/****************************************************************************** * * Copyright(c) 2007 - 2010 Intel Corporation. All rights reserved. * * Portions of this file are derived from the ipw3945 project, as well * as portions of the ieee80211 subsystem header files. * * This program is free software; you can redistribute it and/or modify it * under the terms of version 2 of the GNU General Public License as * published by the Free Software Foundation. * * This program is distributed in the hope that 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. * * You should have received a copy of the GNU General Public License along with * this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110, USA * * The full GNU General Public License is included in this distribution in the * file called LICENSE. * * Contact Information: * Intel Linux Wireless * Intel Corporation, 5200 N.E. Elam Young Parkway, Hillsboro, OR 97124-6497 *****************************************************************************/ #include #include #include #include #include "iwl-eeprom.h" #include "iwl-dev.h" #include "iwl-core.h" #include "iwl-io.h" #include "iwl-commands.h" #include "iwl-debug.h" #include "iwl-power.h" /* * Setting power level allows the card to go to sleep when not busy. * * We calculate a sleep command based on the required latency, which * we get from mac80211. In order to handle thermal throttling, we can * also use pre-defined power levels. */ /* * For now, keep using power level 1 instead of automatically * adjusting ... */ bool no_sleep_autoadjust = true; module_param(no_sleep_autoadjust, bool, S_IRUGO); MODULE_PARM_DESC(no_sleep_autoadjust, "don't automatically adjust sleep level " "according to maximum network latency"); /* * This defines the old power levels. They are still used by default * (level 1) and for thermal throttle (levels 3 through 5) */ struct iwl_power_vec_entry { struct iwl_powertable_cmd cmd; u8 no_dtim; /* number of skip dtim */ }; #define IWL_DTIM_RANGE_0_MAX 2 #define IWL_DTIM_RANGE_1_MAX 10 #define NOSLP cpu_to_le16(0), 0, 0 #define SLP IWL_POWER_DRIVER_ALLOW_SLEEP_MSK, 0, 0 #define TU_TO_USEC 1024 #define SLP_TOUT(T) cpu_to_le32((T) * TU_TO_USEC) #define SLP_VEC(X0, X1, X2, X3, X4) {cpu_to_le32(X0), \ cpu_to_le32(X1), \ cpu_to_le32(X2), \ cpu_to_le32(X3), \ cpu_to_le32(X4)} /* default power management (not Tx power) table values */ /* for DTIM period 0 through IWL_DTIM_RANGE_0_MAX */ /* DTIM 0 - 2 */ static const struct iwl_power_vec_entry range_0[IWL_POWER_NUM] = { {{SLP, SLP_TOUT(200), SLP_TOUT(500), SLP_VEC(1, 1, 2, 2, 0xFF)}, 0}, {{SLP, SLP_TOUT(200), SLP_TOUT(300), SLP_VEC(1, 2, 2, 2, 0xFF)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(100), SLP_VEC(2, 2, 2, 2, 0xFF)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(25), SLP_VEC(2, 2, 4, 4, 0xFF)}, 1}, {{SLP, SLP_TOUT(25), SLP_TOUT(25), SLP_VEC(2, 2, 4, 6, 0xFF)}, 2} }; /* for DTIM period IWL_DTIM_RANGE_0_MAX + 1 through IWL_DTIM_RANGE_1_MAX */ /* DTIM 3 - 10 */ static const struct iwl_power_vec_entry range_1[IWL_POWER_NUM] = { {{SLP, SLP_TOUT(200), SLP_TOUT(500), SLP_VEC(1, 2, 3, 4, 4)}, 0}, {{SLP, SLP_TOUT(200), SLP_TOUT(300), SLP_VEC(1, 2, 3, 4, 7)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(100), SLP_VEC(2, 4, 6, 7, 9)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(25), SLP_VEC(2, 4, 6, 9, 10)}, 1}, {{SLP, SLP_TOUT(25), SLP_TOUT(25), SLP_VEC(2, 4, 6, 10, 10)}, 2} }; /* for DTIM period > IWL_DTIM_RANGE_1_MAX */ /* DTIM 11 - */ static const struct iwl_power_vec_entry range_2[IWL_POWER_NUM] = { {{SLP, SLP_TOUT(200), SLP_TOUT(500), SLP_VEC(1, 2, 3, 4, 0xFF)}, 0}, {{SLP, SLP_TOUT(200), SLP_TOUT(300), SLP_VEC(2, 4, 6, 7, 0xFF)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(100), SLP_VEC(2, 7, 9, 9, 0xFF)}, 0}, {{SLP, SLP_TOUT(50), SLP_TOUT(25), SLP_VEC(2, 7, 9, 9, 0xFF)}, 0}, {{SLP, SLP_TOUT(25), SLP_TOUT(25), SLP_VEC(4, 7, 10, 10, 0xFF)}, 0} }; static void iwl_static_sleep_cmd(struct iwl_priv *priv, struct iwl_powertable_cmd *cmd, enum iwl_power_level lvl, int period) { const struct iwl_power_vec_entry *table; int max_sleep[IWL_POWER_VEC_SIZE] = { 0 }; int i; u8 skip; u32 slp_itrvl; table = range_2; if (period <= IWL_DTIM_RANGE_1_MAX) table = range_1; if (period <= IWL_DTIM_RANGE_0_MAX) table = range_0; BUG_ON(lvl < 0 || lvl >= IWL_POWER_NUM); *cmd = table[lvl].cmd; if (period == 0) { skip = 0; period = 1; for (i = 0; i < IWL_POWER_VEC_SIZE; i++) max_sleep[i] = 1; } else { skip = table[lvl].no_dtim; for (i = 0; i < IWL_POWER_VEC_SIZE; i++) max_sleep[i] = le32_to_cpu(cmd->sleep_interval[i]); max_sleep[IWL_POWER_VEC_SIZE - 1] = skip + 1; } slp_itrvl = le32_to_cpu(cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1]); /* figure out the listen interval based on dtim period and skip */ if (slp_itrvl == 0xFF) cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1] = cpu_to_le32(period * (skip + 1)); slp_itrvl = le32_to_cpu(cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1]); if (slp_itrvl > period) cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1] = cpu_to_le32((slp_itrvl / period) * period); if (skip) cmd->flags |= IWL_POWER_SLEEP_OVER_DTIM_MSK; else cmd->flags &= ~IWL_POWER_SLEEP_OVER_DTIM_MSK; slp_itrvl = le32_to_cpu(cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1]); if (slp_itrvl > IWL_CONN_MAX_LISTEN_INTERVAL) cmd->sleep_interval[IWL_POWER_VEC_SIZE - 1] = cpu_to_le32(IWL_CONN_MAX_LISTEN_INTERVAL); /* enforce max sleep interval */ for (i = IWL_POWER_VEC_SIZE - 1; i >= 0 ; i--) { if (le32_to_cpu(cmd->sleep_interval[i]) > (max_sleep[i] * period)) cmd->sleep_interval[i] = cpu_to_le32(max_sleep[i] * period); if (i != (IWL_POWER_VEC_SIZE - 1)) { if (le32_to_cpu(cmd->sleep_interval[i]) > le32_to_cpu(cmd->sleep_interval[i+1])) cmd->sleep_interval[i] = cmd->sleep_interval[i+1]; } } if (priv->power_data.pci_pm) cmd->flags |= IWL_POWER_PCI_PM_MSK; else cmd->flags &= ~IWL_POWER_PCI_PM_MSK; IWL_DEBUG_POWER(priv, "numSkipDtim = %u, dtimPeriod = %d\n", skip, period); IWL_DEBUG_POWER(priv, "Sleep command for index %d\n", lvl + 1); } /* default Thermal Throttling transaction table * Current state | Throttling Down | Throttling Up *============================================================================= * Condition Nxt State Condition Nxt State Condition Nxt State *----------------------------------------------------------------------------- * IWL_TI_0 T >= 114 CT_KILL 114>T>=105 TI_1 N/A N/A * IWL_TI_1 T >= 114 CT_KILL 114>T>=110 TI_2 T<=95 TI_0 * IWL_TI_2 T >= 114 CT_KILL T<=100 TI_1 * IWL_CT_KILL N/A N/A N/A N/A T<=95 TI_0 *============================================================================= */ static const struct iwl_tt_trans tt_range_0[IWL_TI_STATE_MAX - 1] = { {IWL_TI_0, IWL_ABSOLUTE_ZERO, 104}, {IWL_TI_1, 105, CT_KILL_THRESHOLD - 1}, {IWL_TI_CT_KILL, CT_KILL_THRESHOLD, IWL_ABSOLUTE_MAX} }; static const struct iwl_tt_trans tt_range_1[IWL_TI_STATE_MAX - 1] = { {IWL_TI_0, IWL_ABSOLUTE_ZERO, 95}, {IWL_TI_2, 110, CT_KILL_THRESHOLD - 1}, {IWL_TI_CT_KILL, CT_KILL_THRESHOLD, IWL_ABSOLUTE_MAX} }; static const struct iwl_tt_trans tt_range_2[IWL_TI_STATE_MAX - 1] = { {IWL_TI_1, IWL_ABSOLUTE_ZERO, 100}, {IWL_TI_CT_KILL, CT_KILL_THRESHOLD, IWL_ABSOLUTE_MAX}, {IWL_TI_CT_KILL, CT_KILL_THRESHOLD, IWL_ABSOLUTE_MAX} }; static const struct iwl_tt_trans tt_range_3[IWL_TI_STATE_MAX - 1] = { {IWL_TI_0, IWL_ABSOLUTE_ZERO, CT_KILL_EXIT_THRESHOLD}, {IWL_TI_CT_KILL, CT_KILL_EXIT_THRESHOLD + 1, IWL_ABSOLUTE_MAX}, {IWL_TI_CT_KILL, CT_KILL_EXIT_THRESHOLD + 1, IWL_ABSOLUTE_MAX} }; /* Advance Thermal Throttling default restriction table */ static const struct iwl_tt_restriction restriction_range[IWL_TI_STATE_MAX] = { {IWL_ANT_OK_MULTI, IWL_ANT_OK_MULTI, true }, {IWL_ANT_OK_SINGLE, IWL_ANT_OK_MULTI, true }, {IWL_ANT_OK_SINGLE, IWL_ANT_OK_SINGLE, false }, {IWL_ANT_OK_NONE, IWL_ANT_OK_NONE, false } }; static void iwl_power_sleep_cam_cmd(struct iwl_priv *priv, struct iwl_powertable_cmd *cmd) { memset(cmd, 0, sizeof(*cmd)); if (priv->power_data.pci_pm) cmd->flags |= IWL_POWER_PCI_PM_MSK; IWL_DEBUG_POWER(priv, "Sleep command for CAM\n"); } static void iwl_power_fill_sleep_cmd(struct iwl_priv *priv, struct iwl_powertable_cmd *cmd, int dynps_ms, int wakeup_period) { /* * These are the original power level 3 sleep successions. The * device may behave better with such succession and was also * only tested with that. Just like the original sleep commands, * also adjust the succession here to the wakeup_period below. * The ranges are the same as for the sleep commands, 0-2, 3-9 * and >10, which is selected based on the DTIM interval for * the sleep index but here we use the wakeup period since that * is what we need to do for the latency requirements. */ static const u8 slp_succ_r0[IWL_POWER_VEC_SIZE] = { 2, 2, 2, 2, 2 }; static const u8 slp_succ_r1[IWL_POWER_VEC_SIZE] = { 2, 4, 6, 7, 9 }; static const u8 slp_succ_r2[IWL_POWER_VEC_SIZE] = { 2, 7, 9, 9, 0xFF }; const u8 *slp_succ = slp_succ_r0; int i; if (wakeup_period > IWL_DTIM_RANGE_0_MAX) slp_succ = slp_succ_r1; if (wakeup_period > IWL_DTIM_RANGE_1_MAX) slp_succ = slp_succ_r2; memset(cmd, 0, sizeof(*cmd)); cmd->flags = IWL_POWER_DRIVER_ALLOW_SLEEP_MSK | IWL_POWER_FAST_PD; /* no use seeing frames for others */ if (priv->power_data.pci_pm) cmd->flags |= IWL_POWER_PCI_PM_MSK; cmd->rx_data_timeout = cpu_to_le32(1000 * dynps_ms); cmd->tx_data_timeout = cpu_to_le32(1000 * dynps_ms); for (i = 0; i < IWL_POWER_VEC_SIZE; i++) cmd->sleep_interval[i] = cpu_to_le32(min_t(int, slp_succ[i], wakeup_period)); IWL_DEBUG_POWER(priv, "Automatic sleep command\n"); } static int iwl_set_power(struct iwl_priv *priv, struct iwl_powertable_cmd *cmd) { IWL_DEBUG_POWER(priv, "Sending power/sleep command\n"); IWL_DEBUG_POWER(priv, "Flags value = 0x%08X\n", cmd->flags); IWL_DEBUG_POWER(priv, "Tx timeout = %u\n", le32_to_cpu(cmd->tx_data_timeout)); IWL_DEBUG_POWER(priv, "Rx timeout = %u\n", le32_to_cpu(cmd->rx_data_timeout)); IWL_DEBUG_POWER(priv, "Sleep interval vector = { %d , %d , %d , %d , %d }\n", le32_to_cpu(cmd->sleep_interval[0]), le32_to_cpu(cmd->sleep_interval[1]), le32_to_cpu(cmd->sleep_interval[2]), le32_to_cpu(cmd->sleep_interval[3]), le32_to_cpu(cmd->sleep_interval[4])); return iwl_send_cmd_pdu(priv, POWER_TABLE_CMD, sizeof(struct iwl_powertable_cmd), cmd); } /* priv->mutex must be held */ int iwl_power_update_mode(struct iwl_priv *priv, bool force) { int ret = 0; struct iwl_tt_mgmt *tt = &priv->thermal_throttle; bool enabled = priv->hw->conf.flags & IEEE80211_CONF_PS; bool update_chains; struct iwl_powertable_cmd cmd; int dtimper; /* Don't update the RX chain when chain noise calibration is running */ update_chains = priv->chain_noise_data.state == IWL_CHAIN_NOISE_DONE || priv->chain_noise_data.state == IWL_CHAIN_NOISE_ALIVE; dtimper = priv->hw->conf.ps_dtim_period ?: 1; if (priv->cfg->broken_powersave) iwl_power_sleep_cam_cmd(priv, &cmd); else if (priv->cfg->supports_idle && priv->hw->conf.flags & IEEE80211_CONF_IDLE) iwl_static_sleep_cmd(priv, &cmd, IWL_POWER_INDEX_5, 20); else if (tt->state >= IWL_TI_1) iwl_static_sleep_cmd(priv, &cmd, tt->tt_power_mode, dtimper); else if (!enabled) iwl_power_sleep_cam_cmd(priv, &cmd); else if (priv->power_data.debug_sleep_level_override >= 0) iwl_static_sleep_cmd(priv, &cmd, priv->power_data.debug_sleep_level_override, dtimper); else if (no_sleep_autoadjust) iwl_static_sleep_cmd(priv, &cmd, IWL_POWER_INDEX_1, dtimper); else iwl_power_fill_sleep_cmd(priv, &cmd, priv->hw->conf.dynamic_ps_timeout, priv->hw->conf.max_sleep_period); if (iwl_is_ready_rf(priv) && (memcmp(&priv->power_data.sleep_cmd, &cmd, sizeof(cmd)) || force)) { if (cmd.flags & IWL_POWER_DRIVER_ALLOW_SLEEP_MSK) set_bit(STATUS_POWER_PMI, &priv->status); ret = iwl_set_power(priv, &cmd); if (!ret) { if (!(cmd.flags & IWL_POWER_DRIVER_ALLOW_SLEEP_MSK)) clear_bit(STATUS_POWER_PMI, &priv->status); if (priv->cfg->ops->lib->update_chain_flags && update_chains) priv->cfg->ops->lib->update_chain_flags(priv); else if (priv->cfg->ops->lib->update_chain_flags) IWL_DEBUG_POWER(priv, "Cannot update the power, chain noise " "calibration running: %d\n", priv->chain_noise_data.state); memcpy(&priv->power_data.sleep_cmd, &cmd, sizeof(cmd)); } else IWL_ERR(priv, "set power fail, ret = %d", ret); } return ret; } EXPORT_SYMBOL(iwl_power_update_mode); bool iwl_ht_enabled(struct iwl_priv *priv) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; struct iwl_tt_restriction *restriction; if (!priv->thermal_throttle.advanced_tt) return true; restriction = tt->restriction + tt->state; return restriction->is_ht; } EXPORT_SYMBOL(iwl_ht_enabled); bool iwl_within_ct_kill_margin(struct iwl_priv *priv) { s32 temp = priv->temperature; /* degrees CELSIUS except specified */ bool within_margin = false; if (priv->cfg->temperature_kelvin) temp = KELVIN_TO_CELSIUS(priv->temperature); if (!priv->thermal_throttle.advanced_tt) within_margin = ((temp + IWL_TT_CT_KILL_MARGIN) >= CT_KILL_THRESHOLD_LEGACY) ? true : false; else within_margin = ((temp + IWL_TT_CT_KILL_MARGIN) >= CT_KILL_THRESHOLD) ? true : false; return within_margin; } enum iwl_antenna_ok iwl_tx_ant_restriction(struct iwl_priv *priv) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; struct iwl_tt_restriction *restriction; if (!priv->thermal_throttle.advanced_tt) return IWL_ANT_OK_MULTI; restriction = tt->restriction + tt->state; return restriction->tx_stream; } EXPORT_SYMBOL(iwl_tx_ant_restriction); enum iwl_antenna_ok iwl_rx_ant_restriction(struct iwl_priv *priv) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; struct iwl_tt_restriction *restriction; if (!priv->thermal_throttle.advanced_tt) return IWL_ANT_OK_MULTI; restriction = tt->restriction + tt->state; return restriction->rx_stream; } #define CT_KILL_EXIT_DURATION (5) /* 5 seconds duration */ #define CT_KILL_WAITING_DURATION (300) /* 300ms duration */ /* * toggle the bit to wake up uCode and check the temperature * if the temperature is below CT, uCode will stay awake and send card * state notification with CT_KILL bit clear to inform Thermal Throttling * Management to change state. Otherwise, uCode will go back to sleep * without doing anything, driver should continue the 5 seconds timer * to wake up uCode for temperature check until temperature drop below CT */ static void iwl_tt_check_exit_ct_kill(unsigned long data) { struct iwl_priv *priv = (struct iwl_priv *)data; struct iwl_tt_mgmt *tt = &priv->thermal_throttle; unsigned long flags; if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; if (tt->state == IWL_TI_CT_KILL) { if (priv->thermal_throttle.ct_kill_toggle) { iwl_write32(priv, CSR_UCODE_DRV_GP1_CLR, CSR_UCODE_DRV_GP1_REG_BIT_CT_KILL_EXIT); priv->thermal_throttle.ct_kill_toggle = false; } else { iwl_write32(priv, CSR_UCODE_DRV_GP1_SET, CSR_UCODE_DRV_GP1_REG_BIT_CT_KILL_EXIT); priv->thermal_throttle.ct_kill_toggle = true; } iwl_read32(priv, CSR_UCODE_DRV_GP1); spin_lock_irqsave(&priv->reg_lock, flags); if (!iwl_grab_nic_access(priv)) iwl_release_nic_access(priv); spin_unlock_irqrestore(&priv->reg_lock, flags); /* Reschedule the ct_kill timer to occur in * CT_KILL_EXIT_DURATION seconds to ensure we get a * thermal update */ IWL_DEBUG_POWER(priv, "schedule ct_kill exit timer\n"); mod_timer(&priv->thermal_throttle.ct_kill_exit_tm, jiffies + CT_KILL_EXIT_DURATION * HZ); } } static void iwl_perform_ct_kill_task(struct iwl_priv *priv, bool stop) { if (stop) { IWL_DEBUG_POWER(priv, "Stop all queues\n"); if (priv->mac80211_registered) ieee80211_stop_queues(priv->hw); IWL_DEBUG_POWER(priv, "Schedule 5 seconds CT_KILL Timer\n"); mod_timer(&priv->thermal_throttle.ct_kill_exit_tm, jiffies + CT_KILL_EXIT_DURATION * HZ); } else { IWL_DEBUG_POWER(priv, "Wake all queues\n"); if (priv->mac80211_registered) ieee80211_wake_queues(priv->hw); } } static void iwl_tt_ready_for_ct_kill(unsigned long data) { struct iwl_priv *priv = (struct iwl_priv *)data; struct iwl_tt_mgmt *tt = &priv->thermal_throttle; if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; /* temperature timer expired, ready to go into CT_KILL state */ if (tt->state != IWL_TI_CT_KILL) { IWL_DEBUG_POWER(priv, "entering CT_KILL state when temperature timer expired\n"); tt->state = IWL_TI_CT_KILL; set_bit(STATUS_CT_KILL, &priv->status); iwl_perform_ct_kill_task(priv, true); } } static void iwl_prepare_ct_kill_task(struct iwl_priv *priv) { IWL_DEBUG_POWER(priv, "Prepare to enter IWL_TI_CT_KILL\n"); /* make request to retrieve statistics information */ iwl_send_statistics_request(priv, CMD_SYNC, false); /* Reschedule the ct_kill wait timer */ mod_timer(&priv->thermal_throttle.ct_kill_waiting_tm, jiffies + msecs_to_jiffies(CT_KILL_WAITING_DURATION)); } #define IWL_MINIMAL_POWER_THRESHOLD (CT_KILL_THRESHOLD_LEGACY) #define IWL_REDUCED_PERFORMANCE_THRESHOLD_2 (100) #define IWL_REDUCED_PERFORMANCE_THRESHOLD_1 (90) /* * Legacy thermal throttling * 1) Avoid NIC destruction due to high temperatures * Chip will identify dangerously high temperatures that can * harm the device and will power down * 2) Avoid the NIC power down due to high temperature * Throttle early enough to lower the power consumption before * drastic steps are needed */ static void iwl_legacy_tt_handler(struct iwl_priv *priv, s32 temp, bool force) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; enum iwl_tt_state old_state; #ifdef CONFIG_IWLWIFI_DEBUG if ((tt->tt_previous_temp) && (temp > tt->tt_previous_temp) && ((temp - tt->tt_previous_temp) > IWL_TT_INCREASE_MARGIN)) { IWL_DEBUG_POWER(priv, "Temperature increase %d degree Celsius\n", (temp - tt->tt_previous_temp)); } #endif old_state = tt->state; /* in Celsius */ if (temp >= IWL_MINIMAL_POWER_THRESHOLD) tt->state = IWL_TI_CT_KILL; else if (temp >= IWL_REDUCED_PERFORMANCE_THRESHOLD_2) tt->state = IWL_TI_2; else if (temp >= IWL_REDUCED_PERFORMANCE_THRESHOLD_1) tt->state = IWL_TI_1; else tt->state = IWL_TI_0; #ifdef CONFIG_IWLWIFI_DEBUG tt->tt_previous_temp = temp; #endif /* stop ct_kill_waiting_tm timer */ del_timer_sync(&priv->thermal_throttle.ct_kill_waiting_tm); if (tt->state != old_state) { switch (tt->state) { case IWL_TI_0: /* * When the system is ready to go back to IWL_TI_0 * we only have to call iwl_power_update_mode() to * do so. */ break; case IWL_TI_1: tt->tt_power_mode = IWL_POWER_INDEX_3; break; case IWL_TI_2: tt->tt_power_mode = IWL_POWER_INDEX_4; break; default: tt->tt_power_mode = IWL_POWER_INDEX_5; break; } mutex_lock(&priv->mutex); if (old_state == IWL_TI_CT_KILL) clear_bit(STATUS_CT_KILL, &priv->status); if (tt->state != IWL_TI_CT_KILL && iwl_power_update_mode(priv, true)) { /* TT state not updated * try again during next temperature read */ if (old_state == IWL_TI_CT_KILL) set_bit(STATUS_CT_KILL, &priv->status); tt->state = old_state; IWL_ERR(priv, "Cannot update power mode, " "TT state not updated\n"); } else { if (tt->state == IWL_TI_CT_KILL) { if (force) { set_bit(STATUS_CT_KILL, &priv->status); iwl_perform_ct_kill_task(priv, true); } else { iwl_prepare_ct_kill_task(priv); tt->state = old_state; } } else if (old_state == IWL_TI_CT_KILL && tt->state != IWL_TI_CT_KILL) iwl_perform_ct_kill_task(priv, false); IWL_DEBUG_POWER(priv, "Temperature state changed %u\n", tt->state); IWL_DEBUG_POWER(priv, "Power Index change to %u\n", tt->tt_power_mode); } mutex_unlock(&priv->mutex); } } /* * Advance thermal throttling * 1) Avoid NIC destruction due to high temperatures * Chip will identify dangerously high temperatures that can * harm the device and will power down * 2) Avoid the NIC power down due to high temperature * Throttle early enough to lower the power consumption before * drastic steps are needed * Actions include relaxing the power down sleep thresholds and * decreasing the number of TX streams * 3) Avoid throughput performance impact as much as possible * *============================================================================= * Condition Nxt State Condition Nxt State Condition Nxt State *----------------------------------------------------------------------------- * IWL_TI_0 T >= 114 CT_KILL 114>T>=105 TI_1 N/A N/A * IWL_TI_1 T >= 114 CT_KILL 114>T>=110 TI_2 T<=95 TI_0 * IWL_TI_2 T >= 114 CT_KILL T<=100 TI_1 * IWL_CT_KILL N/A N/A N/A N/A T<=95 TI_0 *============================================================================= */ static void iwl_advance_tt_handler(struct iwl_priv *priv, s32 temp, bool force) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; int i; bool changed = false; enum iwl_tt_state old_state; struct iwl_tt_trans *transaction; old_state = tt->state; for (i = 0; i < IWL_TI_STATE_MAX - 1; i++) { /* based on the current TT state, * find the curresponding transaction table * each table has (IWL_TI_STATE_MAX - 1) entries * tt->transaction + ((old_state * (IWL_TI_STATE_MAX - 1)) * will advance to the correct table. * then based on the current temperature * find the next state need to transaction to * go through all the possible (IWL_TI_STATE_MAX - 1) entries * in the current table to see if transaction is needed */ transaction = tt->transaction + ((old_state * (IWL_TI_STATE_MAX - 1)) + i); if (temp >= transaction->tt_low && temp <= transaction->tt_high) { #ifdef CONFIG_IWLWIFI_DEBUG if ((tt->tt_previous_temp) && (temp > tt->tt_previous_temp) && ((temp - tt->tt_previous_temp) > IWL_TT_INCREASE_MARGIN)) { IWL_DEBUG_POWER(priv, "Temperature increase %d " "degree Celsius\n", (temp - tt->tt_previous_temp)); } tt->tt_previous_temp = temp; #endif if (old_state != transaction->next_state) { changed = true; tt->state = transaction->next_state; } break; } } /* stop ct_kill_waiting_tm timer */ del_timer_sync(&priv->thermal_throttle.ct_kill_waiting_tm); if (changed) { struct iwl_rxon_cmd *rxon = &priv->staging_rxon; if (tt->state >= IWL_TI_1) { /* force PI = IWL_POWER_INDEX_5 in the case of TI > 0 */ tt->tt_power_mode = IWL_POWER_INDEX_5; if (!iwl_ht_enabled(priv)) /* disable HT */ rxon->flags &= ~(RXON_FLG_CHANNEL_MODE_MSK | RXON_FLG_CTRL_CHANNEL_LOC_HI_MSK | RXON_FLG_HT40_PROT_MSK | RXON_FLG_HT_PROT_MSK); else { /* check HT capability and set * according to the system HT capability * in case get disabled before */ iwl_set_rxon_ht(priv, &priv->current_ht_config); } } else { /* * restore system power setting -- it will be * recalculated automatically. */ /* check HT capability and set * according to the system HT capability * in case get disabled before */ iwl_set_rxon_ht(priv, &priv->current_ht_config); } mutex_lock(&priv->mutex); if (old_state == IWL_TI_CT_KILL) clear_bit(STATUS_CT_KILL, &priv->status); if (tt->state != IWL_TI_CT_KILL && iwl_power_update_mode(priv, true)) { /* TT state not updated * try again during next temperature read */ IWL_ERR(priv, "Cannot update power mode, " "TT state not updated\n"); if (old_state == IWL_TI_CT_KILL) set_bit(STATUS_CT_KILL, &priv->status); tt->state = old_state; } else { IWL_DEBUG_POWER(priv, "Thermal Throttling to new state: %u\n", tt->state); if (old_state != IWL_TI_CT_KILL && tt->state == IWL_TI_CT_KILL) { if (force) { IWL_DEBUG_POWER(priv, "Enter IWL_TI_CT_KILL\n"); set_bit(STATUS_CT_KILL, &priv->status); iwl_perform_ct_kill_task(priv, true); } else { iwl_prepare_ct_kill_task(priv); tt->state = old_state; } } else if (old_state == IWL_TI_CT_KILL && tt->state != IWL_TI_CT_KILL) { IWL_DEBUG_POWER(priv, "Exit IWL_TI_CT_KILL\n"); iwl_perform_ct_kill_task(priv, false); } } mutex_unlock(&priv->mutex); } } /* Card State Notification indicated reach critical temperature * if PSP not enable, no Thermal Throttling function will be performed * just set the GP1 bit to acknowledge the event * otherwise, go into IWL_TI_CT_KILL state * since Card State Notification will not provide any temperature reading * for Legacy mode * so just pass the CT_KILL temperature to iwl_legacy_tt_handler() * for advance mode * pass CT_KILL_THRESHOLD+1 to make sure move into IWL_TI_CT_KILL state */ static void iwl_bg_ct_enter(struct work_struct *work) { struct iwl_priv *priv = container_of(work, struct iwl_priv, ct_enter); struct iwl_tt_mgmt *tt = &priv->thermal_throttle; if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; if (!iwl_is_ready(priv)) return; if (tt->state != IWL_TI_CT_KILL) { IWL_ERR(priv, "Device reached critical temperature " "- ucode going to sleep!\n"); if (!priv->thermal_throttle.advanced_tt) iwl_legacy_tt_handler(priv, IWL_MINIMAL_POWER_THRESHOLD, true); else iwl_advance_tt_handler(priv, CT_KILL_THRESHOLD + 1, true); } } /* Card State Notification indicated out of critical temperature * since Card State Notification will not provide any temperature reading * so pass the IWL_REDUCED_PERFORMANCE_THRESHOLD_2 temperature * to iwl_legacy_tt_handler() to get out of IWL_CT_KILL state */ static void iwl_bg_ct_exit(struct work_struct *work) { struct iwl_priv *priv = container_of(work, struct iwl_priv, ct_exit); struct iwl_tt_mgmt *tt = &priv->thermal_throttle; if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; if (!iwl_is_ready(priv)) return; /* stop ct_kill_exit_tm timer */ del_timer_sync(&priv->thermal_throttle.ct_kill_exit_tm); if (tt->state == IWL_TI_CT_KILL) { IWL_ERR(priv, "Device temperature below critical" "- ucode awake!\n"); /* * exit from CT_KILL state * reset the current temperature reading */ priv->temperature = 0; if (!priv->thermal_throttle.advanced_tt) iwl_legacy_tt_handler(priv, IWL_REDUCED_PERFORMANCE_THRESHOLD_2, true); else iwl_advance_tt_handler(priv, CT_KILL_EXIT_THRESHOLD, true); } } void iwl_tt_enter_ct_kill(struct iwl_priv *priv) { if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; IWL_DEBUG_POWER(priv, "Queueing critical temperature enter.\n"); queue_work(priv->workqueue, &priv->ct_enter); } EXPORT_SYMBOL(iwl_tt_enter_ct_kill); void iwl_tt_exit_ct_kill(struct iwl_priv *priv) { if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; IWL_DEBUG_POWER(priv, "Queueing critical temperature exit.\n"); queue_work(priv->workqueue, &priv->ct_exit); } EXPORT_SYMBOL(iwl_tt_exit_ct_kill); static void iwl_bg_tt_work(struct work_struct *work) { struct iwl_priv *priv = container_of(work, struct iwl_priv, tt_work); s32 temp = priv->temperature; /* degrees CELSIUS except specified */ if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; if (priv->cfg->temperature_kelvin) temp = KELVIN_TO_CELSIUS(priv->temperature); if (!priv->thermal_throttle.advanced_tt) iwl_legacy_tt_handler(priv, temp, false); else iwl_advance_tt_handler(priv, temp, false); } void iwl_tt_handler(struct iwl_priv *priv) { if (test_bit(STATUS_EXIT_PENDING, &priv->status)) return; IWL_DEBUG_POWER(priv, "Queueing thermal throttling work.\n"); queue_work(priv->workqueue, &priv->tt_work); } EXPORT_SYMBOL(iwl_tt_handler); /* Thermal throttling initialization * For advance thermal throttling: * Initialize Thermal Index and temperature threshold table * Initialize thermal throttling restriction table */ void iwl_tt_initialize(struct iwl_priv *priv) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; int size = sizeof(struct iwl_tt_trans) * (IWL_TI_STATE_MAX - 1); struct iwl_tt_trans *transaction; IWL_DEBUG_POWER(priv, "Initialize Thermal Throttling\n"); memset(tt, 0, sizeof(struct iwl_tt_mgmt)); tt->state = IWL_TI_0; init_timer(&priv->thermal_throttle.ct_kill_exit_tm); priv->thermal_throttle.ct_kill_exit_tm.data = (unsigned long)priv; priv->thermal_throttle.ct_kill_exit_tm.function = iwl_tt_check_exit_ct_kill; init_timer(&priv->thermal_throttle.ct_kill_waiting_tm); priv->thermal_throttle.ct_kill_waiting_tm.data = (unsigned long)priv; priv->thermal_throttle.ct_kill_waiting_tm.function = iwl_tt_ready_for_ct_kill; /* setup deferred ct kill work */ INIT_WORK(&priv->tt_work, iwl_bg_tt_work); INIT_WORK(&priv->ct_enter, iwl_bg_ct_enter); INIT_WORK(&priv->ct_exit, iwl_bg_ct_exit); if (priv->cfg->adv_thermal_throttle) { IWL_DEBUG_POWER(priv, "Advanced Thermal Throttling\n"); tt->restriction = kzalloc(sizeof(struct iwl_tt_restriction) * IWL_TI_STATE_MAX, GFP_KERNEL); tt->transaction = kzalloc(sizeof(struct iwl_tt_trans) * IWL_TI_STATE_MAX * (IWL_TI_STATE_MAX - 1), GFP_KERNEL); if (!tt->restriction || !tt->transaction) { IWL_ERR(priv, "Fallback to Legacy Throttling\n"); priv->thermal_throttle.advanced_tt = false; kfree(tt->restriction); tt->restriction = NULL; kfree(tt->transaction); tt->transaction = NULL; } else { transaction = tt->transaction + (IWL_TI_0 * (IWL_TI_STATE_MAX - 1)); memcpy(transaction, &tt_range_0[0], size); transaction = tt->transaction + (IWL_TI_1 * (IWL_TI_STATE_MAX - 1)); memcpy(transaction, &tt_range_1[0], size); transaction = tt->transaction + (IWL_TI_2 * (IWL_TI_STATE_MAX - 1)); memcpy(transaction, &tt_range_2[0], size); transaction = tt->transaction + (IWL_TI_CT_KILL * (IWL_TI_STATE_MAX - 1)); memcpy(transaction, &tt_range_3[0], size); size = sizeof(struct iwl_tt_restriction) * IWL_TI_STATE_MAX; memcpy(tt->restriction, &restriction_range[0], size); priv->thermal_throttle.advanced_tt = true; } } else { IWL_DEBUG_POWER(priv, "Legacy Thermal Throttling\n"); priv->thermal_throttle.advanced_tt = false; } } EXPORT_SYMBOL(iwl_tt_initialize); /* cleanup thermal throttling management related memory and timer */ void iwl_tt_exit(struct iwl_priv *priv) { struct iwl_tt_mgmt *tt = &priv->thermal_throttle; /* stop ct_kill_exit_tm timer if activated */ del_timer_sync(&priv->thermal_throttle.ct_kill_exit_tm); /* stop ct_kill_waiting_tm timer if activated */ del_timer_sync(&priv->thermal_throttle.ct_kill_waiting_tm); cancel_work_sync(&priv->tt_work); cancel_work_sync(&priv->ct_enter); cancel_work_sync(&priv->ct_exit); if (priv->thermal_throttle.advanced_tt) { /* free advance thermal throttling memory */ kfree(tt->restriction); tt->restriction = NULL; kfree(tt->transaction); tt->transaction = NULL; } } EXPORT_SYMBOL(iwl_tt_exit); /* initialize to default */ void iwl_power_initialize(struct iwl_priv *priv) { u16 lctl = iwl_pcie_link_ctl(priv); priv->power_data.pci_pm = !(lctl & PCI_CFG_LINK_CTRL_VAL_L0S_EN); priv->power_data.debug_sleep_level_override = -1; memset(&priv->power_data.sleep_cmd, 0, sizeof(priv->power_data.sleep_cmd)); } EXPORT_SYMBOL(iwl_power_initialize);