_src(struct perf_event *event, u64 aux)
{
u64 val = PERF_MEM_NA;
int fl = event->hw.flags;
bool fst = fl & (PERF_X86_EVENT_PEBS_ST | PERF_X86_EVENT_PEBS_HSW_PREC);
if (fl & PERF_X86_EVENT_PEBS_LDLAT)
val = load_latency_data(event, aux);
else if (fl & PERF_X86_EVENT_PEBS_STLAT)
val = store_latency_data(event, aux);
else if (fl & PERF_X86_EVENT_PEBS_LAT_HYBRID)
val = x86_pmu.pebs_latency_data(event, aux);
else if (fst && (fl & PERF_X86_EVENT_PEBS_HSW_PREC))
val = precise_datala_hsw(event, aux);
else if (fst)
val = precise_store_data(aux);
return val;
}
static void setup_pebs_time(struct perf_event *event,
struct perf_sample_data *data,
u64 tsc)
{
/* Converting to a user-defined clock is not supported yet. */
if (event->attr.use_clockid != 0)
return;
/*
* Doesn't support the conversion when the TSC is unstable.
* The TSC unstable case is a corner case and very unlikely to
* happen. If it happens, the TSC in a PEBS record will be
* dropped and fall back to perf_event_clock().
*/
if (!using_native_sched_clock() || !sched_clock_stable())
return;
data->time = native_sched_clock_from_tsc(tsc) + __sched_clock_offset;
data->sample_flags |= PERF_SAMPLE_TIME;
}
#define PERF_SAMPLE_ADDR_TYPE (PERF_SAMPLE_ADDR | \
PERF_SAMPLE_PHYS_ADDR | \
PERF_SAMPLE_DATA_PAGE_SIZE)
static void setup_pebs_fixed_sample_data(struct perf_event *event,
struct pt_regs *iregs, void *__pebs,
struct perf_sample_data *data,
struct pt_regs *regs)
{
/*
* We cast to the biggest pebs_record but are careful not to
* unconditionally access the 'extra' entries.
*/
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct pebs_record_skl *pebs = __pebs;
u64 sample_type;
int fll;
if (pebs == NULL)
return;
sample_type = event->attr.sample_type;
fll = event->hw.flags & PERF_X86_EVENT_PEBS_LDLAT;
perf_sample_data_init(data, 0, event->hw.last_period);
/*
* Use latency for weight (only avail with PEBS-LL)
*/
if (fll && (sample_type & PERF_SAMPLE_WEIGHT_TYPE)) {
data->weight.full = pebs->lat;
data->sample_flags |= PERF_SAMPLE_WEIGHT_TYPE;
}
/*
* data.data_src encodes the data source
*/
if (sample_type & PERF_SAMPLE_DATA_SRC) {
data->data_src.val = get_data_src(event, pebs->dse);
data->sample_flags |= PERF_SAMPLE_DATA_SRC;
}
/*
* We must however always use iregs for the unwinder to stay sane; the
* record BP,SP,IP can point into thin air when the record is from a
* previous PMI context or an (I)RET happened between the record and
* PMI.
*/
perf_sample_save_callchain(data, event, iregs);
/*
* We use the interrupt regs as a base because the PEBS record does not
* contain a full regs set, specifically it seems to lack segment
* descriptors, which get used by things like user_mode().
*
* In the simple case fix up only the IP for PERF_SAMPLE_IP.
*/
*regs = *iregs;
/*
* Initialize regs_>flags from PEBS,
* Clear exact bit (which uses x86 EFLAGS Reserved bit 3),
* i.e., do not rely on it being zero:
*/
regs->flags = pebs->flags & ~PERF_EFLAGS_EXACT;
if (sample_type & PERF_SAMPLE_REGS_INTR) {
regs->ax = pebs->ax;
regs->bx = pebs->bx;
regs->cx = pebs->cx;
regs->dx = pebs->dx;
regs->si = pebs->si;
regs->di = pebs->di;
regs->bp = pebs->bp;
regs->sp = pebs->sp;
#ifndef CONFIG_X86_32
regs->r8 = pebs->r8;
regs->r9 = pebs->r9;
regs->r10 = pebs->r10;
regs->r11 = pebs->r11;
regs->r12 = pebs->r12;
regs->r13 = pebs->r13;
regs->r14 = pebs->r14;
regs->r15 = pebs->r15;
#endif
}
if (event->attr.precise_ip > 1) {
/*
* Haswell and later processors have an 'eventing IP'
* (real IP) which fixes the off-by-1 skid in hardware.
* Use it when precise_ip >= 2 :
*/
if (x86_pmu.intel_cap.pebs_format >= 2) {
set_linear_ip(regs, pebs->real_ip);
regs->flags |= PERF_EFLAGS_EXACT;
} else {
/* Otherwise, use PEBS off-by-1 IP: */
set_linear_ip(regs, pebs->ip);
/*
* With precise_ip >= 2, try to fix up the off-by-1 IP
* using the LBR. If successful, the fixup function
* corrects regs->ip and calls set_linear_ip() on regs:
*/
if (intel_pmu_pebs_fixup_ip(regs))
regs->flags |= PERF_EFLAGS_EXACT;
}
} else {
/*
* When precise_ip == 1, return the PEBS off-by-1 IP,
* no fixup attempted:
*/
set_linear_ip(regs, pebs->ip);
}
if ((sample_type & PERF_SAMPLE_ADDR_TYPE) &&
x86_pmu.intel_cap.pebs_format >= 1) {
data->addr = pebs->dla;
data->sample_flags |= PERF_SAMPLE_ADDR;
}
if (x86_pmu.intel_cap.pebs_format >= 2) {
/* Only set the TSX weight when no memory weight. */
if ((sample_type & PERF_SAMPLE_WEIGHT_TYPE) && !fll) {
data->weight.full = intel_get_tsx_weight(pebs->tsx_tuning);
data->sample_flags |= PERF_SAMPLE_WEIGHT_TYPE;
}
if (sample_type & PERF_SAMPLE_TRANSACTION) {
data->txn = intel_get_tsx_transaction(pebs->tsx_tuning,
pebs->ax);
data->sample_flags |= PERF_SAMPLE_TRANSACTION;
}
}
/*
* v3 supplies an accurate time stamp, so we use that
* for the time stamp.
*
* We can only do this for the default trace clock.
*/
if (x86_pmu.intel_cap.pebs_format >= 3)
setup_pebs_time(event, data, pebs->tsc);
perf_sample_save_brstack(data, event, &cpuc->lbr_stack, NULL);
}
static void adaptive_pebs_save_regs(struct pt_regs *regs,
struct pebs_gprs *gprs)
{
regs->ax = gprs->ax;
regs->bx = gprs->bx;
regs->cx = gprs->cx;
regs->dx = gprs->dx;
regs->si = gprs->si;
regs->di = gprs->di;
regs->bp = gprs->bp;
regs->sp = gprs->sp;
#ifndef CONFIG_X86_32
regs->r8 = gprs->r8;
regs->r9 = gprs->r9;
regs->r10 = gprs->r10;
regs->r11 = gprs->r11;
regs->r12 = gprs->r12;
regs->r13 = gprs->r13;
regs->r14 = gprs->r14;
regs->r15 = gprs->r15;
#endif
}
static void intel_perf_event_update_pmc(struct perf_event *event, u64 pmc)
{
int shift = 64 - x86_pmu.cntval_bits;
struct hw_perf_event *hwc;
u64 delta, prev_pmc;
/*
* A recorded counter may not have an assigned event in the
* following cases. The value should be dropped.
* - An event is deleted. There is still an active PEBS event.
* The PEBS record doesn't shrink on pmu::del().
* If the counter of the deleted event once occurred in a PEBS
* record, PEBS still records the counter until the counter is
* reassigned.
* - An event is stopped for some reason, e.g., throttled.
* During this period, another event is added and takes the
* counter of the stopped event. The stopped event is assigned
* to another new and uninitialized counter, since the
* x86_pmu_start(RELOAD) is not invoked for a stopped event.
* The PEBS__DATA_CFG is updated regardless of the event state.
* The uninitialized counter can be recorded in a PEBS record.
* But the cpuc->events[uninitialized_counter] is always NULL,
* because the event is stopped. The uninitialized value is
* safely dropped.
*/
if (!event)
return;
hwc = &event->hw;
prev_pmc = local64_read(&hwc->prev_count);
/* Only update the count when the PMU is disabled */
WARN_ON(this_cpu_read(cpu_hw_events.enabled));
local64_set(&hwc->prev_count, pmc);
delta = (pmc << shift) - (prev_pmc << shift);
delta >>= shift;
local64_add(delta, &event->count);
local64_sub(delta, &hwc->period_left);
}
static inline void __setup_pebs_counter_group(struct cpu_hw_events *cpuc,
struct perf_event *event,
struct pebs_cntr_header *cntr,
void *next_record)
{
int bit;
for_each_set_bit(bit, (unsigned long *)&cntr->cntr, INTEL_PMC_MAX_GENERIC) {
intel_perf_event_update_pmc(cpuc->events[bit], *(u64 *)next_record);
next_record += sizeof(u64);
}
for_each_set_bit(bit, (unsigned long *)&cntr->fixed, INTEL_PMC_MAX_FIXED) {
/* The slots event will be handled with perf_metric later */
if ((cntr->metrics == INTEL_CNTR_METRICS) &&
(bit + INTEL_PMC_IDX_FIXED == INTEL_PMC_IDX_FIXED_SLOTS)) {
next_record += sizeof(u64);
continue;
}
intel_perf_event_update_pmc(cpuc->events[bit + INTEL_PMC_IDX_FIXED],
*(u64 *)next_record);
next_record += sizeof(u64);
}
/* HW will reload the value right after the overflow. */
if (event->hw.flags & PERF_X86_EVENT_AUTO_RELOAD)
local64_set(&event->hw.prev_count, (u64)-event->hw.sample_period);
if (cntr->metrics == INTEL_CNTR_METRICS) {
static_call(intel_pmu_update_topdown_event)
(cpuc->events[INTEL_PMC_IDX_FIXED_SLOTS],
(u64 *)next_record);
next_record += 2 * sizeof(u64);
}
}
#define PEBS_LATENCY_MASK 0xffff
/*
* With adaptive PEBS the layout depends on what fields are configured.
*/
static void setup_pebs_adaptive_sample_data(struct perf_event *event,
struct pt_regs *iregs, void *__pebs,
struct perf_sample_data *data,
struct pt_regs *regs)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct pebs_basic *basic = __pebs;
void *next_record = basic + 1;
u64 sample_type, format_group;
struct pebs_meminfo *meminfo = NULL;
struct pebs_gprs *gprs = NULL;
struct x86_perf_regs *perf_regs;
if (basic == NULL)
return;
perf_regs = container_of(regs, struct x86_perf_regs, regs);
perf_regs->xmm_regs = NULL;
sample_type = event->attr.sample_type;
format_group = basic->format_group;
perf_sample_data_init(data, 0, event->hw.last_period);
setup_pebs_time(event, data, basic->tsc);
/*
* We must however always use iregs for the unwinder to stay sane; the
* record BP,SP,IP can point into thin air when the record is from a
* previous PMI context or an (I)RET happened between the record and
* PMI.
*/
perf_sample_save_callchain(data, event, iregs);
*regs = *iregs;
/* The ip in basic is EventingIP */
set_linear_ip(regs, basic->ip);
regs->flags = PERF_EFLAGS_EXACT;
if (sample_type & PERF_SAMPLE_WEIGHT_STRUCT) {
if (x86_pmu.flags & PMU_FL_RETIRE_LATENCY)
data->weight.var3_w = basic->retire_latency;
else
data->weight.var3_w = 0;
}
/*
* The record for MEMINFO is in front of GP
* But PERF_SAMPLE_TRANSACTION needs gprs->ax.
* Save the pointer here but process later.
*/
if (format_group & PEBS_DATACFG_MEMINFO) {
meminfo = next_record;
next_record = meminfo + 1;
}
if (format_group & PEBS_DATACFG_GP) {
gprs = next_record;
next_record = gprs + 1;
if (event->attr.precise_ip < 2) {
set_linear_ip(regs, gprs->ip);
regs->flags &= ~PERF_EFLAGS_EXACT;
}
if (sample_type & (PERF_SAMPLE_REGS_INTR | PERF_SAMPLE_REGS_USER))
adaptive_pebs_save_regs(regs, gprs);
}
if (format_group & PEBS_DATACFG_MEMINFO) {
if (sample_type & PERF_SAMPLE_WEIGHT_TYPE) {
u64 latency = x86_pmu.flags & PMU_FL_INSTR_LATENCY ?
meminfo->cache_latency : meminfo->mem_latency;
if (x86_pmu.flags & PMU_FL_INSTR_LATENCY)
data->weight.var2_w = meminfo->instr_latency;
/*
* Although meminfo::latency is defined as a u64,
* only the lower 32 bits include the valid data
* in practice on Ice Lake and earlier platforms.
*/
if (sample_type & PERF_SAMPLE_WEIGHT) {
data->weight.full = latency ?:
intel_get_tsx_weight(meminfo->tsx_tuning);
} else {
data->weight.var1_dw = (u32)latency ?:
intel_get_tsx_weight(meminfo->tsx_tuning);
}
data->sample_flags |= PERF_SAMPLE_WEIGHT_TYPE;
}
if (sample_type & PERF_SAMPLE_DATA_SRC) {
data->data_src.val = get_data_src(event, meminfo->aux);
data->sample_flags |= PERF_SAMPLE_DATA_SRC;
}
if (sample_type & PERF_SAMPLE_ADDR_TYPE) {
data->addr = meminfo->address;
data->sample_flags |= PERF_SAMPLE_ADDR;
}
if (sample_type & PERF_SAMPLE_TRANSACTION) {
data->txn = intel_get_tsx_transaction(meminfo->tsx_tuning,
gprs ? gprs->ax : 0);
data->sample_flags |= PERF_SAMPLE_TRANSACTION;
}
}
if (format_group & PEBS_DATACFG_XMMS) {
struct pebs_xmm *xmm = next_record;
next_record = xmm + 1;
perf_regs->xmm_regs = xmm->xmm;
}
if (format_group & PEBS_DATACFG_LBRS) {
struct lbr_entry *lbr = next_record;
int num_lbr = ((format_group >> PEBS_DATACFG_LBR_SHIFT)
& 0xff) + 1;
next_record = next_record + num_lbr * sizeof(struct lbr_entry);
if (has_branch_stack(event)) {
intel_pmu_store_pebs_lbrs(lbr);
intel_pmu_lbr_save_brstack(data, cpuc, event);
}
}
if (format_group & (PEBS_DATACFG_CNTR | PEBS_DATACFG_METRICS)) {
struct pebs_cntr_header *cntr = next_record;
unsigned int nr;
next_record += sizeof(struct pebs_cntr_header);
/*
* The PEBS_DATA_CFG is a global register, which is the
* superset configuration for all PEBS events.
* For the PEBS record of non-sample-read group, ignore
* the counter snapshot fields.
*/
if (is_pebs_counter_event_group(event)) {
__setup_pebs_counter_group(cpuc, event, cntr, next_record);
data->sample_flags |= PERF_SAMPLE_READ;
}
nr = hweight32(cntr->cntr) + hweight32(cntr->fixed);
if (cntr->metrics == INTEL_CNTR_METRICS)
nr += 2;
next_record += nr * sizeof(u64);
}
WARN_ONCE(next_record != __pebs + basic->format_size,
"PEBS record size %u, expected %llu, config %llx\n",
basic->format_size,
(u64)(next_record - __pebs),
format_group);
}
static inline void *
get_next_pebs_record_by_bit(void *base, void *top, int bit)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
void *at;
u64 pebs_status;
/*
* fmt0 does not have a status bitfield (does not use
* perf_record_nhm format)
*/
if (x86_pmu.intel_cap.pebs_format < 1)
return base;
if (base == NULL)
return NULL;
for (at = base; at < top; at += cpuc->pebs_record_size) {
unsigned long status = get_pebs_status(at);
if (test_bit(bit, (unsigned long *)&status)) {
/* PEBS v3 has accurate status bits */
if (x86_pmu.intel_cap.pebs_format >= 3)
return at;
if (status == (1 << bit))
return at;
/* clear non-PEBS bit and re-check */
pebs_status = status & cpuc->pebs_enabled;
pebs_status &= PEBS_COUNTER_MASK;
if (pebs_status == (1 << bit))
return at;
}
}
return NULL;
}
/*
* Special variant of intel_pmu_save_and_restart() for auto-reload.
*/
static int
intel_pmu_save_and_restart_reload(struct perf_event *event, int count)
{
struct hw_perf_event *hwc = &event->hw;
int shift = 64 - x86_pmu.cntval_bits;
u64 period = hwc->sample_period;
u64 prev_raw_count, new_raw_count;
s64 new, old;
WARN_ON(!period);
/*
* drain_pebs() only happens when the PMU is disabled.
*/
WARN_ON(this_cpu_read(cpu_hw_events.enabled));
prev_raw_count = local64_read(&hwc->prev_count);
new_raw_count = rdpmc(hwc->event_base_rdpmc);
local64_set(&hwc->prev_count, new_raw_count);
/*
* Since the counter increments a negative counter value and
* overflows on the sign switch, giving the interval:
*
* [-period, 0]
*
* the difference between two consecutive reads is:
*
* A) value2 - value1;
* when no overflows have happened in between,
*
* B) (0 - value1) + (value2 - (-period));
* when one overflow happened in between,
*
* C) (0 - value1) + (n - 1) * (period) + (value2 - (-period));
* when @n overflows happened in between.
*
* Here A) is the obvious difference, B) is the extension to the
* discrete interval, where the first term is to the top of the
* interval and the second term is from the bottom of the next
* interval and C) the extension to multiple intervals, where the
* middle term is the whole intervals covered.
*
* An equivalent of C, by reduction, is:
*
* value2 - value1 + n * period
*/
new = ((s64)(new_raw_count << shift) >> shift);
old = ((s64)(prev_raw_count << shift) >> shift);
local64_add(new - old + count * period, &event->count);
local64_set(&hwc->period_left, -new);
perf_event_update_userpage(event);
return 0;
}
typedef void (*setup_fn)(struct perf_event *, struct pt_regs *, void *,
struct perf_sample_data *, struct pt_regs *);
static struct pt_regs dummy_iregs;
static __always_inline void
__intel_pmu_pebs_event(struct perf_event *event,
struct pt_regs *iregs,
struct pt_regs *regs,
struct perf_sample_data *data,
void *at,
setup_fn setup_sample)
{
setup_sample(event, iregs, at, data, regs);
perf_event_output(event, data, regs);
}
static __always_inline void
__intel_pmu_pebs_last_event(struct perf_event *event,
struct pt_regs *iregs,
struct pt_regs *regs,
struct perf_sample_data *data,
void *at,
int count,
setup_fn setup_sample)
{
struct hw_perf_event *hwc = &event->hw;
setup_sample(event, iregs, at, data, regs);
if (iregs == &dummy_iregs) {
/*
* The PEBS records may be drained in the non-overflow context,
* e.g., large PEBS + context switch. Perf should treat the
* last record the same as other PEBS records, and doesn't
* invoke the generic overflow handler.
*/
perf_event_output(event, data, regs);
} else {
/*
* All but the last records are processed.
* The last one is left to be able to call the overflow handler.
*/
perf_event_overflow(event, data, regs);
}
if (hwc->flags & PERF_X86_EVENT_AUTO_RELOAD) {
if ((is_pebs_counter_event_group(event))) {
/*
* The value of each sample has been updated when setup
* the corresponding sample data.
*/
perf_event_update_userpage(event);
} else {
/*
* Now, auto-reload is only enabled in fixed period mode.
* The reload value is always hwc->sample_period.
* May need to change it, if auto-reload is enabled in
* freq mode later.
*/
intel_pmu_save_and_restart_reload(event, count);
}
} else {
/*
* For a non-precise event, it's possible the
* counters-snapshotting records a positive value for the
* overflowed event. Then the HW auto-reload mechanism
* reset the counter to 0 immediately, because the
* pebs_event_reset is cleared if the PERF_X86_EVENT_AUTO_RELOAD
* is not set. The counter backwards may be observed in a
* PMI handler.
*
* Since the event value has been updated when processing the
* counters-snapshotting record, only needs to set the new
* period for the counter.
*/
if (is_pebs_counter_event_group(event))
static_call(x86_pmu_set_period)(event);
else
intel_pmu_save_and_restart(event);
}
}
static __always_inline void
__intel_pmu_pebs_events(struct perf_event *event,
struct pt_regs *iregs,
struct perf_sample_data *data,
void *base, void *top,
int bit, int count,
setup_fn setup_sample)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct x86_perf_regs perf_regs;
struct pt_regs *regs = &perf_regs.regs;
void *at = get_next_pebs_record_by_bit(base, top, bit);
int cnt = count;
if (!iregs)
iregs = &dummy_iregs;
while (cnt > 1) {
__intel_pmu_pebs_event(event, iregs, regs, data, at, setup_sample);
at += cpuc->pebs_record_size;
at = get_next_pebs_record_by_bit(at, top, bit);
cnt--;
}
__intel_pmu_pebs_last_event(event, iregs, regs, data, at, count, setup_sample);
}
static void intel_pmu_drain_pebs_core(struct pt_regs *iregs, struct perf_sample_data *data)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct debug_store *ds = cpuc->ds;
struct perf_event *event = cpuc->events[0]; /* PMC0 only */
struct pebs_record_core *at, *top;
int n;
if (!x86_pmu.pebs_active)
return;
at = (struct pebs_record_core *)(unsigned long)ds->pebs_buffer_base;
top = (struct pebs_record_core *)(unsigned long)ds->pebs_index;
/*
* Whatever else happens, drain the thing
*/
ds->pebs_index = ds->pebs_buffer_base;
if (!test_bit(0, cpuc->active_mask))
return;
WARN_ON_ONCE(!event);
if (!event->attr.precise_ip)
return;
n = top - at;
if (n <= 0) {
if (event->hw.flags & PERF_X86_EVENT_AUTO_RELOAD)
intel_pmu_save_and_restart_reload(event, 0);
return;
}
__intel_pmu_pebs_events(event, iregs, data, at, top, 0, n,
setup_pebs_fixed_sample_data);
}
static void intel_pmu_pebs_event_update_no_drain(struct cpu_hw_events *cpuc, u64 mask)
{
u64 pebs_enabled = cpuc->pebs_enabled & mask;
struct perf_event *event;
int bit;
/*
* The drain_pebs() could be called twice in a short period
* for auto-reload event in pmu::read(). There are no
* overflows have happened in between.
* It needs to call intel_pmu_save_and_restart_reload() to
* update the event->count for this case.
*/
for_each_set_bit(bit, (unsigned long *)&pebs_enabled, X86_PMC_IDX_MAX) {
event = cpuc->events[bit];
if (event->hw.flags & PERF_X86_EVENT_AUTO_RELOAD)
intel_pmu_save_and_restart_reload(event, 0);
}
}
static void intel_pmu_drain_pebs_nhm(struct pt_regs *iregs, struct perf_sample_data *data)
{
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct debug_store *ds = cpuc->ds;
struct perf_event *event;
void *base, *at, *top;
short counts[INTEL_PMC_IDX_FIXED + MAX_FIXED_PEBS_EVENTS] = {};
short error[INTEL_PMC_IDX_FIXED + MAX_FIXED_PEBS_EVENTS] = {};
int max_pebs_events = intel_pmu_max_num_pebs(NULL);
int bit, i, size;
u64 mask;
if (!x86_pmu.pebs_active)
return;
base = (struct pebs_record_nhm *)(unsigned long)ds->pebs_buffer_base;
top = (struct pebs_record_nhm *)(unsigned long)ds->pebs_index;
ds->pebs_index = ds->pebs_buffer_base;
mask = x86_pmu.pebs_events_mask;
size = max_pebs_events;
if (x86_pmu.flags & PMU_FL_PEBS_ALL) {
mask |= x86_pmu.fixed_cntr_mask64 << INTEL_PMC_IDX_FIXED;
size = INTEL_PMC_IDX_FIXED + x86_pmu_max_num_counters_fixed(NULL);
}
if (unlikely(base >= top)) {
intel_pmu_pebs_event_update_no_drain(cpuc, mask);
return;
}
for (at = base; at < top; at += x86_pmu.pebs_record_size) {
struct pebs_record_nhm *p = at;
u64 pebs_status;
pebs_status = p->status & cpuc->pebs_enabled;
pebs_status &= mask;
/* PEBS v3 has more accurate status bits */
if (x86_pmu.intel_cap.pebs_format >= 3) {
for_each_set_bit(bit, (unsigned long *)&pebs_status, size)
counts[bit]++;
continue;
}
/*
* On some CPUs the PEBS status can be zero when PEBS is
* racing with clearing of GLOBAL_STATUS.
*
* Normally we would drop that record, but in the
* case when there is only a single active PEBS event
* we can assume it's for that event.
*/
if (!pebs_status && cpuc->pebs_enabled &&
!(cpuc->pebs_enabled & (cpuc->pebs_enabled-1)))
pebs_status = p->status = cpuc->pebs_enabled;
bit = find_first_bit((unsigned long *)&pebs_status,
max_pebs_events);
if (!(x86_pmu.pebs_events_mask & (1 << bit)))
continue;
/*
* The PEBS hardware does not deal well with the situation
* when events happen near to each other and multiple bits
* are set. But it should happen rarely.
*
* If these events include one PEBS and multiple non-PEBS
* events, it doesn't impact PEBS record. The record will
* be handled normally. (slow path)
*
* If these events include two or more PEBS events, the
* records for the events can be collapsed into a single
* one, and it's not possible to reconstruct all events
* that caused the PEBS record. It's called collision.
* If collision happened, the record will be dropped.
*/
if (pebs_status != (1ULL << bit)) {
for_each_set_bit(i, (unsigned long *)&pebs_status, size)
error[i]++;
continue;
}
counts[bit]++;
}
for_each_set_bit(bit, (unsigned long *)&mask, size) {
if ((counts[bit] == 0) && (error[bit] == 0))
continue;
event = cpuc->events[bit];
if (WARN_ON_ONCE(!event))
continue;
if (WARN_ON_ONCE(!event->attr.precise_ip))
continue;
/* log dropped samples number */
if (error[bit]) {
perf_log_lost_samples(event, error[bit]);
if (iregs)
perf_event_account_interrupt(event);
}
if (counts[bit]) {
__intel_pmu_pebs_events(event, iregs, data, base,
top, bit, counts[bit],
setup_pebs_fixed_sample_data);
}
}
}
static void intel_pmu_drain_pebs_icl(struct pt_regs *iregs, struct perf_sample_data *data)
{
short counts[INTEL_PMC_IDX_FIXED + MAX_FIXED_PEBS_EVENTS] = {};
void *last[INTEL_PMC_IDX_FIXED + MAX_FIXED_PEBS_EVENTS];
struct cpu_hw_events *cpuc = this_cpu_ptr(&cpu_hw_events);
struct debug_store *ds = cpuc->ds;
struct x86_perf_regs perf_regs;
struct pt_regs *regs = &perf_regs.regs;
struct pebs_basic *basic;
struct perf_event *event;
void *base, *at, *top;
int bit;
u64 mask;
if (!x86_pmu.pebs_active)
return;
base = (struct pebs_basic *)(unsigned long)ds->pebs_buffer_base;
top = (struct pebs_basic *)(unsigned long)ds->pebs_index;
ds->pebs_index = ds->pebs_buffer_base;
mask = hybrid(cpuc->pmu, pebs_events_mask) |
(hybrid(cpuc->pmu, fixed_cntr_mask64) << INTEL_PMC_IDX_FIXED);
if (unlikely(base >= top)) {
intel_pmu_pebs_event_update_no_drain(cpuc, mask);
return;
}
if (!iregs)
iregs = &dummy_iregs;
/* Process all but the last event for each counter. */
for (at = base; at < top; at += basic->format_size) {
u64 pebs_status;
basic = at;
if (basic->format_size != cpuc->pebs_record_size)
continue;
pebs_status = basic->applicable_counters & cpuc->pebs_enabled & mask;
for_each_set_bit(bit, (unsigned long *)&pebs_status, X86_PMC_IDX_MAX) {
event = cpuc->events[bit];
if (WARN_ON_ONCE(!event) ||
WARN_ON_ONCE(!event->attr.precise_ip))
continue;
if (counts[bit]++) {
__intel_pmu_pebs_event(event, iregs, regs, data, last[bit],
setup_pebs_adaptive_sample_data);
}
last[bit] = at;
}
}
for_each_set_bit(bit, (unsigned long *)&mask, X86_PMC_IDX_MAX) {
if (!counts[bit])
continue;
event = cpuc->events[bit];
__intel_pmu_pebs_last_event(event, iregs, regs, data, last[bit],
counts[bit], setup_pebs_adaptive_sample_data);
}
}
/*
* PEBS probe and setup
*/
void __init intel_pebs_init(void)
{
/*
* No support for 32bit formats
*/
if (!boot_cpu_has(X86_FEATURE_DTES64))
return;
x86_pmu.ds_pebs = boot_cpu_has(X86_FEATURE_PEBS);
x86_pmu.pebs_buffer_size = PEBS_BUFFER_SIZE;
if (x86_pmu.version <= 4)
x86_pmu.pebs_no_isolation = 1;
if (x86_pmu.ds_pebs) {
char pebs_type = x86_pmu.intel_cap.pebs_trap ? '+' : '-';
char *pebs_qual = "";
int format = x86_pmu.intel_cap.pebs_format;
if (format < 4)
x86_pmu.intel_cap.pebs_baseline = 0;
x86_pmu.pebs_enable = intel_pmu_pebs_enable;
x86_pmu.pebs_disable = intel_pmu_pebs_disable;
x86_pmu.pebs_enable_all = intel_pmu_pebs_enable_all;
x86_pmu.pebs_disable_all = intel_pmu_pebs_disable_all;
switch (format) {
case 0:
pr_cont("PEBS fmt0%c, ", pebs_type);
x86_pmu.pebs_record_size = sizeof(struct pebs_record_core);
/*
* Using >PAGE_SIZE buffers makes the WRMSR to
* PERF_GLOBAL_CTRL in intel_pmu_enable_all()
* mysteriously hang on Core2.
*
* As a workaround, we don't do this.
*/
x86_pmu.pebs_buffer_size = PAGE_SIZE;
x86_pmu.drain_pebs = intel_pmu_drain_pebs_core;
break;
case 1:
pr_cont("PEBS fmt1%c, ", pebs_type);
x86_pmu.pebs_record_size = sizeof(struct pebs_record_nhm);
x86_pmu.drain_pebs = intel_pmu_drain_pebs_nhm;
break;
case 2:
pr_cont("PEBS fmt2%c, ", pebs_type);
x86_pmu.pebs_record_size = sizeof(struct pebs_record_hsw);
x86_pmu.drain_pebs = intel_pmu_drain_pebs_nhm;
break;
case 3:
pr_cont("PEBS fmt3%c, ", pebs_type);
x86_pmu.pebs_record_size =
sizeof(struct pebs_record_skl);
x86_pmu.drain_pebs = intel_pmu_drain_pebs_nhm;
x86_pmu.large_pebs_flags |= PERF_SAMPLE_TIME;
break;
case 6:
if (x86_pmu.intel_cap.pebs_baseline) {
x86_pmu.large_pebs_flags |= PERF_SAMPLE_READ;
x86_pmu.late_setup = intel_pmu_late_setup;
}
fallthrough;
case 5:
x86_pmu.pebs_ept = 1;
fallthrough;
case 4:
x86_pmu.drain_pebs = intel_pmu_drain_pebs_icl;
x86_pmu.pebs_record_size = sizeof(struct pebs_basic);
if (x86_pmu.intel_cap.pebs_baseline) {
x86_pmu.large_pebs_flags |=
PERF_SAMPLE_BRANCH_STACK |
PERF_SAMPLE_TIME;
x86_pmu.flags |= PMU_FL_PEBS_ALL;
x86_pmu.pebs_capable = ~0ULL;
pebs_qual = "-baseline";
x86_get_pmu(smp_processor_id())->capabilities |= PERF_PMU_CAP_EXTENDED_REGS;
} else {
/* Only basic record supported */
x86_pmu.large_pebs_flags &=
~(PERF_SAMPLE_ADDR |
PERF_SAMPLE_TIME |
PERF_SAMPLE_DATA_SRC |
PERF_SAMPLE_TRANSACTION |
PERF_SAMPLE_REGS_USER |
PERF_SAMPLE_REGS_INTR);
}
pr_cont("PEBS fmt%d%c%s, ", format, pebs_type, pebs_qual);
/*
* The PEBS-via-PT is not supported on hybrid platforms,
* because not all CPUs of a hybrid machine support it.
* The global x86_pmu.intel_cap, which only contains the
* common capabilities, is used to check the availability
* of the feature. The per-PMU pebs_output_pt_available
* in a hybrid machine should be ignored.
*/
if (x86_pmu.intel_cap.pebs_output_pt_available) {
pr_cont("PEBS-via-PT, ");
x86_get_pmu(smp_processor_id())->capabilities |= PERF_PMU_CAP_AUX_OUTPUT;
}
break;
default:
pr_cont("no PEBS fmt%d%c, ", format, pebs_type);
x86_pmu.ds_pebs = 0;
}
}
}
void perf_restore_debug_store(void)
{
struct debug_store *ds = __this_cpu_read(cpu_hw_events.ds);
if (!x86_pmu.bts && !x86_pmu.ds_pebs)
return;
wrmsrq(MSR_IA32_DS_AREA, (unsigned long)ds);
}
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