1 .. SPDX-License-Identifier: GPL-2.0
12 :Author: Andrew Murray <andrew.murray@arm.com>
18 This attribute excludes userspace.
20 Userspace always runs at EL0 and thus this attribute will exclude EL0.
26 This attribute excludes the kernel.
28 The kernel runs at EL2 with VHE and EL1 without. Guest kernels always run
31 For the host this attribute will exclude EL1 and additionally EL2 on a VHE
34 For the guest this attribute will exclude EL1. Please note that EL2 is
35 never counted within a guest.
41 This attribute excludes the hypervisor.
43 For a VHE host this attribute is ignored as we consider the host kernel to
46 For a non-VHE host this attribute will exclude EL2 as we consider the
47 hypervisor to be any code that runs at EL2 which is predominantly used for
48 guest/host transitions.
50 For the guest this attribute has no effect. Please note that EL2 is
51 never counted within a guest.
54 exclude_host / exclude_guest
55 ----------------------------
57 These attributes exclude the KVM host and guest, respectively.
59 The KVM host may run at EL0 (userspace), EL1 (non-VHE kernel) and EL2 (VHE
60 kernel or non-VHE hypervisor).
62 The KVM guest may run at EL0 (userspace) and EL1 (kernel).
64 Due to the overlapping exception levels between host and guests we cannot
65 exclusively rely on the PMU's hardware exception filtering - therefore we
66 must enable/disable counting on the entry and exit to the guest. This is
67 performed differently on VHE and non-VHE systems.
69 For non-VHE systems we exclude EL2 for exclude_host - upon entering and
70 exiting the guest we disable/enable the event as appropriate based on the
71 exclude_host and exclude_guest attributes.
73 For VHE systems we exclude EL1 for exclude_guest and exclude both EL0,EL2
74 for exclude_host. Upon entering and exiting the guest we modify the event
75 to include/exclude EL0 as appropriate based on the exclude_host and
76 exclude_guest attributes.
78 The statements above also apply when these attributes are used within a
79 non-VHE guest however please note that EL2 is never counted within a guest.
85 On non-VHE hosts we enable/disable counters on the entry/exit of host/guest
86 transition at EL2 - however there is a period of time between
87 enabling/disabling the counters and entering/exiting the guest. We are
88 able to eliminate counters counting host events on the boundaries of guest
89 entry/exit when counting guest events by filtering out EL2 for
90 exclude_host. However when using !exclude_hv there is a small blackout
91 window at the guest entry/exit where host events are not captured.
93 On VHE systems there are no blackout windows.
95 Perf Userspace PMU Hardware Counter Access
96 ==========================================
100 The perf userspace tool relies on the PMU to monitor events. It offers an
101 abstraction layer over the hardware counters since the underlying
102 implementation is cpu-dependent.
103 Arm64 allows userspace tools to have access to the registers storing the
104 hardware counters' values directly.
106 This targets specifically self-monitoring tasks in order to reduce the overhead
107 by directly accessing the registers without having to go through the kernel.
111 The focus is set on the armv8 PMUv3 which makes sure that the access to the pmu
112 registers is enabled and that the userspace has access to the relevant
113 information in order to use them.
115 In order to have access to the hardware counters, the global sysctl
116 kernel/perf_user_access must first be enabled:
120 echo 1 > /proc/sys/kernel/perf_user_access
122 It is necessary to open the event using the perf tool interface with config1:1
123 attr bit set: the sys_perf_event_open syscall returns a fd which can
124 subsequently be used with the mmap syscall in order to retrieve a page of memory
125 containing information about the event. The PMU driver uses this page to expose
126 to the user the hardware counter's index and other necessary data. Using this
127 index enables the user to access the PMU registers using the `mrs` instruction.
128 Access to the PMU registers is only valid while the sequence lock is unchanged.
129 In particular, the PMSELR_EL0 register is zeroed each time the sequence lock is
132 The userspace access is supported in libperf using the perf_evsel__mmap()
133 and perf_evsel__read() functions. See `tools/lib/perf/tests/test-evsel.c`_ for
136 About heterogeneous systems
137 ---------------------------
138 On heterogeneous systems such as big.LITTLE, userspace PMU counter access can
139 only be enabled when the tasks are pinned to a homogeneous subset of cores and
140 the corresponding PMU instance is opened by specifying the 'type' attribute.
141 The use of generic event types is not supported in this case.
143 Have a look at `tools/perf/arch/arm64/tests/user-events.c`_ for an example. It
144 can be run using the perf tool to check that the access to the registers works
145 correctly from userspace:
151 About chained events and counter sizes
152 --------------------------------------
153 The user can request either a 32-bit (config1:0 == 0) or 64-bit (config1:0 == 1)
154 counter along with userspace access. The sys_perf_event_open syscall will fail
155 if a 64-bit counter is requested and the hardware doesn't support 64-bit
156 counters. Chained events are not supported in conjunction with userspace counter
157 access. If a 32-bit counter is requested on hardware with 64-bit counters, then
158 userspace must treat the upper 32-bits read from the counter as UNKNOWN. The
159 'pmc_width' field in the user page will indicate the valid width of the counter
160 and should be used to mask the upper bits as needed.
163 .. _tools/perf/arch/arm64/tests/user-events.c:
164 https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/tools/perf/arch/arm64/tests/user-events.c
165 .. _tools/lib/perf/tests/test-evsel.c:
166 https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/tools/lib/perf/tests/test-evsel.c
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