// SPDX-License-Identifier: (GPL-2.0-only OR BSD-3-Clause) // Copyright(c) 2015-2020 Intel Corporation. /* * Bandwidth management algorithm based on 2^n gears * */ #include #include #include #include #include #include #include "bus.h" #define SDW_STRM_RATE_GROUPING 1 struct sdw_group_params { unsigned int rate; unsigned int lane; int full_bw; int payload_bw; int hwidth; }; struct sdw_group { unsigned int count; unsigned int max_size; unsigned int *rates; unsigned int *lanes; }; void sdw_compute_slave_ports(struct sdw_master_runtime *m_rt, struct sdw_transport_data *t_data) { struct sdw_slave_runtime *s_rt = NULL; struct sdw_port_runtime *p_rt; int port_bo, sample_int; unsigned int rate, bps, ch = 0; unsigned int slave_total_ch; struct sdw_bus_params *b_params = &m_rt->bus->params; port_bo = t_data->block_offset; list_for_each_entry(s_rt, &m_rt->slave_rt_list, m_rt_node) { rate = m_rt->stream->params.rate; bps = m_rt->stream->params.bps; sample_int = (m_rt->bus->params.curr_dr_freq / rate); slave_total_ch = 0; list_for_each_entry(p_rt, &s_rt->port_list, port_node) { if (p_rt->lane != t_data->lane) continue; ch = hweight32(p_rt->ch_mask); sdw_fill_xport_params(&p_rt->transport_params, p_rt->num, false, SDW_BLK_GRP_CNT_1, sample_int, port_bo, port_bo >> 8, t_data->hstart, t_data->hstop, SDW_BLK_PKG_PER_PORT, p_rt->lane); sdw_fill_port_params(&p_rt->port_params, p_rt->num, bps, SDW_PORT_FLOW_MODE_ISOCH, b_params->s_data_mode); port_bo += bps * ch; slave_total_ch += ch; } if (m_rt->direction == SDW_DATA_DIR_TX && m_rt->ch_count == slave_total_ch) { /* * Slave devices were configured to access all channels * of the stream, which indicates that they operate in * 'mirror mode'. Make sure we reset the port offset for * the next device in the list */ port_bo = t_data->block_offset; } } } EXPORT_SYMBOL(sdw_compute_slave_ports); static void sdw_compute_master_ports(struct sdw_master_runtime *m_rt, struct sdw_group_params *params, int *port_bo, int hstop) { struct sdw_transport_data t_data = {0}; struct sdw_port_runtime *p_rt; struct sdw_bus *bus = m_rt->bus; struct sdw_bus_params *b_params = &bus->params; int sample_int, hstart = 0; unsigned int rate, bps, ch; rate = m_rt->stream->params.rate; bps = m_rt->stream->params.bps; ch = m_rt->ch_count; sample_int = (bus->params.curr_dr_freq / rate); if (rate != params->rate) return; t_data.hstop = hstop; hstart = hstop - params->hwidth + 1; t_data.hstart = hstart; list_for_each_entry(p_rt, &m_rt->port_list, port_node) { if (p_rt->lane != params->lane) continue; sdw_fill_xport_params(&p_rt->transport_params, p_rt->num, false, SDW_BLK_GRP_CNT_1, sample_int, *port_bo, (*port_bo) >> 8, hstart, hstop, SDW_BLK_PKG_PER_PORT, p_rt->lane); sdw_fill_port_params(&p_rt->port_params, p_rt->num, bps, SDW_PORT_FLOW_MODE_ISOCH, b_params->m_data_mode); /* Check for first entry */ if (!(p_rt == list_first_entry(&m_rt->port_list, struct sdw_port_runtime, port_node))) { (*port_bo) += bps * ch; continue; } t_data.hstart = hstart; t_data.hstop = hstop; t_data.block_offset = *port_bo; t_data.sub_block_offset = 0; (*port_bo) += bps * ch; } t_data.lane = params->lane; sdw_compute_slave_ports(m_rt, &t_data); } static void _sdw_compute_port_params(struct sdw_bus *bus, struct sdw_group_params *params, int count) { struct sdw_master_runtime *m_rt; int port_bo, i, l; int hstop; /* Run loop for all groups to compute transport parameters */ for (l = 0; l < SDW_MAX_LANES; l++) { if (l > 0 && !bus->lane_used_bandwidth[l]) continue; /* reset hstop for each lane */ hstop = bus->params.col - 1; for (i = 0; i < count; i++) { if (params[i].lane != l) continue; port_bo = 1; list_for_each_entry(m_rt, &bus->m_rt_list, bus_node) { sdw_compute_master_ports(m_rt, ¶ms[i], &port_bo, hstop); } hstop = hstop - params[i].hwidth; } } } static int sdw_compute_group_params(struct sdw_bus *bus, struct sdw_stream_runtime *stream, struct sdw_group_params *params, struct sdw_group *group) { struct sdw_master_runtime *m_rt; struct sdw_port_runtime *p_rt; int sel_col = bus->params.col; unsigned int rate, bps, ch; int i, l, column_needed; /* Calculate bandwidth per group */ for (i = 0; i < group->count; i++) { params[i].rate = group->rates[i]; params[i].lane = group->lanes[i]; params[i].full_bw = bus->params.curr_dr_freq / params[i].rate; } list_for_each_entry(m_rt, &bus->m_rt_list, bus_node) { if (m_rt->stream == stream) { /* Only runtime during prepare should be added */ if (stream->state != SDW_STREAM_CONFIGURED) continue; } else { /* * Include runtimes with running (ENABLED state) and paused (DISABLED state) * streams */ if (m_rt->stream->state != SDW_STREAM_ENABLED && m_rt->stream->state != SDW_STREAM_DISABLED) continue; } list_for_each_entry(p_rt, &m_rt->port_list, port_node) { rate = m_rt->stream->params.rate; bps = m_rt->stream->params.bps; ch = hweight32(p_rt->ch_mask); for (i = 0; i < group->count; i++) { if (rate == params[i].rate && p_rt->lane == params[i].lane) params[i].payload_bw += bps * ch; } } } for (l = 0; l < SDW_MAX_LANES; l++) { if (l > 0 && !bus->lane_used_bandwidth[l]) continue; /* reset column_needed for each lane */ column_needed = 0; for (i = 0; i < group->count; i++) { if (params[i].lane != l) continue; params[i].hwidth = (sel_col * params[i].payload_bw + params[i].full_bw - 1) / params[i].full_bw; column_needed += params[i].hwidth; /* There is no control column for lane 1 and above */ if (column_needed > sel_col) return -EINVAL; /* Column 0 is control column on lane 0 */ if (params[i].lane == 0 && column_needed > sel_col - 1) return -EINVAL; } } return 0; } static int sdw_add_element_group_count(struct sdw_group *group, unsigned int rate, unsigned int lane) { int num = group->count; int i; for (i = 0; i <= num; i++) { if (rate == group->rates[i] && lane == group->lanes[i]) break; if (i != num) continue; if (group->count >= group->max_size) { unsigned int *rates; unsigned int *lanes; group->max_size += 1; rates = krealloc(group->rates, (sizeof(int) * group->max_size), GFP_KERNEL); if (!rates) return -ENOMEM; group->rates = rates; lanes = krealloc(group->lanes, (sizeof(int) * group->max_size), GFP_KERNEL); if (!lanes) return -ENOMEM; group->lanes = lanes; } group->rates[group->count] = rate; group->lanes[group->count++] = lane; } return 0; } static int sdw_get_group_count(struct sdw_bus *bus, struct sdw_group *group) { struct sdw_master_runtime *m_rt; struct sdw_port_runtime *p_rt; unsigned int rate; int ret = 0; group->count = 0; group->max_size = SDW_STRM_RATE_GROUPING; group->rates = kcalloc(group->max_size, sizeof(int), GFP_KERNEL); if (!group->rates) return -ENOMEM; group->lanes = kcalloc(group->max_size, sizeof(int), GFP_KERNEL); if (!group->lanes) { kfree(group->rates); group->rates = NULL; return -ENOMEM; } list_for_each_entry(m_rt, &bus->m_rt_list, bus_node) { if (m_rt->stream->state == SDW_STREAM_DEPREPARED) continue; rate = m_rt->stream->params.rate; if (m_rt == list_first_entry(&bus->m_rt_list, struct sdw_master_runtime, bus_node)) { group->rates[group->count++] = rate; } /* * Different ports could use different lane, add group element * even if m_rt is the first entry */ list_for_each_entry(p_rt, &m_rt->port_list, port_node) { ret = sdw_add_element_group_count(group, rate, p_rt->lane); if (ret < 0) { kfree(group->rates); kfree(group->lanes); return ret; } } } return ret; } /** * sdw_compute_port_params: Compute transport and port parameters * * @bus: SDW Bus instance * @stream: Soundwire stream */ static int sdw_compute_port_params(struct sdw_bus *bus, struct sdw_stream_runtime *stream) { struct sdw_group_params *params = NULL; struct sdw_group group; int ret; ret = sdw_get_group_count(bus, &group); if (ret < 0) return ret; if (group.count == 0) goto out; params = kcalloc(group.count, sizeof(*params), GFP_KERNEL); if (!params) { ret = -ENOMEM; goto out; } /* Compute transport parameters for grouped streams */ ret = sdw_compute_group_params(bus, stream, params, &group); if (ret < 0) goto free_params; _sdw_compute_port_params(bus, params, group.count); free_params: kfree(params); out: kfree(group.rates); kfree(group.lanes); return ret; } static int sdw_select_row_col(struct sdw_bus *bus, int clk_freq) { struct sdw_master_prop *prop = &bus->prop; int r, c; for (c = 0; c < SDW_FRAME_COLS; c++) { for (r = 0; r < SDW_FRAME_ROWS; r++) { if (sdw_rows[r] != prop->default_row || sdw_cols[c] != prop->default_col) continue; if (clk_freq * (sdw_cols[c] - 1) < bus->params.bandwidth * sdw_cols[c]) continue; bus->params.row = sdw_rows[r]; bus->params.col = sdw_cols[c]; return 0; } } return -EINVAL; } static bool is_clock_scaling_supported(struct sdw_bus *bus) { struct sdw_master_runtime *m_rt; struct sdw_slave_runtime *s_rt; list_for_each_entry(m_rt, &bus->m_rt_list, bus_node) list_for_each_entry(s_rt, &m_rt->slave_rt_list, m_rt_node) if (!is_clock_scaling_supported_by_slave(s_rt->slave)) return false; return true; } /** * is_lane_connected_to_all_peripherals: Check if the given manager lane connects to all peripherals * So that all peripherals can use the manager lane. * * @m_rt: Manager runtime * @lane: Lane number */ static bool is_lane_connected_to_all_peripherals(struct sdw_master_runtime *m_rt, unsigned int lane) { struct sdw_slave_prop *slave_prop; struct sdw_slave_runtime *s_rt; int i; list_for_each_entry(s_rt, &m_rt->slave_rt_list, m_rt_node) { slave_prop = &s_rt->slave->prop; for (i = 1; i < SDW_MAX_LANES; i++) { if (slave_prop->lane_maps[i] == lane) { dev_dbg(&s_rt->slave->dev, "M lane %d is connected to P lane %d\n", lane, i); break; } } if (i == SDW_MAX_LANES) { dev_dbg(&s_rt->slave->dev, "M lane %d is not connected\n", lane); return false; } } return true; } static int get_manager_lane(struct sdw_bus *bus, struct sdw_master_runtime *m_rt, struct sdw_slave_runtime *s_rt, unsigned int curr_dr_freq) { struct sdw_slave_prop *slave_prop = &s_rt->slave->prop; struct sdw_port_runtime *m_p_rt; unsigned int required_bandwidth; int m_lane; int l; for (l = 1; l < SDW_MAX_LANES; l++) { if (!slave_prop->lane_maps[l]) continue; required_bandwidth = 0; list_for_each_entry(m_p_rt, &m_rt->port_list, port_node) { required_bandwidth += m_rt->stream->params.rate * hweight32(m_p_rt->ch_mask) * m_rt->stream->params.bps; } if (required_bandwidth <= curr_dr_freq - bus->lane_used_bandwidth[l]) { /* Check if m_lane is connected to all Peripherals */ if (!is_lane_connected_to_all_peripherals(m_rt, slave_prop->lane_maps[l])) { dev_dbg(bus->dev, "Not all Peripherals are connected to M lane %d\n", slave_prop->lane_maps[l]); continue; } m_lane = slave_prop->lane_maps[l]; dev_dbg(&s_rt->slave->dev, "M lane %d is used\n", m_lane); bus->lane_used_bandwidth[l] += required_bandwidth; /* * Use non-zero manager lane, subtract the lane 0 * bandwidth that is already calculated */ bus->params.bandwidth -= required_bandwidth; return m_lane; } } /* No available multi lane found, only lane 0 can be used */ return 0; } /** * sdw_compute_bus_params: Compute bus parameters * * @bus: SDW Bus instance */ static int sdw_compute_bus_params(struct sdw_bus *bus) { struct sdw_master_prop *mstr_prop = &bus->prop; struct sdw_slave_prop *slave_prop; struct sdw_port_runtime *m_p_rt; struct sdw_port_runtime *s_p_rt; struct sdw_master_runtime *m_rt; struct sdw_slave_runtime *s_rt; unsigned int curr_dr_freq = 0; int i, l, clk_values, ret; bool is_gear = false; int m_lane = 0; u32 *clk_buf; if (mstr_prop->num_clk_gears) { clk_values = mstr_prop->num_clk_gears; clk_buf = mstr_prop->clk_gears; is_gear = true; } else if (mstr_prop->num_clk_freq) { clk_values = mstr_prop->num_clk_freq; clk_buf = mstr_prop->clk_freq; } else { clk_values = 1; clk_buf = NULL; } /* If dynamic scaling is not supported, don't try higher freq */ if (!is_clock_scaling_supported(bus)) clk_values = 1; for (i = 0; i < clk_values; i++) { if (!clk_buf) curr_dr_freq = bus->params.max_dr_freq; else curr_dr_freq = (is_gear) ? (bus->params.max_dr_freq >> clk_buf[i]) : clk_buf[i] * SDW_DOUBLE_RATE_FACTOR; if (curr_dr_freq * (mstr_prop->default_col - 1) >= bus->params.bandwidth * mstr_prop->default_col) break; list_for_each_entry(m_rt, &bus->m_rt_list, bus_node) { /* * Get the first s_rt that will be used to find the available lane that * can be used. No need to check all Peripherals because we can't use * multi-lane if we can't find any available lane for the first Peripheral. */ s_rt = list_first_entry(&m_rt->slave_rt_list, struct sdw_slave_runtime, m_rt_node); /* * Find the available Manager lane that connected to the first Peripheral. */ m_lane = get_manager_lane(bus, m_rt, s_rt, curr_dr_freq); if (m_lane > 0) goto out; } /* * TODO: Check all the Slave(s) port(s) audio modes and find * whether given clock rate is supported with glitchless * transition. */ } if (i == clk_values) { dev_err(bus->dev, "%s: could not find clock value for bandwidth %d\n", __func__, bus->params.bandwidth); return -EINVAL; } out: /* multilane can be used */ if (m_lane > 0) { /* Set Peripheral lanes */ list_for_each_entry(s_rt, &m_rt->slave_rt_list, m_rt_node) { slave_prop = &s_rt->slave->prop; for (l = 1; l < SDW_MAX_LANES; l++) { if (slave_prop->lane_maps[l] == m_lane) { list_for_each_entry(s_p_rt, &s_rt->port_list, port_node) { s_p_rt->lane = l; dev_dbg(&s_rt->slave->dev, "Set P lane %d for port %d\n", l, s_p_rt->num); } break; } } } /* * Set Manager lanes. Configure the last m_rt in bus->m_rt_list only since * we don't want to touch other m_rts that are already working. */ list_for_each_entry(m_p_rt, &m_rt->port_list, port_node) { m_p_rt->lane = m_lane; } } if (!mstr_prop->default_frame_rate || !mstr_prop->default_row) return -EINVAL; mstr_prop->default_col = curr_dr_freq / mstr_prop->default_frame_rate / mstr_prop->default_row; ret = sdw_select_row_col(bus, curr_dr_freq); if (ret < 0) { dev_err(bus->dev, "%s: could not find frame configuration for bus dr_freq %d\n", __func__, curr_dr_freq); return -EINVAL; } bus->params.curr_dr_freq = curr_dr_freq; return 0; } /** * sdw_compute_params: Compute bus, transport and port parameters * * @bus: SDW Bus instance * @stream: Soundwire stream */ int sdw_compute_params(struct sdw_bus *bus, struct sdw_stream_runtime *stream) { int ret; /* Computes clock frequency, frame shape and frame frequency */ ret = sdw_compute_bus_params(bus); if (ret < 0) return ret; /* Compute transport and port params */ ret = sdw_compute_port_params(bus, stream); if (ret < 0) { dev_err(bus->dev, "Compute transport params failed: %d\n", ret); return ret; } return 0; } EXPORT_SYMBOL(sdw_compute_params); MODULE_LICENSE("Dual BSD/GPL"); MODULE_DESCRIPTION("SoundWire Generic Bandwidth Allocation");