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android-kvm / linux / 0ea32f50b36fd0372b3232db85d340294d7f0a8a / . / drivers / gpu / drm / amd / display / dc / dml2 / dml2_wrapper.c
blob: 72cca367062e163be2dbe41f7af452c515467a54 [file] [log] [blame]
/* SPDX-License-Identifier: MIT */
/*
* Copyright 2023 Advanced Micro Devices, Inc.
*
* 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 COPYRIGHT HOLDER(S) OR AUTHOR(S) 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.
*
* Authors: AMD
*
*/
#include "display_mode_core.h"
#include "dml2_internal_types.h"
#include "dml2_utils.h"
#include "dml2_policy.h"
#include "dml2_translation_helper.h"
#include "dml2_mall_phantom.h"
#include "dml2_dc_resource_mgmt.h"
static void initialize_dml2_ip_params(struct dml2_context *dml2, const struct dc *in_dc, struct ip_params_st *out)
{
if (dml2->config.use_native_soc_bb_construction)
dml2_init_ip_params(dml2, in_dc, out);
else
dml2_translate_ip_params(in_dc, out);
}
static void initialize_dml2_soc_bbox(struct dml2_context *dml2, const struct dc *in_dc, struct soc_bounding_box_st *out)
{
if (dml2->config.use_native_soc_bb_construction)
dml2_init_socbb_params(dml2, in_dc, out);
else
dml2_translate_socbb_params(in_dc, out);
}
static void initialize_dml2_soc_states(struct dml2_context *dml2,
const struct dc *in_dc, const struct soc_bounding_box_st *in_bbox, struct soc_states_st *out)
{
if (dml2->config.use_native_soc_bb_construction)
dml2_init_soc_states(dml2, in_dc, in_bbox, out);
else
dml2_translate_soc_states(in_dc, out, in_dc->dml.soc.num_states);
}
static void map_hw_resources(struct dml2_context *dml2,
struct dml_display_cfg_st *in_out_display_cfg, struct dml_mode_support_info_st *mode_support_info)
{
unsigned int num_pipes = 0;
int i, j;
for (i = 0; i < __DML_NUM_PLANES__; i++) {
in_out_display_cfg->hw.ODMMode[i] = mode_support_info->ODMMode[i];
in_out_display_cfg->hw.DPPPerSurface[i] = mode_support_info->DPPPerSurface[i];
in_out_display_cfg->hw.DSCEnabled[i] = mode_support_info->DSCEnabled[i];
in_out_display_cfg->hw.NumberOfDSCSlices[i] = mode_support_info->NumberOfDSCSlices[i];
in_out_display_cfg->hw.DLGRefClkFreqMHz = 24;
if (dml2->v20.dml_core_ctx.project != dml_project_dcn35 &&
dml2->v20.dml_core_ctx.project != dml_project_dcn351) {
/*dGPU default as 50Mhz*/
in_out_display_cfg->hw.DLGRefClkFreqMHz = 50;
}
for (j = 0; j < mode_support_info->DPPPerSurface[i]; j++) {
if (i >= __DML2_WRAPPER_MAX_STREAMS_PLANES__) {
dml_print("DML::%s: Index out of bounds: i=%d, __DML2_WRAPPER_MAX_STREAMS_PLANES__=%d\n",
__func__, i, __DML2_WRAPPER_MAX_STREAMS_PLANES__);
break;
}
dml2->v20.scratch.dml_to_dc_pipe_mapping.dml_pipe_idx_to_stream_id[num_pipes] = dml2->v20.scratch.dml_to_dc_pipe_mapping.disp_cfg_to_stream_id[i];
dml2->v20.scratch.dml_to_dc_pipe_mapping.dml_pipe_idx_to_stream_id_valid[num_pipes] = true;
dml2->v20.scratch.dml_to_dc_pipe_mapping.dml_pipe_idx_to_plane_id[num_pipes] = dml2->v20.scratch.dml_to_dc_pipe_mapping.disp_cfg_to_plane_id[i];
dml2->v20.scratch.dml_to_dc_pipe_mapping.dml_pipe_idx_to_plane_id_valid[num_pipes] = true;
num_pipes++;
}
}
}
static unsigned int pack_and_call_dml_mode_support_ex(struct dml2_context *dml2,
const struct dml_display_cfg_st *display_cfg,
struct dml_mode_support_info_st *evaluation_info)
{
struct dml2_wrapper_scratch *s = &dml2->v20.scratch;
s->mode_support_params.mode_lib = &dml2->v20.dml_core_ctx;
s->mode_support_params.in_display_cfg = display_cfg;
s->mode_support_params.out_evaluation_info = evaluation_info;
memset(evaluation_info, 0, sizeof(struct dml_mode_support_info_st));
s->mode_support_params.out_lowest_state_idx = 0;
return dml_mode_support_ex(&s->mode_support_params);
}
static bool optimize_configuration(struct dml2_context *dml2, struct dml2_wrapper_optimize_configuration_params *p)
{
int unused_dpps = p->ip_params->max_num_dpp;
int i, j;
int odms_needed, refresh_rate_hz, dpps_needed, subvp_height, pstate_width_fw_delay_lines, surface_count;
int subvp_timing_to_add, new_timing_index, subvp_surface_to_add, new_surface_index;
float frame_time_sec, max_frame_time_sec;
int largest_blend_and_timing = 0;
bool optimization_done = false;
for (i = 0; i < (int) p->cur_display_config->num_timings; i++) {
if (p->cur_display_config->plane.BlendingAndTiming[i] > largest_blend_and_timing)
largest_blend_and_timing = p->cur_display_config->plane.BlendingAndTiming[i];
}
if (p->new_policy != p->cur_policy)
*p->new_policy = *p->cur_policy;
if (p->new_display_config != p->cur_display_config)
*p->new_display_config = *p->cur_display_config;
// Optimize P-State Support
if (dml2->config.use_native_pstate_optimization) {
if (p->cur_mode_support_info->DRAMClockChangeSupport[0] == dml_dram_clock_change_unsupported) {
// Find a display with < 120Hz refresh rate with maximal refresh rate that's not already subvp
subvp_timing_to_add = -1;
subvp_surface_to_add = -1;
max_frame_time_sec = 0;
surface_count = 0;
for (i = 0; i < (int) p->cur_display_config->num_timings; i++) {
refresh_rate_hz = (int)div_u64((unsigned long long) p->cur_display_config->timing.PixelClock[i] * 1000 * 1000,
(p->cur_display_config->timing.HTotal[i] * p->cur_display_config->timing.VTotal[i]));
if (refresh_rate_hz < 120) {
// Check its upstream surfaces to see if this one could be converted to subvp.
dpps_needed = 0;
for (j = 0; j < (int) p->cur_display_config->num_surfaces; j++) {
if (p->cur_display_config->plane.BlendingAndTiming[j] == i &&
p->cur_display_config->plane.UseMALLForPStateChange[j] == dml_use_mall_pstate_change_disable) {
dpps_needed += p->cur_mode_support_info->DPPPerSurface[j];
subvp_surface_to_add = j;
surface_count++;
}
}
if (surface_count == 1 && dpps_needed > 0 && dpps_needed <= unused_dpps) {
frame_time_sec = (float)1 / refresh_rate_hz;
if (frame_time_sec > max_frame_time_sec) {
max_frame_time_sec = frame_time_sec;
subvp_timing_to_add = i;
}
}
}
}
if (subvp_timing_to_add >= 0) {
new_timing_index = p->new_display_config->num_timings++;
new_surface_index = p->new_display_config->num_surfaces++;
// Add a phantom pipe reflecting the main pipe's timing
dml2_util_copy_dml_timing(&p->new_display_config->timing, new_timing_index, subvp_timing_to_add);
pstate_width_fw_delay_lines = (int)(((double)(p->config->svp_pstate.subvp_fw_processing_delay_us +
p->config->svp_pstate.subvp_pstate_allow_width_us) / 1000000) *
(p->new_display_config->timing.PixelClock[subvp_timing_to_add] * 1000 * 1000) /
(double)p->new_display_config->timing.HTotal[subvp_timing_to_add]);
subvp_height = p->cur_mode_support_info->SubViewportLinesNeededInMALL[subvp_timing_to_add] + pstate_width_fw_delay_lines;
p->new_display_config->timing.VActive[new_timing_index] = subvp_height;
p->new_display_config->timing.VTotal[new_timing_index] = subvp_height +
p->new_display_config->timing.VTotal[subvp_timing_to_add] - p->new_display_config->timing.VActive[subvp_timing_to_add];
p->new_display_config->output.OutputDisabled[new_timing_index] = true;
p->new_display_config->plane.UseMALLForPStateChange[subvp_surface_to_add] = dml_use_mall_pstate_change_sub_viewport;
dml2_util_copy_dml_plane(&p->new_display_config->plane, new_surface_index, subvp_surface_to_add);
dml2_util_copy_dml_surface(&p->new_display_config->surface, new_surface_index, subvp_surface_to_add);
p->new_display_config->plane.ViewportHeight[new_surface_index] = subvp_height;
p->new_display_config->plane.ViewportHeightChroma[new_surface_index] = subvp_height;
p->new_display_config->plane.ViewportStationary[new_surface_index] = false;
p->new_display_config->plane.UseMALLForStaticScreen[new_surface_index] = dml_use_mall_static_screen_disable;
p->new_display_config->plane.UseMALLForPStateChange[new_surface_index] = dml_use_mall_pstate_change_phantom_pipe;
p->new_display_config->plane.NumberOfCursors[new_surface_index] = 0;
p->new_policy->ImmediateFlipRequirement[new_surface_index] = dml_immediate_flip_not_required;
p->new_display_config->plane.BlendingAndTiming[new_surface_index] = new_timing_index;
optimization_done = true;
}
}
}
// Optimize Clocks
if (!optimization_done) {
if (largest_blend_and_timing == 0 && p->cur_policy->ODMUse[0] == dml_odm_use_policy_combine_as_needed && dml2->config.minimize_dispclk_using_odm) {
odms_needed = dml2_util_get_maximum_odm_combine_for_output(dml2->config.optimize_odm_4to1,
p->cur_display_config->output.OutputEncoder[0], p->cur_mode_support_info->DSCEnabled[0]) - 1;
if (odms_needed <= unused_dpps) {
unused_dpps -= odms_needed;
if (odms_needed == 1) {
p->new_policy->ODMUse[0] = dml_odm_use_policy_combine_2to1;
optimization_done = true;
} else if (odms_needed == 3) {
p->new_policy->ODMUse[0] = dml_odm_use_policy_combine_4to1;
optimization_done = true;
} else
optimization_done = false;
}
}
}
return optimization_done;
}
static int calculate_lowest_supported_state_for_temp_read(struct dml2_context *dml2, struct dc_state *display_state)
{
struct dml2_calculate_lowest_supported_state_for_temp_read_scratch *s = &dml2->v20.scratch.dml2_calculate_lowest_supported_state_for_temp_read_scratch;
struct dml2_wrapper_scratch *s_global = &dml2->v20.scratch;
unsigned int dml_result = 0;
int result = -1, i, j;
build_unoptimized_policy_settings(dml2->v20.dml_core_ctx.project, &dml2->v20.dml_core_ctx.policy);
/* Zero out before each call before proceeding */
memset(s, 0, sizeof(struct dml2_calculate_lowest_supported_state_for_temp_read_scratch));
memset(&s_global->mode_support_params, 0, sizeof(struct dml_mode_support_ex_params_st));
memset(&s_global->dml_to_dc_pipe_mapping, 0, sizeof(struct dml2_dml_to_dc_pipe_mapping));
for (i = 0; i < dml2->config.dcn_pipe_count; i++) {
/* Calling resource_build_scaling_params will populate the pipe params
* with the necessary information needed for correct DML calculations
* This is also done in DML1 driver code path and hence display_state
* cannot be const.
*/
struct pipe_ctx *pipe = &display_state->res_ctx.pipe_ctx[i];
if (pipe->plane_state) {
if (!dml2->config.callbacks.build_scaling_params(pipe)) {
ASSERT(false);
return false;
}
}
}
map_dc_state_into_dml_display_cfg(dml2, display_state, &s->cur_display_config);
for (i = 0; i < dml2->v20.dml_core_ctx.states.num_states; i++) {
s->uclk_change_latencies[i] = dml2->v20.dml_core_ctx.states.state_array[i].dram_clock_change_latency_us;
}
for (i = 0; i < 4; i++) {
for (j = 0; j < dml2->v20.dml_core_ctx.states.num_states; j++) {
dml2->v20.dml_core_ctx.states.state_array[j].dram_clock_change_latency_us = s_global->dummy_pstate_table[i].dummy_pstate_latency_us;
}
dml_result = pack_and_call_dml_mode_support_ex(dml2, &s->cur_display_config, &s->evaluation_info);
if (dml_result && s->evaluation_info.DRAMClockChangeSupport[0] == dml_dram_clock_change_vactive) {
map_hw_resources(dml2, &s->cur_display_config, &s->evaluation_info);
dml_result = dml_mode_programming(&dml2->v20.dml_core_ctx, s_global->mode_support_params.out_lowest_state_idx, &s->cur_display_config, true);
ASSERT(dml_result);
dml2_extract_watermark_set(&dml2->v20.g6_temp_read_watermark_set, &dml2->v20.dml_core_ctx);
dml2->v20.g6_temp_read_watermark_set.cstate_pstate.fclk_pstate_change_ns = dml2->v20.g6_temp_read_watermark_set.cstate_pstate.pstate_change_ns;
result = s_global->mode_support_params.out_lowest_state_idx;
while (dml2->v20.dml_core_ctx.states.state_array[result].dram_speed_mts < s_global->dummy_pstate_table[i].dram_speed_mts)
result++;
break;
}
}
for (i = 0; i < dml2->v20.dml_core_ctx.states.num_states; i++) {
dml2->v20.dml_core_ctx.states.state_array[i].dram_clock_change_latency_us = s->uclk_change_latencies[i];
}
return result;
}
static void copy_dummy_pstate_table(struct dummy_pstate_entry *dest, struct dummy_pstate_entry *src, unsigned int num_entries)
{
for (int i = 0; i < num_entries; i++) {
dest[i] = src[i];
}
}
static bool are_timings_requiring_odm_doing_blending(const struct dml_display_cfg_st *display_cfg,
const struct dml_mode_support_info_st *evaluation_info)
{
unsigned int planes_per_timing[__DML_NUM_PLANES__] = {0};
int i;
for (i = 0; i < display_cfg->num_surfaces; i++)
planes_per_timing[display_cfg->plane.BlendingAndTiming[i]]++;
for (i = 0; i < __DML_NUM_PLANES__; i++) {
if (planes_per_timing[i] > 1 && evaluation_info->ODMMode[i] != dml_odm_mode_bypass)
return true;
}
return false;
}
static bool does_configuration_meet_sw_policies(struct dml2_context *ctx, const struct dml_display_cfg_st *display_cfg,
const struct dml_mode_support_info_st *evaluation_info)
{
bool pass = true;
if (!ctx->config.enable_windowed_mpo_odm) {
if (are_timings_requiring_odm_doing_blending(display_cfg, evaluation_info))
pass = false;
}
return pass;
}
static bool dml_mode_support_wrapper(struct dml2_context *dml2,
struct dc_state *display_state)
{
struct dml2_wrapper_scratch *s = &dml2->v20.scratch;
unsigned int result = 0, i;
unsigned int optimized_result = true;
build_unoptimized_policy_settings(dml2->v20.dml_core_ctx.project, &dml2->v20.dml_core_ctx.policy);
/* Zero out before each call before proceeding */
memset(&s->cur_display_config, 0, sizeof(struct dml_display_cfg_st));
memset(&s->mode_support_params, 0, sizeof(struct dml_mode_support_ex_params_st));
memset(&s->dml_to_dc_pipe_mapping, 0, sizeof(struct dml2_dml_to_dc_pipe_mapping));
memset(&s->optimize_configuration_params, 0, sizeof(struct dml2_wrapper_optimize_configuration_params));
for (i = 0; i < dml2->config.dcn_pipe_count; i++) {
/* Calling resource_build_scaling_params will populate the pipe params
* with the necessary information needed for correct DML calculations
* This is also done in DML1 driver code path and hence display_state
* cannot be const.
*/
struct pipe_ctx *pipe = &display_state->res_ctx.pipe_ctx[i];
if (pipe->plane_state) {
if (!dml2->config.callbacks.build_scaling_params(pipe)) {
ASSERT(false);
return false;
}
}
}
map_dc_state_into_dml_display_cfg(dml2, display_state, &s->cur_display_config);
if (!dml2->config.skip_hw_state_mapping)
dml2_apply_det_buffer_allocation_policy(dml2, &s->cur_display_config);
result = pack_and_call_dml_mode_support_ex(dml2,
&s->cur_display_config,
&s->mode_support_info);
if (result)
result = does_configuration_meet_sw_policies(dml2, &s->cur_display_config, &s->mode_support_info);
// Try to optimize
if (result) {
s->cur_policy = dml2->v20.dml_core_ctx.policy;
s->optimize_configuration_params.dml_core_ctx = &dml2->v20.dml_core_ctx;
s->optimize_configuration_params.config = &dml2->config;
s->optimize_configuration_params.ip_params = &dml2->v20.dml_core_ctx.ip;
s->optimize_configuration_params.cur_display_config = &s->cur_display_config;
s->optimize_configuration_params.cur_mode_support_info = &s->mode_support_info;
s->optimize_configuration_params.cur_policy = &s->cur_policy;
s->optimize_configuration_params.new_display_config = &s->new_display_config;
s->optimize_configuration_params.new_policy = &s->new_policy;
while (optimized_result && optimize_configuration(dml2, &s->optimize_configuration_params)) {
dml2->v20.dml_core_ctx.policy = s->new_policy;
optimized_result = pack_and_call_dml_mode_support_ex(dml2,
&s->new_display_config,
&s->mode_support_info);
if (optimized_result)
optimized_result = does_configuration_meet_sw_policies(dml2, &s->new_display_config, &s->mode_support_info);
// If the new optimized state is supposed, then set current = new
if (optimized_result) {
s->cur_display_config = s->new_display_config;
s->cur_policy = s->new_policy;
} else {
// Else, restore policy to current
dml2->v20.dml_core_ctx.policy = s->cur_policy;
}
}
// Optimize ended with a failed config, so we need to restore DML state to last passing
if (!optimized_result) {
result = pack_and_call_dml_mode_support_ex(dml2,
&s->cur_display_config,
&s->mode_support_info);
}
}
if (result)
map_hw_resources(dml2, &s->cur_display_config, &s->mode_support_info);
return result;
}
static int find_drr_eligible_stream(struct dc_state *display_state)
{
int i;
for (i = 0; i < display_state->stream_count; i++) {
if (dc_state_get_stream_subvp_type(display_state, display_state->streams[i]) == SUBVP_NONE
&& display_state->streams[i]->ignore_msa_timing_param) {
// Use ignore_msa_timing_param flag to identify as DRR
return i;
}
}
return -1;
}
static bool optimize_pstate_with_svp_and_drr(struct dml2_context *dml2, struct dc_state *display_state)
{
struct dml2_wrapper_scratch *s = &dml2->v20.scratch;
bool pstate_optimization_done = false;
bool pstate_optimization_success = false;
bool result = false;
int drr_display_index = 0, non_svp_streams = 0;
bool force_svp = dml2->config.svp_pstate.force_enable_subvp;
bool advanced_pstate_switching = false;
display_state->bw_ctx.bw.dcn.clk.fw_based_mclk_switching = false;
display_state->bw_ctx.bw.dcn.legacy_svp_drr_stream_index_valid = false;
result = dml_mode_support_wrapper(dml2, display_state);
if (!result) {
pstate_optimization_done = true;
} else if (!advanced_pstate_switching ||
(s->mode_support_info.DRAMClockChangeSupport[0] != dml_dram_clock_change_unsupported && !force_svp)) {
pstate_optimization_success = true;
pstate_optimization_done = true;
}
if (display_state->stream_count == 1 && dml2->config.callbacks.can_support_mclk_switch_using_fw_based_vblank_stretch(dml2->config.callbacks.dc, display_state)) {
display_state->bw_ctx.bw.dcn.clk.fw_based_mclk_switching = true;
result = dml_mode_support_wrapper(dml2, display_state);
} else {
non_svp_streams = display_state->stream_count;
while (!pstate_optimization_done) {
result = dml_mode_programming(&dml2->v20.dml_core_ctx, s->mode_support_params.out_lowest_state_idx, &s->cur_display_config, true);
// Always try adding SVP first
if (result)
result = dml2_svp_add_phantom_pipe_to_dc_state(dml2, display_state, &s->mode_support_info);
else
pstate_optimization_done = true;
if (result) {
result = dml_mode_support_wrapper(dml2, display_state);
} else {
pstate_optimization_done = true;
}
if (result) {
non_svp_streams--;
if (s->mode_support_info.DRAMClockChangeSupport[0] != dml_dram_clock_change_unsupported) {
if (dml2_svp_validate_static_schedulability(dml2, display_state, s->mode_support_info.DRAMClockChangeSupport[0])) {
pstate_optimization_success = true;
pstate_optimization_done = true;
} else {
pstate_optimization_success = false;
pstate_optimization_done = false;
}
} else {
drr_display_index = find_drr_eligible_stream(display_state);
// If there is only 1 remaining non SubVP pipe that is DRR, check static
// schedulability for SubVP + DRR.
if (non_svp_streams == 1 && drr_display_index >= 0) {
if (dml2_svp_drr_schedulable(dml2, display_state, &display_state->streams[drr_display_index]->timing)) {
display_state->bw_ctx.bw.dcn.legacy_svp_drr_stream_index_valid = true;
display_state->bw_ctx.bw.dcn.legacy_svp_drr_stream_index = drr_display_index;
result = dml_mode_support_wrapper(dml2, display_state);
}
if (result && s->mode_support_info.DRAMClockChangeSupport[0] != dml_dram_clock_change_unsupported) {
pstate_optimization_success = true;
pstate_optimization_done = true;
} else {
pstate_optimization_success = false;
pstate_optimization_done = false;
}
}
if (pstate_optimization_success) {
pstate_optimization_done = true;
} else {
pstate_optimization_done = false;
}
}
}
}
}
if (!pstate_optimization_success) {
dml2_svp_remove_all_phantom_pipes(dml2, display_state);
display_state->bw_ctx.bw.dcn.clk.fw_based_mclk_switching = false;
display_state->bw_ctx.bw.dcn.legacy_svp_drr_stream_index_valid = false;
result = dml_mode_support_wrapper(dml2, display_state);
}
return result;
}
static bool call_dml_mode_support_and_programming(struct dc_state *context)
{
unsigned int result = 0;
unsigned int min_state;
int min_state_for_g6_temp_read = 0;
struct dml2_context *dml2 = context->bw_ctx.dml2;
struct dml2_wrapper_scratch *s = &dml2->v20.scratch;
min_state_for_g6_temp_read = calculate_lowest_supported_state_for_temp_read(dml2, context);
ASSERT(min_state_for_g6_temp_read >= 0);
if (!dml2->config.use_native_pstate_optimization) {
result = optimize_pstate_with_svp_and_drr(dml2, context);
} else {
result = dml_mode_support_wrapper(dml2, context);
}
/* Upon trying to sett certain frequencies in FRL, min_state_for_g6_temp_read is reported as -1. This leads to an invalid value of min_state causing crashes later on.
* Use the default logic for min_state only when min_state_for_g6_temp_read is a valid value. In other cases, use the value calculated by the DML directly.
*/
if (min_state_for_g6_temp_read >= 0)
min_state = min_state_for_g6_temp_read > s->mode_support_params.out_lowest_state_idx ? min_state_for_g6_temp_read : s->mode_support_params.out_lowest_state_idx;
else
min_state = s->mode_support_params.out_lowest_state_idx;
if (result)
result = dml_mode_programming(&dml2->v20.dml_core_ctx, min_state, &s->cur_display_config, true);
return result;
}
static bool dml2_validate_and_build_resource(const struct dc *in_dc, struct dc_state *context)
{
struct dml2_context *dml2 = context->bw_ctx.dml2;
struct dml2_wrapper_scratch *s = &dml2->v20.scratch;
struct dml2_dcn_clocks out_clks;
unsigned int result = 0;
bool need_recalculation = false;
if (!context || context->stream_count == 0)
return true;
/* Zero out before each call before proceeding */
memset(&dml2->v20.scratch, 0, sizeof(struct dml2_wrapper_scratch));
memset(&dml2->v20.dml_core_ctx.policy, 0, sizeof(struct dml_mode_eval_policy_st));
memset(&dml2->v20.dml_core_ctx.ms, 0, sizeof(struct mode_support_st));
memset(&dml2->v20.dml_core_ctx.mp, 0, sizeof(struct mode_program_st));
/* Initialize DET scratch */
dml2_initialize_det_scratch(dml2);
copy_dummy_pstate_table(s->dummy_pstate_table, in_dc->clk_mgr->bw_params->dummy_pstate_table, 4);
result = call_dml_mode_support_and_programming(context);
/* Call map dc pipes to map the pipes based on the DML output. For correctly determining if recalculation
* is required or not, the resource context needs to correctly reflect the number of active pipes. We would
* only know the correct number if active pipes after dml2_map_dc_pipes is called.
*/
if (result && !dml2->config.skip_hw_state_mapping)
dml2_map_dc_pipes(dml2, context, &s->cur_display_config, &s->dml_to_dc_pipe_mapping, in_dc->current_state);
/* Verify and update DET Buffer configuration if needed. dml2_verify_det_buffer_configuration will check if DET Buffer
* size needs to be updated. If yes it will update the DETOverride variable and set need_recalculation flag to true.
* Based on that flag, run mode support again. Verification needs to be run after dml_mode_programming because the getters
* return correct det buffer values only after dml_mode_programming is called.
*/
if (result && !dml2->config.skip_hw_state_mapping) {
need_recalculation = dml2_verify_det_buffer_configuration(dml2, context, &dml2->det_helper_scratch);
if (need_recalculation) {
/* Engage the DML again if recalculation is required. */
call_dml_mode_support_and_programming(context);
if (!dml2->config.skip_hw_state_mapping) {
dml2_map_dc_pipes(dml2, context, &s->cur_display_config, &s->dml_to_dc_pipe_mapping, in_dc->current_state);
}
need_recalculation = dml2_verify_det_buffer_configuration(dml2, context, &dml2->det_helper_scratch);
ASSERT(need_recalculation == false);
}
}
if (result) {
unsigned int lowest_state_idx = s->mode_support_params.out_lowest_state_idx;
out_clks.dispclk_khz = (unsigned int)dml2->v20.dml_core_ctx.mp.Dispclk_calculated * 1000;
out_clks.p_state_supported = s->mode_support_info.DRAMClockChangeSupport[0] != dml_dram_clock_change_unsupported;
if (in_dc->config.use_default_clock_table &&
(lowest_state_idx < dml2->v20.dml_core_ctx.states.num_states - 1)) {
lowest_state_idx = dml2->v20.dml_core_ctx.states.num_states - 1;
out_clks.dispclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].dispclk_mhz * 1000;
}
out_clks.dcfclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].dcfclk_mhz * 1000;
out_clks.fclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].fabricclk_mhz * 1000;
out_clks.uclk_mts = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].dram_speed_mts;
out_clks.phyclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].phyclk_mhz * 1000;
out_clks.socclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].socclk_mhz * 1000;
out_clks.ref_dtbclk_khz = (unsigned int)dml2->v20.dml_core_ctx.states.state_array[lowest_state_idx].dtbclk_mhz * 1000;
context->bw_ctx.bw.dcn.clk.dtbclk_en = is_dtbclk_required(in_dc, context);
if (!dml2->config.skip_hw_state_mapping) {
/* Call dml2_calculate_rq_and_dlg_params */
dml2_calculate_rq_and_dlg_params(in_dc, context, &context->res_ctx, dml2, in_dc->res_pool->pipe_count);
}
dml2_copy_clocks_to_dc_state(&out_clks, context);
dml2_extract_watermark_set(&context->bw_ctx.bw.dcn.watermarks.a, &dml2->v20.dml_core_ctx);
dml2_extract_watermark_set(&context->bw_ctx.bw.dcn.watermarks.b, &dml2->v20.dml_core_ctx);
memcpy(&context->bw_ctx.bw.dcn.watermarks.c, &dml2->v20.g6_temp_read_watermark_set, sizeof(context->bw_ctx.bw.dcn.watermarks.c));
dml2_extract_watermark_set(&context->bw_ctx.bw.dcn.watermarks.d, &dml2->v20.dml_core_ctx);
//copy for deciding zstate use
context->bw_ctx.dml.vba.StutterPeriod = context->bw_ctx.dml2->v20.dml_core_ctx.mp.StutterPeriod;
}
return result;
}
static bool dml2_validate_only(struct dc_state *context)
{
struct dml2_context *dml2 = context->bw_ctx.dml2;
unsigned int result = 0;
if (!context || context->stream_count == 0)
return true;
/* Zero out before each call before proceeding */
memset(&dml2->v20.scratch, 0, sizeof(struct dml2_wrapper_scratch));
memset(&dml2->v20.dml_core_ctx.policy, 0, sizeof(struct dml_mode_eval_policy_st));
memset(&dml2->v20.dml_core_ctx.ms, 0, sizeof(struct mode_support_st));
memset(&dml2->v20.dml_core_ctx.mp, 0, sizeof(struct mode_program_st));
build_unoptimized_policy_settings(dml2->v20.dml_core_ctx.project, &dml2->v20.dml_core_ctx.policy);
map_dc_state_into_dml_display_cfg(dml2, context, &dml2->v20.scratch.cur_display_config);
result = pack_and_call_dml_mode_support_ex(dml2,
&dml2->v20.scratch.cur_display_config,
&dml2->v20.scratch.mode_support_info);
if (result)
result = does_configuration_meet_sw_policies(dml2, &dml2->v20.scratch.cur_display_config, &dml2->v20.scratch.mode_support_info);
return (result == 1) ? true : false;
}
static void dml2_apply_debug_options(const struct dc *dc, struct dml2_context *dml2)
{
if (dc->debug.override_odm_optimization) {
dml2->config.minimize_dispclk_using_odm = dc->debug.minimize_dispclk_using_odm;
}
}
bool dml2_validate(const struct dc *in_dc, struct dc_state *context, bool fast_validate)
{
bool out = false;
if (!(context->bw_ctx.dml2))
return false;
dml2_apply_debug_options(in_dc, context->bw_ctx.dml2);
/* Use dml_validate_only for fast_validate path */
if (fast_validate)
out = dml2_validate_only(context);
else
out = dml2_validate_and_build_resource(in_dc, context);
return out;
}
static inline struct dml2_context *dml2_allocate_memory(void)
{
return (struct dml2_context *) kzalloc(sizeof(struct dml2_context), GFP_KERNEL);
}
static void dml2_init(const struct dc *in_dc, const struct dml2_configuration_options *config, struct dml2_context **dml2)
{
// Store config options
(*dml2)->config = *config;
switch (in_dc->ctx->dce_version) {
case DCN_VERSION_3_5:
(*dml2)->v20.dml_core_ctx.project = dml_project_dcn35;
break;
case DCN_VERSION_3_51:
(*dml2)->v20.dml_core_ctx.project = dml_project_dcn351;
break;
case DCN_VERSION_3_2:
(*dml2)->v20.dml_core_ctx.project = dml_project_dcn32;
break;
case DCN_VERSION_3_21:
(*dml2)->v20.dml_core_ctx.project = dml_project_dcn321;
break;
default:
(*dml2)->v20.dml_core_ctx.project = dml_project_default;
break;
}
initialize_dml2_ip_params(*dml2, in_dc, &(*dml2)->v20.dml_core_ctx.ip);
initialize_dml2_soc_bbox(*dml2, in_dc, &(*dml2)->v20.dml_core_ctx.soc);
initialize_dml2_soc_states(*dml2, in_dc, &(*dml2)->v20.dml_core_ctx.soc, &(*dml2)->v20.dml_core_ctx.states);
}
bool dml2_create(const struct dc *in_dc, const struct dml2_configuration_options *config, struct dml2_context **dml2)
{
// Allocate Mode Lib Ctx
*dml2 = dml2_allocate_memory();
if (!(*dml2))
return false;
dml2_init(in_dc, config, dml2);
return true;
}
void dml2_destroy(struct dml2_context *dml2)
{
if (!dml2)
return;
kfree(dml2);
}
void dml2_extract_dram_and_fclk_change_support(struct dml2_context *dml2,
unsigned int *fclk_change_support, unsigned int *dram_clk_change_support)
{
*fclk_change_support = (unsigned int) dml2->v20.dml_core_ctx.ms.support.FCLKChangeSupport[0];
*dram_clk_change_support = (unsigned int) dml2->v20.dml_core_ctx.ms.support.DRAMClockChangeSupport[0];
}
void dml2_copy(struct dml2_context *dst_dml2,
struct dml2_context *src_dml2)
{
/* copy Mode Lib Ctx */
memcpy(dst_dml2, src_dml2, sizeof(struct dml2_context));
}
bool dml2_create_copy(struct dml2_context **dst_dml2,
struct dml2_context *src_dml2)
{
/* Allocate Mode Lib Ctx */
*dst_dml2 = dml2_allocate_memory();
if (!(*dst_dml2))
return false;
/* copy Mode Lib Ctx */
dml2_copy(*dst_dml2, src_dml2);
return true;
}
void dml2_reinit(const struct dc *in_dc,
const struct dml2_configuration_options *config,
struct dml2_context **dml2)
{
dml2_init(in_dc, config, dml2);
}