superrob1500
/
mirror-linux
mirror of https://github.com/torvalds/linux
1
0
Fork 0
Code Issues Packages Projects Releases Wiki Activity

perf/arm_cspmu: nvidia: Add Tegra410 PCIE PMU 

Adds PCIE PMU support in Tegra410 SOC. This PMU is instanced
in each root complex in the SOC and can capture traffic from
PCIE device to various memory types. This PMU can filter traffic
based on the originating root port or BDF and the target memory
types (CPU DRAM, GPU Memory, CXL Memory, or remote Memory).

Reviewed-by: Ilkka Koskinen <ilkka@os.amperecomputing.com>
Signed-off-by: Besar Wicaksono <bwicaksono@nvidia.com>
Signed-off-by: Will Deacon <will@kernel.org>
master
Besar Wicaksono 2026-03-24 01:29:48 +00:00 committed by Will Deacon
parent bc86281fe4
commit bf585ba147
2 changed files with 368 additions and 5 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

163
Documentation/admin-guide/perf/nvidia-tegra410-pmu.rst
View File

@ -6,6 +6,7 @@ The NVIDIA Tegra410 SoC includes various system PMUs to measure key performance
metrics like memory bandwidth, latency, and utilization:
* Unified Coherence Fabric (UCF)
* PCIE
PMU Driver
----------
@ -104,3 +105,165 @@ Example usage:
destination filter = remote memory::
perf stat -a -e nvidia_ucf_pmu_1/event=0x0,src_loc_noncpu=0x1,dst_rem=0x1/
PCIE PMU
--------
This PMU is located in the SOC fabric connecting the PCIE root complex (RC) and
the memory subsystem. It monitors all read/write traffic from the root port(s)
or a particular BDF in a PCIE RC to local or remote memory. There is one PMU per
PCIE RC in the SoC. Each RC can have up to 16 lanes that can be bifurcated into
up to 8 root ports. The traffic from each root port can be filtered using RP or
BDF filter. For example, specifying "src_rp_mask=0xFF" means the PMU counter will
capture traffic from all RPs. Please see below for more details.
The events and configuration options of this PMU device are described in sysfs,
see /sys/bus/event_source/devices/nvidia_pcie_pmu_<socket-id>_rc_<pcie-rc-id>.
The events in this PMU can be used to measure bandwidth, utilization, and
latency:
* rd_req: count the number of read requests by PCIE device.
* wr_req: count the number of write requests by PCIE device.
* rd_bytes: count the number of bytes transferred by rd_req.
* wr_bytes: count the number of bytes transferred by wr_req.
* rd_cum_outs: count outstanding rd_req each cycle.
* cycles: count the clock cycles of SOC fabric connected to the PCIE interface.
The average bandwidth is calculated as::
AVG_RD_BANDWIDTH_IN_GBPS = RD_BYTES / ELAPSED_TIME_IN_NS
AVG_WR_BANDWIDTH_IN_GBPS = WR_BYTES / ELAPSED_TIME_IN_NS
The average request rate is calculated as::
AVG_RD_REQUEST_RATE = RD_REQ / CYCLES
AVG_WR_REQUEST_RATE = WR_REQ / CYCLES
The average latency is calculated as::
FREQ_IN_GHZ = CYCLES / ELAPSED_TIME_IN_NS
AVG_LATENCY_IN_CYCLES = RD_CUM_OUTS / RD_REQ
AVERAGE_LATENCY_IN_NS = AVG_LATENCY_IN_CYCLES / FREQ_IN_GHZ
The PMU events can be filtered based on the traffic source and destination.
The source filter indicates the PCIE devices that will be monitored. The
destination filter specifies the destination memory type, e.g. local system
memory (CMEM), local GPU memory (GMEM), or remote memory. The local/remote
classification of the destination filter is based on the home socket of the
address, not where the data actually resides. These filters can be found in
/sys/bus/event_source/devices/nvidia_pcie_pmu_<socket-id>_rc_<pcie-rc-id>/format/.
The list of event filters:
* Source filter:
* src_rp_mask: bitmask of root ports that will be monitored. Each bit in this
bitmask represents the RP index in the RC. If the bit is set, all devices under
the associated RP will be monitored. E.g "src_rp_mask=0xF" will monitor
devices in root port 0 to 3.
* src_bdf: the BDF that will be monitored. This is a 16-bit value that
follows formula: (bus << 8) + (device << 3) + (function). For example, the
value of BDF 27:01.1 is 0x2781.
* src_bdf_en: enable the BDF filter. If this is set, the BDF filter value in
"src_bdf" is used to filter the traffic.
Note that Root-Port and BDF filters are mutually exclusive and the PMU in
each RC can only have one BDF filter for the whole counters. If BDF filter
is enabled, the BDF filter value will be applied to all events.
* Destination filter:
* dst_loc_cmem: if set, count events to local system memory (CMEM) address
* dst_loc_gmem: if set, count events to local GPU memory (GMEM) address
* dst_loc_pcie_p2p: if set, count events to local PCIE peer address
* dst_loc_pcie_cxl: if set, count events to local CXL memory address
* dst_rem: if set, count events to remote memory address
If the source filter is not specified, the PMU will count events from all root
ports. If the destination filter is not specified, the PMU will count events
to all destinations.
Example usage:
* Count event id 0x0 from root port 0 of PCIE RC-0 on socket 0 targeting all
destinations::
perf stat -a -e nvidia_pcie_pmu_0_rc_0/event=0x0,src_rp_mask=0x1/
* Count event id 0x1 from root port 0 and 1 of PCIE RC-1 on socket 0 and
targeting just local CMEM of socket 0::
perf stat -a -e nvidia_pcie_pmu_0_rc_1/event=0x1,src_rp_mask=0x3,dst_loc_cmem=0x1/
* Count event id 0x2 from root port 0 of PCIE RC-2 on socket 1 targeting all
destinations::
perf stat -a -e nvidia_pcie_pmu_1_rc_2/event=0x2,src_rp_mask=0x1/
* Count event id 0x3 from root port 0 and 1 of PCIE RC-3 on socket 1 and
targeting just local CMEM of socket 1::
perf stat -a -e nvidia_pcie_pmu_1_rc_3/event=0x3,src_rp_mask=0x3,dst_loc_cmem=0x1/
* Count event id 0x4 from BDF 01:01.0 of PCIE RC-4 on socket 0 targeting all
destinations::
perf stat -a -e nvidia_pcie_pmu_0_rc_4/event=0x4,src_bdf=0x0180,src_bdf_en=0x1/
Mapping the RC# to lspci segment number can be non-trivial; hence a new NVIDIA
Designated Vendor Specific Capability (DVSEC) register is added into the PCIE config space
for each RP. This DVSEC has vendor id "10de" and DVSEC id of "0x4". The DVSEC register
contains the following information to map PCIE devices under the RP back to its RC# :
- Bus# (byte 0xc) : bus number as reported by the lspci output
- Segment# (byte 0xd) : segment number as reported by the lspci output
- RP# (byte 0xe) : port number as reported by LnkCap attribute from lspci for a device with Root Port capability
- RC# (byte 0xf): root complex number associated with the RP
- Socket# (byte 0x10): socket number associated with the RP
Example script for mapping lspci BDF to RC# and socket#::
#!/bin/bash
while read bdf rest; do
dvsec4_reg=$(lspci -vv -s $bdf | awk '
/Designated Vendor-Specific: Vendor=10de ID=0004/ {
match($0, /\[([0-9a-fA-F]+)/, arr);
print "0x" arr[1];
exit
}
')
if [ -n "$dvsec4_reg" ]; then
bus=$(setpci -s $bdf $(printf '0x%x' $((${dvsec4_reg} + 0xc))).b)
segment=$(setpci -s $bdf $(printf '0x%x' $((${dvsec4_reg} + 0xd))).b)
rp=$(setpci -s $bdf $(printf '0x%x' $((${dvsec4_reg} + 0xe))).b)
rc=$(setpci -s $bdf $(printf '0x%x' $((${dvsec4_reg} + 0xf))).b)
socket=$(setpci -s $bdf $(printf '0x%x' $((${dvsec4_reg} + 0x10))).b)
echo "$bdf: Bus=$bus, Segment=$segment, RP=$rp, RC=$rc, Socket=$socket"
fi
done < <(lspci -d 10de:)
Example output::
0001:00:00.0: Bus=00, Segment=01, RP=00, RC=00, Socket=00
0002:80:00.0: Bus=80, Segment=02, RP=01, RC=01, Socket=00
0002:a0:00.0: Bus=a0, Segment=02, RP=02, RC=01, Socket=00
0002:c0:00.0: Bus=c0, Segment=02, RP=03, RC=01, Socket=00
0002:e0:00.0: Bus=e0, Segment=02, RP=04, RC=01, Socket=00
0003:00:00.0: Bus=00, Segment=03, RP=00, RC=02, Socket=00
0004:00:00.0: Bus=00, Segment=04, RP=00, RC=03, Socket=00
0005:00:00.0: Bus=00, Segment=05, RP=00, RC=04, Socket=00
0005:40:00.0: Bus=40, Segment=05, RP=01, RC=04, Socket=00
0005:c0:00.0: Bus=c0, Segment=05, RP=02, RC=04, Socket=00
0006:00:00.0: Bus=00, Segment=06, RP=00, RC=05, Socket=00
0009:00:00.0: Bus=00, Segment=09, RP=00, RC=00, Socket=01
000a:80:00.0: Bus=80, Segment=0a, RP=01, RC=01, Socket=01
000a:a0:00.0: Bus=a0, Segment=0a, RP=02, RC=01, Socket=01
000a:e0:00.0: Bus=e0, Segment=0a, RP=03, RC=01, Socket=01
000b:00:00.0: Bus=00, Segment=0b, RP=00, RC=02, Socket=01
000c:00:00.0: Bus=00, Segment=0c, RP=00, RC=03, Socket=01
000d:00:00.0: Bus=00, Segment=0d, RP=00, RC=04, Socket=01
000d:40:00.0: Bus=40, Segment=0d, RP=01, RC=04, Socket=01
000d:c0:00.0: Bus=c0, Segment=0d, RP=02, RC=04, Socket=01
000e:00:00.0: Bus=00, Segment=0e, RP=00, RC=05, Socket=01

210
drivers/perf/arm_cspmu/nvidia_cspmu.c
View File

@ -8,6 +8,7 @@
#include <linux/io.h>
#include <linux/module.h>
#include <linux/property.h>
#include <linux/topology.h>
#include "arm_cspmu.h"
@ -28,6 +29,19 @@
#define NV_UCF_FILTER_DST GENMASK_ULL(11, 8)
#define NV_UCF_FILTER_DEFAULT (NV_UCF_FILTER_SRC | NV_UCF_FILTER_DST)
#define NV_PCIE_V2_PORT_COUNT 8ULL
#define NV_PCIE_V2_FILTER_ID_MASK GENMASK_ULL(24, 0)
#define NV_PCIE_V2_FILTER_PORT GENMASK_ULL(NV_PCIE_V2_PORT_COUNT - 1, 0)
#define NV_PCIE_V2_FILTER_BDF_VAL GENMASK_ULL(23, NV_PCIE_V2_PORT_COUNT)
#define NV_PCIE_V2_FILTER_BDF_EN BIT(24)
#define NV_PCIE_V2_FILTER_BDF_VAL_EN GENMASK_ULL(24, NV_PCIE_V2_PORT_COUNT)
#define NV_PCIE_V2_FILTER_DEFAULT NV_PCIE_V2_FILTER_PORT
#define NV_PCIE_V2_DST_COUNT 5ULL
#define NV_PCIE_V2_FILTER2_ID_MASK GENMASK_ULL(4, 0)
#define NV_PCIE_V2_FILTER2_DST GENMASK_ULL(NV_PCIE_V2_DST_COUNT - 1, 0)
#define NV_PCIE_V2_FILTER2_DEFAULT NV_PCIE_V2_FILTER2_DST
#define NV_GENERIC_FILTER_ID_MASK GENMASK_ULL(31, 0)
#define NV_PRODID_MASK (PMIIDR_PRODUCTID | PMIIDR_VARIANT | PMIIDR_REVISION)
@ -161,6 +175,16 @@ static struct attribute *ucf_pmu_event_attrs[] = {
NULL
};
static struct attribute *pcie_v2_pmu_event_attrs[] = {
ARM_CSPMU_EVENT_ATTR(rd_bytes, 0x0),
ARM_CSPMU_EVENT_ATTR(wr_bytes, 0x1),
ARM_CSPMU_EVENT_ATTR(rd_req, 0x2),
ARM_CSPMU_EVENT_ATTR(wr_req, 0x3),
ARM_CSPMU_EVENT_ATTR(rd_cum_outs, 0x4),
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,
@ -201,6 +225,19 @@ static struct attribute *ucf_pmu_format_attrs[] = {
NULL
};
static struct attribute *pcie_v2_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
ARM_CSPMU_FORMAT_ATTR(src_rp_mask, "config1:0-7"),
ARM_CSPMU_FORMAT_ATTR(src_bdf, "config1:8-23"),
ARM_CSPMU_FORMAT_ATTR(src_bdf_en, "config1:24"),
ARM_CSPMU_FORMAT_ATTR(dst_loc_cmem, "config2:0"),
ARM_CSPMU_FORMAT_ATTR(dst_loc_gmem, "config2:1"),
ARM_CSPMU_FORMAT_ATTR(dst_loc_pcie_p2p, "config2:2"),
ARM_CSPMU_FORMAT_ATTR(dst_loc_pcie_cxl, "config2:3"),
ARM_CSPMU_FORMAT_ATTR(dst_rem, "config2:4"),
NULL
};
static struct attribute *generic_pmu_format_attrs[] = {
ARM_CSPMU_FORMAT_EVENT_ATTR,
ARM_CSPMU_FORMAT_FILTER_ATTR,
@ -232,6 +269,32 @@ nv_cspmu_get_name(const struct arm_cspmu *cspmu)
return ctx->name;
}
#if defined(CONFIG_ACPI) && defined(CONFIG_ARM64)
static int nv_cspmu_get_inst_id(const struct arm_cspmu *cspmu, u32 *id)
{
struct fwnode_handle *fwnode;
struct acpi_device *adev;
int ret;
adev = arm_cspmu_acpi_dev_get(cspmu);
if (!adev)
return -ENODEV;
fwnode = acpi_fwnode_handle(adev);
ret = fwnode_property_read_u32(fwnode, "instance_id", id);
if (ret)
dev_err(cspmu->dev, "Failed to get instance ID\n");
acpi_dev_put(adev);
return ret;
}
#else
static int nv_cspmu_get_inst_id(const struct arm_cspmu *cspmu, u32 *id)
{
return -EINVAL;
}
#endif
static u32 nv_cspmu_event_filter(const struct perf_event *event)
{
const struct nv_cspmu_ctx *ctx =
@ -277,6 +340,20 @@ static void nv_cspmu_set_ev_filter(struct arm_cspmu *cspmu,
}
}
static void nv_cspmu_reset_ev_filter(struct arm_cspmu *cspmu,
const struct perf_event *event)
{
const struct nv_cspmu_ctx *ctx =
to_nv_cspmu_ctx(to_arm_cspmu(event->pmu));
const u32 offset = 4 * event->hw.idx;
if (ctx->get_filter)
writel(0, cspmu->base0 + PMEVFILTR + offset);
if (ctx->get_filter2)
writel(0, cspmu->base0 + PMEVFILT2R + offset);
}
static void nv_cspmu_set_cc_filter(struct arm_cspmu *cspmu,
const struct perf_event *event)
{
@ -307,9 +384,103 @@ static u32 ucf_pmu_event_filter(const struct perf_event *event)
return ret;
}
static u32 pcie_v2_pmu_bdf_val_en(u32 filter)
{
const u32 bdf_en = FIELD_GET(NV_PCIE_V2_FILTER_BDF_EN, filter);
/* Returns both BDF value and enable bit if BDF filtering is enabled. */
if (bdf_en)
return FIELD_GET(NV_PCIE_V2_FILTER_BDF_VAL_EN, filter);
/* Ignore the BDF value if BDF filter is not enabled. */
return 0;
}
static u32 pcie_v2_pmu_event_filter(const struct perf_event *event)
{
u32 filter, lead_filter, lead_bdf;
struct perf_event *leader;
const struct nv_cspmu_ctx *ctx =
to_nv_cspmu_ctx(to_arm_cspmu(event->pmu));
filter = event->attr.config1 & ctx->filter_mask;
if (filter != 0)
return filter;
leader = event->group_leader;
/* Use leader's filter value if its BDF filtering is enabled. */
if (event != leader) {
lead_filter = pcie_v2_pmu_event_filter(leader);
lead_bdf = pcie_v2_pmu_bdf_val_en(lead_filter);
if (lead_bdf != 0)
return lead_filter;
}
/* Otherwise, return default filter value. */
return ctx->filter_default_val;
}
static int pcie_v2_pmu_validate_event(struct arm_cspmu *cspmu,
struct perf_event *new_ev)
{
/*
* Make sure the events are using same BDF filter since the PCIE-SRC PMU
* only supports one common BDF filter setting for all of the counters.
*/
int idx;
u32 new_filter, new_rp, new_bdf, new_lead_filter, new_lead_bdf;
struct perf_event *new_leader;
if (cspmu->impl.ops.is_cycle_counter_event(new_ev))
return 0;
new_leader = new_ev->group_leader;
new_filter = pcie_v2_pmu_event_filter(new_ev);
new_lead_filter = pcie_v2_pmu_event_filter(new_leader);
new_bdf = pcie_v2_pmu_bdf_val_en(new_filter);
new_lead_bdf = pcie_v2_pmu_bdf_val_en(new_lead_filter);
new_rp = FIELD_GET(NV_PCIE_V2_FILTER_PORT, new_filter);
if (new_rp != 0 && new_bdf != 0) {
dev_err(cspmu->dev,
"RP and BDF filtering are mutually exclusive\n");
return -EINVAL;
}
if (new_bdf != new_lead_bdf) {
dev_err(cspmu->dev,
"sibling and leader BDF value should be equal\n");
return -EINVAL;
}
/* Compare BDF filter on existing events. */
idx = find_first_bit(cspmu->hw_events.used_ctrs,
cspmu->cycle_counter_logical_idx);
if (idx != cspmu->cycle_counter_logical_idx) {
struct perf_event *leader = cspmu->hw_events.events[idx]->group_leader;
const u32 lead_filter = pcie_v2_pmu_event_filter(leader);
const u32 lead_bdf = pcie_v2_pmu_bdf_val_en(lead_filter);
if (new_lead_bdf != lead_bdf) {
dev_err(cspmu->dev, "only one BDF value is supported\n");
return -EINVAL;
}
}
return 0;
}
enum nv_cspmu_name_fmt {
NAME_FMT_GENERIC,
NAME_FMT_SOCKET
NAME_FMT_SOCKET,
NAME_FMT_SOCKET_INST,
};
struct nv_cspmu_match {
@ -427,6 +598,26 @@ static const struct nv_cspmu_match nv_cspmu_match[] = {
.get_filter = ucf_pmu_event_filter,
},
},
{
.prodid = 0x10301000,
.prodid_mask = NV_PRODID_MASK,
.name_pattern = "nvidia_pcie_pmu_%u_rc_%u",
.name_fmt = NAME_FMT_SOCKET_INST,
.template_ctx = {
.event_attr = pcie_v2_pmu_event_attrs,
.format_attr = pcie_v2_pmu_format_attrs,
.filter_mask = NV_PCIE_V2_FILTER_ID_MASK,
.filter_default_val = NV_PCIE_V2_FILTER_DEFAULT,
.filter2_mask = NV_PCIE_V2_FILTER2_ID_MASK,
.filter2_default_val = NV_PCIE_V2_FILTER2_DEFAULT,
.get_filter = pcie_v2_pmu_event_filter,
.get_filter2 = nv_cspmu_event_filter2,
},
.ops = {
.validate_event = pcie_v2_pmu_validate_event,
.reset_ev_filter = nv_cspmu_reset_ev_filter,
}
},
{
.prodid = 0,
.prodid_mask = 0,
@ -450,7 +641,7 @@ static const struct nv_cspmu_match nv_cspmu_match[] = {
static char *nv_cspmu_format_name(const struct arm_cspmu *cspmu,
const struct nv_cspmu_match *match)
{
char *name;
char *name = NULL;
struct device *dev = cspmu->dev;
static atomic_t pmu_generic_idx = {0};
@ -464,13 +655,20 @@ static char *nv_cspmu_format_name(const struct arm_cspmu *cspmu,
socket);
break;
}
case NAME_FMT_SOCKET_INST: {
const int cpu = cpumask_first(&cspmu->associated_cpus);
const int socket = cpu_to_node(cpu);
u32 inst_id;
if (!nv_cspmu_get_inst_id(cspmu, &inst_id))
name = devm_kasprintf(dev, GFP_KERNEL,
match->name_pattern, socket, inst_id);
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;
@ -511,8 +709,10 @@ static int nv_cspmu_init_ops(struct arm_cspmu *cspmu)
cspmu->impl.ctx = ctx;
/* NVIDIA specific callbacks. */
SET_OP(validate_event, impl_ops, match, NULL);
SET_OP(set_cc_filter, impl_ops, match, nv_cspmu_set_cc_filter);
SET_OP(set_ev_filter, impl_ops, match, nv_cspmu_set_ev_filter);
SET_OP(reset_ev_filter, impl_ops, match, NULL);
SET_OP(get_event_attrs, impl_ops, match, nv_cspmu_get_event_attrs);
SET_OP(get_format_attrs, impl_ops, match, nv_cspmu_get_format_attrs);
SET_OP(get_name, impl_ops, match, nv_cspmu_get_name);