perf: arm_cspmu: Add support for NVIDIA SCF and MCF attribute

Add support for NVIDIA System Cache Fabric (SCF) and Memory Control
Fabric (MCF) PMU attributes for CoreSight PMU implementation in
NVIDIA devices.

Acked-by: Suzuki K Poulose <suzuki.poulose@arm.com>
Signed-off-by: Besar Wicaksono <bwicaksono@nvidia.com>
Link: https://lore.kernel.org/r/20221111222330.48602-3-bwicaksono@nvidia.com
Signed-off-by: Will Deacon <will@kernel.org>
This commit is contained in:
Besar Wicaksono 2022-11-11 16:23:29 -06:00 committed by Will Deacon
parent e37dfd6573
commit 84481be716
6 changed files with 726 additions and 1 deletions

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@ -19,3 +19,4 @@ Performance monitor support
arm_dsu_pmu
thunderx2-pmu
alibaba_pmu
nvidia-pmu

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@ -0,0 +1,299 @@
=========================================================
NVIDIA Tegra SoC Uncore Performance Monitoring Unit (PMU)
=========================================================
The NVIDIA Tegra SoC includes various system PMUs to measure key performance
metrics like memory bandwidth, latency, and utilization:
* Scalable Coherency Fabric (SCF)
* NVLink-C2C0
* NVLink-C2C1
* CNVLink
* PCIE
PMU Driver
----------
The PMUs in this document are based on ARM CoreSight PMU Architecture as
described in document: ARM IHI 0091. Since this is a standard architecture, the
PMUs are managed by a common driver "arm-cs-arch-pmu". This driver describes
the available events and configuration of each PMU in sysfs. Please see the
sections below to get the sysfs path of each PMU. Like other uncore PMU drivers,
the driver provides "cpumask" sysfs attribute to show the CPU id used to handle
the PMU event. There is also "associated_cpus" sysfs attribute, which contains a
list of CPUs associated with the PMU instance.
.. _SCF_PMU_Section:
SCF PMU
-------
The SCF PMU monitors system level cache events, CPU traffic, and
strongly-ordered (SO) PCIE write traffic to local/remote memory. Please see
:ref:`NVIDIA_Uncore_PMU_Traffic_Coverage_Section` for more info about the PMU
traffic coverage.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_sources/devices/nvidia_scf_pmu_<socket-id>.
Example usage:
* Count event id 0x0 in socket 0::
perf stat -a -e nvidia_scf_pmu_0/event=0x0/
* Count event id 0x0 in socket 1::
perf stat -a -e nvidia_scf_pmu_1/event=0x0/
NVLink-C2C0 PMU
--------------------
The NVLink-C2C0 PMU monitors incoming traffic from a GPU/CPU connected with
NVLink-C2C (Chip-2-Chip) interconnect. The type of traffic captured by this PMU
varies dependent on the chip configuration:
* NVIDIA Grace Hopper Superchip: Hopper GPU is connected with Grace SoC.
In this config, the PMU captures GPU ATS translated or EGM traffic from the GPU.
* NVIDIA Grace CPU Superchip: two Grace CPU SoCs are connected.
In this config, the PMU captures read and relaxed ordered (RO) writes from
PCIE device of the remote SoC.
Please see :ref:`NVIDIA_Uncore_PMU_Traffic_Coverage_Section` for more info about
the PMU traffic coverage.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_sources/devices/nvidia_nvlink_c2c0_pmu_<socket-id>.
Example usage:
* Count event id 0x0 from the GPU/CPU connected with socket 0::
perf stat -a -e nvidia_nvlink_c2c0_pmu_0/event=0x0/
* Count event id 0x0 from the GPU/CPU connected with socket 1::
perf stat -a -e nvidia_nvlink_c2c0_pmu_1/event=0x0/
* Count event id 0x0 from the GPU/CPU connected with socket 2::
perf stat -a -e nvidia_nvlink_c2c0_pmu_2/event=0x0/
* Count event id 0x0 from the GPU/CPU connected with socket 3::
perf stat -a -e nvidia_nvlink_c2c0_pmu_3/event=0x0/
NVLink-C2C1 PMU
-------------------
The NVLink-C2C1 PMU monitors incoming traffic from a GPU connected with
NVLink-C2C (Chip-2-Chip) interconnect. This PMU captures untranslated GPU
traffic, in contrast with NvLink-C2C0 PMU that captures ATS translated traffic.
Please see :ref:`NVIDIA_Uncore_PMU_Traffic_Coverage_Section` for more info about
the PMU traffic coverage.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_sources/devices/nvidia_nvlink_c2c1_pmu_<socket-id>.
Example usage:
* Count event id 0x0 from the GPU connected with socket 0::
perf stat -a -e nvidia_nvlink_c2c1_pmu_0/event=0x0/
* Count event id 0x0 from the GPU connected with socket 1::
perf stat -a -e nvidia_nvlink_c2c1_pmu_1/event=0x0/
* Count event id 0x0 from the GPU connected with socket 2::
perf stat -a -e nvidia_nvlink_c2c1_pmu_2/event=0x0/
* Count event id 0x0 from the GPU connected with socket 3::
perf stat -a -e nvidia_nvlink_c2c1_pmu_3/event=0x0/
CNVLink PMU
---------------
The CNVLink PMU monitors traffic from GPU and PCIE device on remote sockets
to local memory. For PCIE traffic, this PMU captures read and relaxed ordered
(RO) write traffic. Please see :ref:`NVIDIA_Uncore_PMU_Traffic_Coverage_Section`
for more info about the PMU traffic coverage.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_sources/devices/nvidia_cnvlink_pmu_<socket-id>.
Each SoC socket can be connected to one or more sockets via CNVLink. The user can
use "rem_socket" bitmap parameter to select the remote socket(s) to monitor.
Each bit represents the socket number, e.g. "rem_socket=0xE" corresponds to
socket 1 to 3.
/sys/bus/event_sources/devices/nvidia_cnvlink_pmu_<socket-id>/format/rem_socket
shows the valid bits that can be set in the "rem_socket" parameter.
The PMU can not distinguish the remote traffic initiator, therefore it does not
provide filter to select the traffic source to monitor. It reports combined
traffic from remote GPU and PCIE devices.
Example usage:
* Count event id 0x0 for the traffic from remote socket 1, 2, and 3 to socket 0::
perf stat -a -e nvidia_cnvlink_pmu_0/event=0x0,rem_socket=0xE/
* Count event id 0x0 for the traffic from remote socket 0, 2, and 3 to socket 1::
perf stat -a -e nvidia_cnvlink_pmu_1/event=0x0,rem_socket=0xD/
* Count event id 0x0 for the traffic from remote socket 0, 1, and 3 to socket 2::
perf stat -a -e nvidia_cnvlink_pmu_2/event=0x0,rem_socket=0xB/
* Count event id 0x0 for the traffic from remote socket 0, 1, and 2 to socket 3::
perf stat -a -e nvidia_cnvlink_pmu_3/event=0x0,rem_socket=0x7/
PCIE PMU
------------
The PCIE PMU monitors all read/write traffic from PCIE root ports to
local/remote memory. Please see :ref:`NVIDIA_Uncore_PMU_Traffic_Coverage_Section`
for more info about the PMU traffic coverage.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_sources/devices/nvidia_pcie_pmu_<socket-id>.
Each SoC socket can support multiple root ports. The user can use
"root_port" bitmap parameter to select the port(s) to monitor, i.e.
"root_port=0xF" corresponds to root port 0 to 3.
/sys/bus/event_sources/devices/nvidia_pcie_pmu_<socket-id>/format/root_port
shows the valid bits that can be set in the "root_port" parameter.
Example usage:
* Count event id 0x0 from root port 0 and 1 of socket 0::
perf stat -a -e nvidia_pcie_pmu_0/event=0x0,root_port=0x3/
* Count event id 0x0 from root port 0 and 1 of socket 1::
perf stat -a -e nvidia_pcie_pmu_1/event=0x0,root_port=0x3/
.. _NVIDIA_Uncore_PMU_Traffic_Coverage_Section:
Traffic Coverage
----------------
The PMU traffic coverage may vary dependent on the chip configuration:
* **NVIDIA Grace Hopper Superchip**: Hopper GPU is connected with Grace SoC.
Example configuration with two Grace SoCs::
********************************* *********************************
* SOCKET-A * * SOCKET-B *
* * * *
* :::::::: * * :::::::: *
* : PCIE : * * : PCIE : *
* :::::::: * * :::::::: *
* | * * | *
* | * * | *
* ::::::: ::::::::: * * ::::::::: ::::::: *
* : : : : * * : : : : *
* : GPU :<--NVLink-->: Grace :<---CNVLink--->: Grace :<--NVLink-->: GPU : *
* : : C2C : SoC : * * : SoC : C2C : : *
* ::::::: ::::::::: * * ::::::::: ::::::: *
* | | * * | | *
* | | * * | | *
* &&&&&&&& &&&&&&&& * * &&&&&&&& &&&&&&&& *
* & GMEM & & CMEM & * * & CMEM & & GMEM & *
* &&&&&&&& &&&&&&&& * * &&&&&&&& &&&&&&&& *
* * * *
********************************* *********************************
GMEM = GPU Memory (e.g. HBM)
CMEM = CPU Memory (e.g. LPDDR5X)
|
| Following table contains traffic coverage of Grace SoC PMU in socket-A:
::
+--------------+-------+-----------+-----------+-----+----------+----------+
| | Source |
+ +-------+-----------+-----------+-----+----------+----------+
| Destination | |GPU ATS |GPU Not-ATS| | Socket-B | Socket-B |
| |PCI R/W|Translated,|Translated | CPU | CPU/PCIE1| GPU/PCIE2|
| | |EGM | | | | |
+==============+=======+===========+===========+=====+==========+==========+
| Local | PCIE |NVLink-C2C0|NVLink-C2C1| SCF | SCF PMU | CNVLink |
| SYSRAM/CMEM | PMU |PMU |PMU | PMU | | PMU |
+--------------+-------+-----------+-----------+-----+----------+----------+
| Local GMEM | PCIE | N/A |NVLink-C2C1| SCF | SCF PMU | CNVLink |
| | PMU | |PMU | PMU | | PMU |
+--------------+-------+-----------+-----------+-----+----------+----------+
| Remote | PCIE |NVLink-C2C0|NVLink-C2C1| SCF | | |
| SYSRAM/CMEM | PMU |PMU |PMU | PMU | N/A | N/A |
| over CNVLink | | | | | | |
+--------------+-------+-----------+-----------+-----+----------+----------+
| Remote GMEM | PCIE |NVLink-C2C0|NVLink-C2C1| SCF | | |
| over CNVLink | PMU |PMU |PMU | PMU | N/A | N/A |
+--------------+-------+-----------+-----------+-----+----------+----------+
PCIE1 traffic represents strongly ordered (SO) writes.
PCIE2 traffic represents reads and relaxed ordered (RO) writes.
* **NVIDIA Grace CPU Superchip**: two Grace CPU SoCs are connected.
Example configuration with two Grace SoCs::
******************* *******************
* SOCKET-A * * SOCKET-B *
* * * *
* :::::::: * * :::::::: *
* : PCIE : * * : PCIE : *
* :::::::: * * :::::::: *
* | * * | *
* | * * | *
* ::::::::: * * ::::::::: *
* : : * * : : *
* : Grace :<--------NVLink------->: Grace : *
* : SoC : * C2C * : SoC : *
* ::::::::: * * ::::::::: *
* | * * | *
* | * * | *
* &&&&&&&& * * &&&&&&&& *
* & CMEM & * * & CMEM & *
* &&&&&&&& * * &&&&&&&& *
* * * *
******************* *******************
GMEM = GPU Memory (e.g. HBM)
CMEM = CPU Memory (e.g. LPDDR5X)
|
| Following table contains traffic coverage of Grace SoC PMU in socket-A:
::
+-----------------+-----------+---------+----------+-------------+
| | Source |
+ +-----------+---------+----------+-------------+
| Destination | | | Socket-B | Socket-B |
| | PCI R/W | CPU | CPU/PCIE1| PCIE2 |
| | | | | |
+=================+===========+=========+==========+=============+
| Local | PCIE PMU | SCF PMU | SCF PMU | NVLink-C2C0 |
| SYSRAM/CMEM | | | | PMU |
+-----------------+-----------+---------+----------+-------------+
| Remote | | | | |
| SYSRAM/CMEM | PCIE PMU | SCF PMU | N/A | N/A |
| over NVLink-C2C | | | | |
+-----------------+-----------+---------+----------+-------------+
PCIE1 traffic represents strongly ordered (SO) writes.
PCIE2 traffic represents reads and relaxed ordered (RO) writes.

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@ -3,4 +3,5 @@
# SPDX-License-Identifier: GPL-2.0
obj-$(CONFIG_ARM_CORESIGHT_PMU_ARCH_SYSTEM_PMU) += \
arm_cspmu.o
arm_cspmu.o \
nvidia_cspmu.o

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@ -31,6 +31,7 @@
#include <acpi/processor.h>
#include "arm_cspmu.h"
#include "nvidia_cspmu.h"
#define PMUNAME "arm_cspmu"
#define DRVNAME "arm-cs-arch-pmu"
@ -116,6 +117,9 @@
*/
#define HILOHI_MAX_POLL 1000
/* JEDEC-assigned JEP106 identification code */
#define ARM_CSPMU_IMPL_ID_NVIDIA 0x36B
static unsigned long arm_cspmu_cpuhp_state;
/*
@ -382,6 +386,11 @@ struct impl_match {
};
static const struct impl_match impl_match[] = {
{
.pmiidr = ARM_CSPMU_IMPL_ID_NVIDIA,
.mask = ARM_CSPMU_PMIIDR_IMPLEMENTER,
.impl_init_ops = nv_cspmu_init_ops
},
{}
};

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@ -0,0 +1,398 @@
// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2022, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
*
*/
/* Support for NVIDIA specific attributes. */
#include <linux/topology.h>
#include "nvidia_cspmu.h"
#define NV_PCIE_PORT_COUNT 10ULL
#define NV_PCIE_FILTER_ID_MASK GENMASK_ULL(NV_PCIE_PORT_COUNT - 1, 0)
#define NV_NVL_C2C_PORT_COUNT 2ULL
#define NV_NVL_C2C_FILTER_ID_MASK GENMASK_ULL(NV_NVL_C2C_PORT_COUNT - 1, 0)
#define NV_CNVL_PORT_COUNT 4ULL
#define NV_CNVL_FILTER_ID_MASK GENMASK_ULL(NV_CNVL_PORT_COUNT - 1, 0)
#define NV_GENERIC_FILTER_ID_MASK GENMASK_ULL(31, 0)
#define NV_PRODID_MASK GENMASK(31, 0)
#define NV_FORMAT_NAME_GENERIC 0
#define to_nv_cspmu_ctx(cspmu) ((struct nv_cspmu_ctx *)(cspmu->impl.ctx))
#define NV_CSPMU_EVENT_ATTR_4_INNER(_pref, _num, _suff, _config) \
ARM_CSPMU_EVENT_ATTR(_pref##_num##_suff, _config)
#define NV_CSPMU_EVENT_ATTR_4(_pref, _suff, _config) \
NV_CSPMU_EVENT_ATTR_4_INNER(_pref, _0_, _suff, _config), \
NV_CSPMU_EVENT_ATTR_4_INNER(_pref, _1_, _suff, _config + 1), \
NV_CSPMU_EVENT_ATTR_4_INNER(_pref, _2_, _suff, _config + 2), \
NV_CSPMU_EVENT_ATTR_4_INNER(_pref, _3_, _suff, _config + 3)
struct nv_cspmu_ctx {
const char *name;
u32 filter_mask;
u32 filter_default_val;
struct attribute **event_attr;
struct attribute **format_attr;
};
static struct attribute *scf_pmu_event_attrs[] = {
ARM_CSPMU_EVENT_ATTR(bus_cycles, 0x1d),
ARM_CSPMU_EVENT_ATTR(scf_cache_allocate, 0xF0),
ARM_CSPMU_EVENT_ATTR(scf_cache_refill, 0xF1),
ARM_CSPMU_EVENT_ATTR(scf_cache, 0xF2),
ARM_CSPMU_EVENT_ATTR(scf_cache_wb, 0xF3),
NV_CSPMU_EVENT_ATTR_4(socket, rd_data, 0x101),
NV_CSPMU_EVENT_ATTR_4(socket, dl_rsp, 0x105),
NV_CSPMU_EVENT_ATTR_4(socket, wb_data, 0x109),
NV_CSPMU_EVENT_ATTR_4(socket, ev_rsp, 0x10d),
NV_CSPMU_EVENT_ATTR_4(socket, prb_data, 0x111),
NV_CSPMU_EVENT_ATTR_4(socket, rd_outstanding, 0x115),
NV_CSPMU_EVENT_ATTR_4(socket, dl_outstanding, 0x119),
NV_CSPMU_EVENT_ATTR_4(socket, wb_outstanding, 0x11d),
NV_CSPMU_EVENT_ATTR_4(socket, wr_outstanding, 0x121),
NV_CSPMU_EVENT_ATTR_4(socket, ev_outstanding, 0x125),
NV_CSPMU_EVENT_ATTR_4(socket, prb_outstanding, 0x129),
NV_CSPMU_EVENT_ATTR_4(socket, rd_access, 0x12d),
NV_CSPMU_EVENT_ATTR_4(socket, dl_access, 0x131),
NV_CSPMU_EVENT_ATTR_4(socket, wb_access, 0x135),
NV_CSPMU_EVENT_ATTR_4(socket, wr_access, 0x139),
NV_CSPMU_EVENT_ATTR_4(socket, ev_access, 0x13d),
NV_CSPMU_EVENT_ATTR_4(socket, prb_access, 0x141),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_rd_data, 0x145),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_rd_access, 0x149),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wb_access, 0x14d),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_rd_outstanding, 0x151),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wr_outstanding, 0x155),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_rd_data, 0x159),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_rd_access, 0x15d),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wb_access, 0x161),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_rd_outstanding, 0x165),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wr_outstanding, 0x169),
ARM_CSPMU_EVENT_ATTR(gmem_rd_data, 0x16d),
ARM_CSPMU_EVENT_ATTR(gmem_rd_access, 0x16e),
ARM_CSPMU_EVENT_ATTR(gmem_rd_outstanding, 0x16f),
ARM_CSPMU_EVENT_ATTR(gmem_dl_rsp, 0x170),
ARM_CSPMU_EVENT_ATTR(gmem_dl_access, 0x171),
ARM_CSPMU_EVENT_ATTR(gmem_dl_outstanding, 0x172),
ARM_CSPMU_EVENT_ATTR(gmem_wb_data, 0x173),
ARM_CSPMU_EVENT_ATTR(gmem_wb_access, 0x174),
ARM_CSPMU_EVENT_ATTR(gmem_wb_outstanding, 0x175),
ARM_CSPMU_EVENT_ATTR(gmem_ev_rsp, 0x176),
ARM_CSPMU_EVENT_ATTR(gmem_ev_access, 0x177),
ARM_CSPMU_EVENT_ATTR(gmem_ev_outstanding, 0x178),
ARM_CSPMU_EVENT_ATTR(gmem_wr_data, 0x179),
ARM_CSPMU_EVENT_ATTR(gmem_wr_outstanding, 0x17a),
ARM_CSPMU_EVENT_ATTR(gmem_wr_access, 0x17b),
NV_CSPMU_EVENT_ATTR_4(socket, wr_data, 0x17c),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wr_data, 0x180),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wb_data, 0x184),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wr_access, 0x188),
NV_CSPMU_EVENT_ATTR_4(ocu, gmem_wb_outstanding, 0x18c),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wr_data, 0x190),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wb_data, 0x194),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wr_access, 0x198),
NV_CSPMU_EVENT_ATTR_4(ocu, rem_wb_outstanding, 0x19c),
ARM_CSPMU_EVENT_ATTR(gmem_wr_total_bytes, 0x1a0),
ARM_CSPMU_EVENT_ATTR(remote_socket_wr_total_bytes, 0x1a1),
ARM_CSPMU_EVENT_ATTR(remote_socket_rd_data, 0x1a2),
ARM_CSPMU_EVENT_ATTR(remote_socket_rd_outstanding, 0x1a3),
ARM_CSPMU_EVENT_ATTR(remote_socket_rd_access, 0x1a4),
ARM_CSPMU_EVENT_ATTR(cmem_rd_data, 0x1a5),
ARM_CSPMU_EVENT_ATTR(cmem_rd_access, 0x1a6),
ARM_CSPMU_EVENT_ATTR(cmem_rd_outstanding, 0x1a7),
ARM_CSPMU_EVENT_ATTR(cmem_dl_rsp, 0x1a8),
ARM_CSPMU_EVENT_ATTR(cmem_dl_access, 0x1a9),
ARM_CSPMU_EVENT_ATTR(cmem_dl_outstanding, 0x1aa),
ARM_CSPMU_EVENT_ATTR(cmem_wb_data, 0x1ab),
ARM_CSPMU_EVENT_ATTR(cmem_wb_access, 0x1ac),
ARM_CSPMU_EVENT_ATTR(cmem_wb_outstanding, 0x1ad),
ARM_CSPMU_EVENT_ATTR(cmem_ev_rsp, 0x1ae),
ARM_CSPMU_EVENT_ATTR(cmem_ev_access, 0x1af),
ARM_CSPMU_EVENT_ATTR(cmem_ev_outstanding, 0x1b0),
ARM_CSPMU_EVENT_ATTR(cmem_wr_data, 0x1b1),
ARM_CSPMU_EVENT_ATTR(cmem_wr_outstanding, 0x1b2),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_rd_data, 0x1b3),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_rd_access, 0x1b7),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wb_access, 0x1bb),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_rd_outstanding, 0x1bf),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wr_outstanding, 0x1c3),
ARM_CSPMU_EVENT_ATTR(ocu_prb_access, 0x1c7),
ARM_CSPMU_EVENT_ATTR(ocu_prb_data, 0x1c8),
ARM_CSPMU_EVENT_ATTR(ocu_prb_outstanding, 0x1c9),
ARM_CSPMU_EVENT_ATTR(cmem_wr_access, 0x1ca),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wr_access, 0x1cb),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wb_data, 0x1cf),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wr_data, 0x1d3),
NV_CSPMU_EVENT_ATTR_4(ocu, cmem_wb_outstanding, 0x1d7),
ARM_CSPMU_EVENT_ATTR(cmem_wr_total_bytes, 0x1db),
ARM_CSPMU_EVENT_ATTR(cycles, ARM_CSPMU_EVT_CYCLES_DEFAULT),
NULL,
};
static struct attribute *mcf_pmu_event_attrs[] = {
ARM_CSPMU_EVENT_ATTR(rd_bytes_loc, 0x0),
ARM_CSPMU_EVENT_ATTR(rd_bytes_rem, 0x1),
ARM_CSPMU_EVENT_ATTR(wr_bytes_loc, 0x2),
ARM_CSPMU_EVENT_ATTR(wr_bytes_rem, 0x3),
ARM_CSPMU_EVENT_ATTR(total_bytes_loc, 0x4),
ARM_CSPMU_EVENT_ATTR(total_bytes_rem, 0x5),
ARM_CSPMU_EVENT_ATTR(rd_req_loc, 0x6),
ARM_CSPMU_EVENT_ATTR(rd_req_rem, 0x7),
ARM_CSPMU_EVENT_ATTR(wr_req_loc, 0x8),
ARM_CSPMU_EVENT_ATTR(wr_req_rem, 0x9),
ARM_CSPMU_EVENT_ATTR(total_req_loc, 0xa),
ARM_CSPMU_EVENT_ATTR(total_req_rem, 0xb),
ARM_CSPMU_EVENT_ATTR(rd_cum_outs_loc, 0xc),
ARM_CSPMU_EVENT_ATTR(rd_cum_outs_rem, 0xd),
ARM_CSPMU_EVENT_ATTR(cycles, ARM_CSPMU_EVT_CYCLES_DEFAULT),
NULL,
};
static struct attribute *generic_pmu_event_attrs[] = {
ARM_CSPMU_EVENT_ATTR(cycles, ARM_CSPMU_EVT_CYCLES_DEFAULT),
NULL,
};
static struct attribute *scf_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
NULL,
};
static struct attribute *pcie_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
ARM_CSPMU_FORMAT_ATTR(root_port, "config1:0-9"),
NULL,
};
static struct attribute *nvlink_c2c_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
NULL,
};
static struct attribute *cnvlink_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
ARM_CSPMU_FORMAT_ATTR(rem_socket, "config1:0-3"),
NULL,
};
static struct attribute *generic_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
ARM_CSPMU_FORMAT_FILTER_ATTR,
NULL,
};
static struct attribute **
nv_cspmu_get_event_attrs(const struct arm_cspmu *cspmu)
{
const struct nv_cspmu_ctx *ctx = to_nv_cspmu_ctx(cspmu);
return ctx->event_attr;
}
static struct attribute **
nv_cspmu_get_format_attrs(const struct arm_cspmu *cspmu)
{
const struct nv_cspmu_ctx *ctx = to_nv_cspmu_ctx(cspmu);
return ctx->format_attr;
}
static const char *
nv_cspmu_get_name(const struct arm_cspmu *cspmu)
{
const struct nv_cspmu_ctx *ctx = to_nv_cspmu_ctx(cspmu);
return ctx->name;
}
static u32 nv_cspmu_event_filter(const struct perf_event *event)
{
const struct nv_cspmu_ctx *ctx =
to_nv_cspmu_ctx(to_arm_cspmu(event->pmu));
if (ctx->filter_mask == 0)
return ctx->filter_default_val;
return event->attr.config1 & ctx->filter_mask;
}
enum nv_cspmu_name_fmt {
NAME_FMT_GENERIC,
NAME_FMT_SOCKET
};
struct nv_cspmu_match {
u32 prodid;
u32 prodid_mask;
u64 filter_mask;
u32 filter_default_val;
const char *name_pattern;
enum nv_cspmu_name_fmt name_fmt;
struct attribute **event_attr;
struct attribute **format_attr;
};
static const struct nv_cspmu_match nv_cspmu_match[] = {
{
.prodid = 0x103,
.prodid_mask = NV_PRODID_MASK,
.filter_mask = NV_PCIE_FILTER_ID_MASK,
.filter_default_val = NV_PCIE_FILTER_ID_MASK,
.name_pattern = "nvidia_pcie_pmu_%u",
.name_fmt = NAME_FMT_SOCKET,
.event_attr = mcf_pmu_event_attrs,
.format_attr = pcie_pmu_format_attrs
},
{
.prodid = 0x104,
.prodid_mask = NV_PRODID_MASK,
.filter_mask = 0x0,
.filter_default_val = NV_NVL_C2C_FILTER_ID_MASK,
.name_pattern = "nvidia_nvlink_c2c1_pmu_%u",
.name_fmt = NAME_FMT_SOCKET,
.event_attr = mcf_pmu_event_attrs,
.format_attr = nvlink_c2c_pmu_format_attrs
},
{
.prodid = 0x105,
.prodid_mask = NV_PRODID_MASK,
.filter_mask = 0x0,
.filter_default_val = NV_NVL_C2C_FILTER_ID_MASK,
.name_pattern = "nvidia_nvlink_c2c0_pmu_%u",
.name_fmt = NAME_FMT_SOCKET,
.event_attr = mcf_pmu_event_attrs,
.format_attr = nvlink_c2c_pmu_format_attrs
},
{
.prodid = 0x106,
.prodid_mask = NV_PRODID_MASK,
.filter_mask = NV_CNVL_FILTER_ID_MASK,
.filter_default_val = NV_CNVL_FILTER_ID_MASK,
.name_pattern = "nvidia_cnvlink_pmu_%u",
.name_fmt = NAME_FMT_SOCKET,
.event_attr = mcf_pmu_event_attrs,
.format_attr = cnvlink_pmu_format_attrs
},
{
.prodid = 0x2CF,
.prodid_mask = NV_PRODID_MASK,
.filter_mask = 0x0,
.filter_default_val = 0x0,
.name_pattern = "nvidia_scf_pmu_%u",
.name_fmt = NAME_FMT_SOCKET,
.event_attr = scf_pmu_event_attrs,
.format_attr = scf_pmu_format_attrs
},
{
.prodid = 0,
.prodid_mask = 0,
.filter_mask = NV_GENERIC_FILTER_ID_MASK,
.filter_default_val = NV_GENERIC_FILTER_ID_MASK,
.name_pattern = "nvidia_uncore_pmu_%u",
.name_fmt = NAME_FMT_GENERIC,
.event_attr = generic_pmu_event_attrs,
.format_attr = generic_pmu_format_attrs
},
};
static char *nv_cspmu_format_name(const struct arm_cspmu *cspmu,
const struct nv_cspmu_match *match)
{
char *name;
struct device *dev = cspmu->dev;
static atomic_t pmu_generic_idx = {0};
switch (match->name_fmt) {
case NAME_FMT_SOCKET: {
const int cpu = cpumask_first(&cspmu->associated_cpus);
const int socket = cpu_to_node(cpu);
name = devm_kasprintf(dev, GFP_KERNEL, match->name_pattern,
socket);
break;
}
case NAME_FMT_GENERIC:
name = devm_kasprintf(dev, GFP_KERNEL, match->name_pattern,
atomic_fetch_inc(&pmu_generic_idx));
break;
default:
name = NULL;
break;
}
return name;
}
int nv_cspmu_init_ops(struct arm_cspmu *cspmu)
{
u32 prodid;
struct nv_cspmu_ctx *ctx;
struct device *dev = cspmu->dev;
struct arm_cspmu_impl_ops *impl_ops = &cspmu->impl.ops;
const struct nv_cspmu_match *match = nv_cspmu_match;
ctx = devm_kzalloc(dev, sizeof(struct nv_cspmu_ctx), GFP_KERNEL);
if (!ctx)
return -ENOMEM;
prodid = FIELD_GET(ARM_CSPMU_PMIIDR_PRODUCTID, cspmu->impl.pmiidr);
/* Find matching PMU. */
for (; match->prodid; match++) {
const u32 prodid_mask = match->prodid_mask;
if ((match->prodid & prodid_mask) == (prodid & prodid_mask))
break;
}
ctx->name = nv_cspmu_format_name(cspmu, match);
ctx->filter_mask = match->filter_mask;
ctx->filter_default_val = match->filter_default_val;
ctx->event_attr = match->event_attr;
ctx->format_attr = match->format_attr;
cspmu->impl.ctx = ctx;
/* NVIDIA specific callbacks. */
impl_ops->event_filter = nv_cspmu_event_filter;
impl_ops->get_event_attrs = nv_cspmu_get_event_attrs;
impl_ops->get_format_attrs = nv_cspmu_get_format_attrs;
impl_ops->get_name = nv_cspmu_get_name;
/* Set others to NULL to use default callback. */
impl_ops->event_type = NULL;
impl_ops->event_attr_is_visible = NULL;
impl_ops->get_identifier = NULL;
impl_ops->is_cycle_counter_event = NULL;
return 0;
}
EXPORT_SYMBOL_GPL(nv_cspmu_init_ops);

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/* SPDX-License-Identifier: GPL-2.0
*
* Copyright (c) 2022, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
*
*/
/* Support for NVIDIA specific attributes. */
#ifndef __NVIDIA_CSPMU_H__
#define __NVIDIA_CSPMU_H__
#include "arm_cspmu.h"
/* Allocate NVIDIA descriptor. */
int nv_cspmu_init_ops(struct arm_cspmu *cspmu);
#endif /* __NVIDIA_CSPMU_H__ */