/*
* GV11B fifo
*
* Copyright (c) 2015-2017, NVIDIA CORPORATION. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*/
#include <linux/delay.h>
#include <linux/types.h>
#include <nvgpu/semaphore.h>
#include <nvgpu/timers.h>
#include <nvgpu/log.h>
#include "gk20a/gk20a.h"
#include "gk20a/fifo_gk20a.h"
#include "gk20a/ctxsw_trace_gk20a.h"
#include "gk20a/channel_gk20a.h"
#include "gp10b/fifo_gp10b.h"
#include <nvgpu/hw/gv11b/hw_pbdma_gv11b.h>
#include <nvgpu/hw/gv11b/hw_fifo_gv11b.h>
#include <nvgpu/hw/gv11b/hw_ram_gv11b.h>
#include <nvgpu/hw/gv11b/hw_ccsr_gv11b.h>
#include <nvgpu/hw/gv11b/hw_usermode_gv11b.h>
#include <nvgpu/hw/gv11b/hw_top_gv11b.h>
#include <nvgpu/hw/gv11b/hw_gmmu_gv11b.h>
#include <nvgpu/hw/gv11b/hw_mc_gv11b.h>
#include "fifo_gv11b.h"
#include "subctx_gv11b.h"
#include "gr_gv11b.h"
#define CHANNEL_INFO_VEID0 0
#define PBDMA_SUBDEVICE_ID 1
static void gv11b_get_tsg_runlist_entry(struct tsg_gk20a *tsg, u32 *runlist)
{
u32 runlist_entry_0 = ram_rl_entry_type_tsg_v();
if (tsg->timeslice_timeout)
runlist_entry_0 |=
ram_rl_entry_tsg_timeslice_scale_f(tsg->timeslice_scale) |
ram_rl_entry_tsg_timeslice_timeout_f(tsg->timeslice_timeout);
else
runlist_entry_0 |=
ram_rl_entry_tsg_timeslice_scale_f(
ram_rl_entry_tsg_timeslice_scale_3_v()) |
ram_rl_entry_tsg_timeslice_timeout_f(
ram_rl_entry_tsg_timeslice_timeout_128_v());
runlist[0] = runlist_entry_0;
runlist[1] = ram_rl_entry_tsg_length_f(tsg->num_active_channels);
runlist[2] = ram_rl_entry_tsg_tsgid_f(tsg->tsgid);
runlist[3] = 0;
gk20a_dbg_info("gv11b tsg runlist [0] %x [1] %x [2] %x [3] %x\n",
runlist[0], runlist[1], runlist[2], runlist[3]);
}
static void gv11b_get_ch_runlist_entry(struct channel_gk20a *c, u32 *runlist)
{
struct gk20a *g = c->g;
u32 addr_lo, addr_hi;
u32 runlist_entry;
/* Time being use 0 pbdma sequencer */
runlist_entry = ram_rl_entry_type_channel_v() |
ram_rl_entry_chan_runqueue_selector_f(0) |
ram_rl_entry_chan_userd_target_f(
ram_rl_entry_chan_userd_target_sys_mem_ncoh_v()) |
ram_rl_entry_chan_inst_target_f(
ram_rl_entry_chan_userd_target_sys_mem_ncoh_v());
addr_lo = u64_lo32(c->userd_iova) >>
ram_rl_entry_chan_userd_ptr_align_shift_v();
addr_hi = u64_hi32(c->userd_iova);
runlist[0] = runlist_entry | ram_rl_entry_chan_userd_ptr_lo_f(addr_lo);
runlist[1] = ram_rl_entry_chan_userd_ptr_hi_f(addr_hi);
addr_lo = u64_lo32(gk20a_mm_inst_block_addr(g, &c->inst_block)) >>
ram_rl_entry_chan_inst_ptr_align_shift_v();
addr_hi = u64_hi32(gk20a_mm_inst_block_addr(g, &c->inst_block));
runlist[2] = ram_rl_entry_chan_inst_ptr_lo_f(addr_lo) |
ram_rl_entry_chid_f(c->hw_chid);
runlist[3] = ram_rl_entry_chan_inst_ptr_hi_f(addr_hi);
gk20a_dbg_info("gv11b channel runlist [0] %x [1] %x [2] %x [3] %x\n",
runlist[0], runlist[1], runlist[2], runlist[3]);
}
static void gv11b_userd_writeback_config(struct gk20a *g)
{
gk20a_writel(g, fifo_userd_writeback_r(), fifo_userd_writeback_timer_f(
fifo_userd_writeback_timer_100us_v()));
}
static int channel_gv11b_setup_ramfc(struct channel_gk20a *c,
u64 gpfifo_base, u32 gpfifo_entries,
unsigned long acquire_timeout, u32 flags)
{
struct gk20a *g = c->g;
struct nvgpu_mem *mem = &c->inst_block;
u32 data;
gk20a_dbg_fn("");
nvgpu_memset(g, mem, 0, 0, ram_fc_size_val_v());
nvgpu_mem_wr32(g, mem, ram_fc_gp_base_w(),
pbdma_gp_base_offset_f(
u64_lo32(gpfifo_base >> pbdma_gp_base_rsvd_s())));
nvgpu_mem_wr32(g, mem, ram_fc_gp_base_hi_w(),
pbdma_gp_base_hi_offset_f(u64_hi32(gpfifo_base)) |
pbdma_gp_base_hi_limit2_f(ilog2(gpfifo_entries)));
nvgpu_mem_wr32(g, mem, ram_fc_signature_w(),
c->g->ops.fifo.get_pbdma_signature(c->g));
nvgpu_mem_wr32(g, mem, ram_fc_pb_header_w(),
pbdma_pb_header_priv_user_f() |
pbdma_pb_header_method_zero_f() |
pbdma_pb_header_subchannel_zero_f() |
pbdma_pb_header_level_main_f() |
pbdma_pb_header_first_true_f() |
pbdma_pb_header_type_inc_f());
nvgpu_mem_wr32(g, mem, ram_fc_subdevice_w(),
pbdma_subdevice_id_f(PBDMA_SUBDEVICE_ID) |
pbdma_subdevice_status_active_f() |
pbdma_subdevice_channel_dma_enable_f());
nvgpu_mem_wr32(g, mem, ram_fc_target_w(),
pbdma_target_eng_ctx_valid_true_f() |
pbdma_target_ce_ctx_valid_true_f() |
pbdma_target_engine_sw_f());
nvgpu_mem_wr32(g, mem, ram_fc_acquire_w(),
g->ops.fifo.pbdma_acquire_val(acquire_timeout));
nvgpu_mem_wr32(g, mem, ram_fc_runlist_timeslice_w(),
pbdma_runlist_timeslice_timeout_128_f() |
pbdma_runlist_timeslice_timescale_3_f() |
pbdma_runlist_timeslice_enable_true_f());
nvgpu_mem_wr32(g, mem, ram_fc_chid_w(), ram_fc_chid_id_f(c->hw_chid));
/* Until full subcontext is supported, always use VEID0 */
nvgpu_mem_wr32(g, mem, ram_fc_set_channel_info_w(),
pbdma_set_channel_info_scg_type_graphics_compute0_f() |
pbdma_set_channel_info_veid_f(CHANNEL_INFO_VEID0));
if (c->is_privileged_channel) {
/* Set privilege level for channel */
nvgpu_mem_wr32(g, mem, ram_fc_config_w(),
pbdma_config_auth_level_privileged_f());
gk20a_fifo_setup_ramfc_for_privileged_channel(c);
}
/* Enable userd writeback */
data = nvgpu_mem_rd32(g, mem, ram_fc_config_w());
data = data | pbdma_config_userd_writeback_enable_f();
nvgpu_mem_wr32(g, mem, ram_fc_config_w(),data);
gv11b_userd_writeback_config(g);
return channel_gp10b_commit_userd(c);
}
static void gv11b_ring_channel_doorbell(struct channel_gk20a *c)
{
gk20a_dbg_info("channel ring door bell %d\n", c->hw_chid);
gk20a_writel(c->g, usermode_notify_channel_pending_r(),
usermode_notify_channel_pending_id_f(c->hw_chid));
}
static u32 gv11b_userd_gp_get(struct gk20a *g, struct channel_gk20a *c)
{
struct nvgpu_mem *userd_mem = &g->fifo.userd;
u32 offset = c->hw_chid * (g->fifo.userd_entry_size / sizeof(u32));
return nvgpu_mem_rd32(g, userd_mem,
offset + ram_userd_gp_get_w());
}
static void gv11b_userd_gp_put(struct gk20a *g, struct channel_gk20a *c)
{
struct nvgpu_mem *userd_mem = &g->fifo.userd;
u32 offset = c->hw_chid * (g->fifo.userd_entry_size / sizeof(u32));
nvgpu_mem_wr32(g, userd_mem, offset + ram_userd_gp_put_w(),
c->gpfifo.put);
/* commit everything to cpu */
smp_mb();
gv11b_ring_channel_doorbell(c);
}
static void channel_gv11b_unbind(struct channel_gk20a *ch)
{
gk20a_dbg_fn("");
gk20a_fifo_channel_unbind(ch);
}
static u32 gv11b_fifo_get_num_fifos(struct gk20a *g)
{
return ccsr_channel__size_1_v();
}
static bool gv11b_is_fault_engine_subid_gpc(struct gk20a *g, u32 engine_subid)
{
return (engine_subid == gmmu_fault_client_type_gpc_v());
}
static void gv11b_dump_channel_status_ramfc(struct gk20a *g,
struct gk20a_debug_output *o,
u32 hw_chid,
struct ch_state *ch_state)
{
u32 channel = gk20a_readl(g, ccsr_channel_r(hw_chid));
u32 status = ccsr_channel_status_v(channel);
u32 *inst_mem;
struct channel_gk20a *c = g->fifo.channel + hw_chid;
struct nvgpu_semaphore_int *hw_sema = NULL;
if (c->hw_sema)
hw_sema = c->hw_sema;
if (!ch_state)
return;
inst_mem = &ch_state->inst_block[0];
gk20a_debug_output(o, "%d-%s, pid %d, refs: %d: ", hw_chid,
dev_name(g->dev),
ch_state->pid,
ch_state->refs);
gk20a_debug_output(o, "channel status: %s in use %s %s\n",
ccsr_channel_enable_v(channel) ? "" : "not",
gk20a_decode_ccsr_chan_status(status),
ccsr_channel_busy_v(channel) ? "busy" : "not busy");
gk20a_debug_output(o, "RAMFC : TOP: %016llx PUT: %016llx GET: %016llx "
"FETCH: %016llx\nHEADER: %08x COUNT: %08x\n"
"SEMAPHORE: addr hi: %08x addr lo: %08x\n"
"payload %08x execute %08x\n",
(u64)inst_mem[ram_fc_pb_top_level_get_w()] +
((u64)inst_mem[ram_fc_pb_top_level_get_hi_w()] << 32ULL),
(u64)inst_mem[ram_fc_pb_put_w()] +
((u64)inst_mem[ram_fc_pb_put_hi_w()] << 32ULL),
(u64)inst_mem[ram_fc_pb_get_w()] +
((u64)inst_mem[ram_fc_pb_get_hi_w()] << 32ULL),
(u64)inst_mem[ram_fc_pb_fetch_w()] +
((u64)inst_mem[ram_fc_pb_fetch_hi_w()] << 32ULL),
inst_mem[ram_fc_pb_header_w()],
inst_mem[ram_fc_pb_count_w()],
inst_mem[ram_fc_sem_addr_hi_w()],
inst_mem[ram_fc_sem_addr_lo_w()],
inst_mem[ram_fc_sem_payload_lo_w()],
inst_mem[ram_fc_sem_execute_w()]);
if (hw_sema)
gk20a_debug_output(o, "SEMA STATE: value: 0x%08x "
"next_val: 0x%08x addr: 0x%010llx\n",
__nvgpu_semaphore_read(hw_sema),
atomic_read(&hw_sema->next_value),
nvgpu_hw_sema_addr(hw_sema));
gk20a_debug_output(o, "\n");
}
static void gv11b_dump_eng_status(struct gk20a *g,
struct gk20a_debug_output *o)
{
u32 i, host_num_engines;
host_num_engines = nvgpu_get_litter_value(g, GPU_LIT_HOST_NUM_ENGINES);
for (i = 0; i < host_num_engines; i++) {
u32 status = gk20a_readl(g, fifo_engine_status_r(i));
u32 ctx_status = fifo_engine_status_ctx_status_v(status);
gk20a_debug_output(o, "%s eng %d: ", dev_name(g->dev), i);
gk20a_debug_output(o,
"id: %d (%s), next_id: %d (%s), ctx status: %s ",
fifo_engine_status_id_v(status),
fifo_engine_status_id_type_v(status) ?
"tsg" : "channel",
fifo_engine_status_next_id_v(status),
fifo_engine_status_next_id_type_v(status) ?
"tsg" : "channel",
gk20a_decode_pbdma_chan_eng_ctx_status(ctx_status));
if (fifo_engine_status_eng_reload_v(status))
gk20a_debug_output(o, "ctx_reload ");
if (fifo_engine_status_faulted_v(status))
gk20a_debug_output(o, "faulted ");
if (fifo_engine_status_engine_v(status))
gk20a_debug_output(o, "busy ");
gk20a_debug_output(o, "\n");
}
gk20a_debug_output(o, "\n");
}
static u32 gv11b_fifo_intr_0_error_mask(struct gk20a *g)
{
u32 intr_0_error_mask =
fifo_intr_0_bind_error_pending_f() |
fifo_intr_0_sched_error_pending_f() |
fifo_intr_0_chsw_error_pending_f() |
fifo_intr_0_fb_flush_timeout_pending_f() |
fifo_intr_0_lb_error_pending_f();
return intr_0_error_mask;
}
static int gv11b_fifo_poll_pbdma_chan_status(struct gk20a *g, u32 id,
u32 pbdma_id, unsigned int timeout_rc_type)
{
struct nvgpu_timeout timeout;
unsigned long delay = GR_IDLE_CHECK_DEFAULT;
u32 pbdma_stat;
u32 chan_stat;
int ret = -EBUSY;
/*
* If the PBDMA has a stalling interrupt and receives a NACK, the PBDMA
* won't save out until the STALLING interrupt is cleared. Note that
* the stalling interrupt need not be directly addressed, as simply
* clearing of the interrupt bit will be sufficient to allow the PBDMA
* to save out. If the stalling interrupt was due to a SW method or
* another deterministic failure, the PBDMA will assert it when the
* channel is reloaded/resumed. Note that the fault will still be
* reported to SW.
*/
if (timeout_rc_type == PREEMPT_TIMEOUT_NORC) {
/* called from recovery */
u32 pbdma_intr_0, pbdma_intr_1;
pbdma_intr_0 = gk20a_readl(g, pbdma_intr_0_r(pbdma_id));
pbdma_intr_1 = gk20a_readl(g, pbdma_intr_1_r(pbdma_id));
if (pbdma_intr_0)
gk20a_writel(g, pbdma_intr_0_r(pbdma_id), pbdma_intr_0);
if (pbdma_intr_1)
gk20a_writel(g, pbdma_intr_1_r(pbdma_id), pbdma_intr_1);
}
nvgpu_timeout_init(g, &timeout, gk20a_get_gr_idle_timeout(g),
NVGPU_TIMER_CPU_TIMER);
/* Verify that ch/tsg is no longer on the pbdma */
do {
pbdma_stat = gk20a_readl(g, fifo_pbdma_status_r(pbdma_id));
chan_stat = fifo_pbdma_status_chan_status_v(pbdma_stat);
gk20a_dbg_info("wait preempt pbdma");
if (chan_stat ==
fifo_pbdma_status_chan_status_valid_v() ||
chan_stat ==
fifo_pbdma_status_chan_status_chsw_save_v()) {
if (id != fifo_pbdma_status_id_v(pbdma_stat)) {
ret = 0;
break;
}
} else if (chan_stat ==
fifo_pbdma_status_chan_status_chsw_load_v()) {
if (id != fifo_pbdma_status_next_id_v(pbdma_stat)) {
ret = 0;
break;
}
} else if (chan_stat ==
fifo_pbdma_status_chan_status_chsw_switch_v()) {
if ((id != fifo_pbdma_status_next_id_v(pbdma_stat)) &&
(id != fifo_pbdma_status_id_v(pbdma_stat))) {
ret = 0;
break;
}
} else {
/* pbdma status is invalid i.e. it is not loaded */
ret = 0;
break;
}
usleep_range(delay, delay * 2);
delay = min_t(unsigned long,
delay << 1, GR_IDLE_CHECK_MAX);
} while (!nvgpu_timeout_expired_msg(&timeout,
"preempt timeout pbdma"));
return ret;
}
static int gv11b_fifo_poll_eng_ctx_status(struct gk20a *g, u32 id,
u32 engine_idx, u32 *reset_eng_bitmask,
unsigned int timeout_rc_type)
{
struct nvgpu_timeout timeout;
unsigned long delay = GR_IDLE_CHECK_DEFAULT;
u32 eng_stat;
u32 ctx_stat;
int ret = -EBUSY;
nvgpu_timeout_init(g, &timeout, gk20a_get_gr_idle_timeout(g),
NVGPU_TIMER_CPU_TIMER);
/* Check if ch/tsg has saved off the engine or if ctxsw is hung */
do {
eng_stat = gk20a_readl(g, fifo_engine_status_r(engine_idx));
ctx_stat = fifo_engine_status_ctx_status_v(eng_stat);
if (ctx_stat ==
fifo_engine_status_ctx_status_ctxsw_switch_v()) {
gk20a_dbg_info("engine save hasn't started yet");
} else if (ctx_stat ==
fifo_engine_status_ctx_status_valid_v() ||
ctx_stat ==
fifo_engine_status_ctx_status_ctxsw_save_v()) {
if (id == fifo_engine_status_id_v(eng_stat)) {
if (timeout_rc_type == PREEMPT_TIMEOUT_NORC) {
/* called from recovery, eng seems to be hung */
*reset_eng_bitmask |= BIT(engine_idx);
ret = 0;
break;
} else {
gk20a_dbg_info("wait preempt engine. "
"ctx_status (valid/save)=%u", ctx_stat);
}
} else {
/* context is not running on the engine */
ret = 0;
break;
}
} else if (ctx_stat ==
fifo_engine_status_ctx_status_ctxsw_load_v()) {
if (id == fifo_engine_status_next_id_v(eng_stat)) {
if (timeout_rc_type == PREEMPT_TIMEOUT_NORC) {
/* called from recovery, eng seems to be hung */
*reset_eng_bitmask |= BIT(engine_idx);
ret = 0;
break;
} else {
gk20a_dbg_info("wait preempt engine. "
"ctx_status (load)=%u", ctx_stat);
}
} else {
/* context is not running on the engine */
ret = 0;
break;
}
} else {
/* Preempt should be finished */
ret = 0;
break;
}
usleep_range(delay, delay * 2);
delay = min_t(unsigned long,
delay << 1, GR_IDLE_CHECK_MAX);
} while (!nvgpu_timeout_expired_msg(&timeout,
"preempt timeout eng"));
return ret;
}
static void gv11b_reset_eng_faulted_ch(struct gk20a *g, u32 hw_chid)
{
u32 reg_val;
reg_val = gk20a_readl(g, ccsr_channel_r(hw_chid));
reg_val |= ccsr_channel_eng_faulted_reset_f();
gk20a_writel(g, ccsr_channel_r(hw_chid), reg_val);
}
static void gv11b_reset_eng_faulted_tsg(struct tsg_gk20a *tsg)
{
struct gk20a *g = tsg->g;
struct channel_gk20a *ch;
down_read(&tsg->ch_list_lock);
list_for_each_entry(ch, &tsg->ch_list, ch_entry) {
gv11b_reset_eng_faulted_ch(g, ch->hw_chid);
}
up_read(&tsg->ch_list_lock);
}
static void gv11b_reset_pbdma_faulted_ch(struct gk20a *g, u32 hw_chid)
{
u32 reg_val;
reg_val = gk20a_readl(g, ccsr_channel_r(hw_chid));
reg_val |= ccsr_channel_pbdma_faulted_reset_f();
gk20a_writel(g, ccsr_channel_r(hw_chid), reg_val);
}
static void gv11b_reset_pbdma_faulted_tsg(struct tsg_gk20a *tsg)
{
struct gk20a *g = tsg->g;
struct channel_gk20a *ch;
down_read(&tsg->ch_list_lock);
list_for_each_entry(ch, &tsg->ch_list, ch_entry) {
gv11b_reset_pbdma_faulted_ch(g, ch->hw_chid);
}
up_read(&tsg->ch_list_lock);
}
static u32 gv11b_fifo_get_runlists_mask(struct gk20a *g, u32 act_eng_bitmask,
u32 id, unsigned int id_type, unsigned int rc_type,
struct mmu_fault_info *mmfault)
{
u32 runlists_mask = 0;
struct fifo_gk20a *f = &g->fifo;
struct fifo_runlist_info_gk20a *runlist;
u32 pbdma_bitmask = 0;
if (id_type != ID_TYPE_UNKNOWN) {
if (id_type == ID_TYPE_TSG)
runlists_mask |= fifo_sched_disable_runlist_m(
f->tsg[id].runlist_id);
else
runlists_mask |= fifo_sched_disable_runlist_m(
f->channel[id].runlist_id);
}
if (rc_type == RC_TYPE_MMU_FAULT && mmfault) {
if (mmfault->faulted_pbdma != FIFO_INVAL_PBDMA_ID)
pbdma_bitmask = BIT(mmfault->faulted_pbdma);
for (id = 0; id < f->max_runlists; id++) {
runlist = &f->runlist_info[id];
if (runlist->eng_bitmask & act_eng_bitmask)
runlists_mask |=
fifo_sched_disable_runlist_m(id);
if (runlist->pbdma_bitmask & pbdma_bitmask)
runlists_mask |=
fifo_sched_disable_runlist_m(id);
}
}
if (id_type == ID_TYPE_UNKNOWN) {
for (id = 0; id < f->max_runlists; id++) {
if (act_eng_bitmask) {
/* eng ids are known */
runlist = &f->runlist_info[id];
if (runlist->eng_bitmask & act_eng_bitmask)
runlists_mask |=
fifo_sched_disable_runlist_m(id);
} else {
runlists_mask |=
fifo_sched_disable_runlist_m(id);
}
}
}
gk20a_dbg_info("runlists_mask = %08x", runlists_mask);
return runlists_mask;
}
static void gv11b_fifo_runlist_event_intr_disable(struct gk20a *g)
{
u32 reg_val;
reg_val = gk20a_readl(g, fifo_intr_en_0_r());
reg_val &= fifo_intr_0_runlist_event_pending_f();
gk20a_writel(g, fifo_intr_en_0_r(), reg_val);
}
static void gv11b_fifo_runlist_event_intr_enable(struct gk20a *g)
{
u32 reg_val;
reg_val = gk20a_readl(g, fifo_intr_en_0_r());
reg_val |= fifo_intr_0_runlist_event_pending_f();
gk20a_writel(g, fifo_intr_en_0_r(), reg_val);
}
static void gv11b_fifo_issue_runlist_preempt(struct gk20a *g,
u32 runlists_mask)
{
u32 reg_val;
/* issue runlist preempt */
reg_val = gk20a_readl(g, fifo_runlist_preempt_r());
reg_val |= runlists_mask;
gk20a_writel(g, fifo_runlist_preempt_r(), reg_val);
}
static int gv11b_fifo_poll_runlist_preempt_pending(struct gk20a *g,
u32 runlists_mask)
{
struct nvgpu_timeout timeout;
u32 delay = GR_IDLE_CHECK_DEFAULT;
int ret = -EBUSY;
nvgpu_timeout_init(g, &timeout, gk20a_get_gr_idle_timeout(g),
NVGPU_TIMER_CPU_TIMER);
do {
if (!((gk20a_readl(g, fifo_runlist_preempt_r())) &
runlists_mask)) {
ret = 0;
break;
}
usleep_range(delay, delay * 2);
delay = min_t(unsigned long,
delay << 1, GR_IDLE_CHECK_MAX);
} while (!nvgpu_timeout_expired_msg(&timeout,
"runlist preempt timeout"));
return ret;
}
static int gv11b_fifo_is_preempt_pending(struct gk20a *g, u32 id,
unsigned int id_type, unsigned int timeout_rc_type)
{
struct fifo_gk20a *f = &g->fifo;
unsigned long runlist_served_pbdmas;
unsigned long runlist_served_engines;
u32 pbdma_id;
u32 act_eng_id;
u32 runlist_id;
int func_ret;
int ret = 0;
gk20a_dbg_fn("");
if (id_type == ID_TYPE_TSG)
runlist_id = f->tsg[id].runlist_id;
else
runlist_id = f->channel[id].runlist_id;
runlist_served_pbdmas = f->runlist_info[runlist_id].pbdma_bitmask;
runlist_served_engines = f->runlist_info[runlist_id].eng_bitmask;
for_each_set_bit(pbdma_id, &runlist_served_pbdmas, f->num_pbdma) {
func_ret = gv11b_fifo_poll_pbdma_chan_status(g, id, pbdma_id,
timeout_rc_type);
if (func_ret != 0) {
gk20a_dbg_info("preempt timeout pbdma %d", pbdma_id);
ret |= func_ret;
}
}
f->runlist_info[runlist_id].reset_eng_bitmask = 0;
for_each_set_bit(act_eng_id, &runlist_served_engines, f->num_engines) {
func_ret = gv11b_fifo_poll_eng_ctx_status(g, id, act_eng_id,
&f->runlist_info[runlist_id].reset_eng_bitmask,
timeout_rc_type);
if (func_ret != 0) {
gk20a_dbg_info("preempt timeout engine %d", act_eng_id);
ret |= func_ret;
}
}
return ret;
}
static int gv11b_fifo_preempt_channel(struct gk20a *g, u32 hw_chid)
{
struct fifo_gk20a *f = &g->fifo;
u32 ret = 0;
u32 token = PMU_INVALID_MUTEX_OWNER_ID;
u32 mutex_ret = 0;
u32 runlist_id;
gk20a_dbg_fn("%d", hw_chid);
runlist_id = f->channel[hw_chid].runlist_id;
gk20a_dbg_fn("runlist_id %d", runlist_id);
nvgpu_mutex_acquire(&f->runlist_info[runlist_id].mutex);
mutex_ret = pmu_mutex_acquire(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
ret = __locked_fifo_preempt(g, hw_chid, false);
if (!mutex_ret)
pmu_mutex_release(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
nvgpu_mutex_release(&f->runlist_info[runlist_id].mutex);
return ret;
}
static int __locked_fifo_preempt_runlists(struct gk20a *g, u32 runlists_mask)
{
int ret;
/*
* Disable runlist event interrupt as it will get
* triggered after runlist preempt finishes
*/
gv11b_fifo_runlist_event_intr_disable(g);
/* issue runlist preempt */
gv11b_fifo_issue_runlist_preempt(g, runlists_mask);
/* poll for runlist preempt done */
ret = gv11b_fifo_poll_runlist_preempt_pending(g, runlists_mask);
/* Clear outstanding runlist event */
gk20a_fifo_handle_runlist_event(g);
/* Enable runlist event interrupt*/
gv11b_fifo_runlist_event_intr_enable(g);
return ret;
}
static int gv11b_fifo_preempt_tsg(struct gk20a *g, u32 tsgid)
{
struct fifo_gk20a *f = &g->fifo;
u32 ret = 0;
u32 token = PMU_INVALID_MUTEX_OWNER_ID;
u32 mutex_ret = 0;
u32 runlist_id;
gk20a_dbg_fn("%d", tsgid);
runlist_id = f->tsg[tsgid].runlist_id;
gk20a_dbg_fn("runlist_id %d", runlist_id);
nvgpu_mutex_acquire(&f->runlist_info[runlist_id].mutex);
mutex_ret = pmu_mutex_acquire(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
ret = __locked_fifo_preempt(g, tsgid, true);
if (!mutex_ret)
pmu_mutex_release(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
nvgpu_mutex_release(&f->runlist_info[runlist_id].mutex);
return ret;
}
static int gv11b_fifo_preempt_runlists(struct gk20a *g, u32 runlists_mask)
{
int ret = 0;
u32 token = PMU_INVALID_MUTEX_OWNER_ID;
u32 mutex_ret = 0;
u32 runlist_id;
gk20a_dbg_fn("");
for (runlist_id = 0; runlist_id < g->fifo.max_runlists; runlist_id++) {
if (runlists_mask & fifo_runlist_preempt_runlist_m(runlist_id))
nvgpu_mutex_acquire(&g->fifo.
runlist_info[runlist_id].mutex);
}
mutex_ret = pmu_mutex_acquire(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
ret = __locked_fifo_preempt_runlists(g, runlists_mask);
if (!mutex_ret)
pmu_mutex_release(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
for (runlist_id = 0; runlist_id < g->fifo.max_runlists; runlist_id++) {
if (runlists_mask & fifo_runlist_preempt_runlist_m(runlist_id))
nvgpu_mutex_release(&g->fifo.
runlist_info[runlist_id].mutex);
}
return ret;
}
static int __locked_fifo_preempt_ch_tsg(struct gk20a *g, u32 id,
unsigned int id_type, unsigned int timeout_rc_type)
{
int ret;
/* issue preempt */
gk20a_fifo_issue_preempt(g, id, id_type);
/* wait for preempt */
ret = g->ops.fifo.is_preempt_pending(g, id, id_type,
timeout_rc_type);
if (ret && (timeout_rc_type == PREEMPT_TIMEOUT_RC))
__locked_fifo_preempt_timeout_rc(g, id, id_type);
return ret;
}
static int gv11b_fifo_preempt_ch_tsg(struct gk20a *g, u32 id,
unsigned int id_type, unsigned int timeout_rc_type)
{
struct fifo_gk20a *f = &g->fifo;
u32 ret = 0;
u32 token = PMU_INVALID_MUTEX_OWNER_ID;
u32 mutex_ret = 0;
u32 runlist_id;
if (id_type == ID_TYPE_TSG)
runlist_id = f->tsg[id].runlist_id;
else if (id_type == ID_TYPE_CHANNEL)
runlist_id = f->channel[id].runlist_id;
else
return -EINVAL;
if (runlist_id >= g->fifo.max_runlists) {
gk20a_dbg_info("runlist_id = %d", runlist_id);
return -EINVAL;
}
gk20a_dbg_fn("preempt id = %d, runlist_id = %d", id, runlist_id);
nvgpu_mutex_acquire(&f->runlist_info[runlist_id].mutex);
mutex_ret = pmu_mutex_acquire(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
ret = __locked_fifo_preempt_ch_tsg(g, id, id_type, timeout_rc_type);
if (!mutex_ret)
pmu_mutex_release(&g->pmu, PMU_MUTEX_ID_FIFO, &token);
nvgpu_mutex_release(&f->runlist_info[runlist_id].mutex);
return ret;
}
static void gv11b_fifo_teardown_ch_tsg(struct gk20a *g, u32 act_eng_bitmask,
u32 id, unsigned int id_type, unsigned int rc_type,
struct mmu_fault_info *mmfault)
{
bool verbose = false;
struct tsg_gk20a *tsg = NULL;
struct channel_gk20a *refch = NULL;
u32 runlists_mask, runlist_id;
struct fifo_runlist_info_gk20a *runlist = NULL;
u32 engine_id, client_type = ~0;
gk20a_dbg_info("active engine ids bitmask =0x%x", act_eng_bitmask);
gk20a_dbg_info("hw id =%d", id);
gk20a_dbg_info("id_type =%d", id_type);
gk20a_dbg_info("rc_type =%d", rc_type);
gk20a_dbg_info("mmu_fault =0x%p", mmfault);
runlists_mask = gv11b_fifo_get_runlists_mask(g, act_eng_bitmask, id,
id_type, rc_type, mmfault);
gk20a_fifo_set_runlist_state(g, runlists_mask, RUNLIST_DISABLED,
!RUNLIST_INFO_MUTEX_LOCKED);
g->fifo.deferred_reset_pending = false;
/* Disable power management */
if (g->support_pmu && g->elpg_enabled) {
if (gk20a_pmu_disable_elpg(g))
nvgpu_err(g, "failed to set disable elpg");
}
if (g->ops.clock_gating.slcg_gr_load_gating_prod)
g->ops.clock_gating.slcg_gr_load_gating_prod(g,
false);
if (g->ops.clock_gating.slcg_perf_load_gating_prod)
g->ops.clock_gating.slcg_perf_load_gating_prod(g,
false);
if (g->ops.clock_gating.slcg_ltc_load_gating_prod)
g->ops.clock_gating.slcg_ltc_load_gating_prod(g,
false);
gr_gk20a_init_cg_mode(g, ELCG_MODE, ELCG_RUN);
if (rc_type == RC_TYPE_MMU_FAULT)
gk20a_debug_dump(g->dev);
/* get the channel/TSG */
if (rc_type == RC_TYPE_MMU_FAULT && mmfault && mmfault->refch) {
refch = mmfault->refch;
client_type = mmfault->client_type;
if (gk20a_is_channel_marked_as_tsg(refch)) {
tsg = &g->fifo.tsg[refch->tsgid];
if (mmfault->faulted_pbdma != FIFO_INVAL_PBDMA_ID)
gv11b_reset_pbdma_faulted_tsg(tsg);
if (mmfault->faulted_engine != FIFO_INVAL_ENGINE_ID)
gv11b_reset_eng_faulted_tsg(tsg);
} else {
if (mmfault->faulted_pbdma != FIFO_INVAL_PBDMA_ID)
gv11b_reset_pbdma_faulted_ch(g, refch->hw_chid);
if (mmfault->faulted_engine != FIFO_INVAL_ENGINE_ID)
gv11b_reset_eng_faulted_ch(g, refch->hw_chid);
}
} else {
if (id_type == ID_TYPE_TSG)
tsg = &g->fifo.tsg[id];
else if (id_type == ID_TYPE_CHANNEL)
refch = gk20a_channel_get(&g->fifo.channel[id]);
}
if (id_type == ID_TYPE_TSG || id_type == ID_TYPE_CHANNEL) {
g->ops.fifo.preempt_ch_tsg(g, id, id_type,
PREEMPT_TIMEOUT_NORC);
} else {
gv11b_fifo_preempt_runlists(g, runlists_mask);
}
if (tsg) {
if (!g->fifo.deferred_reset_pending) {
if (rc_type == RC_TYPE_MMU_FAULT) {
gk20a_fifo_set_ctx_mmu_error_tsg(g, tsg);
verbose = gk20a_fifo_error_tsg(g, tsg);
}
}
gk20a_fifo_abort_tsg(g, tsg->tsgid, false);
if (refch)
gk20a_channel_put(refch);
} else if (refch) {
if (!g->fifo.deferred_reset_pending) {
if (rc_type == RC_TYPE_MMU_FAULT) {
gk20a_fifo_set_ctx_mmu_error_ch(g, refch);
verbose = gk20a_fifo_error_ch(g, refch);
}
}
gk20a_channel_abort(refch, false);
gk20a_channel_put(refch);
} else {
nvgpu_err(g, "id unknown, abort runlist");
for (runlist_id = 0; runlist_id < g->fifo.max_runlists;
runlist_id++) {
if (runlists_mask & BIT(runlist_id))
g->ops.fifo.update_runlist(g, runlist_id,
FIFO_INVAL_CHANNEL_ID, false, true);
}
}
/* check if engine reset should be deferred */
for (runlist_id = 0; runlist_id < g->fifo.max_runlists; runlist_id++) {
runlist = &g->fifo.runlist_info[runlist_id];
if ((runlists_mask & BIT(runlist_id)) &&
runlist->reset_eng_bitmask) {
unsigned long __reset_eng_bitmask =
runlist->reset_eng_bitmask;
for_each_set_bit(engine_id, &__reset_eng_bitmask, 32) {
if ((refch || tsg) &&
gk20a_fifo_should_defer_engine_reset(g,
engine_id, client_type, false)) {
g->fifo.deferred_fault_engines |=
BIT(engine_id);
/* handled during channel free */
g->fifo.deferred_reset_pending = true;
gk20a_dbg(gpu_dbg_intr | gpu_dbg_gpu_dbg,
"sm debugger attached,"
" deferring channel recovery to channel free");
} else {
/*
* if lock is already taken, a reset is
* taking place so no need to repeat
*/
if (nvgpu_mutex_tryacquire(
&g->fifo.gr_reset_mutex)) {
gk20a_fifo_reset_engine(g,
engine_id);
nvgpu_mutex_release(
&g->fifo.gr_reset_mutex);
}
}
}
}
}
if (refch)
gk20a_ctxsw_trace_channel_reset(g, refch);
else if (tsg)
gk20a_ctxsw_trace_tsg_reset(g, tsg);
gk20a_fifo_set_runlist_state(g, runlists_mask, RUNLIST_ENABLED,
!RUNLIST_INFO_MUTEX_LOCKED);
/* It is safe to enable ELPG again. */
if (g->support_pmu && g->elpg_enabled)
gk20a_pmu_enable_elpg(g);
}
static void gv11b_fifo_init_pbdma_intr_descs(struct fifo_gk20a *f)
{
/*
* These are all errors which indicate something really wrong
* going on in the device
*/
f->intr.pbdma.device_fatal_0 =
pbdma_intr_0_memreq_pending_f() |
pbdma_intr_0_memack_timeout_pending_f() |
pbdma_intr_0_memack_extra_pending_f() |
pbdma_intr_0_memdat_timeout_pending_f() |
pbdma_intr_0_memdat_extra_pending_f() |
pbdma_intr_0_memflush_pending_f() |
pbdma_intr_0_memop_pending_f() |
pbdma_intr_0_lbconnect_pending_f() |
pbdma_intr_0_lback_timeout_pending_f() |
pbdma_intr_0_lback_extra_pending_f() |
pbdma_intr_0_lbdat_timeout_pending_f() |
pbdma_intr_0_lbdat_extra_pending_f() |
pbdma_intr_0_pri_pending_f();
/*
* These are data parsing, framing errors or others which can be
* recovered from with intervention... or just resetting the
* channel
*/
f->intr.pbdma.channel_fatal_0 =
pbdma_intr_0_gpfifo_pending_f() |
pbdma_intr_0_gpptr_pending_f() |
pbdma_intr_0_gpentry_pending_f() |
pbdma_intr_0_gpcrc_pending_f() |
pbdma_intr_0_pbptr_pending_f() |
pbdma_intr_0_pbentry_pending_f() |
pbdma_intr_0_pbcrc_pending_f() |
pbdma_intr_0_method_pending_f() |
pbdma_intr_0_methodcrc_pending_f() |
pbdma_intr_0_pbseg_pending_f() |
pbdma_intr_0_clear_faulted_error_pending_f() |
pbdma_intr_0_eng_reset_pending_f() |
pbdma_intr_0_semaphore_pending_f() |
pbdma_intr_0_signature_pending_f();
/* Can be used for sw-methods, or represents a recoverable timeout. */
f->intr.pbdma.restartable_0 =
pbdma_intr_0_device_pending_f();
}
static u32 gv11b_fifo_intr_0_en_mask(struct gk20a *g)
{
u32 intr_0_en_mask;
intr_0_en_mask = g->ops.fifo.intr_0_error_mask(g);
intr_0_en_mask |= fifo_intr_0_runlist_event_pending_f() |
fifo_intr_0_pbdma_intr_pending_f() |
fifo_intr_0_ctxsw_timeout_pending_f();
return intr_0_en_mask;
}
static int gv11b_init_fifo_reset_enable_hw(struct gk20a *g)
{
u32 intr_stall;
u32 mask;
u32 timeout;
unsigned int i;
u32 host_num_pbdma = nvgpu_get_litter_value(g, GPU_LIT_HOST_NUM_PBDMA);
gk20a_dbg_fn("");
/* enable pmc pfifo */
g->ops.mc.reset(g, mc_enable_pfifo_enabled_f());
if (g->ops.clock_gating.slcg_ce2_load_gating_prod)
g->ops.clock_gating.slcg_ce2_load_gating_prod(g,
g->slcg_enabled);
if (g->ops.clock_gating.slcg_fifo_load_gating_prod)
g->ops.clock_gating.slcg_fifo_load_gating_prod(g,
g->slcg_enabled);
if (g->ops.clock_gating.blcg_fifo_load_gating_prod)
g->ops.clock_gating.blcg_fifo_load_gating_prod(g,
g->blcg_enabled);
/* enable pbdma */
mask = 0;
for (i = 0; i < host_num_pbdma; ++i)
mask |= mc_enable_pb_sel_f(mc_enable_pb_0_enabled_v(), i);
gk20a_writel(g, mc_enable_pb_r(), mask);
timeout = gk20a_readl(g, fifo_fb_timeout_r());
timeout = set_field(timeout, fifo_fb_timeout_period_m(),
fifo_fb_timeout_period_init_f());
gk20a_dbg_info("fifo_fb_timeout reg val = 0x%08x", timeout);
gk20a_writel(g, fifo_fb_timeout_r(), timeout);
/* write pbdma timeout value */
for (i = 0; i < host_num_pbdma; i++) {
timeout = gk20a_readl(g, pbdma_timeout_r(i));
timeout = set_field(timeout, pbdma_timeout_period_m(),
pbdma_timeout_period_init_f());
gk20a_dbg_info("pbdma_timeout reg val = 0x%08x", timeout);
gk20a_writel(g, pbdma_timeout_r(i), timeout);
}
/* clear and enable pbdma interrupt */
for (i = 0; i < host_num_pbdma; i++) {
gk20a_writel(g, pbdma_intr_0_r(i), 0xFFFFFFFF);
gk20a_writel(g, pbdma_intr_1_r(i), 0xFFFFFFFF);
intr_stall = gk20a_readl(g, pbdma_intr_stall_r(i));
gk20a_dbg_info("pbdma id:%u, intr_en_0 0x%08x", i, intr_stall);
gk20a_writel(g, pbdma_intr_en_0_r(i), intr_stall);
intr_stall = gk20a_readl(g, pbdma_intr_stall_1_r(i));
gk20a_dbg_info("pbdma id:%u, intr_en_1 0x%08x", i, intr_stall);
gk20a_writel(g, pbdma_intr_en_1_r(i), intr_stall);
}
/* clear ctxsw timeout interrupts */
gk20a_writel(g, fifo_intr_ctxsw_timeout_r(), ~0);
/* enable ctxsw timeout */
timeout = GRFIFO_TIMEOUT_CHECK_PERIOD_US;
timeout = scale_ptimer(timeout,
ptimer_scalingfactor10x(g->ptimer_src_freq));
timeout |= fifo_eng_ctxsw_timeout_detection_enabled_f();
gk20a_writel(g, fifo_eng_ctxsw_timeout_r(), timeout);
/* clear runlist interrupts */
gk20a_writel(g, fifo_intr_runlist_r(), ~0);
/* clear and enable pfifo interrupt */
gk20a_writel(g, fifo_intr_0_r(), 0xFFFFFFFF);
mask = gv11b_fifo_intr_0_en_mask(g);
gk20a_dbg_info("fifo_intr_en_0 0x%08x", mask);
gk20a_writel(g, fifo_intr_en_0_r(), mask);
gk20a_dbg_info("fifo_intr_en_1 = 0x80000000");
gk20a_writel(g, fifo_intr_en_1_r(), 0x80000000);
gk20a_dbg_fn("done");
return 0;
}
static const char *const gv11b_sched_error_str[] = {
"xxx-0",
"xxx-1",
"xxx-2",
"xxx-3",
"xxx-4",
"engine_reset",
"rl_ack_timeout",
"rl_ack_extra",
"rl_rdat_timeout",
"rl_rdat_extra",
"xxx-a",
"xxx-b",
"rl_req_timeout",
"new_runlist",
"code_config_while_busy",
"xxx-f",
"xxx-0x10",
"xxx-0x11",
"xxx-0x12",
"xxx-0x13",
"xxx-0x14",
"xxx-0x15",
"xxx-0x16",
"xxx-0x17",
"xxx-0x18",
"xxx-0x19",
"xxx-0x1a",
"xxx-0x1b",
"xxx-0x1c",
"xxx-0x1d",
"xxx-0x1e",
"xxx-0x1f",
"bad_tsg",
};
static bool gv11b_fifo_handle_sched_error(struct gk20a *g)
{
u32 sched_error;
sched_error = gk20a_readl(g, fifo_intr_sched_error_r());
if (sched_error < ARRAY_SIZE(gv11b_sched_error_str))
nvgpu_err(g, "fifo sched error :%s",
gv11b_sched_error_str[sched_error]);
else
nvgpu_err(g, "fifo sched error code not supported");
if (sched_error == SCHED_ERROR_CODE_BAD_TSG ) {
/* id is unknown, preempt all runlists and do recovery */
gk20a_fifo_recover(g, 0, 0, false, false, false);
}
return false;
}
static u32 gv11b_fifo_ctxsw_timeout_info(struct gk20a *g, u32 active_eng_id)
{
u32 tsgid = FIFO_INVAL_TSG_ID;
u32 timeout_info;
u32 ctx_status, info_status;
timeout_info = gk20a_readl(g,
fifo_intr_ctxsw_timeout_info_r(active_eng_id));
/*
* ctxsw_state and tsgid are snapped at the point of the timeout and
* will not change while the corresponding INTR_CTXSW_TIMEOUT_ENGINE bit
* is PENDING.
*/
ctx_status = fifo_intr_ctxsw_timeout_info_ctxsw_state_v(timeout_info);
if (ctx_status ==
fifo_intr_ctxsw_timeout_info_ctxsw_state_load_v()) {
tsgid = fifo_intr_ctxsw_timeout_info_next_tsgid_v(timeout_info);
} else if (ctx_status ==
fifo_intr_ctxsw_timeout_info_ctxsw_state_switch_v() ||
ctx_status ==
fifo_intr_ctxsw_timeout_info_ctxsw_state_save_v()) {
tsgid = fifo_intr_ctxsw_timeout_info_prev_tsgid_v(timeout_info);
}
gk20a_dbg_info("ctxsw timeout info: tsgid = %d", tsgid);
/*
* STATUS indicates whether the context request ack was eventually
* received and whether a subsequent request timed out. This field is
* updated live while the corresponding INTR_CTXSW_TIMEOUT_ENGINE bit
* is PENDING. STATUS starts in AWAITING_ACK, and progresses to
* ACK_RECEIVED and finally ends with DROPPED_TIMEOUT.
*
* AWAITING_ACK - context request ack still not returned from engine.
* ENG_WAS_RESET - The engine was reset via a PRI write to NV_PMC_ENABLE
* or NV_PMC_ELPG_ENABLE prior to receiving the ack. Host will not
* expect ctx ack to return, but if it is already in flight, STATUS will
* transition shortly to ACK_RECEIVED unless the interrupt is cleared
* first. Once the engine is reset, additional context switches can
* occur; if one times out, STATUS will transition to DROPPED_TIMEOUT
* if the interrupt isn't cleared first.
* ACK_RECEIVED - The ack for the timed-out context request was
* received between the point of the timeout and this register being
* read. Note this STATUS can be reported during the load stage of the
* same context switch that timed out if the timeout occurred during the
* save half of a context switch. Additional context requests may have
* completed or may be outstanding, but no further context timeout has
* occurred. This simplifies checking for spurious context switch
* timeouts.
* DROPPED_TIMEOUT - The originally timed-out context request acked,
* but a subsequent context request then timed out.
* Information about the subsequent timeout is not stored; in fact, that
* context request may also have already been acked by the time SW
* SW reads this register. If not, there is a chance SW can get the
* dropped information by clearing the corresponding
* INTR_CTXSW_TIMEOUT_ENGINE bit and waiting for the timeout to occur
* again. Note, however, that if the engine does time out again,
* it may not be from the original request that caused the
* DROPPED_TIMEOUT state, as that request may
* be acked in the interim.
*/
info_status = fifo_intr_ctxsw_timeout_info_status_v(timeout_info);
if (info_status ==
fifo_intr_ctxsw_timeout_info_status_awaiting_ack_v()) {
gk20a_dbg_info("ctxsw timeout info : awaiting ack");
} else if (info_status ==
fifo_intr_ctxsw_timeout_info_status_eng_was_reset_v()) {
gk20a_dbg_info("ctxsw timeout info : eng was reset");
} else if (info_status ==
fifo_intr_ctxsw_timeout_info_status_ack_received_v()) {
gk20a_dbg_info("ctxsw timeout info : ack received");
/* no need to recover */
tsgid = FIFO_INVAL_TSG_ID;
} else if (info_status ==
fifo_intr_ctxsw_timeout_info_status_dropped_timeout_v()) {
gk20a_dbg_info("ctxsw timeout info : dropped timeout");
/* no need to recover */
tsgid = FIFO_INVAL_TSG_ID;
} else {
gk20a_dbg_info("ctxsw timeout info status = %u", info_status);
}
return tsgid;
}
static bool gv11b_fifo_handle_ctxsw_timeout(struct gk20a *g, u32 fifo_intr)
{
bool ret = false;
u32 tsgid = FIFO_INVAL_TSG_ID;
u32 engine_id, active_eng_id;
u32 timeout_val, ctxsw_timeout_engines;
if (!(fifo_intr & fifo_intr_0_ctxsw_timeout_pending_f()))
return ret;
/* get ctxsw timedout engines */
ctxsw_timeout_engines = gk20a_readl(g, fifo_intr_ctxsw_timeout_r());
if (ctxsw_timeout_engines == 0) {
nvgpu_err(g, "no eng ctxsw timeout pending");
return ret;
}
timeout_val = gk20a_readl(g, fifo_eng_ctxsw_timeout_r());
timeout_val = fifo_eng_ctxsw_timeout_period_v(timeout_val);
gk20a_dbg_info("eng ctxsw timeout period = 0x%x", timeout_val);
for (engine_id = 0; engine_id < g->fifo.num_engines; engine_id++) {
active_eng_id = g->fifo.active_engines_list[engine_id];
if (ctxsw_timeout_engines &
fifo_intr_ctxsw_timeout_engine_pending_f(
active_eng_id)) {
struct fifo_gk20a *f = &g->fifo;
u32 ms = 0;
bool verbose = false;
tsgid = gv11b_fifo_ctxsw_timeout_info(g, active_eng_id);
if (tsgid == FIFO_INVAL_TSG_ID)
continue;
if (gk20a_fifo_check_tsg_ctxsw_timeout(
&f->tsg[tsgid], &verbose, &ms)) {
ret = true;
nvgpu_err(g,
"ctxsw timeout error:"
"active engine id =%u, %s=%d, ms=%u",
active_eng_id, "tsg", tsgid, ms);
/* Cancel all channels' timeout */
gk20a_channel_timeout_restart_all_channels(g);
gk20a_fifo_recover(g, BIT(active_eng_id), tsgid,
true, true, verbose);
} else {
gk20a_dbg_info(
"fifo is waiting for ctx switch: "
"for %d ms, %s=%d", ms, "tsg", tsgid);
}
}
}
/* clear interrupt */
gk20a_writel(g, fifo_intr_ctxsw_timeout_r(), ctxsw_timeout_engines);
return ret;
}
static unsigned int gv11b_fifo_handle_pbdma_intr_0(struct gk20a *g,
u32 pbdma_id, u32 pbdma_intr_0,
u32 *handled, u32 *error_notifier)
{
unsigned int rc_type = RC_TYPE_NO_RC;
rc_type = gk20a_fifo_handle_pbdma_intr_0(g, pbdma_id,
pbdma_intr_0, handled, error_notifier);
if (pbdma_intr_0 & pbdma_intr_0_clear_faulted_error_pending_f()) {
gk20a_dbg(gpu_dbg_intr, "clear faulted error on pbdma id %d",
pbdma_id);
gk20a_fifo_reset_pbdma_method(g, pbdma_id, 0);
*handled |= pbdma_intr_0_clear_faulted_error_pending_f();
rc_type = RC_TYPE_PBDMA_FAULT;
}
if (pbdma_intr_0 & pbdma_intr_0_eng_reset_pending_f()) {
gk20a_dbg(gpu_dbg_intr, "eng reset intr on pbdma id %d",
pbdma_id);
*handled |= pbdma_intr_0_eng_reset_pending_f();
rc_type = RC_TYPE_PBDMA_FAULT;
}
return rc_type;
}
void gv11b_init_fifo(struct gpu_ops *gops)
{
gp10b_init_fifo(gops);
/* for gv11b no need to do any thing special for fifo hw setup */
gops->fifo.init_fifo_setup_hw = NULL;
gops->fifo.runlist_entry_size = ram_rl_entry_size_v;
gops->fifo.get_tsg_runlist_entry = gv11b_get_tsg_runlist_entry;
gops->fifo.get_ch_runlist_entry = gv11b_get_ch_runlist_entry;
gops->fifo.get_num_fifos = gv11b_fifo_get_num_fifos;
gops->fifo.userd_gp_get = gv11b_userd_gp_get;
gops->fifo.userd_gp_put = gv11b_userd_gp_put;
gops->fifo.setup_ramfc = channel_gv11b_setup_ramfc;
gops->fifo.resetup_ramfc = NULL;
gops->fifo.unbind_channel = channel_gv11b_unbind;
gops->fifo.eng_runlist_base_size = fifo_eng_runlist_base__size_1_v;
gops->fifo.free_channel_ctx_header = gv11b_free_subctx_header;
gops->fifo.device_info_fault_id = top_device_info_data_fault_id_enum_v;
gops->fifo.is_fault_engine_subid_gpc = gv11b_is_fault_engine_subid_gpc;
gops->fifo.trigger_mmu_fault = NULL;
gops->fifo.dump_pbdma_status = gk20a_dump_pbdma_status;
gops->fifo.dump_eng_status = gv11b_dump_eng_status;
gops->fifo.dump_channel_status_ramfc = gv11b_dump_channel_status_ramfc;
gops->fifo.intr_0_error_mask = gv11b_fifo_intr_0_error_mask;
gops->fifo.preempt_channel = gv11b_fifo_preempt_channel;
gops->fifo.preempt_tsg = gv11b_fifo_preempt_tsg;
gops->fifo.is_preempt_pending = gv11b_fifo_is_preempt_pending;
gops->fifo.preempt_ch_tsg = gv11b_fifo_preempt_ch_tsg;
gops->fifo.init_pbdma_intr_descs = gv11b_fifo_init_pbdma_intr_descs;
gops->fifo.reset_enable_hw = gv11b_init_fifo_reset_enable_hw;
gops->fifo.teardown_ch_tsg = gv11b_fifo_teardown_ch_tsg;
gops->fifo.handle_sched_error = gv11b_fifo_handle_sched_error;
gops->fifo.handle_ctxsw_timeout = gv11b_fifo_handle_ctxsw_timeout;
gops->fifo.handle_pbdma_intr_0 =
gv11b_fifo_handle_pbdma_intr_0;
}