nv-tegra-mirror/linux-nvgpu
1
0
Fork 0
mirror of git://nv-tegra.nvidia.com/linux-nvgpu.git synced 2025-12-22 17:36:20 +03:00
Code Issues Packages Projects Releases Wiki Activity
Files
2f3c1adad40cb1525da167b7e3590083594ae6d1
linux-nvgpu/drivers/gpu/nvgpu/hal/perf/perf_gv11b.c
Antony Clince Alex c0f4723339 gpu: nvgpu: perbuf: update PMA buffer mapping 
The PMA unit can only access GPU VAs within a 4GB window, hence both
the user allocated PMA buffer and the kernel allocated bytes available
buffer should lie in the same 4GB window. This is accomplished by
carving out and reserving a 4GB VA space in perbuf.vm and using fixed
GPU VAs to ensure that both buffers are bound within the same 4GB window.

In addition, update ALLOC_PMA_STREAM to use pma_buffer_offset,
pma_buffer_map_size fields correctly.

Bug 3503708

Change-Id: Ic5297a22c2db42b18ff5e676d565d3be3c1cd780
Signed-off-by: Antony Clince Alex <aalex@nvidia.com>
Reviewed-on: https://git-master.nvidia.com/r/c/linux-nvgpu/+/2671637
Reviewed-by: svcacv <svcacv@nvidia.com>
Reviewed-by: Deepak Nibade <dnibade@nvidia.com>
Reviewed-by: svc-mobile-coverity <svc-mobile-coverity@nvidia.com>
Reviewed-by: svc-mobile-cert <svc-mobile-cert@nvidia.com>
Reviewed-by: Vaibhav Kachore <vkachore@nvidia.com>
GVS: Gerrit_Virtual_Submit
2022-03-07 15:17:35 -08:00

648 lines
15 KiB
C
Raw Blame History

/*
* Copyright (c) 2018-2022, NVIDIA CORPORATION. All rights reserved.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
#include <nvgpu/io.h>
#include <nvgpu/mm.h>
#include <nvgpu/fbp.h>
#include <nvgpu/gr/gr_utils.h>
#include <nvgpu/gr/config.h>
#include <nvgpu/bug.h>
#include <nvgpu/gk20a.h>
#include <nvgpu/utils.h>
#include "perf_gv11b.h"
#include <nvgpu/hw/gv11b/hw_perf_gv11b.h>
#define PMM_ROUTER_OFFSET 0x200U
bool gv11b_perf_get_membuf_overflow_status(struct gk20a *g)
{
const u32 st = perf_pmasys_control_membuf_status_overflowed_f();
return st == (nvgpu_readl(g, perf_pmasys_control_r()) & st);
}
u32 gv11b_perf_get_membuf_pending_bytes(struct gk20a *g)
{
return nvgpu_readl(g, perf_pmasys_mem_bytes_r());
}
void gv11b_perf_set_membuf_handled_bytes(struct gk20a *g,
u32 entries, u32 entry_size)
{
if (entries > 0U) {
nvgpu_writel(g, perf_pmasys_mem_bump_r(), entries * entry_size);
}
}
void gv11b_perf_membuf_reset_streaming(struct gk20a *g)
{
u32 engine_status;
u32 num_unread_bytes;
engine_status = nvgpu_readl(g, perf_pmasys_enginestatus_r());
WARN_ON(0U ==
(engine_status & perf_pmasys_enginestatus_rbufempty_empty_f()));
nvgpu_writel(g, perf_pmasys_control_r(),
perf_pmasys_control_membuf_clear_status_doit_f());
num_unread_bytes = nvgpu_readl(g, perf_pmasys_mem_bytes_r());
if (num_unread_bytes != 0U) {
nvgpu_writel(g, perf_pmasys_mem_bump_r(), num_unread_bytes);
}
}
void gv11b_perf_enable_membuf(struct gk20a *g, u32 size, u64 buf_addr)
{
u32 addr_lo;
u32 addr_hi;
addr_lo = u64_lo32(buf_addr);
addr_hi = u64_hi32(buf_addr);
nvgpu_writel(g, perf_pmasys_outbase_r(), addr_lo);
nvgpu_writel(g, perf_pmasys_outbaseupper_r(),
perf_pmasys_outbaseupper_ptr_f(addr_hi));
nvgpu_writel(g, perf_pmasys_outsize_r(), size);
}
void gv11b_perf_disable_membuf(struct gk20a *g)
{
nvgpu_writel(g, perf_pmasys_outbase_r(), 0);
nvgpu_writel(g, perf_pmasys_outbaseupper_r(),
perf_pmasys_outbaseupper_ptr_f(0));
nvgpu_writel(g, perf_pmasys_outsize_r(), 0);
}
void gv11b_perf_bind_mem_bytes_buffer_addr(struct gk20a *g, u64 buf_addr)
{
u32 addr_lo;
/*
* For mem bytes addr, the upper 8 bits of the 40bit VA is taken
* from perf_pmasys_channel_outbaseupper_r(), so only consider
* the lower 32bits in the buf_addr and discard the rest.
*/
buf_addr = u64_lo32(buf_addr);
buf_addr = buf_addr >> perf_pmasys_mem_bytes_addr_ptr_b();
addr_lo = nvgpu_safe_cast_u64_to_u32(buf_addr);
nvgpu_writel(g, perf_pmasys_mem_bytes_addr_r(),
perf_pmasys_mem_bytes_addr_ptr_f(addr_lo));
}
int gv11b_perf_update_get_put(struct gk20a *g, u64 bytes_consumed,
bool update_available_bytes, u64 *put_ptr,
bool *overflowed)
{
u32 val;
if (bytes_consumed != 0U) {
nvgpu_writel(g, perf_pmasys_mem_bump_r(), (u32)bytes_consumed);
}
if (update_available_bytes) {
val = nvgpu_readl(g, perf_pmasys_control_r());
val = set_field(val, perf_pmasys_control_update_bytes_m(),
perf_pmasys_control_update_bytes_doit_f());
nvgpu_writel(g, perf_pmasys_control_r(), val);
}
if (put_ptr) {
*put_ptr = (u64)nvgpu_readl(g, perf_pmasys_mem_head_r());
}
if (overflowed) {
*overflowed = g->ops.perf.get_membuf_overflow_status(g);
}
return 0;
}
void gv11b_perf_init_inst_block(struct gk20a *g, struct nvgpu_mem *inst_block)
{
u32 inst_block_ptr = nvgpu_inst_block_ptr(g, inst_block);
nvgpu_writel(g, perf_pmasys_mem_block_r(),
perf_pmasys_mem_block_base_f(inst_block_ptr) |
perf_pmasys_mem_block_valid_true_f() |
nvgpu_aperture_mask(g, inst_block,
perf_pmasys_mem_block_target_sys_ncoh_f(),
perf_pmasys_mem_block_target_sys_coh_f(),
perf_pmasys_mem_block_target_lfb_f()));
}
void gv11b_perf_deinit_inst_block(struct gk20a *g)
{
nvgpu_writel(g, perf_pmasys_mem_block_r(),
perf_pmasys_mem_block_base_f(0) |
perf_pmasys_mem_block_valid_false_f() |
perf_pmasys_mem_block_target_f(0));
}
u32 gv11b_perf_get_pmmsys_per_chiplet_offset(void)
{
return (perf_pmmsys_extent_v() - perf_pmmsys_base_v() + 1U);
}
u32 gv11b_perf_get_pmmgpc_per_chiplet_offset(void)
{
return (perf_pmmgpc_extent_v() - perf_pmmgpc_base_v() + 1U);
}
u32 gv11b_perf_get_pmmfbp_per_chiplet_offset(void)
{
return (perf_pmmfbp_extent_v() - perf_pmmfbp_base_v() + 1U);
}
static const u32 hwpm_sys_perfmon_regs[] =
{
/* This list is autogenerated. Do not edit. */
0x00240040,
0x00240044,
0x00240048,
0x0024004c,
0x00240050,
0x00240054,
0x00240058,
0x0024005c,
0x00240060,
0x00240064,
0x00240068,
0x0024006c,
0x00240070,
0x00240074,
0x00240078,
0x0024007c,
0x00240080,
0x00240084,
0x00240088,
0x0024008c,
0x00240090,
0x00240094,
0x00240098,
0x0024009c,
0x002400a0,
0x002400a4,
0x002400a8,
0x002400ac,
0x002400b0,
0x002400b4,
0x002400b8,
0x002400bc,
0x002400c0,
0x002400c4,
0x002400c8,
0x002400cc,
0x002400d0,
0x002400d4,
0x002400d8,
0x002400dc,
0x002400e0,
0x002400e4,
0x002400e8,
0x002400ec,
0x002400f8,
0x002400fc,
0x00240104,
0x00240108,
0x0024010c,
0x00240110,
0x00240120,
0x00240114,
0x00240118,
0x0024011c,
0x00240124,
};
static const u32 hwpm_gpc_perfmon_regs[] =
{
/* This list is autogenerated. Do not edit. */
0x00278040,
0x00278044,
0x00278048,
0x0027804c,
0x00278050,
0x00278054,
0x00278058,
0x0027805c,
0x00278060,
0x00278064,
0x00278068,
0x0027806c,
0x00278070,
0x00278074,
0x00278078,
0x0027807c,
0x00278080,
0x00278084,
0x00278088,
0x0027808c,
0x00278090,
0x00278094,
0x00278098,
0x0027809c,
0x002780a0,
0x002780a4,
0x002780a8,
0x002780ac,
0x002780b0,
0x002780b4,
0x002780b8,
0x002780bc,
0x002780c0,
0x002780c4,
0x002780c8,
0x002780cc,
0x002780d0,
0x002780d4,
0x002780d8,
0x002780dc,
0x002780e0,
0x002780e4,
0x002780e8,
0x002780ec,
0x002780f8,
0x002780fc,
0x00278104,
0x00278108,
0x0027810c,
0x00278110,
0x00278120,
0x00278114,
0x00278118,
0x0027811c,
0x00278124,
};
static const u32 hwpm_fbp_perfmon_regs[] =
{
/* This list is autogenerated. Do not edit. */
0x0027c040,
0x0027c044,
0x0027c048,
0x0027c04c,
0x0027c050,
0x0027c054,
0x0027c058,
0x0027c05c,
0x0027c060,
0x0027c064,
0x0027c068,
0x0027c06c,
0x0027c070,
0x0027c074,
0x0027c078,
0x0027c07c,
0x0027c080,
0x0027c084,
0x0027c088,
0x0027c08c,
0x0027c090,
0x0027c094,
0x0027c098,
0x0027c09c,
0x0027c0a0,
0x0027c0a4,
0x0027c0a8,
0x0027c0ac,
0x0027c0b0,
0x0027c0b4,
0x0027c0b8,
0x0027c0bc,
0x0027c0c0,
0x0027c0c4,
0x0027c0c8,
0x0027c0cc,
0x0027c0d0,
0x0027c0d4,
0x0027c0d8,
0x0027c0dc,
0x0027c0e0,
0x0027c0e4,
0x0027c0e8,
0x0027c0ec,
0x0027c0f8,
0x0027c0fc,
0x0027c104,
0x0027c108,
0x0027c10c,
0x0027c110,
0x0027c120,
0x0027c114,
0x0027c118,
0x0027c11c,
0x0027c124,
};
const u32 *gv11b_perf_get_hwpm_sys_perfmon_regs(u32 *count)
{
*count = sizeof(hwpm_sys_perfmon_regs) / sizeof(hwpm_sys_perfmon_regs[0]);
return hwpm_sys_perfmon_regs;
}
const u32 *gv11b_perf_get_hwpm_gpc_perfmon_regs(u32 *count)
{
*count = sizeof(hwpm_gpc_perfmon_regs) / sizeof(hwpm_gpc_perfmon_regs[0]);
return hwpm_gpc_perfmon_regs;
}
const u32 *gv11b_perf_get_hwpm_fbp_perfmon_regs(u32 *count)
{
*count = sizeof(hwpm_fbp_perfmon_regs) / sizeof(hwpm_fbp_perfmon_regs[0]);
return hwpm_fbp_perfmon_regs;
}
void gv11b_perf_set_pmm_register(struct gk20a *g, u32 offset, u32 val,
u32 num_chiplets, u32 chiplet_stride, u32 num_perfmons)
{
u32 perfmon_index = 0;
u32 chiplet_index = 0;
u32 reg_offset = 0;
for (chiplet_index = 0; chiplet_index < num_chiplets; chiplet_index++) {
for (perfmon_index = 0; perfmon_index < num_perfmons;
perfmon_index++) {
reg_offset = offset + perfmon_index *
perf_pmmsys_perdomain_offset_v() +
chiplet_index * chiplet_stride;
nvgpu_writel(g, reg_offset, val);
}
}
}
void gv11b_perf_get_num_hwpm_perfmon(struct gk20a *g, u32 *num_sys_perfmon,
u32 *num_fbp_perfmon, u32 *num_gpc_perfmon)
{
int err;
u32 buf_offset_lo, buf_offset_addr, num_offsets;
u32 perfmon_index = 0;
for (perfmon_index = 0; perfmon_index <
perf_pmmsys_engine_sel__size_1_v();
perfmon_index++) {
err = g->ops.gr.get_pm_ctx_buffer_offsets(g,
perf_pmmsys_engine_sel_r(perfmon_index),
1,
&buf_offset_lo,
&buf_offset_addr,
&num_offsets);
if (err != 0) {
break;
}
}
*num_sys_perfmon = perfmon_index;
for (perfmon_index = 0; perfmon_index <
perf_pmmfbp_engine_sel__size_1_v();
perfmon_index++) {
err = g->ops.gr.get_pm_ctx_buffer_offsets(g,
perf_pmmfbp_engine_sel_r(perfmon_index),
1,
&buf_offset_lo,
&buf_offset_addr,
&num_offsets);
if (err != 0) {
break;
}
}
*num_fbp_perfmon = perfmon_index;
for (perfmon_index = 0; perfmon_index <
perf_pmmgpc_engine_sel__size_1_v();
perfmon_index++) {
err = g->ops.gr.get_pm_ctx_buffer_offsets(g,
perf_pmmgpc_engine_sel_r(perfmon_index),
1,
&buf_offset_lo,
&buf_offset_addr,
&num_offsets);
if (err != 0) {
break;
}
}
*num_gpc_perfmon = perfmon_index;
}
void gv11b_perf_reset_hwpm_pmm_registers(struct gk20a *g)
{
u32 count;
const u32 *perfmon_regs;
u32 i;
perfmon_regs = g->ops.perf.get_hwpm_sys_perfmon_regs(&count);
for (i = 0U; i < count; i++) {
g->ops.perf.set_pmm_register(g, perfmon_regs[i], 0U, 1U,
g->ops.perf.get_pmmsys_per_chiplet_offset(),
g->num_sys_perfmon);
}
/*
* All the registers are broadcast ones so trigger
* g->ops.gr.set_pmm_register() only with 1 chiplet even for
* GPC and FBP chiplets.
*/
perfmon_regs = g->ops.perf.get_hwpm_fbp_perfmon_regs(&count);
for (i = 0U; i < count; i++) {
g->ops.perf.set_pmm_register(g, perfmon_regs[i], 0U, 1U,
g->ops.perf.get_pmmfbp_per_chiplet_offset(),
g->num_fbp_perfmon);
}
perfmon_regs = g->ops.perf.get_hwpm_gpc_perfmon_regs(&count);
for (i = 0U; i < count; i++) {
g->ops.perf.set_pmm_register(g, perfmon_regs[i], 0U, 1U,
g->ops.perf.get_pmmgpc_per_chiplet_offset(),
g->num_gpc_perfmon);
}
if (g->ops.priv_ring.read_pri_fence != NULL) {
g->ops.priv_ring.read_pri_fence(g);
}
}
void gv11b_perf_init_hwpm_pmm_register(struct gk20a *g)
{
g->ops.perf.set_pmm_register(g, perf_pmmsys_engine_sel_r(0), 0xFFFFFFFFU,
1U, g->ops.perf.get_pmmsys_per_chiplet_offset(),
g->num_sys_perfmon);
g->ops.perf.set_pmm_register(g, perf_pmmfbp_engine_sel_r(0), 0xFFFFFFFFU,
nvgpu_fbp_get_num_fbps(g->fbp),
g->ops.perf.get_pmmfbp_per_chiplet_offset(),
g->num_fbp_perfmon);
g->ops.perf.set_pmm_register(g, perf_pmmgpc_engine_sel_r(0), 0xFFFFFFFFU,
nvgpu_gr_config_get_gpc_count(nvgpu_gr_get_config_ptr(g)),
g->ops.perf.get_pmmgpc_per_chiplet_offset(),
g->num_gpc_perfmon);
}
void gv11b_perf_pma_stream_enable(struct gk20a *g, bool enable)
{
u32 reg_val;
reg_val = nvgpu_readl(g, perf_pmasys_control_r());
if (enable) {
reg_val = set_field(reg_val,
perf_pmasys_control_stream_m(),
perf_pmasys_control_stream_enable_f());
} else {
reg_val = set_field(reg_val,
perf_pmasys_control_stream_m(),
perf_pmasys_control_stream_disable_f());
}
nvgpu_writel(g, perf_pmasys_control_r(), reg_val);
}
void gv11b_perf_disable_all_perfmons(struct gk20a *g)
{
g->ops.perf.set_pmm_register(g, perf_pmmsys_control_r(0U), 0U, 1U,
g->ops.perf.get_pmmsys_per_chiplet_offset(),
g->num_sys_perfmon);
g->ops.perf.set_pmm_register(g, perf_pmmfbp_fbps_control_r(0U), 0U, 1U,
g->ops.perf.get_pmmfbp_per_chiplet_offset(),
g->num_fbp_perfmon);
g->ops.perf.set_pmm_register(g, perf_pmmgpc_gpcs_control_r(0U), 0U, 1U,
g->ops.perf.get_pmmgpc_per_chiplet_offset(),
g->num_gpc_perfmon);
if (g->ops.priv_ring.read_pri_fence != NULL) {
g->ops.priv_ring.read_pri_fence(g);
}
}
static int poll_for_pmm_router_idle(struct gk20a *g, u32 offset, u32 timeout_ms)
{
struct nvgpu_timeout timeout;
u32 reg_val;
u32 status;
nvgpu_timeout_init_cpu_timer(g, &timeout, timeout_ms);
do {
reg_val = nvgpu_readl(g, offset);
status = perf_pmmsysrouter_enginestatus_status_v(reg_val);
if ((status == perf_pmmsysrouter_enginestatus_status_empty_v()) ||
(status == perf_pmmsysrouter_enginestatus_status_quiescent_v())) {
return 0;
}
nvgpu_usleep_range(20, 40);
} while (nvgpu_timeout_expired(&timeout) == 0);
return -ETIMEDOUT;
}
int gv11b_perf_wait_for_idle_pmm_routers(struct gk20a *g)
{
u32 num_gpc, num_fbp;
int err;
u32 i;
num_gpc = nvgpu_gr_config_get_gpc_count(nvgpu_gr_get_config_ptr(g));
num_fbp = nvgpu_fbp_get_num_fbps(g->fbp);
/* wait for all perfmons to report idle */
err = poll_for_pmm_router_idle(g, perf_pmmsysrouter_perfmonstatus_r(), 1);
if (err != 0) {
return err;
}
for (i = 0U; i < num_gpc; ++i) {
err = poll_for_pmm_router_idle(g,
perf_pmmgpcrouter_perfmonstatus_r() + (i * PMM_ROUTER_OFFSET),
1);
if (err != 0) {
return err;
}
}
for (i = 0U; i < num_fbp; ++i) {
err = poll_for_pmm_router_idle(g,
perf_pmmfbprouter_perfmonstatus_r() + (i * PMM_ROUTER_OFFSET),
1);
if (err != 0) {
return err;
}
}
/* wait for all routers to report idle */
err = poll_for_pmm_router_idle(g, perf_pmmsysrouter_enginestatus_r(), 1);
if (err != 0) {
return err;
}
for (i = 0U; i < num_gpc; ++i) {
err = poll_for_pmm_router_idle(g,
perf_pmmgpcrouter_enginestatus_r() + (i * PMM_ROUTER_OFFSET),
1);
if (err != 0) {
return err;
}
}
for (i = 0U; i < num_fbp; ++i) {
err = poll_for_pmm_router_idle(g,
perf_pmmfbprouter_enginestatus_r() + (i * PMM_ROUTER_OFFSET),
1);
if (err != 0) {
return err;
}
}
return 0;
}
int gv11b_perf_wait_for_idle_pma(struct gk20a *g)
{
struct nvgpu_timeout timeout;
u32 status, rbufempty_status;
u32 timeout_ms = 1;
u32 reg_val;
nvgpu_timeout_init_cpu_timer(g, &timeout, timeout_ms);
do {
reg_val = nvgpu_readl(g, perf_pmasys_enginestatus_r());
status = perf_pmasys_enginestatus_status_v(reg_val);
rbufempty_status = perf_pmasys_enginestatus_rbufempty_v(reg_val);
if ((status == perf_pmasys_enginestatus_status_empty_v()) &&
(rbufempty_status == perf_pmasys_enginestatus_rbufempty_empty_v())) {
return 0;
}
nvgpu_usleep_range(20, 40);
} while (nvgpu_timeout_expired(&timeout) == 0);
return -ETIMEDOUT;
}
Reference in New Issue View Git Blame Copy Permalink