Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Srinivas Kandagatla | 6245 | 89.53% | 2 | 25.00% |
Neil Armstrong | 311 | 4.46% | 1 | 12.50% |
Srinivasa Rao Mandadapu | 296 | 4.24% | 2 | 25.00% |
Johan Hovold | 103 | 1.48% | 1 | 12.50% |
Krzysztof Kozlowski | 18 | 0.26% | 1 | 12.50% |
Pierre-Louis Bossart | 2 | 0.03% | 1 | 12.50% |
Total | 6975 | 8 |
// SPDX-License-Identifier: GPL-2.0-only // Copyright (c) 2015-2021, The Linux Foundation. All rights reserved. #include <linux/module.h> #include <linux/init.h> #include <linux/slab.h> #include <linux/device.h> #include <linux/pm_runtime.h> #include <linux/printk.h> #include <linux/delay.h> #include <linux/kernel.h> #include <sound/soc.h> #include <sound/jack.h> #include "wcd-mbhc-v2.h" #define HS_DETECT_PLUG_TIME_MS (3 * 1000) #define MBHC_BUTTON_PRESS_THRESHOLD_MIN 250 #define GND_MIC_SWAP_THRESHOLD 4 #define GND_MIC_USBC_SWAP_THRESHOLD 2 #define WCD_FAKE_REMOVAL_MIN_PERIOD_MS 100 #define HPHL_CROSS_CONN_THRESHOLD 100 #define HS_VREF_MIN_VAL 1400 #define FAKE_REM_RETRY_ATTEMPTS 3 #define WCD_MBHC_ADC_HS_THRESHOLD_MV 1700 #define WCD_MBHC_ADC_HPH_THRESHOLD_MV 75 #define WCD_MBHC_ADC_MICBIAS_MV 1800 #define WCD_MBHC_FAKE_INS_RETRY 4 #define WCD_MBHC_JACK_MASK (SND_JACK_HEADSET | SND_JACK_LINEOUT | \ SND_JACK_MECHANICAL) #define WCD_MBHC_JACK_BUTTON_MASK (SND_JACK_BTN_0 | SND_JACK_BTN_1 | \ SND_JACK_BTN_2 | SND_JACK_BTN_3 | \ SND_JACK_BTN_4 | SND_JACK_BTN_5) enum wcd_mbhc_adc_mux_ctl { MUX_CTL_AUTO = 0, MUX_CTL_IN2P, MUX_CTL_IN3P, MUX_CTL_IN4P, MUX_CTL_HPH_L, MUX_CTL_HPH_R, MUX_CTL_NONE, }; struct wcd_mbhc { struct device *dev; struct snd_soc_component *component; struct snd_soc_jack *jack; struct wcd_mbhc_config *cfg; const struct wcd_mbhc_cb *mbhc_cb; const struct wcd_mbhc_intr *intr_ids; struct wcd_mbhc_field *fields; /* Delayed work to report long button press */ struct delayed_work mbhc_btn_dwork; /* Work to handle plug report */ struct work_struct mbhc_plug_detect_work; /* Work to correct accessory type */ struct work_struct correct_plug_swch; struct mutex lock; int buttons_pressed; u32 hph_status; /* track headhpone status */ u8 current_plug; unsigned int swap_thr; bool is_btn_press; bool in_swch_irq_handler; bool hs_detect_work_stop; bool is_hs_recording; bool extn_cable_hph_rem; bool force_linein; bool impedance_detect; unsigned long event_state; unsigned long jiffies_atreport; /* impedance of hphl and hphr */ uint32_t zl, zr; /* Holds type of Headset - Mono/Stereo */ enum wcd_mbhc_hph_type hph_type; /* Holds mbhc detection method - ADC/Legacy */ int mbhc_detection_logic; }; static inline int wcd_mbhc_write_field(const struct wcd_mbhc *mbhc, int field, int val) { if (!mbhc->fields[field].reg) return 0; return snd_soc_component_write_field(mbhc->component, mbhc->fields[field].reg, mbhc->fields[field].mask, val); } static inline int wcd_mbhc_read_field(const struct wcd_mbhc *mbhc, int field) { if (!mbhc->fields[field].reg) return 0; return snd_soc_component_read_field(mbhc->component, mbhc->fields[field].reg, mbhc->fields[field].mask); } static void wcd_program_hs_vref(struct wcd_mbhc *mbhc) { u32 reg_val = ((mbhc->cfg->v_hs_max - HS_VREF_MIN_VAL) / 100); wcd_mbhc_write_field(mbhc, WCD_MBHC_HS_VREF, reg_val); } static void wcd_program_btn_threshold(const struct wcd_mbhc *mbhc, bool micbias) { struct snd_soc_component *component = mbhc->component; mbhc->mbhc_cb->set_btn_thr(component, mbhc->cfg->btn_low, mbhc->cfg->btn_high, mbhc->cfg->num_btn, micbias); } static void wcd_mbhc_curr_micbias_control(const struct wcd_mbhc *mbhc, const enum wcd_mbhc_cs_mb_en_flag cs_mb_en) { /* * Some codecs handle micbias/pullup enablement in codec * drivers itself and micbias is not needed for regular * plug type detection. So if micbias_control callback function * is defined, just return. */ if (mbhc->mbhc_cb->mbhc_micbias_control) return; switch (cs_mb_en) { case WCD_MBHC_EN_CS: wcd_mbhc_write_field(mbhc, WCD_MBHC_MICB_CTRL, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 3); /* Program Button threshold registers as per CS */ wcd_program_btn_threshold(mbhc, false); break; case WCD_MBHC_EN_MB: wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); /* Disable PULL_UP_EN & enable MICBIAS */ wcd_mbhc_write_field(mbhc, WCD_MBHC_MICB_CTRL, 2); /* Program Button threshold registers as per MICBIAS */ wcd_program_btn_threshold(mbhc, true); break; case WCD_MBHC_EN_PULLUP: wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 3); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); wcd_mbhc_write_field(mbhc, WCD_MBHC_MICB_CTRL, 1); /* Program Button threshold registers as per MICBIAS */ wcd_program_btn_threshold(mbhc, true); break; case WCD_MBHC_EN_NONE: wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); wcd_mbhc_write_field(mbhc, WCD_MBHC_MICB_CTRL, 0); break; default: dev_err(mbhc->dev, "%s: Invalid parameter", __func__); break; } } int wcd_mbhc_event_notify(struct wcd_mbhc *mbhc, unsigned long event) { struct snd_soc_component *component; bool micbias2 = false; if (!mbhc) return 0; component = mbhc->component; if (mbhc->mbhc_cb->micbias_enable_status) micbias2 = mbhc->mbhc_cb->micbias_enable_status(component, MIC_BIAS_2); switch (event) { /* MICBIAS usage change */ case WCD_EVENT_POST_DAPM_MICBIAS_2_ON: mbhc->is_hs_recording = true; break; case WCD_EVENT_POST_MICBIAS_2_ON: /* Disable current source if micbias2 enabled */ if (mbhc->mbhc_cb->mbhc_micbias_control) { if (wcd_mbhc_read_field(mbhc, WCD_MBHC_FSM_EN)) wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); } else { mbhc->is_hs_recording = true; wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_MB); } break; case WCD_EVENT_PRE_MICBIAS_2_OFF: /* * Before MICBIAS_2 is turned off, if FSM is enabled, * make sure current source is enabled so as to detect * button press/release events */ if (mbhc->mbhc_cb->mbhc_micbias_control/* && !mbhc->micbias_enable*/) { if (wcd_mbhc_read_field(mbhc, WCD_MBHC_FSM_EN)) wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 3); } break; /* MICBIAS usage change */ case WCD_EVENT_POST_DAPM_MICBIAS_2_OFF: mbhc->is_hs_recording = false; break; case WCD_EVENT_POST_MICBIAS_2_OFF: if (!mbhc->mbhc_cb->mbhc_micbias_control) mbhc->is_hs_recording = false; /* Enable PULL UP if PA's are enabled */ if ((test_bit(WCD_MBHC_EVENT_PA_HPHL, &mbhc->event_state)) || (test_bit(WCD_MBHC_EVENT_PA_HPHR, &mbhc->event_state))) /* enable pullup and cs, disable mb */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_PULLUP); else /* enable current source and disable mb, pullup*/ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_CS); break; case WCD_EVENT_POST_HPHL_PA_OFF: clear_bit(WCD_MBHC_EVENT_PA_HPHL, &mbhc->event_state); /* check if micbias is enabled */ if (micbias2) /* Disable cs, pullup & enable micbias */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_MB); else /* Disable micbias, pullup & enable cs */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_CS); break; case WCD_EVENT_POST_HPHR_PA_OFF: clear_bit(WCD_MBHC_EVENT_PA_HPHR, &mbhc->event_state); /* check if micbias is enabled */ if (micbias2) /* Disable cs, pullup & enable micbias */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_MB); else /* Disable micbias, pullup & enable cs */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_CS); break; case WCD_EVENT_PRE_HPHL_PA_ON: set_bit(WCD_MBHC_EVENT_PA_HPHL, &mbhc->event_state); /* check if micbias is enabled */ if (micbias2) /* Disable cs, pullup & enable micbias */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_MB); else /* Disable micbias, enable pullup & cs */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_PULLUP); break; case WCD_EVENT_PRE_HPHR_PA_ON: set_bit(WCD_MBHC_EVENT_PA_HPHR, &mbhc->event_state); /* check if micbias is enabled */ if (micbias2) /* Disable cs, pullup & enable micbias */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_MB); else /* Disable micbias, enable pullup & cs */ wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_PULLUP); break; default: break; } return 0; } EXPORT_SYMBOL_GPL(wcd_mbhc_event_notify); static int wcd_cancel_btn_work(struct wcd_mbhc *mbhc) { return cancel_delayed_work_sync(&mbhc->mbhc_btn_dwork); } static void wcd_micbias_disable(struct wcd_mbhc *mbhc) { struct snd_soc_component *component = mbhc->component; if (mbhc->mbhc_cb->mbhc_micbias_control) mbhc->mbhc_cb->mbhc_micbias_control(component, MIC_BIAS_2, MICB_DISABLE); if (mbhc->mbhc_cb->mbhc_micb_ctrl_thr_mic) mbhc->mbhc_cb->mbhc_micb_ctrl_thr_mic(component, MIC_BIAS_2, false); if (mbhc->mbhc_cb->set_micbias_value) { mbhc->mbhc_cb->set_micbias_value(component); wcd_mbhc_write_field(mbhc, WCD_MBHC_MICB_CTRL, 0); } } static void wcd_mbhc_report_plug_removal(struct wcd_mbhc *mbhc, enum snd_jack_types jack_type) { mbhc->hph_status &= ~jack_type; /* * cancel possibly scheduled btn work and * report release if we reported button press */ if (!wcd_cancel_btn_work(mbhc) && mbhc->buttons_pressed) { snd_soc_jack_report(mbhc->jack, 0, mbhc->buttons_pressed); mbhc->buttons_pressed &= ~WCD_MBHC_JACK_BUTTON_MASK; } wcd_micbias_disable(mbhc); mbhc->hph_type = WCD_MBHC_HPH_NONE; mbhc->zl = mbhc->zr = 0; snd_soc_jack_report(mbhc->jack, mbhc->hph_status, WCD_MBHC_JACK_MASK); mbhc->current_plug = MBHC_PLUG_TYPE_NONE; mbhc->force_linein = false; } static void wcd_mbhc_compute_impedance(struct wcd_mbhc *mbhc) { if (!mbhc->impedance_detect) return; if (mbhc->cfg->linein_th != 0) { u8 fsm_en = wcd_mbhc_read_field(mbhc, WCD_MBHC_FSM_EN); /* Set MUX_CTL to AUTO for Z-det */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_MUX_CTL, MUX_CTL_AUTO); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); mbhc->mbhc_cb->compute_impedance(mbhc->component, &mbhc->zl, &mbhc->zr); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, fsm_en); } } static void wcd_mbhc_report_plug_insertion(struct wcd_mbhc *mbhc, enum snd_jack_types jack_type) { bool is_pa_on; /* * Report removal of current jack type. * Headphone to headset shouldn't report headphone * removal. */ if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADSET && jack_type == SND_JACK_HEADPHONE) mbhc->hph_status &= ~SND_JACK_HEADSET; /* Report insertion */ switch (jack_type) { case SND_JACK_HEADPHONE: mbhc->current_plug = MBHC_PLUG_TYPE_HEADPHONE; break; case SND_JACK_HEADSET: mbhc->current_plug = MBHC_PLUG_TYPE_HEADSET; mbhc->jiffies_atreport = jiffies; break; case SND_JACK_LINEOUT: mbhc->current_plug = MBHC_PLUG_TYPE_HIGH_HPH; break; default: break; } is_pa_on = wcd_mbhc_read_field(mbhc, WCD_MBHC_HPH_PA_EN); if (!is_pa_on) { wcd_mbhc_compute_impedance(mbhc); if ((mbhc->zl > mbhc->cfg->linein_th) && (mbhc->zr > mbhc->cfg->linein_th) && (jack_type == SND_JACK_HEADPHONE)) { jack_type = SND_JACK_LINEOUT; mbhc->force_linein = true; mbhc->current_plug = MBHC_PLUG_TYPE_HIGH_HPH; if (mbhc->hph_status) { mbhc->hph_status &= ~(SND_JACK_HEADSET | SND_JACK_LINEOUT); snd_soc_jack_report(mbhc->jack, mbhc->hph_status, WCD_MBHC_JACK_MASK); } } } /* Do not calculate impedance again for lineout * as during playback pa is on and impedance values * will not be correct resulting in lineout detected * as headphone. */ if (is_pa_on && mbhc->force_linein) { jack_type = SND_JACK_LINEOUT; mbhc->current_plug = MBHC_PLUG_TYPE_HIGH_HPH; if (mbhc->hph_status) { mbhc->hph_status &= ~(SND_JACK_HEADSET | SND_JACK_LINEOUT); snd_soc_jack_report(mbhc->jack, mbhc->hph_status, WCD_MBHC_JACK_MASK); } } mbhc->hph_status |= jack_type; if (jack_type == SND_JACK_HEADPHONE && mbhc->mbhc_cb->mbhc_micb_ramp_control) mbhc->mbhc_cb->mbhc_micb_ramp_control(mbhc->component, false); snd_soc_jack_report(mbhc->jack, (mbhc->hph_status | SND_JACK_MECHANICAL), WCD_MBHC_JACK_MASK); } static void wcd_mbhc_report_plug(struct wcd_mbhc *mbhc, int insertion, enum snd_jack_types jack_type) { WARN_ON(!mutex_is_locked(&mbhc->lock)); if (!insertion) /* Report removal */ wcd_mbhc_report_plug_removal(mbhc, jack_type); else wcd_mbhc_report_plug_insertion(mbhc, jack_type); } static void wcd_cancel_hs_detect_plug(struct wcd_mbhc *mbhc, struct work_struct *work) { mbhc->hs_detect_work_stop = true; mutex_unlock(&mbhc->lock); cancel_work_sync(work); mutex_lock(&mbhc->lock); } static void wcd_mbhc_cancel_pending_work(struct wcd_mbhc *mbhc) { /* cancel pending button press */ wcd_cancel_btn_work(mbhc); /* cancel correct work function */ wcd_cancel_hs_detect_plug(mbhc, &mbhc->correct_plug_swch); } static void wcd_mbhc_elec_hs_report_unplug(struct wcd_mbhc *mbhc) { wcd_mbhc_cancel_pending_work(mbhc); /* Report extension cable */ wcd_mbhc_report_plug(mbhc, 1, SND_JACK_LINEOUT); /* * Disable HPHL trigger and MIC Schmitt triggers. * Setup for insertion detection. */ disable_irq_nosync(mbhc->intr_ids->mbhc_hs_rem_intr); wcd_mbhc_curr_micbias_control(mbhc, WCD_MBHC_EN_NONE); /* Disable HW FSM */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC, 3); /* Set the detection type appropriately */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_DETECTION_TYPE, 1); enable_irq(mbhc->intr_ids->mbhc_hs_ins_intr); } static void wcd_mbhc_find_plug_and_report(struct wcd_mbhc *mbhc, enum wcd_mbhc_plug_type plug_type) { if (mbhc->current_plug == plug_type) return; mutex_lock(&mbhc->lock); switch (plug_type) { case MBHC_PLUG_TYPE_HEADPHONE: wcd_mbhc_report_plug(mbhc, 1, SND_JACK_HEADPHONE); break; case MBHC_PLUG_TYPE_HEADSET: wcd_mbhc_report_plug(mbhc, 1, SND_JACK_HEADSET); break; case MBHC_PLUG_TYPE_HIGH_HPH: wcd_mbhc_report_plug(mbhc, 1, SND_JACK_LINEOUT); break; case MBHC_PLUG_TYPE_GND_MIC_SWAP: if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADPHONE) wcd_mbhc_report_plug(mbhc, 0, SND_JACK_HEADPHONE); if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADSET) wcd_mbhc_report_plug(mbhc, 0, SND_JACK_HEADSET); break; default: WARN(1, "Unexpected current plug_type %d, plug_type %d\n", mbhc->current_plug, plug_type); break; } mutex_unlock(&mbhc->lock); } static void wcd_schedule_hs_detect_plug(struct wcd_mbhc *mbhc, struct work_struct *work) { WARN_ON(!mutex_is_locked(&mbhc->lock)); mbhc->hs_detect_work_stop = false; schedule_work(work); } static void wcd_mbhc_adc_detect_plug_type(struct wcd_mbhc *mbhc) { struct snd_soc_component *component = mbhc->component; WARN_ON(!mutex_is_locked(&mbhc->lock)); if (mbhc->mbhc_cb->hph_pull_down_ctrl) mbhc->mbhc_cb->hph_pull_down_ctrl(component, false); wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 0); if (mbhc->mbhc_cb->mbhc_micbias_control) { mbhc->mbhc_cb->mbhc_micbias_control(component, MIC_BIAS_2, MICB_ENABLE); wcd_schedule_hs_detect_plug(mbhc, &mbhc->correct_plug_swch); } } static void mbhc_plug_detect_fn(struct work_struct *work) { struct wcd_mbhc *mbhc = container_of(work, struct wcd_mbhc, mbhc_plug_detect_work); struct snd_soc_component *component = mbhc->component; enum snd_jack_types jack_type; bool detection_type; mutex_lock(&mbhc->lock); mbhc->in_swch_irq_handler = true; wcd_mbhc_cancel_pending_work(mbhc); detection_type = wcd_mbhc_read_field(mbhc, WCD_MBHC_MECH_DETECTION_TYPE); /* Set the detection type appropriately */ wcd_mbhc_write_field(mbhc, WCD_MBHC_MECH_DETECTION_TYPE, !detection_type); /* Enable micbias ramp */ if (mbhc->mbhc_cb->mbhc_micb_ramp_control) mbhc->mbhc_cb->mbhc_micb_ramp_control(component, true); if (detection_type) { if (mbhc->current_plug != MBHC_PLUG_TYPE_NONE) goto exit; /* Make sure MASTER_BIAS_CTL is enabled */ mbhc->mbhc_cb->mbhc_bias(component, true); mbhc->is_btn_press = false; wcd_mbhc_adc_detect_plug_type(mbhc); } else { /* Disable HW FSM */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); mbhc->extn_cable_hph_rem = false; if (mbhc->current_plug == MBHC_PLUG_TYPE_NONE) goto exit; mbhc->is_btn_press = false; switch (mbhc->current_plug) { case MBHC_PLUG_TYPE_HEADPHONE: jack_type = SND_JACK_HEADPHONE; break; case MBHC_PLUG_TYPE_HEADSET: jack_type = SND_JACK_HEADSET; break; case MBHC_PLUG_TYPE_HIGH_HPH: if (mbhc->mbhc_detection_logic == WCD_DETECTION_ADC) wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_ISRC_EN, 0); jack_type = SND_JACK_LINEOUT; break; case MBHC_PLUG_TYPE_GND_MIC_SWAP: dev_err(mbhc->dev, "Ground and Mic Swapped on plug\n"); goto exit; default: dev_err(mbhc->dev, "Invalid current plug: %d\n", mbhc->current_plug); goto exit; } disable_irq_nosync(mbhc->intr_ids->mbhc_hs_rem_intr); disable_irq_nosync(mbhc->intr_ids->mbhc_hs_ins_intr); wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_DETECTION_TYPE, 1); wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC, 0); wcd_mbhc_report_plug(mbhc, 0, jack_type); } exit: mbhc->in_swch_irq_handler = false; mutex_unlock(&mbhc->lock); } static irqreturn_t wcd_mbhc_mech_plug_detect_irq(int irq, void *data) { struct wcd_mbhc *mbhc = data; if (!mbhc->cfg->typec_analog_mux) schedule_work(&mbhc->mbhc_plug_detect_work); return IRQ_HANDLED; } int wcd_mbhc_typec_report_unplug(struct wcd_mbhc *mbhc) { if (!mbhc || !mbhc->cfg->typec_analog_mux) return -EINVAL; if (mbhc->mbhc_cb->clk_setup) mbhc->mbhc_cb->clk_setup(mbhc->component, false); wcd_mbhc_write_field(mbhc, WCD_MBHC_L_DET_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_MECH_DETECTION_TYPE, 0); schedule_work(&mbhc->mbhc_plug_detect_work); return 0; } EXPORT_SYMBOL_GPL(wcd_mbhc_typec_report_unplug); int wcd_mbhc_typec_report_plug(struct wcd_mbhc *mbhc) { if (!mbhc || !mbhc->cfg->typec_analog_mux) return -EINVAL; if (mbhc->mbhc_cb->clk_setup) mbhc->mbhc_cb->clk_setup(mbhc->component, true); wcd_mbhc_write_field(mbhc, WCD_MBHC_L_DET_EN, 1); schedule_work(&mbhc->mbhc_plug_detect_work); return 0; } EXPORT_SYMBOL_GPL(wcd_mbhc_typec_report_plug); static int wcd_mbhc_get_button_mask(struct wcd_mbhc *mbhc) { int mask = 0; int btn; btn = wcd_mbhc_read_field(mbhc, WCD_MBHC_BTN_RESULT); switch (btn) { case 0: mask = SND_JACK_BTN_0; break; case 1: mask = SND_JACK_BTN_1; break; case 2: mask = SND_JACK_BTN_2; break; case 3: mask = SND_JACK_BTN_3; break; case 4: mask = SND_JACK_BTN_4; break; case 5: mask = SND_JACK_BTN_5; break; default: break; } return mask; } static void wcd_btn_long_press_fn(struct work_struct *work) { struct delayed_work *dwork = to_delayed_work(work); struct wcd_mbhc *mbhc = container_of(dwork, struct wcd_mbhc, mbhc_btn_dwork); if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADSET) snd_soc_jack_report(mbhc->jack, mbhc->buttons_pressed, mbhc->buttons_pressed); } static irqreturn_t wcd_mbhc_btn_press_handler(int irq, void *data) { struct wcd_mbhc *mbhc = data; int mask; unsigned long msec_val; mutex_lock(&mbhc->lock); wcd_cancel_btn_work(mbhc); mbhc->is_btn_press = true; msec_val = jiffies_to_msecs(jiffies - mbhc->jiffies_atreport); /* Too short, ignore button press */ if (msec_val < MBHC_BUTTON_PRESS_THRESHOLD_MIN) goto done; /* If switch interrupt already kicked in, ignore button press */ if (mbhc->in_swch_irq_handler) goto done; /* Plug isn't headset, ignore button press */ if (mbhc->current_plug != MBHC_PLUG_TYPE_HEADSET) goto done; mask = wcd_mbhc_get_button_mask(mbhc); mbhc->buttons_pressed |= mask; if (schedule_delayed_work(&mbhc->mbhc_btn_dwork, msecs_to_jiffies(400)) == 0) WARN(1, "Button pressed twice without release event\n"); done: mutex_unlock(&mbhc->lock); return IRQ_HANDLED; } static irqreturn_t wcd_mbhc_btn_release_handler(int irq, void *data) { struct wcd_mbhc *mbhc = data; int ret; mutex_lock(&mbhc->lock); if (mbhc->is_btn_press) mbhc->is_btn_press = false; else /* fake btn press */ goto exit; if (!(mbhc->buttons_pressed & WCD_MBHC_JACK_BUTTON_MASK)) goto exit; ret = wcd_cancel_btn_work(mbhc); if (ret == 0) { /* Reporting long button release event */ snd_soc_jack_report(mbhc->jack, 0, mbhc->buttons_pressed); } else { if (!mbhc->in_swch_irq_handler) { /* Reporting btn press n Release */ snd_soc_jack_report(mbhc->jack, mbhc->buttons_pressed, mbhc->buttons_pressed); snd_soc_jack_report(mbhc->jack, 0, mbhc->buttons_pressed); } } mbhc->buttons_pressed &= ~WCD_MBHC_JACK_BUTTON_MASK; exit: mutex_unlock(&mbhc->lock); return IRQ_HANDLED; } static irqreturn_t wcd_mbhc_hph_ocp_irq(struct wcd_mbhc *mbhc, bool hphr) { /* TODO Find a better way to report this to Userspace */ dev_err(mbhc->dev, "MBHC Over Current on %s detected\n", hphr ? "HPHR" : "HPHL"); wcd_mbhc_write_field(mbhc, WCD_MBHC_OCP_FSM_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_OCP_FSM_EN, 1); return IRQ_HANDLED; } static irqreturn_t wcd_mbhc_hphl_ocp_irq(int irq, void *data) { return wcd_mbhc_hph_ocp_irq(data, false); } static irqreturn_t wcd_mbhc_hphr_ocp_irq(int irq, void *data) { return wcd_mbhc_hph_ocp_irq(data, true); } static int wcd_mbhc_initialise(struct wcd_mbhc *mbhc) { struct snd_soc_component *component = mbhc->component; int ret; ret = pm_runtime_get_sync(component->dev); if (ret < 0 && ret != -EACCES) { dev_err_ratelimited(component->dev, "pm_runtime_get_sync failed in %s, ret %d\n", __func__, ret); pm_runtime_put_noidle(component->dev); return ret; } mutex_lock(&mbhc->lock); if (mbhc->cfg->typec_analog_mux) mbhc->swap_thr = GND_MIC_USBC_SWAP_THRESHOLD; else mbhc->swap_thr = GND_MIC_SWAP_THRESHOLD; /* setup HS detection */ if (mbhc->mbhc_cb->hph_pull_up_control_v2) mbhc->mbhc_cb->hph_pull_up_control_v2(component, mbhc->cfg->typec_analog_mux ? HS_PULLUP_I_OFF : HS_PULLUP_I_DEFAULT); else if (mbhc->mbhc_cb->hph_pull_up_control) mbhc->mbhc_cb->hph_pull_up_control(component, mbhc->cfg->typec_analog_mux ? I_OFF : I_DEFAULT); else wcd_mbhc_write_field(mbhc, WCD_MBHC_HS_L_DET_PULL_UP_CTRL, mbhc->cfg->typec_analog_mux ? 0 : 3); wcd_mbhc_write_field(mbhc, WCD_MBHC_HPHL_PLUG_TYPE, mbhc->cfg->hphl_swh); wcd_mbhc_write_field(mbhc, WCD_MBHC_GND_PLUG_TYPE, mbhc->cfg->gnd_swh); wcd_mbhc_write_field(mbhc, WCD_MBHC_SW_HPH_LP_100K_TO_GND, 1); if (mbhc->cfg->gnd_det_en && mbhc->mbhc_cb->mbhc_gnd_det_ctrl) mbhc->mbhc_cb->mbhc_gnd_det_ctrl(component, true); wcd_mbhc_write_field(mbhc, WCD_MBHC_HS_L_DET_PULL_UP_COMP_CTRL, 1); /* Plug detect is triggered manually if analog goes through USBCC */ if (mbhc->cfg->typec_analog_mux) wcd_mbhc_write_field(mbhc, WCD_MBHC_L_DET_EN, 0); else wcd_mbhc_write_field(mbhc, WCD_MBHC_L_DET_EN, 1); if (mbhc->cfg->typec_analog_mux) /* Insertion debounce set to 48ms */ wcd_mbhc_write_field(mbhc, WCD_MBHC_INSREM_DBNC, 4); else /* Insertion debounce set to 96ms */ wcd_mbhc_write_field(mbhc, WCD_MBHC_INSREM_DBNC, 6); /* Button Debounce set to 16ms */ wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_DBNC, 2); /* enable bias */ mbhc->mbhc_cb->mbhc_bias(component, true); /* enable MBHC clock */ if (mbhc->mbhc_cb->clk_setup) mbhc->mbhc_cb->clk_setup(component, mbhc->cfg->typec_analog_mux ? false : true); /* program HS_VREF value */ wcd_program_hs_vref(mbhc); wcd_program_btn_threshold(mbhc, false); mutex_unlock(&mbhc->lock); pm_runtime_mark_last_busy(component->dev); pm_runtime_put_autosuspend(component->dev); return 0; } static int wcd_mbhc_get_micbias(struct wcd_mbhc *mbhc) { int micbias = 0; if (mbhc->mbhc_cb->get_micbias_val) { mbhc->mbhc_cb->get_micbias_val(mbhc->component, &micbias); } else { u8 vout_ctl = 0; /* Read MBHC Micbias (Mic Bias2) voltage */ vout_ctl = wcd_mbhc_read_field(mbhc, WCD_MBHC_MICB2_VOUT); /* Formula for getting micbias from vout * micbias = 1.0V + VOUT_CTL * 50mV */ micbias = 1000 + (vout_ctl * 50); } return micbias; } static int wcd_get_voltage_from_adc(u8 val, int micbias) { /* Formula for calculating voltage from ADC * Voltage = ADC_RESULT*12.5mV*V_MICBIAS/1.8 */ return ((val * 125 * micbias)/(WCD_MBHC_ADC_MICBIAS_MV * 10)); } static int wcd_measure_adc_continuous(struct wcd_mbhc *mbhc) { u8 adc_result; int output_mv; int retry = 3; u8 adc_en; /* Pre-requisites for ADC continuous measurement */ /* Read legacy electircal detection and disable */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC, 0x00); /* Set ADC to continuous measurement */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, 1); /* Read ADC Enable bit to restore after adc measurement */ adc_en = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_EN); /* Disable ADC_ENABLE bit */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 0); /* Disable MBHC FSM */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); /* Set the MUX selection to IN2P */ wcd_mbhc_write_field(mbhc, WCD_MBHC_MUX_CTL, MUX_CTL_IN2P); /* Enable MBHC FSM */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); /* Enable ADC_ENABLE bit */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 1); while (retry--) { /* wait for 3 msec before reading ADC result */ usleep_range(3000, 3100); adc_result = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_RESULT); } /* Restore ADC Enable */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, adc_en); /* Get voltage from ADC result */ output_mv = wcd_get_voltage_from_adc(adc_result, wcd_mbhc_get_micbias(mbhc)); return output_mv; } static int wcd_measure_adc_once(struct wcd_mbhc *mbhc, int mux_ctl) { struct device *dev = mbhc->dev; u8 adc_timeout = 0; u8 adc_complete = 0; u8 adc_result; int retry = 6; int ret; int output_mv = 0; u8 adc_en; wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, 0); /* Read ADC Enable bit to restore after adc measurement */ adc_en = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_EN); /* Trigger ADC one time measurement */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); /* Set the appropriate MUX selection */ wcd_mbhc_write_field(mbhc, WCD_MBHC_MUX_CTL, mux_ctl); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 1); while (retry--) { /* wait for 600usec to get adc results */ usleep_range(600, 610); /* check for ADC Timeout */ adc_timeout = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_TIMEOUT); if (adc_timeout) continue; /* Read ADC complete bit */ adc_complete = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_COMPLETE); if (!adc_complete) continue; /* Read ADC result */ adc_result = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_RESULT); /* Get voltage from ADC result */ output_mv = wcd_get_voltage_from_adc(adc_result, wcd_mbhc_get_micbias(mbhc)); break; } /* Restore ADC Enable */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, adc_en); if (retry <= 0) { dev_err(dev, "%s: adc complete: %d, adc timeout: %d\n", __func__, adc_complete, adc_timeout); ret = -EINVAL; } else { ret = output_mv; } return ret; } /* To determine if cross connection occurred */ static int wcd_check_cross_conn(struct wcd_mbhc *mbhc) { u8 adc_mode, elect_ctl, adc_en, fsm_en; int hphl_adc_res, hphr_adc_res; bool is_cross_conn = false; /* If PA is enabled, dont check for cross-connection */ if (wcd_mbhc_read_field(mbhc, WCD_MBHC_HPH_PA_EN)) return -EINVAL; /* Read legacy electircal detection and disable */ elect_ctl = wcd_mbhc_read_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC); wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC, 0); /* Read and set ADC to single measurement */ adc_mode = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_MODE); /* Read ADC Enable bit to restore after adc measurement */ adc_en = wcd_mbhc_read_field(mbhc, WCD_MBHC_ADC_EN); /* Read FSM status */ fsm_en = wcd_mbhc_read_field(mbhc, WCD_MBHC_FSM_EN); /* Get adc result for HPH L */ hphl_adc_res = wcd_measure_adc_once(mbhc, MUX_CTL_HPH_L); if (hphl_adc_res < 0) return hphl_adc_res; /* Get adc result for HPH R in mV */ hphr_adc_res = wcd_measure_adc_once(mbhc, MUX_CTL_HPH_R); if (hphr_adc_res < 0) return hphr_adc_res; if (hphl_adc_res > HPHL_CROSS_CONN_THRESHOLD || hphr_adc_res > HPHL_CROSS_CONN_THRESHOLD) is_cross_conn = true; wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 0); /* Set the MUX selection to Auto */ wcd_mbhc_write_field(mbhc, WCD_MBHC_MUX_CTL, MUX_CTL_AUTO); wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, 1); /* Restore ADC Enable */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, adc_en); /* Restore ADC mode */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, adc_mode); /* Restore FSM state */ wcd_mbhc_write_field(mbhc, WCD_MBHC_FSM_EN, fsm_en); /* Restore electrical detection */ wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_SCHMT_ISRC, elect_ctl); return is_cross_conn; } static int wcd_mbhc_adc_get_hs_thres(struct wcd_mbhc *mbhc) { int hs_threshold, micbias_mv; micbias_mv = wcd_mbhc_get_micbias(mbhc); if (mbhc->cfg->hs_thr) { if (mbhc->cfg->micb_mv == micbias_mv) hs_threshold = mbhc->cfg->hs_thr; else hs_threshold = (mbhc->cfg->hs_thr * micbias_mv) / mbhc->cfg->micb_mv; } else { hs_threshold = ((WCD_MBHC_ADC_HS_THRESHOLD_MV * micbias_mv) / WCD_MBHC_ADC_MICBIAS_MV); } return hs_threshold; } static int wcd_mbhc_adc_get_hph_thres(struct wcd_mbhc *mbhc) { int hph_threshold, micbias_mv; micbias_mv = wcd_mbhc_get_micbias(mbhc); if (mbhc->cfg->hph_thr) { if (mbhc->cfg->micb_mv == micbias_mv) hph_threshold = mbhc->cfg->hph_thr; else hph_threshold = (mbhc->cfg->hph_thr * micbias_mv) / mbhc->cfg->micb_mv; } else { hph_threshold = ((WCD_MBHC_ADC_HPH_THRESHOLD_MV * micbias_mv) / WCD_MBHC_ADC_MICBIAS_MV); } return hph_threshold; } static void wcd_mbhc_adc_update_fsm_source(struct wcd_mbhc *mbhc, enum wcd_mbhc_plug_type plug_type) { bool micbias2 = false; switch (plug_type) { case MBHC_PLUG_TYPE_HEADPHONE: wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 3); break; case MBHC_PLUG_TYPE_HEADSET: if (mbhc->mbhc_cb->micbias_enable_status) micbias2 = mbhc->mbhc_cb->micbias_enable_status(mbhc->component, MIC_BIAS_2); if (!mbhc->is_hs_recording && !micbias2) wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 3); break; default: wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); break; } } static void wcd_mbhc_bcs_enable(struct wcd_mbhc *mbhc, int plug_type, bool enable) { switch (plug_type) { case MBHC_PLUG_TYPE_HEADSET: case MBHC_PLUG_TYPE_HEADPHONE: if (mbhc->mbhc_cb->bcs_enable) mbhc->mbhc_cb->bcs_enable(mbhc->component, enable); break; default: break; } } static int wcd_mbhc_get_plug_from_adc(struct wcd_mbhc *mbhc, int adc_result) { enum wcd_mbhc_plug_type plug_type; u32 hph_thr, hs_thr; hs_thr = wcd_mbhc_adc_get_hs_thres(mbhc); hph_thr = wcd_mbhc_adc_get_hph_thres(mbhc); if (adc_result < hph_thr) plug_type = MBHC_PLUG_TYPE_HEADPHONE; else if (adc_result > hs_thr) plug_type = MBHC_PLUG_TYPE_HIGH_HPH; else plug_type = MBHC_PLUG_TYPE_HEADSET; return plug_type; } static int wcd_mbhc_get_spl_hs_thres(struct wcd_mbhc *mbhc) { int hs_threshold, micbias_mv; micbias_mv = wcd_mbhc_get_micbias(mbhc); if (mbhc->cfg->hs_thr && mbhc->cfg->micb_mv != WCD_MBHC_ADC_MICBIAS_MV) { if (mbhc->cfg->micb_mv == micbias_mv) hs_threshold = mbhc->cfg->hs_thr; else hs_threshold = (mbhc->cfg->hs_thr * micbias_mv) / mbhc->cfg->micb_mv; } else { hs_threshold = ((WCD_MBHC_ADC_HS_THRESHOLD_MV * micbias_mv) / WCD_MBHC_ADC_MICBIAS_MV); } return hs_threshold; } static bool wcd_mbhc_check_for_spl_headset(struct wcd_mbhc *mbhc) { bool is_spl_hs = false; int output_mv, hs_threshold, hph_threshold; if (!mbhc->mbhc_cb->mbhc_micb_ctrl_thr_mic) return false; /* Bump up MIC_BIAS2 to 2.7V */ mbhc->mbhc_cb->mbhc_micb_ctrl_thr_mic(mbhc->component, MIC_BIAS_2, true); usleep_range(10000, 10100); output_mv = wcd_measure_adc_once(mbhc, MUX_CTL_IN2P); hs_threshold = wcd_mbhc_get_spl_hs_thres(mbhc); hph_threshold = wcd_mbhc_adc_get_hph_thres(mbhc); if (!(output_mv > hs_threshold || output_mv < hph_threshold)) is_spl_hs = true; /* Back MIC_BIAS2 to 1.8v if the type is not special headset */ if (!is_spl_hs) { mbhc->mbhc_cb->mbhc_micb_ctrl_thr_mic(mbhc->component, MIC_BIAS_2, false); /* Add 10ms delay for micbias to settle */ usleep_range(10000, 10100); } return is_spl_hs; } static void wcd_correct_swch_plug(struct work_struct *work) { struct wcd_mbhc *mbhc; struct snd_soc_component *component; enum wcd_mbhc_plug_type plug_type = MBHC_PLUG_TYPE_INVALID; unsigned long timeout; int pt_gnd_mic_swap_cnt = 0; int output_mv, cross_conn, hs_threshold, try = 0, micbias_mv; bool is_spl_hs = false; bool is_pa_on; int ret; mbhc = container_of(work, struct wcd_mbhc, correct_plug_swch); component = mbhc->component; ret = pm_runtime_get_sync(component->dev); if (ret < 0 && ret != -EACCES) { dev_err_ratelimited(component->dev, "pm_runtime_get_sync failed in %s, ret %d\n", __func__, ret); pm_runtime_put_noidle(component->dev); return; } micbias_mv = wcd_mbhc_get_micbias(mbhc); hs_threshold = wcd_mbhc_adc_get_hs_thres(mbhc); /* Mask ADC COMPLETE interrupt */ disable_irq_nosync(mbhc->intr_ids->mbhc_hs_ins_intr); /* Check for cross connection */ do { cross_conn = wcd_check_cross_conn(mbhc); try++; } while (try < mbhc->swap_thr); if (cross_conn > 0) { plug_type = MBHC_PLUG_TYPE_GND_MIC_SWAP; dev_err(mbhc->dev, "cross connection found, Plug type %d\n", plug_type); goto correct_plug_type; } /* Find plug type */ output_mv = wcd_measure_adc_continuous(mbhc); plug_type = wcd_mbhc_get_plug_from_adc(mbhc, output_mv); /* * Report plug type if it is either headset or headphone * else start the 3 sec loop */ switch (plug_type) { case MBHC_PLUG_TYPE_HEADPHONE: wcd_mbhc_find_plug_and_report(mbhc, plug_type); break; case MBHC_PLUG_TYPE_HEADSET: wcd_mbhc_find_plug_and_report(mbhc, plug_type); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 1); break; default: break; } correct_plug_type: /* Disable BCS slow insertion detection */ wcd_mbhc_bcs_enable(mbhc, plug_type, false); timeout = jiffies + msecs_to_jiffies(HS_DETECT_PLUG_TIME_MS); while (!time_after(jiffies, timeout)) { if (mbhc->hs_detect_work_stop) { wcd_micbias_disable(mbhc); goto exit; } msleep(180); /* * Use ADC single mode to minimize the chance of missing out * btn press/release for HEADSET type during correct work. */ output_mv = wcd_measure_adc_once(mbhc, MUX_CTL_IN2P); plug_type = wcd_mbhc_get_plug_from_adc(mbhc, output_mv); is_pa_on = wcd_mbhc_read_field(mbhc, WCD_MBHC_HPH_PA_EN); if (output_mv > hs_threshold && !is_spl_hs) { is_spl_hs = wcd_mbhc_check_for_spl_headset(mbhc); output_mv = wcd_measure_adc_once(mbhc, MUX_CTL_IN2P); if (is_spl_hs) { hs_threshold *= wcd_mbhc_get_micbias(mbhc); hs_threshold /= micbias_mv; } } if ((output_mv <= hs_threshold) && !is_pa_on) { /* Check for cross connection*/ cross_conn = wcd_check_cross_conn(mbhc); if (cross_conn > 0) { /* cross-connection */ pt_gnd_mic_swap_cnt++; if (pt_gnd_mic_swap_cnt < mbhc->swap_thr) continue; else plug_type = MBHC_PLUG_TYPE_GND_MIC_SWAP; } else if (!cross_conn) { /* no cross connection */ pt_gnd_mic_swap_cnt = 0; plug_type = wcd_mbhc_get_plug_from_adc(mbhc, output_mv); continue; } else /* Error if (cross_conn < 0) */ continue; if (pt_gnd_mic_swap_cnt == mbhc->swap_thr) { /* US_EU gpio present, flip switch */ if (mbhc->cfg->swap_gnd_mic) { if (mbhc->cfg->swap_gnd_mic(component, true)) continue; } } } /* cable is extension cable */ if (output_mv > hs_threshold || mbhc->force_linein) plug_type = MBHC_PLUG_TYPE_HIGH_HPH; } wcd_mbhc_bcs_enable(mbhc, plug_type, true); if (plug_type == MBHC_PLUG_TYPE_HIGH_HPH) { if (is_spl_hs) plug_type = MBHC_PLUG_TYPE_HEADSET; else wcd_mbhc_write_field(mbhc, WCD_MBHC_ELECT_ISRC_EN, 1); } wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 0); wcd_mbhc_find_plug_and_report(mbhc, plug_type); /* * Set DETECTION_DONE bit for HEADSET * so that btn press/release interrupt can be generated. * For other plug type, clear the bit. */ if (plug_type == MBHC_PLUG_TYPE_HEADSET) wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 1); else wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 0); if (mbhc->mbhc_cb->mbhc_micbias_control) wcd_mbhc_adc_update_fsm_source(mbhc, plug_type); exit: if (mbhc->mbhc_cb->mbhc_micbias_control/* && !mbhc->micbias_enable*/) mbhc->mbhc_cb->mbhc_micbias_control(component, MIC_BIAS_2, MICB_DISABLE); /* * If plug type is corrected from special headset to headphone, * clear the micbias enable flag, set micbias back to 1.8V and * disable micbias. */ if (plug_type == MBHC_PLUG_TYPE_HEADPHONE) { wcd_micbias_disable(mbhc); /* * Enable ADC COMPLETE interrupt for HEADPHONE. * Btn release may happen after the correct work, ADC COMPLETE * interrupt needs to be captured to correct plug type. */ enable_irq(mbhc->intr_ids->mbhc_hs_ins_intr); } if (mbhc->mbhc_cb->hph_pull_down_ctrl) mbhc->mbhc_cb->hph_pull_down_ctrl(component, true); pm_runtime_mark_last_busy(component->dev); pm_runtime_put_autosuspend(component->dev); } static irqreturn_t wcd_mbhc_adc_hs_rem_irq(int irq, void *data) { struct wcd_mbhc *mbhc = data; unsigned long timeout; int adc_threshold, output_mv, retry = 0; mutex_lock(&mbhc->lock); timeout = jiffies + msecs_to_jiffies(WCD_FAKE_REMOVAL_MIN_PERIOD_MS); adc_threshold = wcd_mbhc_adc_get_hs_thres(mbhc); do { retry++; /* * read output_mv every 10ms to look for * any change in IN2_P */ usleep_range(10000, 10100); output_mv = wcd_measure_adc_once(mbhc, MUX_CTL_IN2P); /* Check for fake removal */ if ((output_mv <= adc_threshold) && retry > FAKE_REM_RETRY_ATTEMPTS) goto exit; } while (!time_after(jiffies, timeout)); /* * ADC COMPLETE and ELEC_REM interrupts are both enabled for * HEADPHONE, need to reject the ADC COMPLETE interrupt which * follows ELEC_REM one when HEADPHONE is removed. */ if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADPHONE) mbhc->extn_cable_hph_rem = true; wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_MODE, 0); wcd_mbhc_write_field(mbhc, WCD_MBHC_ADC_EN, 0); wcd_mbhc_elec_hs_report_unplug(mbhc); wcd_mbhc_write_field(mbhc, WCD_MBHC_BTN_ISRC_CTL, 0); exit: mutex_unlock(&mbhc->lock); return IRQ_HANDLED; } static irqreturn_t wcd_mbhc_adc_hs_ins_irq(int irq, void *data) { struct wcd_mbhc *mbhc = data; u8 clamp_state; u8 clamp_retry = WCD_MBHC_FAKE_INS_RETRY; /* * ADC COMPLETE and ELEC_REM interrupts are both enabled for HEADPHONE, * need to reject the ADC COMPLETE interrupt which follows ELEC_REM one * when HEADPHONE is removed. */ if (mbhc->extn_cable_hph_rem == true) { mbhc->extn_cable_hph_rem = false; return IRQ_HANDLED; } do { clamp_state = wcd_mbhc_read_field(mbhc, WCD_MBHC_IN2P_CLAMP_STATE); if (clamp_state) return IRQ_HANDLED; /* * check clamp for 120ms but at 30ms chunks to leave * room for other interrupts to be processed */ usleep_range(30000, 30100); } while (--clamp_retry); /* * If current plug is headphone then there is no chance to * get ADC complete interrupt, so connected cable should be * headset not headphone. */ if (mbhc->current_plug == MBHC_PLUG_TYPE_HEADPHONE) { disable_irq_nosync(mbhc->intr_ids->mbhc_hs_ins_intr); wcd_mbhc_write_field(mbhc, WCD_MBHC_DETECTION_DONE, 1); wcd_mbhc_find_plug_and_report(mbhc, MBHC_PLUG_TYPE_HEADSET); return IRQ_HANDLED; } return IRQ_HANDLED; } int wcd_mbhc_get_impedance(struct wcd_mbhc *mbhc, uint32_t *zl, uint32_t *zr) { *zl = mbhc->zl; *zr = mbhc->zr; if (*zl && *zr) return 0; else return -EINVAL; } EXPORT_SYMBOL(wcd_mbhc_get_impedance); void wcd_mbhc_set_hph_type(struct wcd_mbhc *mbhc, int hph_type) { mbhc->hph_type = hph_type; } EXPORT_SYMBOL(wcd_mbhc_set_hph_type); int wcd_mbhc_get_hph_type(struct wcd_mbhc *mbhc) { return mbhc->hph_type; } EXPORT_SYMBOL(wcd_mbhc_get_hph_type); int wcd_mbhc_start(struct wcd_mbhc *mbhc, struct wcd_mbhc_config *cfg, struct snd_soc_jack *jack) { if (!mbhc || !cfg || !jack) return -EINVAL; mbhc->cfg = cfg; mbhc->jack = jack; return wcd_mbhc_initialise(mbhc); } EXPORT_SYMBOL(wcd_mbhc_start); void wcd_mbhc_stop(struct wcd_mbhc *mbhc) { mbhc->current_plug = MBHC_PLUG_TYPE_NONE; mbhc->hph_status = 0; disable_irq_nosync(mbhc->intr_ids->hph_left_ocp); disable_irq_nosync(mbhc->intr_ids->hph_right_ocp); } EXPORT_SYMBOL(wcd_mbhc_stop); int wcd_dt_parse_mbhc_data(struct device *dev, struct wcd_mbhc_config *cfg) { struct device_node *np = dev->of_node; int ret, i, microvolt; if (of_property_read_bool(np, "qcom,hphl-jack-type-normally-closed")) cfg->hphl_swh = false; else cfg->hphl_swh = true; if (of_property_read_bool(np, "qcom,ground-jack-type-normally-closed")) cfg->gnd_swh = false; else cfg->gnd_swh = true; ret = of_property_read_u32(np, "qcom,mbhc-headset-vthreshold-microvolt", µvolt); if (ret) dev_dbg(dev, "missing qcom,mbhc-hs-mic-max-vthreshold--microvolt in dt node\n"); else cfg->hs_thr = microvolt/1000; ret = of_property_read_u32(np, "qcom,mbhc-headphone-vthreshold-microvolt", µvolt); if (ret) dev_dbg(dev, "missing qcom,mbhc-hs-mic-min-vthreshold-microvolt entry\n"); else cfg->hph_thr = microvolt/1000; ret = of_property_read_u32_array(np, "qcom,mbhc-buttons-vthreshold-microvolt", &cfg->btn_high[0], WCD_MBHC_DEF_BUTTONS); if (ret) dev_err(dev, "missing qcom,mbhc-buttons-vthreshold-microvolt entry\n"); for (i = 0; i < WCD_MBHC_DEF_BUTTONS; i++) { if (ret) /* default voltage */ cfg->btn_high[i] = 500000; else /* Micro to Milli Volts */ cfg->btn_high[i] = cfg->btn_high[i]/1000; } return 0; } EXPORT_SYMBOL(wcd_dt_parse_mbhc_data); struct wcd_mbhc *wcd_mbhc_init(struct snd_soc_component *component, const struct wcd_mbhc_cb *mbhc_cb, const struct wcd_mbhc_intr *intr_ids, struct wcd_mbhc_field *fields, bool impedance_det_en) { struct device *dev = component->dev; struct wcd_mbhc *mbhc; int ret; if (!intr_ids || !fields || !mbhc_cb || !mbhc_cb->mbhc_bias || !mbhc_cb->set_btn_thr) { dev_err(dev, "%s: Insufficient mbhc configuration\n", __func__); return ERR_PTR(-EINVAL); } mbhc = kzalloc(sizeof(*mbhc), GFP_KERNEL); if (!mbhc) return ERR_PTR(-ENOMEM); mbhc->component = component; mbhc->dev = dev; mbhc->intr_ids = intr_ids; mbhc->mbhc_cb = mbhc_cb; mbhc->fields = fields; mbhc->mbhc_detection_logic = WCD_DETECTION_ADC; if (mbhc_cb->compute_impedance) mbhc->impedance_detect = impedance_det_en; INIT_DELAYED_WORK(&mbhc->mbhc_btn_dwork, wcd_btn_long_press_fn); mutex_init(&mbhc->lock); INIT_WORK(&mbhc->correct_plug_swch, wcd_correct_swch_plug); INIT_WORK(&mbhc->mbhc_plug_detect_work, mbhc_plug_detect_fn); ret = request_threaded_irq(mbhc->intr_ids->mbhc_sw_intr, NULL, wcd_mbhc_mech_plug_detect_irq, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "mbhc sw intr", mbhc); if (ret) goto err_free_mbhc; ret = request_threaded_irq(mbhc->intr_ids->mbhc_btn_press_intr, NULL, wcd_mbhc_btn_press_handler, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "Button Press detect", mbhc); if (ret) goto err_free_sw_intr; ret = request_threaded_irq(mbhc->intr_ids->mbhc_btn_release_intr, NULL, wcd_mbhc_btn_release_handler, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "Button Release detect", mbhc); if (ret) goto err_free_btn_press_intr; ret = request_threaded_irq(mbhc->intr_ids->mbhc_hs_ins_intr, NULL, wcd_mbhc_adc_hs_ins_irq, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "Elect Insert", mbhc); if (ret) goto err_free_btn_release_intr; disable_irq_nosync(mbhc->intr_ids->mbhc_hs_ins_intr); ret = request_threaded_irq(mbhc->intr_ids->mbhc_hs_rem_intr, NULL, wcd_mbhc_adc_hs_rem_irq, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "Elect Remove", mbhc); if (ret) goto err_free_hs_ins_intr; disable_irq_nosync(mbhc->intr_ids->mbhc_hs_rem_intr); ret = request_threaded_irq(mbhc->intr_ids->hph_left_ocp, NULL, wcd_mbhc_hphl_ocp_irq, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "HPH_L OCP detect", mbhc); if (ret) goto err_free_hs_rem_intr; ret = request_threaded_irq(mbhc->intr_ids->hph_right_ocp, NULL, wcd_mbhc_hphr_ocp_irq, IRQF_ONESHOT | IRQF_TRIGGER_RISING, "HPH_R OCP detect", mbhc); if (ret) goto err_free_hph_left_ocp; return mbhc; err_free_hph_left_ocp: free_irq(mbhc->intr_ids->hph_left_ocp, mbhc); err_free_hs_rem_intr: free_irq(mbhc->intr_ids->mbhc_hs_rem_intr, mbhc); err_free_hs_ins_intr: free_irq(mbhc->intr_ids->mbhc_hs_ins_intr, mbhc); err_free_btn_release_intr: free_irq(mbhc->intr_ids->mbhc_btn_release_intr, mbhc); err_free_btn_press_intr: free_irq(mbhc->intr_ids->mbhc_btn_press_intr, mbhc); err_free_sw_intr: free_irq(mbhc->intr_ids->mbhc_sw_intr, mbhc); err_free_mbhc: kfree(mbhc); dev_err(dev, "Failed to request mbhc interrupts %d\n", ret); return ERR_PTR(ret); } EXPORT_SYMBOL(wcd_mbhc_init); void wcd_mbhc_deinit(struct wcd_mbhc *mbhc) { free_irq(mbhc->intr_ids->hph_right_ocp, mbhc); free_irq(mbhc->intr_ids->hph_left_ocp, mbhc); free_irq(mbhc->intr_ids->mbhc_hs_rem_intr, mbhc); free_irq(mbhc->intr_ids->mbhc_hs_ins_intr, mbhc); free_irq(mbhc->intr_ids->mbhc_btn_release_intr, mbhc); free_irq(mbhc->intr_ids->mbhc_btn_press_intr, mbhc); free_irq(mbhc->intr_ids->mbhc_sw_intr, mbhc); mutex_lock(&mbhc->lock); wcd_cancel_hs_detect_plug(mbhc, &mbhc->correct_plug_swch); cancel_work_sync(&mbhc->mbhc_plug_detect_work); mutex_unlock(&mbhc->lock); kfree(mbhc); } EXPORT_SYMBOL(wcd_mbhc_deinit); static int __init mbhc_init(void) { return 0; } static void __exit mbhc_exit(void) { } module_init(mbhc_init); module_exit(mbhc_exit); MODULE_DESCRIPTION("wcd MBHC v2 module"); MODULE_LICENSE("GPL");
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