// SPDX-License-Identifier: GPL-2.0 /* * ALSA SoC Texas Instruments TAS67524 Quad-Channel Audio Amplifier * * Copyright (C) 2026 Texas Instruments Incorporated - https://www.ti.com/ * Author: Sen Wang */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "tas675x.h" #define TAS675X_FAULT_CHECK_INTERVAL_MS 200 enum tas675x_type { TAS67524, }; struct tas675x_reg_param { u8 page; u8 reg; u32 val; }; struct tas675x_priv { struct device *dev; struct regmap *regmap; enum tas675x_type dev_type; /* Custom regmap lock; protects writes across books */ struct mutex io_lock; struct gpio_desc *pd_gpio; struct gpio_desc *stby_gpio; struct regulator_bulk_data supplies[2]; struct regulator *vbat; bool fast_boot; int audio_slot; int llp_slot; int vpredict_slot; int isense_slot; int bclk_offset; int slot_width; unsigned int tx_mask; int gpio1_func; int gpio2_func; unsigned long active_playback_dais; unsigned long active_capture_dais; unsigned int rate; unsigned int saved_rtldg_en; #define TAS675X_DSP_PARAM_NUM 2 struct tas675x_reg_param dsp_params[TAS675X_DSP_PARAM_NUM]; /* Fault monitor, disabled when Fault IRQ is used */ struct delayed_work fault_check_work; #define TAS675X_FAULT_REGS_NUM 9 unsigned int last_status[TAS675X_FAULT_REGS_NUM]; }; static const char * const tas675x_supply_names[] = { "dvdd", /* Digital power supply */ "pvdd", /* Output powerstage supply */ }; /* Page 1 setup initialization defaults */ static const struct reg_sequence tas675x_page1_init[] = { REG_SEQ0(TAS675X_PAGE_REG(1, 0xC8), 0x20), /* Charge pump clock */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x2F), 0x90), /* VBAT idle */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x29), 0x40), /* OC/CBC threshold */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x2E), 0x0C), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC5), 0x02), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC6), 0x10), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x1F), 0x20), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x16), 0x01), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0x1E), 0x04), /* OC/CBC config */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC1), 0x00), /* CH1 DC fault */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC2), 0x04), /* CH2 DC fault */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC3), 0x00), /* CH3 DC fault */ REG_SEQ0(TAS675X_PAGE_REG(1, 0xC4), 0x00), /* CH4 DC fault */ }; static inline const char *tas675x_state_name(unsigned int state) { switch (state & 0x0F) { case TAS675X_STATE_DEEPSLEEP: return "DEEPSLEEP"; case TAS675X_STATE_LOAD_DIAG: return "LOAD_DIAG"; case TAS675X_STATE_SLEEP: return "SLEEP"; case TAS675X_STATE_HIZ: return "HIZ"; case TAS675X_STATE_PLAY: return "PLAY"; case TAS675X_STATE_FAULT: return "FAULT"; case TAS675X_STATE_AUTOREC: return "AUTOREC"; default: return "UNKNOWN"; } } static inline int tas675x_set_state_all(struct tas675x_priv *tas, u8 state) { const struct reg_sequence seq[] = { REG_SEQ0(TAS675X_STATE_CTRL_CH1_CH2_REG, state), REG_SEQ0(TAS675X_STATE_CTRL_CH3_CH4_REG, state), }; return regmap_multi_reg_write(tas->regmap, seq, ARRAY_SIZE(seq)); } static inline int tas675x_select_book(struct regmap *regmap, u8 book) { int ret; /* Reset page to 0 before switching books */ ret = regmap_write(regmap, TAS675X_PAGE_CTRL_REG, 0x00); if (!ret) ret = regmap_write(regmap, TAS675X_BOOK_CTRL_REG, book); return ret; } /* Raw I2C version of tas675x_select_book, must be called with io_lock held */ static inline int __tas675x_select_book(struct tas675x_priv *tas, u8 book) { struct i2c_client *client = to_i2c_client(tas->dev); int ret; /* Reset page to 0 before switching books */ ret = i2c_smbus_write_byte_data(client, TAS675X_PAGE_CTRL_REG, 0x00); if (ret) return ret; return i2c_smbus_write_byte_data(client, TAS675X_BOOK_CTRL_REG, book); } static int tas675x_dsp_mem_write(struct tas675x_priv *tas, u8 page, u8 reg, u32 val) { struct i2c_client *client = to_i2c_client(tas->dev); u8 buf[4]; int ret; /* DSP registers are 32 bit big-endian */ buf[0] = (val >> 24) & 0xFF; buf[1] = (val >> 16) & 0xFF; buf[2] = (val >> 8) & 0xFF; buf[3] = val & 0xFF; /* * DSP regs in a different book, therefore block * regmap access before completion. */ mutex_lock(&tas->io_lock); ret = __tas675x_select_book(tas, TAS675X_BOOK_DSP); if (ret) goto out; ret = i2c_smbus_write_byte_data(client, TAS675X_PAGE_CTRL_REG, page); if (ret) goto out; ret = i2c_smbus_write_i2c_block_data(client, reg, sizeof(buf), buf); out: __tas675x_select_book(tas, TAS675X_BOOK_DEFAULT); mutex_unlock(&tas->io_lock); return ret; } static int tas675x_dsp_mem_read(struct tas675x_priv *tas, u8 page, u8 reg, u32 *val) { struct i2c_client *client = to_i2c_client(tas->dev); u8 buf[4]; int ret; /* * DSP regs in a different book, therefore block * regmap access before completion. */ mutex_lock(&tas->io_lock); ret = __tas675x_select_book(tas, TAS675X_BOOK_DSP); if (ret) goto out; ret = i2c_smbus_write_byte_data(client, TAS675X_PAGE_CTRL_REG, page); if (ret) goto out; ret = i2c_smbus_read_i2c_block_data(client, reg, sizeof(buf), buf); if (ret == sizeof(buf)) { *val = (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3]; ret = 0; } else if (ret >= 0) { ret = -EIO; } out: __tas675x_select_book(tas, TAS675X_BOOK_DEFAULT); mutex_unlock(&tas->io_lock); return ret; } static const struct { const char *name; int val; } tas675x_gpio_func_map[] = { /* Output functions */ { "low", TAS675X_GPIO_SEL_LOW }, { "auto-mute", TAS675X_GPIO_SEL_AUTO_MUTE_ALL }, { "auto-mute-ch4", TAS675X_GPIO_SEL_AUTO_MUTE_CH4 }, { "auto-mute-ch3", TAS675X_GPIO_SEL_AUTO_MUTE_CH3 }, { "auto-mute-ch2", TAS675X_GPIO_SEL_AUTO_MUTE_CH2 }, { "auto-mute-ch1", TAS675X_GPIO_SEL_AUTO_MUTE_CH1 }, { "sdout2", TAS675X_GPIO_SEL_SDOUT2 }, { "sdout1", TAS675X_GPIO_SEL_SDOUT1 }, { "warn", TAS675X_GPIO_SEL_WARN }, { "fault", TAS675X_GPIO_SEL_FAULT }, { "clock-sync", TAS675X_GPIO_SEL_CLOCK_SYNC }, { "invalid-clock", TAS675X_GPIO_SEL_INVALID_CLK }, { "high", TAS675X_GPIO_SEL_HIGH }, /* Input functions */ { "mute", TAS675X_GPIO_IN_MUTE }, { "phase-sync", TAS675X_GPIO_IN_PHASE_SYNC }, { "sdin2", TAS675X_GPIO_IN_SDIN2 }, { "deep-sleep", TAS675X_GPIO_IN_DEEP_SLEEP }, { "hiz", TAS675X_GPIO_IN_HIZ }, { "play", TAS675X_GPIO_IN_PLAY }, { "sleep", TAS675X_GPIO_IN_SLEEP }, }; static int tas675x_gpio_func_parse(struct device *dev, const char *propname) { const char *str; int i, ret; ret = device_property_read_string(dev, propname, &str); if (ret) return -1; for (i = 0; i < ARRAY_SIZE(tas675x_gpio_func_map); i++) { if (!strcmp(str, tas675x_gpio_func_map[i].name)) return tas675x_gpio_func_map[i].val; } dev_warn(dev, "Invalid %s value '%s'\n", propname, str); return -1; } static const struct { unsigned int reg; unsigned int mask; } tas675x_gpio_input_table[TAS675X_GPIO_IN_NUM] = { [TAS675X_GPIO_IN_ID_MUTE] = { TAS675X_GPIO_INPUT_MUTE_REG, TAS675X_GPIO_IN_MUTE_MASK }, [TAS675X_GPIO_IN_ID_PHASE_SYNC] = { TAS675X_GPIO_INPUT_SYNC_REG, TAS675X_GPIO_IN_SYNC_MASK }, [TAS675X_GPIO_IN_ID_SDIN2] = { TAS675X_GPIO_INPUT_SDIN2_REG, TAS675X_GPIO_IN_SDIN2_MASK }, [TAS675X_GPIO_IN_ID_DEEP_SLEEP] = { TAS675X_GPIO_INPUT_SLEEP_HIZ_REG, TAS675X_GPIO_IN_DEEP_SLEEP_MASK }, [TAS675X_GPIO_IN_ID_HIZ] = { TAS675X_GPIO_INPUT_SLEEP_HIZ_REG, TAS675X_GPIO_IN_HIZ_MASK }, [TAS675X_GPIO_IN_ID_PLAY] = { TAS675X_GPIO_INPUT_PLAY_SLEEP_REG, TAS675X_GPIO_IN_PLAY_MASK }, [TAS675X_GPIO_IN_ID_SLEEP] = { TAS675X_GPIO_INPUT_PLAY_SLEEP_REG, TAS675X_GPIO_IN_SLEEP_MASK }, }; static void tas675x_config_gpio_pin(struct regmap *regmap, int func_id, unsigned int out_sel_reg, unsigned int pin_idx, unsigned int *gpio_ctrl) { int id; if (func_id < 0) return; if (func_id & TAS675X_GPIO_FUNC_INPUT) { /* 3-bit mux: 0 = disabled, 0b1 = GPIO1, 0b10 = GPIO2 */ id = func_id & ~TAS675X_GPIO_FUNC_INPUT; regmap_update_bits(regmap, tas675x_gpio_input_table[id].reg, tas675x_gpio_input_table[id].mask, (pin_idx + 1) << __ffs(tas675x_gpio_input_table[id].mask)); } else { /* Output GPIO, update selection register and enable bit */ regmap_write(regmap, out_sel_reg, func_id); *gpio_ctrl |= pin_idx ? TAS675X_GPIO2_OUTPUT_EN : TAS675X_GPIO1_OUTPUT_EN; } } static int tas675x_rtldg_thresh_info(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_info *uinfo) { uinfo->type = SNDRV_CTL_ELEM_TYPE_INTEGER; uinfo->count = 1; uinfo->value.integer.min = 0; /* threshold reg ranges up to 24bit */ uinfo->value.integer.max = 0x00FFFFFF; return 0; } static int tas675x_set_rtldg_thresh(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); const struct tas675x_reg_param *t = (const struct tas675x_reg_param *)kcontrol->private_value; u32 val = ucontrol->value.integer.value[0]; int ret; ret = tas675x_dsp_mem_write(tas, t->page, t->reg, val); /* Cache the value */ if (!ret) { int i; for (i = 0; i < ARRAY_SIZE(tas->dsp_params); i++) { if (tas->dsp_params[i].page == t->page && tas->dsp_params[i].reg == t->reg) { tas->dsp_params[i].val = val; break; } } } /* Return 1 to notify change, or propagate error */ return ret ? ret : 1; } static int tas675x_get_rtldg_thresh(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); const struct tas675x_reg_param *t = (const struct tas675x_reg_param *)kcontrol->private_value; u32 val = 0; int ret; ret = tas675x_dsp_mem_read(tas, t->page, t->reg, &val); if (!ret) ucontrol->value.integer.value[0] = val; return ret; } static const struct tas675x_reg_param tas675x_dsp_defaults[] = { [TAS675X_DSP_PARAM_ID_OL_THRESH] = { TAS675X_DSP_PAGE_RTLDG, TAS675X_DSP_RTLDG_OL_THRESH_REG }, [TAS675X_DSP_PARAM_ID_SL_THRESH] = { TAS675X_DSP_PAGE_RTLDG, TAS675X_DSP_RTLDG_SL_THRESH_REG }, }; static_assert(ARRAY_SIZE(tas675x_dsp_defaults) == TAS675X_DSP_PARAM_NUM); static int tas675x_set_dcldg_trigger(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); unsigned int state, state34; int ret; if (!ucontrol->value.integer.value[0]) return 0; if (snd_soc_component_active(comp)) return -EBUSY; ret = pm_runtime_resume_and_get(tas->dev); if (ret < 0) return ret; /* * Abort automatic DC LDG retry loops (startup or init-after-fault) * and clear faults before manual diagnostics. */ regmap_update_bits(tas->regmap, TAS675X_DC_LDG_CTRL_REG, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT); regmap_write(tas->regmap, TAS675X_RESET_REG, TAS675X_FAULT_CLEAR); /* Wait for LOAD_DIAG to exit */ ret = regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH1_CH2_REG, state, (state & 0x0F) != TAS675X_STATE_LOAD_DIAG && (state >> 4) != TAS675X_STATE_LOAD_DIAG, TAS675X_POLL_INTERVAL_US, TAS675X_STATE_TRANSITION_TIMEOUT_US); ret |= regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH3_CH4_REG, state34, (state34 & 0x0F) != TAS675X_STATE_LOAD_DIAG && (state34 >> 4) != TAS675X_STATE_LOAD_DIAG, TAS675X_POLL_INTERVAL_US, TAS675X_STATE_TRANSITION_TIMEOUT_US); if (ret) { dev_err(tas->dev, "DC LDG: abort timeout (CH1/2=0x%02x [%s/%s], CH3/4=0x%02x [%s/%s])\n", state, tas675x_state_name(state), tas675x_state_name(state >> 4), state34, tas675x_state_name(state34), tas675x_state_name(state34 >> 4)); goto out_restore_ldg_ctrl; } /* Transition to HIZ state */ ret = tas675x_set_state_all(tas, TAS675X_STATE_HIZ_BOTH); if (ret) goto out_restore_ldg_ctrl; /* Set LOAD_DIAG state for manual DC LDG */ ret = tas675x_set_state_all(tas, TAS675X_STATE_LOAD_DIAG_BOTH); if (ret) goto out_restore_ldg_ctrl; /* Wait for device to transition to LOAD_DIAG state */ ret = regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH1_CH2_REG, state, state == TAS675X_STATE_LOAD_DIAG_BOTH, TAS675X_POLL_INTERVAL_US, TAS675X_STATE_TRANSITION_TIMEOUT_US); ret |= regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH3_CH4_REG, state34, state34 == TAS675X_STATE_LOAD_DIAG_BOTH, TAS675X_POLL_INTERVAL_US, TAS675X_STATE_TRANSITION_TIMEOUT_US); if (ret) { dev_err(tas->dev, "DC LDG: LOAD_DIAG timeout (CH1/2=0x%02x [%s/%s], CH3/4=0x%02x [%s/%s])\n", state, tas675x_state_name(state), tas675x_state_name(state >> 4), state34, tas675x_state_name(state34), tas675x_state_name(state34 >> 4)); goto out_restore_hiz; } /* Clear ABORT and BYPASS bits to enable manual DC LDG */ ret = regmap_update_bits(tas->regmap, TAS675X_DC_LDG_CTRL_REG, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT, 0); if (ret) goto out_restore_hiz; dev_dbg(tas->dev, "DC LDG: Started\n"); /* Poll all channels for SLEEP state */ ret = regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH1_CH2_REG, state, state == TAS675X_STATE_SLEEP_BOTH, TAS675X_POLL_INTERVAL_US, TAS675X_DC_LDG_TIMEOUT_US); ret |= regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH3_CH4_REG, state34, state34 == TAS675X_STATE_SLEEP_BOTH, TAS675X_POLL_INTERVAL_US, TAS675X_DC_LDG_TIMEOUT_US); if (ret) { dev_err(tas->dev, "DC LDG: SLEEP timeout (CH1/2=0x%02x [%s/%s], CH3/4=0x%02x [%s/%s])\n", state, tas675x_state_name(state), tas675x_state_name(state >> 4), state34, tas675x_state_name(state34), tas675x_state_name(state34 >> 4)); goto out_restore_hiz; } dev_dbg(tas->dev, "DC LDG: Completed successfully (CH1/2=0x%02x, CH3/4=0x%02x)\n", state, state34); out_restore_hiz: tas675x_set_state_all(tas, TAS675X_STATE_HIZ_BOTH); out_restore_ldg_ctrl: regmap_update_bits(tas->regmap, TAS675X_DC_LDG_CTRL_REG, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT, 0); pm_runtime_mark_last_busy(tas->dev); pm_runtime_put_autosuspend(tas->dev); return ret; } static int tas675x_set_acldg_trigger(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); unsigned int state, state34; int ret; if (!ucontrol->value.integer.value[0]) return 0; if (snd_soc_component_active(comp)) return -EBUSY; ret = pm_runtime_resume_and_get(tas->dev); if (ret < 0) return ret; /* AC Load Diagnostics requires SLEEP state */ ret = tas675x_set_state_all(tas, TAS675X_STATE_SLEEP_BOTH); if (ret) { dev_err(tas->dev, "AC LDG: Failed to set SLEEP state: %d\n", ret); goto out; } /* Start AC LDG on all 4 channels (0x0F) */ ret = regmap_write(tas->regmap, TAS675X_AC_LDG_CTRL_REG, 0x0F); if (ret) { dev_err(tas->dev, "AC LDG: Failed to start: %d\n", ret); goto out; } dev_dbg(tas->dev, "AC LDG: Started\n"); /* Poll all channels for SLEEP state */ ret = regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH1_CH2_REG, state, (state == TAS675X_STATE_SLEEP_BOTH), TAS675X_POLL_INTERVAL_US, TAS675X_AC_LDG_TIMEOUT_US); if (ret) { dev_err(tas->dev, "AC LDG: CH1/CH2 timeout: %d (state=0x%02x [%s/%s])\n", ret, state, tas675x_state_name(state), tas675x_state_name(state >> 4)); regmap_write(tas->regmap, TAS675X_AC_LDG_CTRL_REG, 0x00); goto out; } ret = regmap_read_poll_timeout(tas->regmap, TAS675X_STATE_REPORT_CH3_CH4_REG, state34, (state34 == TAS675X_STATE_SLEEP_BOTH), TAS675X_POLL_INTERVAL_US, TAS675X_AC_LDG_TIMEOUT_US); if (ret) { dev_err(tas->dev, "AC LDG: CH3/CH4 timeout: %d (state=0x%02x [%s/%s])\n", ret, state34, tas675x_state_name(state34), tas675x_state_name(state34 >> 4)); regmap_write(tas->regmap, TAS675X_AC_LDG_CTRL_REG, 0x00); goto out; } dev_dbg(tas->dev, "AC LDG: Completed successfully (CH1/2=0x%02x, CH3/4=0x%02x)\n", state, state34); regmap_write(tas->regmap, TAS675X_AC_LDG_CTRL_REG, 0x00); out: pm_runtime_mark_last_busy(tas->dev); pm_runtime_put_autosuspend(tas->dev); return ret; } static int tas675x_rtldg_impedance_info(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_info *uinfo) { uinfo->type = SNDRV_CTL_ELEM_TYPE_INTEGER; uinfo->count = 1; uinfo->value.integer.min = 0; uinfo->value.integer.max = 0xFFFF; return 0; } static int tas675x_get_rtldg_impedance(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); unsigned int msb_reg = (unsigned int)kcontrol->private_value; u8 buf[2]; int ret; ret = regmap_bulk_read(tas->regmap, msb_reg, buf, 2); if (ret) return ret; ucontrol->value.integer.value[0] = (buf[0] << 8) | buf[1]; return 0; } static int tas675x_dc_resistance_info(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_info *uinfo) { /* 10-bit: 2-bit MSB + 8-bit LSB, 0.1 ohm/code, 0-102.3 ohm */ uinfo->type = SNDRV_CTL_ELEM_TYPE_INTEGER; uinfo->count = 1; uinfo->value.integer.min = 0; uinfo->value.integer.max = 1023; return 0; } static int tas675x_get_dc_resistance(struct snd_kcontrol *kcontrol, struct snd_ctl_elem_value *ucontrol) { struct snd_soc_component *comp = snd_kcontrol_chip(kcontrol); struct tas675x_priv *tas = snd_soc_component_get_drvdata(comp); unsigned int lsb_reg = (unsigned int)kcontrol->private_value; unsigned int msb, lsb, shift; int ret; ret = regmap_read(tas->regmap, TAS675X_DC_LDG_DCR_MSB_REG, &msb); if (ret) return ret; ret = regmap_read(tas->regmap, lsb_reg, &lsb); if (ret) return ret; /* 2-bit MSB: CH1=[7:6], CH2=[5:4], CH3=[3:2], CH4=[1:0] */ shift = 6 - (lsb_reg - TAS675X_CH1_DC_LDG_DCR_LSB_REG) * 2; msb = (msb >> shift) & 0x3; ucontrol->value.integer.value[0] = (msb << 8) | lsb; return 0; } /* Counterparts with read-only access */ #define SOC_SINGLE_RO(xname, xreg, xshift, xmax) \ { .iface = SNDRV_CTL_ELEM_IFACE_MIXER, \ .name = xname, \ .access = SNDRV_CTL_ELEM_ACCESS_READ | SNDRV_CTL_ELEM_ACCESS_VOLATILE, \ .info = snd_soc_info_volsw, \ .get = snd_soc_get_volsw, \ .private_value = SOC_SINGLE_VALUE(xreg, xshift, 0, xmax, 0, 0) } #define SOC_DC_RESIST_RO(xname, xlsb_reg) \ { .name = xname, \ .iface = SNDRV_CTL_ELEM_IFACE_MIXER, \ .access = SNDRV_CTL_ELEM_ACCESS_READ | SNDRV_CTL_ELEM_ACCESS_VOLATILE, \ .info = tas675x_dc_resistance_info, \ .get = tas675x_get_dc_resistance, \ .private_value = (xlsb_reg) } #define SOC_RTLDG_IMP_RO(xname, xreg) \ { .name = xname, \ .iface = SNDRV_CTL_ELEM_IFACE_MIXER, \ .access = SNDRV_CTL_ELEM_ACCESS_READ | SNDRV_CTL_ELEM_ACCESS_VOLATILE, \ .info = tas675x_rtldg_impedance_info, \ .get = tas675x_get_rtldg_impedance, \ .private_value = (xreg) } #define SOC_DSP_THRESH_EXT(xname, xthresh) \ { .name = xname, \ .iface = SNDRV_CTL_ELEM_IFACE_MIXER, \ .info = tas675x_rtldg_thresh_info, \ .get = tas675x_get_rtldg_thresh, \ .put = tas675x_set_rtldg_thresh, \ .private_value = (unsigned long)&(xthresh) } /* * DAC digital volumes. From -103 to 0 dB in 0.5 dB steps, -103.5 dB means mute. * DAC analog gain. From -15.5 to 0 dB in 0.5 dB steps, no mute. */ static const DECLARE_TLV_DB_SCALE(tas675x_dig_vol_tlv, -10350, 50, 1); static const DECLARE_TLV_DB_SCALE(tas675x_ana_gain_tlv, -1550, 50, 0); static const char * const tas675x_ss_texts[] = { "Disabled", "Triangle", "Random", "Triangle and Random" }; static SOC_ENUM_SINGLE_DECL(tas675x_ss_enum, TAS675X_SS_CTRL_REG, 0, tas675x_ss_texts); static const char * const tas675x_ss_tri_range_texts[] = { "6.5%", "13.5%", "5%", "10%" }; static SOC_ENUM_SINGLE_DECL(tas675x_ss_tri_range_enum, TAS675X_SS_RANGE_CTRL_REG, 0, tas675x_ss_tri_range_texts); static const char * const tas675x_ss_rdm_range_texts[] = { "0.83%", "2.50%", "5.83%", "12.50%", "25.83%" }; static SOC_ENUM_SINGLE_DECL(tas675x_ss_rdm_range_enum, TAS675X_SS_RANGE_CTRL_REG, 4, tas675x_ss_rdm_range_texts); static const char * const tas675x_ss_rdm_dwell_texts[] = { "1/FSS to 2/FSS", "1/FSS to 4/FSS", "1/FSS to 8/FSS", "1/FSS to 15/FSS" }; static SOC_ENUM_SINGLE_DECL(tas675x_ss_rdm_dwell_enum, TAS675X_SS_RANGE_CTRL_REG, 2, tas675x_ss_rdm_dwell_texts); static const char * const tas675x_oc_limit_texts[] = { "Level 4", "Level 3", "Level 2", "Level 1" }; static SOC_ENUM_SINGLE_DECL(tas675x_oc_limit_enum, TAS675X_CURRENT_LIMIT_CTRL_REG, 0, tas675x_oc_limit_texts); static const char * const tas675x_otw_texts[] = { "Disabled", ">95C", ">110C", ">125C", ">135C", ">145C", ">155C", ">165C" }; static SOC_ENUM_SINGLE_DECL(tas675x_ch1_otw_enum, TAS675X_OTW_CTRL_CH1_CH2_REG, 4, tas675x_otw_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch2_otw_enum, TAS675X_OTW_CTRL_CH1_CH2_REG, 0, tas675x_otw_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch3_otw_enum, TAS675X_OTW_CTRL_CH3_CH4_REG, 4, tas675x_otw_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch4_otw_enum, TAS675X_OTW_CTRL_CH3_CH4_REG, 0, tas675x_otw_texts); static const char * const tas675x_dc_ldg_sl_texts[] = { "0.5 Ohm", "1 Ohm", "1.5 Ohm", "2 Ohm", "2.5 Ohm", "3 Ohm", "3.5 Ohm", "4 Ohm", "4.5 Ohm", "5 Ohm" }; static SOC_ENUM_SINGLE_DECL(tas675x_ch1_dc_ldg_sl_enum, TAS675X_DC_LDG_SL_CH1_CH2_CTRL_REG, 4, tas675x_dc_ldg_sl_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch2_dc_ldg_sl_enum, TAS675X_DC_LDG_SL_CH1_CH2_CTRL_REG, 0, tas675x_dc_ldg_sl_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch3_dc_ldg_sl_enum, TAS675X_DC_LDG_SL_CH3_CH4_CTRL_REG, 4, tas675x_dc_ldg_sl_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch4_dc_ldg_sl_enum, TAS675X_DC_LDG_SL_CH3_CH4_CTRL_REG, 0, tas675x_dc_ldg_sl_texts); static const char * const tas675x_dc_slol_ramp_texts[] = { "15 ms", "30 ms", "10 ms", "20 ms" }; static SOC_ENUM_SINGLE_DECL(tas675x_dc_slol_ramp_enum, TAS675X_DC_LDG_TIME_CTRL_REG, 6, tas675x_dc_slol_ramp_texts); static const char * const tas675x_dc_slol_settling_texts[] = { "10 ms", "5 ms", "20 ms", "15 ms" }; static SOC_ENUM_SINGLE_DECL(tas675x_dc_slol_settling_enum, TAS675X_DC_LDG_TIME_CTRL_REG, 4, tas675x_dc_slol_settling_texts); static const char * const tas675x_dc_s2pg_ramp_texts[] = { "5 ms", "2.5 ms", "10 ms", "15 ms" }; static SOC_ENUM_SINGLE_DECL(tas675x_dc_s2pg_ramp_enum, TAS675X_DC_LDG_TIME_CTRL_REG, 2, tas675x_dc_s2pg_ramp_texts); static const char * const tas675x_dc_s2pg_settling_texts[] = { "10 ms", "5 ms", "20 ms", "30 ms" }; static SOC_ENUM_SINGLE_DECL(tas675x_dc_s2pg_settling_enum, TAS675X_DC_LDG_TIME_CTRL_REG, 0, tas675x_dc_s2pg_settling_texts); static const char * const tas675x_dsp_mode_texts[] = { "Normal", "LLP", "FFLP" }; static SOC_ENUM_SINGLE_DECL(tas675x_dsp_mode_enum, TAS675X_LL_EN_REG, 0, tas675x_dsp_mode_texts); static const char * const tas675x_ana_ramp_texts[] = { "15us", "60us", "200us", "400us" }; static SOC_ENUM_SINGLE_DECL(tas675x_ana_ramp_enum, TAS675X_ANALOG_GAIN_RAMP_CTRL_REG, 2, tas675x_ana_ramp_texts); static const char * const tas675x_ramp_rate_texts[] = { "4 FS", "16 FS", "32 FS", "Instant" }; static SOC_ENUM_SINGLE_DECL(tas675x_ramp_down_rate_enum, TAS675X_DIG_VOL_RAMP_CTRL_REG, 6, tas675x_ramp_rate_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ramp_up_rate_enum, TAS675X_DIG_VOL_RAMP_CTRL_REG, 2, tas675x_ramp_rate_texts); static const char * const tas675x_ramp_step_texts[] = { "4dB", "2dB", "1dB", "0.5dB" }; static SOC_ENUM_SINGLE_DECL(tas675x_ramp_down_step_enum, TAS675X_DIG_VOL_RAMP_CTRL_REG, 4, tas675x_ramp_step_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ramp_up_step_enum, TAS675X_DIG_VOL_RAMP_CTRL_REG, 0, tas675x_ramp_step_texts); static const char * const tas675x_vol_combine_ch12_texts[] = { "Independent", "CH2 follows CH1", "CH1 follows CH2" }; static SOC_ENUM_SINGLE_DECL(tas675x_vol_combine_ch12_enum, TAS675X_DIG_VOL_COMBINE_CTRL_REG, 0, tas675x_vol_combine_ch12_texts); static const char * const tas675x_vol_combine_ch34_texts[] = { "Independent", "CH4 follows CH3", "CH3 follows CH4" }; static SOC_ENUM_SINGLE_DECL(tas675x_vol_combine_ch34_enum, TAS675X_DIG_VOL_COMBINE_CTRL_REG, 2, tas675x_vol_combine_ch34_texts); static const char * const tas675x_auto_mute_time_texts[] = { "11.5ms", "53ms", "106.5ms", "266.5ms", "535ms", "1065ms", "2665ms", "5330ms" }; static SOC_ENUM_SINGLE_DECL(tas675x_ch1_mute_time_enum, TAS675X_AUTO_MUTE_TIMING_CH1_CH2_REG, 4, tas675x_auto_mute_time_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch2_mute_time_enum, TAS675X_AUTO_MUTE_TIMING_CH1_CH2_REG, 0, tas675x_auto_mute_time_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch3_mute_time_enum, TAS675X_AUTO_MUTE_TIMING_CH3_CH4_REG, 4, tas675x_auto_mute_time_texts); static SOC_ENUM_SINGLE_DECL(tas675x_ch4_mute_time_enum, TAS675X_AUTO_MUTE_TIMING_CH3_CH4_REG, 0, tas675x_auto_mute_time_texts); /* * ALSA Mixer Controls * * For detailed documentation of each control see: * Documentation/sound/codecs/tas675x.rst */ static const struct snd_kcontrol_new tas675x_snd_controls[] = { /* Volume & Gain Control */ SOC_DOUBLE_R_TLV("Analog Playback Volume", TAS675X_ANALOG_GAIN_CH1_CH2_REG, TAS675X_ANALOG_GAIN_CH3_CH4_REG, 1, 0x1F, 1, tas675x_ana_gain_tlv), SOC_ENUM("Analog Gain Ramp Step", tas675x_ana_ramp_enum), SOC_SINGLE_RANGE_TLV("CH1 Digital Playback Volume", TAS675X_DIG_VOL_CH1_REG, 0, 0x30, 0xFF, 1, tas675x_dig_vol_tlv), SOC_SINGLE_RANGE_TLV("CH2 Digital Playback Volume", TAS675X_DIG_VOL_CH2_REG, 0, 0x30, 0xFF, 1, tas675x_dig_vol_tlv), SOC_SINGLE_RANGE_TLV("CH3 Digital Playback Volume", TAS675X_DIG_VOL_CH3_REG, 0, 0x30, 0xFF, 1, tas675x_dig_vol_tlv), SOC_SINGLE_RANGE_TLV("CH4 Digital Playback Volume", TAS675X_DIG_VOL_CH4_REG, 0, 0x30, 0xFF, 1, tas675x_dig_vol_tlv), SOC_ENUM("Volume Ramp Down Rate", tas675x_ramp_down_rate_enum), SOC_ENUM("Volume Ramp Down Step", tas675x_ramp_down_step_enum), SOC_ENUM("Volume Ramp Up Rate", tas675x_ramp_up_rate_enum), SOC_ENUM("Volume Ramp Up Step", tas675x_ramp_up_step_enum), SOC_ENUM("CH1/2 Volume Combine", tas675x_vol_combine_ch12_enum), SOC_ENUM("CH3/4 Volume Combine", tas675x_vol_combine_ch34_enum), /* Auto Mute & Silence Detection */ SOC_SINGLE("CH1 Auto Mute Switch", TAS675X_AUTO_MUTE_EN_REG, 0, 1, 0), SOC_SINGLE("CH2 Auto Mute Switch", TAS675X_AUTO_MUTE_EN_REG, 1, 1, 0), SOC_SINGLE("CH3 Auto Mute Switch", TAS675X_AUTO_MUTE_EN_REG, 2, 1, 0), SOC_SINGLE("CH4 Auto Mute Switch", TAS675X_AUTO_MUTE_EN_REG, 3, 1, 0), SOC_SINGLE("Auto Mute Combine Switch", TAS675X_AUTO_MUTE_EN_REG, 4, 1, 0), SOC_ENUM("CH1 Auto Mute Time", tas675x_ch1_mute_time_enum), SOC_ENUM("CH2 Auto Mute Time", tas675x_ch2_mute_time_enum), SOC_ENUM("CH3 Auto Mute Time", tas675x_ch3_mute_time_enum), SOC_ENUM("CH4 Auto Mute Time", tas675x_ch4_mute_time_enum), /* Clock & EMI Management */ SOC_ENUM("Spread Spectrum Mode", tas675x_ss_enum), SOC_ENUM("SS Triangle Range", tas675x_ss_tri_range_enum), SOC_ENUM("SS Random Range", tas675x_ss_rdm_range_enum), SOC_ENUM("SS Random Dwell Range", tas675x_ss_rdm_dwell_enum), SOC_SINGLE("SS Triangle Dwell Min", TAS675X_SS_DWELL_CTRL_REG, 4, 15, 0), SOC_SINGLE("SS Triangle Dwell Max", TAS675X_SS_DWELL_CTRL_REG, 0, 15, 0), /* Hardware Protection */ SOC_SINGLE("OTSD Auto Recovery Switch", TAS675X_OTSD_RECOVERY_EN_REG, 1, 1, 0), SOC_ENUM("Overcurrent Limit Level", tas675x_oc_limit_enum), SOC_ENUM("CH1 OTW Threshold", tas675x_ch1_otw_enum), SOC_ENUM("CH2 OTW Threshold", tas675x_ch2_otw_enum), SOC_ENUM("CH3 OTW Threshold", tas675x_ch3_otw_enum), SOC_ENUM("CH4 OTW Threshold", tas675x_ch4_otw_enum), /* DSP Signal Path & Mode */ SOC_ENUM("DSP Signal Path Mode", tas675x_dsp_mode_enum), /* DC Load Diagnostics */ { .iface = SNDRV_CTL_ELEM_IFACE_MIXER, .name = "DC LDG Trigger", .access = SNDRV_CTL_ELEM_ACCESS_WRITE, .info = snd_ctl_boolean_mono_info, .put = tas675x_set_dcldg_trigger, }, SOC_SINGLE("DC LDG Auto Diagnostics Switch", TAS675X_DC_LDG_CTRL_REG, 0, 1, 1), SOC_SINGLE("CH1 LO LDG Switch", TAS675X_DC_LDG_LO_CTRL_REG, 3, 1, 0), SOC_SINGLE("CH2 LO LDG Switch", TAS675X_DC_LDG_LO_CTRL_REG, 2, 1, 0), SOC_SINGLE("CH3 LO LDG Switch", TAS675X_DC_LDG_LO_CTRL_REG, 1, 1, 0), SOC_SINGLE("CH4 LO LDG Switch", TAS675X_DC_LDG_LO_CTRL_REG, 0, 1, 0), SOC_ENUM("DC LDG SLOL Ramp Time", tas675x_dc_slol_ramp_enum), SOC_ENUM("DC LDG SLOL Settling Time", tas675x_dc_slol_settling_enum), SOC_ENUM("DC LDG S2PG Ramp Time", tas675x_dc_s2pg_ramp_enum), SOC_ENUM("DC LDG S2PG Settling Time", tas675x_dc_s2pg_settling_enum), SOC_ENUM("CH1 DC LDG SL Threshold", tas675x_ch1_dc_ldg_sl_enum), SOC_ENUM("CH2 DC LDG SL Threshold", tas675x_ch2_dc_ldg_sl_enum), SOC_ENUM("CH3 DC LDG SL Threshold", tas675x_ch3_dc_ldg_sl_enum), SOC_ENUM("CH4 DC LDG SL Threshold", tas675x_ch4_dc_ldg_sl_enum), SOC_SINGLE_RO("DC LDG Result", TAS675X_DC_LDG_RESULT_REG, 0, 0xFF), SOC_SINGLE_RO("CH1 DC LDG Report", TAS675X_DC_LDG_REPORT_CH1_CH2_REG, 4, 0x0F), SOC_SINGLE_RO("CH2 DC LDG Report", TAS675X_DC_LDG_REPORT_CH1_CH2_REG, 0, 0x0F), SOC_SINGLE_RO("CH3 DC LDG Report", TAS675X_DC_LDG_REPORT_CH3_CH4_REG, 4, 0x0F), SOC_SINGLE_RO("CH4 DC LDG Report", TAS675X_DC_LDG_REPORT_CH3_CH4_REG, 0, 0x0F), SOC_SINGLE_RO("CH1 LO LDG Report", TAS675X_DC_LDG_RESULT_REG, 7, 1), SOC_SINGLE_RO("CH2 LO LDG Report", TAS675X_DC_LDG_RESULT_REG, 6, 1), SOC_SINGLE_RO("CH3 LO LDG Report", TAS675X_DC_LDG_RESULT_REG, 5, 1), SOC_SINGLE_RO("CH4 LO LDG Report", TAS675X_DC_LDG_RESULT_REG, 4, 1), SOC_DC_RESIST_RO("CH1 DC Resistance", TAS675X_CH1_DC_LDG_DCR_LSB_REG), SOC_DC_RESIST_RO("CH2 DC Resistance", TAS675X_CH2_DC_LDG_DCR_LSB_REG), SOC_DC_RESIST_RO("CH3 DC Resistance", TAS675X_CH3_DC_LDG_DCR_LSB_REG), SOC_DC_RESIST_RO("CH4 DC Resistance", TAS675X_CH4_DC_LDG_DCR_LSB_REG), /* AC Load Diagnostics */ { .iface = SNDRV_CTL_ELEM_IFACE_MIXER, .name = "AC LDG Trigger", .access = SNDRV_CTL_ELEM_ACCESS_WRITE, .info = snd_ctl_boolean_mono_info, .put = tas675x_set_acldg_trigger, }, SOC_SINGLE("AC LDG Gain", TAS675X_AC_LDG_CTRL_REG, 4, 1, 0), SOC_SINGLE("AC LDG Test Frequency", TAS675X_AC_LDG_FREQ_CTRL_REG, 0, 0xFF, 0), SOC_SINGLE_RO("CH1 AC LDG Real", TAS675X_AC_LDG_REPORT_CH1_R_REG, 0, 0xFF), SOC_SINGLE_RO("CH1 AC LDG Imag", TAS675X_AC_LDG_REPORT_CH1_I_REG, 0, 0xFF), SOC_SINGLE_RO("CH2 AC LDG Real", TAS675X_AC_LDG_REPORT_CH2_R_REG, 0, 0xFF), SOC_SINGLE_RO("CH2 AC LDG Imag", TAS675X_AC_LDG_REPORT_CH2_I_REG, 0, 0xFF), SOC_SINGLE_RO("CH3 AC LDG Real", TAS675X_AC_LDG_REPORT_CH3_R_REG, 0, 0xFF), SOC_SINGLE_RO("CH3 AC LDG Imag", TAS675X_AC_LDG_REPORT_CH3_I_REG, 0, 0xFF), SOC_SINGLE_RO("CH4 AC LDG Real", TAS675X_AC_LDG_REPORT_CH4_R_REG, 0, 0xFF), SOC_SINGLE_RO("CH4 AC LDG Imag", TAS675X_AC_LDG_REPORT_CH4_I_REG, 0, 0xFF), /* Temperature and Voltage Monitoring */ SOC_SINGLE_RO("PVDD Sense", TAS675X_PVDD_SENSE_REG, 0, 0xFF), SOC_SINGLE_RO("Global Temperature", TAS675X_TEMP_GLOBAL_REG, 0, 0xFF), SOC_SINGLE_RO("CH1 Temperature Range", TAS675X_TEMP_CH1_CH2_REG, 6, 3), SOC_SINGLE_RO("CH2 Temperature Range", TAS675X_TEMP_CH1_CH2_REG, 4, 3), SOC_SINGLE_RO("CH3 Temperature Range", TAS675X_TEMP_CH3_CH4_REG, 2, 3), SOC_SINGLE_RO("CH4 Temperature Range", TAS675X_TEMP_CH3_CH4_REG, 0, 3), /* Speaker Protection & Detection */ SOC_SINGLE("Tweeter Detection Switch", TAS675X_TWEETER_DETECT_CTRL_REG, 0, 1, 1), SOC_SINGLE("Tweeter Detect Threshold", TAS675X_TWEETER_DETECT_THRESH_REG, 0, 0xFF, 0), SOC_SINGLE_RO("CH1 Tweeter Detect Report", TAS675X_TWEETER_REPORT_REG, 3, 1), SOC_SINGLE_RO("CH2 Tweeter Detect Report", TAS675X_TWEETER_REPORT_REG, 2, 1), SOC_SINGLE_RO("CH3 Tweeter Detect Report", TAS675X_TWEETER_REPORT_REG, 1, 1), SOC_SINGLE_RO("CH4 Tweeter Detect Report", TAS675X_TWEETER_REPORT_REG, 0, 1), /* * Unavailable in LLP, available in Normal & FFLP */ SOC_SINGLE("Thermal Foldback Switch", TAS675X_DSP_CTRL_REG, 0, 1, 0), SOC_SINGLE("PVDD Foldback Switch", TAS675X_DSP_CTRL_REG, 4, 1, 0), SOC_SINGLE("DC Blocker Bypass Switch", TAS675X_DC_BLOCK_BYP_REG, 0, 1, 0), SOC_SINGLE("Clip Detect Switch", TAS675X_CLIP_DETECT_CTRL_REG, 6, 1, 0), SOC_SINGLE("Audio SDOUT Switch", TAS675X_DSP_CTRL_REG, 5, 1, 0), /* * Unavailable in both FFLP and LLP, Normal mode only */ /* Real-Time Load Diagnostics */ SOC_SINGLE("CH1 RTLDG Switch", TAS675X_RTLDG_EN_REG, 3, 1, 0), SOC_SINGLE("CH2 RTLDG Switch", TAS675X_RTLDG_EN_REG, 2, 1, 0), SOC_SINGLE("CH3 RTLDG Switch", TAS675X_RTLDG_EN_REG, 1, 1, 0), SOC_SINGLE("CH4 RTLDG Switch", TAS675X_RTLDG_EN_REG, 0, 1, 0), SOC_SINGLE("RTLDG Clip Mask Switch", TAS675X_RTLDG_EN_REG, 4, 1, 0), SOC_SINGLE("ISENSE Calibration Switch", TAS675X_ISENSE_CAL_REG, 3, 1, 0), SOC_DSP_THRESH_EXT("RTLDG Open Load Threshold", tas675x_dsp_defaults[TAS675X_DSP_PARAM_ID_OL_THRESH]), SOC_DSP_THRESH_EXT("RTLDG Short Load Threshold", tas675x_dsp_defaults[TAS675X_DSP_PARAM_ID_SL_THRESH]), SOC_RTLDG_IMP_RO("CH1 RTLDG Impedance", TAS675X_CH1_RTLDG_IMP_MSB_REG), SOC_RTLDG_IMP_RO("CH2 RTLDG Impedance", TAS675X_CH2_RTLDG_IMP_MSB_REG), SOC_RTLDG_IMP_RO("CH3 RTLDG Impedance", TAS675X_CH3_RTLDG_IMP_MSB_REG), SOC_RTLDG_IMP_RO("CH4 RTLDG Impedance", TAS675X_CH4_RTLDG_IMP_MSB_REG), }; static const struct snd_kcontrol_new tas675x_audio_path_switch = SOC_DAPM_SINGLE("Switch", SND_SOC_NOPM, 0, 1, 1); static const struct snd_kcontrol_new tas675x_anc_path_switch = SOC_DAPM_SINGLE("Switch", SND_SOC_NOPM, 0, 1, 1); static const struct snd_soc_dapm_widget tas675x_dapm_widgets[] = { SND_SOC_DAPM_SUPPLY("Analog Core", SND_SOC_NOPM, 0, 0, NULL, 0), SND_SOC_DAPM_SUPPLY("SDOUT Vpredict", SND_SOC_NOPM, 0, 0, NULL, 0), SND_SOC_DAPM_SUPPLY("SDOUT Isense", SND_SOC_NOPM, 0, 0, NULL, 0), SND_SOC_DAPM_DAC("Audio DAC", "Playback", SND_SOC_NOPM, 0, 0), SND_SOC_DAPM_DAC("ANC DAC", "ANC Playback", SND_SOC_NOPM, 0, 0), SND_SOC_DAPM_ADC("Feedback ADC", "Feedback Capture", SND_SOC_NOPM, 0, 0), SND_SOC_DAPM_SWITCH("Audio Path", SND_SOC_NOPM, 0, 0, &tas675x_audio_path_switch), SND_SOC_DAPM_SWITCH("ANC Path", SND_SOC_NOPM, 0, 0, &tas675x_anc_path_switch), /* * Even though all channels are coupled in terms of power control, * use logical outputs for each channel to allow independent routing * and DAPM controls if needed. */ SND_SOC_DAPM_OUTPUT("OUT_CH1"), SND_SOC_DAPM_OUTPUT("OUT_CH2"), SND_SOC_DAPM_OUTPUT("OUT_CH3"), SND_SOC_DAPM_OUTPUT("OUT_CH4"), SND_SOC_DAPM_INPUT("SPEAKER_LOAD"), }; static const struct snd_soc_dapm_route tas675x_dapm_routes[] = { { "Audio DAC", NULL, "Analog Core" }, { "Audio Path", "Switch", "Audio DAC" }, { "OUT_CH1", NULL, "Audio Path" }, { "OUT_CH2", NULL, "Audio Path" }, { "OUT_CH3", NULL, "Audio Path" }, { "OUT_CH4", NULL, "Audio Path" }, { "ANC DAC", NULL, "Analog Core" }, { "ANC Path", "Switch", "ANC DAC" }, { "OUT_CH1", NULL, "ANC Path" }, { "OUT_CH2", NULL, "ANC Path" }, { "OUT_CH3", NULL, "ANC Path" }, { "OUT_CH4", NULL, "ANC Path" }, { "Feedback ADC", NULL, "Analog Core" }, { "Feedback ADC", NULL, "SDOUT Vpredict" }, { "Feedback ADC", NULL, "SDOUT Isense" }, { "Feedback ADC", NULL, "SPEAKER_LOAD" }, }; static void tas675x_program_slot_offsets(struct tas675x_priv *tas, int dai_id, int slot_width) { int offset = 0; switch (dai_id) { case 0: /* Standard Audio on SDIN */ if (tas->audio_slot >= 0) offset = tas->audio_slot * slot_width; else if (tas->tx_mask) offset = __ffs(tas->tx_mask) * slot_width; else return; offset += tas->bclk_offset; regmap_update_bits(tas->regmap, TAS675X_SDIN_OFFSET_MSB_REG, TAS675X_SDIN_AUDIO_OFF_MSB_MASK, FIELD_PREP(TAS675X_SDIN_AUDIO_OFF_MSB_MASK, offset >> 8)); regmap_write(tas->regmap, TAS675X_SDIN_AUDIO_OFFSET_REG, offset & 0xFF); break; case 1: /* * Low-Latency Playback on SDIN, **only** enabled in LLP mode * and to be mixed with main audio before output amplification * to achieve ANC/RNC. */ if (tas->llp_slot >= 0) offset = tas->llp_slot * slot_width; else if (tas->tx_mask) offset = __ffs(tas->tx_mask) * slot_width; else return; offset += tas->bclk_offset; regmap_update_bits(tas->regmap, TAS675X_SDIN_OFFSET_MSB_REG, TAS675X_SDIN_LL_OFF_MSB_MASK, FIELD_PREP(TAS675X_SDIN_LL_OFF_MSB_MASK, offset >> 8)); regmap_write(tas->regmap, TAS675X_SDIN_LL_OFFSET_REG, offset & 0xFF); break; case 2: /* SDOUT Data Output (Vpredict + Isense feedback) */ if (!tas->slot_width) break; if (tas->vpredict_slot >= 0) { offset = tas->vpredict_slot * slot_width; offset += tas->bclk_offset; regmap_update_bits(tas->regmap, TAS675X_SDOUT_OFFSET_MSB_REG, TAS675X_SDOUT_VP_OFF_MSB_MASK, FIELD_PREP(TAS675X_SDOUT_VP_OFF_MSB_MASK, offset >> 8)); regmap_write(tas->regmap, TAS675X_VPREDICT_OFFSET_REG, offset & 0xFF); } if (tas->isense_slot >= 0) { offset = tas->isense_slot * slot_width; offset += tas->bclk_offset; regmap_update_bits(tas->regmap, TAS675X_SDOUT_OFFSET_MSB_REG, TAS675X_SDOUT_IS_OFF_MSB_MASK, FIELD_PREP(TAS675X_SDOUT_IS_OFF_MSB_MASK, offset >> 8)); regmap_write(tas->regmap, TAS675X_ISENSE_OFFSET_REG, offset & 0xFF); } break; } if (offset > 511) dev_warn(tas->dev, "DAI %d slot offset %d exceeds 511 SCLK limit\n", dai_id, offset); } static int tas675x_hw_params(struct snd_pcm_substream *substream, struct snd_pcm_hw_params *params, struct snd_soc_dai *dai) { struct snd_soc_component *component = dai->component; struct tas675x_priv *tas = snd_soc_component_get_drvdata(component); unsigned int rate = params_rate(params); u8 word_length; /* * Single clock domain: SDIN and SDOUT share one SCLK/FSYNC pair, * so all active DAIs must use the same sample rate. */ if ((tas->active_playback_dais || tas->active_capture_dais) && tas->rate && tas->rate != rate) { dev_err(component->dev, "Rate %u conflicts with active rate %u\n", rate, tas->rate); return -EINVAL; } switch (params_width(params)) { case 16: word_length = TAS675X_WL_16BIT; break; case 20: word_length = TAS675X_WL_20BIT; break; case 24: word_length = TAS675X_WL_24BIT; break; case 32: word_length = TAS675X_WL_32BIT; break; default: return -EINVAL; } if (substream->stream == SNDRV_PCM_STREAM_PLAYBACK) { /* * RTLDG is not supported above 96kHz. Auto-disable to * prevent DSP overload and restore when rate drops back. */ if (rate > 96000) { unsigned int val; regmap_read(component->regmap, TAS675X_RTLDG_EN_REG, &val); if (val & TAS675X_RTLDG_CH_EN_MASK) { tas->saved_rtldg_en = val; dev_dbg(component->dev, "Sample rate %dHz > 96kHz: Auto-disabling RTLDG\n", rate); regmap_update_bits(component->regmap, TAS675X_RTLDG_EN_REG, TAS675X_RTLDG_CH_EN_MASK, 0x00); } } else if (tas->saved_rtldg_en) { unsigned int cur; /* * Respect overrides and only restore if RTLDG is still auto-disabled */ regmap_read(component->regmap, TAS675X_RTLDG_EN_REG, &cur); if (!(cur & TAS675X_RTLDG_CH_EN_MASK)) { dev_dbg(component->dev, "Restoring RTLDG config after high-rate stream\n"); regmap_update_bits(component->regmap, TAS675X_RTLDG_EN_REG, TAS675X_RTLDG_CH_EN_MASK, TAS675X_RTLDG_CH_EN_MASK & tas->saved_rtldg_en); } tas->saved_rtldg_en = 0; } /* Set SDIN word length (audio path + low-latency path) */ regmap_update_bits(component->regmap, TAS675X_SDIN_CTRL_REG, TAS675X_SDIN_WL_MASK, FIELD_PREP(TAS675X_SDIN_AUDIO_WL_MASK, word_length) | FIELD_PREP(TAS675X_SDIN_LL_WL_MASK, word_length)); } else { /* Set SDOUT word length (VPREDICT + ISENSE) for capture */ regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_WL_MASK, FIELD_PREP(TAS675X_SDOUT_VP_WL_MASK, word_length) | FIELD_PREP(TAS675X_SDOUT_IS_WL_MASK, word_length)); } tas675x_program_slot_offsets(tas, dai->id, tas->slot_width ?: params_width(params)); tas->rate = rate; return 0; } static int tas675x_set_fmt(struct snd_soc_dai *dai, unsigned int fmt) { struct snd_soc_component *component = dai->component; struct tas675x_priv *tas = snd_soc_component_get_drvdata(component); bool tdm_mode = false, i2s_mode = false; /* Enforce Clocking Direction (Codec is strictly a consumer) */ switch (fmt & SND_SOC_DAIFMT_CLOCK_PROVIDER_MASK) { case SND_SOC_DAIFMT_BC_FC: break; default: dev_err(component->dev, "Unsupported clock provider format\n"); return -EINVAL; } /* SCLK polarity: NB_NF or IB_NF only (no FSYNC inversion support) */ switch (fmt & SND_SOC_DAIFMT_INV_MASK) { case SND_SOC_DAIFMT_NB_NF: regmap_update_bits(component->regmap, TAS675X_SCLK_INV_CTRL_REG, TAS675X_SCLK_INV_MASK, 0x00); break; case SND_SOC_DAIFMT_IB_NF: regmap_update_bits(component->regmap, TAS675X_SCLK_INV_CTRL_REG, TAS675X_SCLK_INV_MASK, TAS675X_SCLK_INV_MASK); break; default: dev_err(component->dev, "Unsupported clock inversion\n"); return -EINVAL; } /* Configure Audio Format and TDM Enable */ switch (fmt & SND_SOC_DAIFMT_FORMAT_MASK) { case SND_SOC_DAIFMT_I2S: i2s_mode = true; tas->bclk_offset = 0; regmap_update_bits(component->regmap, TAS675X_AUDIO_IF_CTRL_REG, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_MASK | TAS675X_FS_PULSE_MASK, TAS675X_SAP_FMT_I2S); regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_SELECT_MASK, TAS675X_SDOUT_SELECT_NON_TDM); break; case SND_SOC_DAIFMT_RIGHT_J: tas->bclk_offset = 0; regmap_update_bits(component->regmap, TAS675X_AUDIO_IF_CTRL_REG, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_MASK | TAS675X_FS_PULSE_MASK, TAS675X_SAP_FMT_RIGHT_J); regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_SELECT_MASK, TAS675X_SDOUT_SELECT_NON_TDM); break; case SND_SOC_DAIFMT_LEFT_J: tas->bclk_offset = 0; regmap_update_bits(component->regmap, TAS675X_AUDIO_IF_CTRL_REG, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_MASK | TAS675X_FS_PULSE_MASK, TAS675X_SAP_FMT_LEFT_J); regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_SELECT_MASK, TAS675X_SDOUT_SELECT_NON_TDM); break; case SND_SOC_DAIFMT_DSP_A: tdm_mode = true; tas->bclk_offset = 1; regmap_update_bits(component->regmap, TAS675X_AUDIO_IF_CTRL_REG, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_MASK | TAS675X_FS_PULSE_MASK, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_TDM | TAS675X_FS_PULSE_SHORT); regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_SELECT_MASK, TAS675X_SDOUT_SELECT_TDM_SDOUT1); break; case SND_SOC_DAIFMT_DSP_B: tdm_mode = true; tas->bclk_offset = 0; regmap_update_bits(component->regmap, TAS675X_AUDIO_IF_CTRL_REG, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_MASK | TAS675X_FS_PULSE_MASK, TAS675X_TDM_EN_BIT | TAS675X_SAP_FMT_TDM | TAS675X_FS_PULSE_SHORT); regmap_update_bits(component->regmap, TAS675X_SDOUT_CTRL_REG, TAS675X_SDOUT_SELECT_MASK, TAS675X_SDOUT_SELECT_TDM_SDOUT1); break; default: dev_err(component->dev, "Unsupported DAI format\n"); return -EINVAL; } /* Setup Vpredict and Isense outputs */ if (dai->id == 2) { unsigned int sdout_en = 0; if (tdm_mode) { /* TDM: Vpredict and Isense may coexist on separate slots */ if (tas->vpredict_slot >= 0) sdout_en |= TAS675X_SDOUT_EN_VPREDICT; if (tas->isense_slot >= 0) sdout_en |= TAS675X_SDOUT_EN_ISENSE; regmap_update_bits(component->regmap, TAS675X_SDOUT_EN_REG, TAS675X_SDOUT_EN_VPREDICT | TAS675X_SDOUT_EN_ISENSE, sdout_en); if (tas->vpredict_slot >= 0 && tas->isense_slot >= 0 && abs(tas->vpredict_slot - tas->isense_slot) < 4) dev_warn(component->dev, "ti,vpredict-slot-no and ti,isense-slot-no overlaps (each occupies 4 consecutive slots)\n"); } else if (i2s_mode) { /* I2S: only one source at a time; Vpredict takes priority */ if (tas->vpredict_slot >= 0) sdout_en = TAS675X_SDOUT_NON_TDM_SEL_VPREDICT | TAS675X_SDOUT_EN_NON_TDM_ALL; else if (tas->isense_slot >= 0) sdout_en = TAS675X_SDOUT_NON_TDM_SEL_ISENSE | TAS675X_SDOUT_EN_NON_TDM_ALL; regmap_update_bits(component->regmap, TAS675X_SDOUT_EN_REG, TAS675X_SDOUT_NON_TDM_SEL_MASK | TAS675X_SDOUT_EN_NON_TDM_ALL, sdout_en); if (sdout_en && tas->gpio1_func != TAS675X_GPIO_SEL_SDOUT2 && tas->gpio2_func != TAS675X_GPIO_SEL_SDOUT2) dev_warn(component->dev, "sdout enabled in I2S mode but no GPIO configured as SDOUT2; Ch3/Ch4 will be absent\n"); } } return 0; } static int tas675x_set_tdm_slot(struct snd_soc_dai *dai, unsigned int tx_mask, unsigned int rx_mask, int slots, int slot_width) { struct tas675x_priv *tas = snd_soc_component_get_drvdata(dai->component); if (slots == 0) { tas->slot_width = 0; tas->tx_mask = 0; return 0; } /* No rx_mask as hardware does not support channel muxing for capture */ tas->slot_width = slot_width; tas->tx_mask = tx_mask; return 0; } static int tas675x_mute_stream(struct snd_soc_dai *dai, int mute, int direction) { struct snd_soc_component *component = dai->component; struct tas675x_priv *tas = snd_soc_component_get_drvdata(component); unsigned int discard; int ret; if (direction == SNDRV_PCM_STREAM_CAPTURE) { if (mute) clear_bit(dai->id, &tas->active_capture_dais); else set_bit(dai->id, &tas->active_capture_dais); return 0; } /* * Track which playback DAIs are active. * The TAS675x has two playback DAIs (main audio and LLP). * Only transition to SLEEP when ALL are muted. */ if (mute) clear_bit(dai->id, &tas->active_playback_dais); else set_bit(dai->id, &tas->active_playback_dais); /* Last playback stream */ if (mute && !tas->active_playback_dais) { ret = tas675x_set_state_all(tas, TAS675X_STATE_SLEEP_BOTH); regmap_read(tas->regmap, TAS675X_CLK_FAULT_LATCHED_REG, &discard); return ret; } return tas675x_set_state_all(tas, tas->active_playback_dais ? TAS675X_STATE_PLAY_BOTH : TAS675X_STATE_SLEEP_BOTH); } static const struct snd_soc_dai_ops tas675x_dai_ops = { .hw_params = tas675x_hw_params, .set_fmt = tas675x_set_fmt, .set_tdm_slot = tas675x_set_tdm_slot, .mute_stream = tas675x_mute_stream, }; static struct snd_soc_dai_driver tas675x_dais[] = { { .name = "tas675x-audio", .id = 0, .playback = { .stream_name = "Playback", .channels_min = 2, .channels_max = 4, .rates = SNDRV_PCM_RATE_44100 | SNDRV_PCM_RATE_48000 | SNDRV_PCM_RATE_96000 | SNDRV_PCM_RATE_192000, .formats = SNDRV_PCM_FMTBIT_S16_LE | SNDRV_PCM_FMTBIT_S20_LE | SNDRV_PCM_FMTBIT_S24_LE | SNDRV_PCM_FMTBIT_S32_LE, }, .ops = &tas675x_dai_ops, }, /* Only available when Low Latency Path (LLP) is enabled */ { .name = "tas675x-anc", .id = 1, .playback = { .stream_name = "ANC Playback", .channels_min = 2, .channels_max = 4, .rates = SNDRV_PCM_RATE_48000 | SNDRV_PCM_RATE_96000, .formats = SNDRV_PCM_FMTBIT_S16_LE | SNDRV_PCM_FMTBIT_S20_LE | SNDRV_PCM_FMTBIT_S24_LE | SNDRV_PCM_FMTBIT_S32_LE, }, .ops = &tas675x_dai_ops, }, { .name = "tas675x-feedback", .id = 2, .capture = { .stream_name = "Feedback Capture", .channels_min = 2, .channels_max = 8, .rates = SNDRV_PCM_RATE_48000, .formats = SNDRV_PCM_FMTBIT_S16_LE | SNDRV_PCM_FMTBIT_S20_LE | SNDRV_PCM_FMTBIT_S24_LE | SNDRV_PCM_FMTBIT_S32_LE, }, .ops = &tas675x_dai_ops, } }; /* * Enable regulators and release hardware reset GPIOs. * The device is not I2C-accessible until this returns. */ static int tas675x_hw_enable(struct tas675x_priv *tas) { int ret; ret = regulator_bulk_enable(ARRAY_SIZE(tas->supplies), tas->supplies); if (ret) { dev_err(tas->dev, "Failed to enable regulators: %d\n", ret); return ret; } if (!IS_ERR(tas->vbat)) { ret = regulator_enable(tas->vbat); if (ret) { dev_err(tas->dev, "Failed to enable vbat: %d\n", ret); regulator_bulk_disable(ARRAY_SIZE(tas->supplies), tas->supplies); return ret; } } if (tas->pd_gpio && tas->stby_gpio) { /* * Independent Pin Control * Deassert PD first to boot digital, then STBY for analog. */ /* Min 4ms digital boot wait */ gpiod_set_value_cansleep(tas->pd_gpio, 0); usleep_range(4000, 5000); /* ~2ms analog stabilization */ gpiod_set_value_cansleep(tas->stby_gpio, 0); usleep_range(2000, 3000); } else if (tas->pd_gpio) { /* * Simultaneous Pin Release * STBY tied to PD or hardwired HIGH. */ /* 6ms wait for simultaneous release transition */ gpiod_set_value_cansleep(tas->pd_gpio, 0); usleep_range(6000, 7000); } else { /* * PD hardwired, device in DEEP_SLEEP. * Digital core already booted, I2C active. Deassert STBY * to bring up the analog output stage. */ /* ~2ms analog stabilization */ gpiod_set_value_cansleep(tas->stby_gpio, 0); usleep_range(2000, 3000); } return 0; } static void tas675x_hw_disable(struct tas675x_priv *tas) { if (tas->stby_gpio) gpiod_set_value_cansleep(tas->stby_gpio, 1); if (tas->pd_gpio) gpiod_set_value_cansleep(tas->pd_gpio, 1); /* * Hold PD/STBY asserted for at least 10ms * before removing PVDD, VBAT or DVDD. */ usleep_range(10000, 11000); if (!IS_ERR(tas->vbat)) regulator_disable(tas->vbat); regulator_bulk_disable(ARRAY_SIZE(tas->supplies), tas->supplies); } /* * Write device start-up defaults. * Must be called after tas675x_hw_enable() and after regcache is enabled. */ static int tas675x_init_device(struct tas675x_priv *tas) { struct regmap *regmap = tas->regmap; unsigned int val; int ret, i; /* Clear POR fault flag to prevent IRQ storm */ regmap_read(regmap, TAS675X_POWER_FAULT_LATCHED_REG, &val); /* Bypass DC Load Diagnostics for fast boot */ if (tas->fast_boot) regmap_update_bits(regmap, TAS675X_DC_LDG_CTRL_REG, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT); tas675x_select_book(regmap, TAS675X_BOOK_DEFAULT); /* Enter setup mode */ ret = regmap_write(regmap, TAS675X_SETUP_REG1, TAS675X_SETUP_ENTER_VAL1); if (ret) goto err; ret = regmap_write(regmap, TAS675X_SETUP_REG2, TAS675X_SETUP_ENTER_VAL2); if (ret) goto err; /* Set all channels to Sleep (required before Page 1 config) */ tas675x_set_state_all(tas, TAS675X_STATE_SLEEP_BOTH); /* Set DAC clock per TRM startup script */ regmap_write(regmap, TAS675X_DAC_CLK_REG, 0x00); /* * Switch to Page 1 for safety-critical OC/CBC configuration, * while bypassing regcache. (Page 1 not accessible post setup) */ regcache_cache_bypass(regmap, true); ret = regmap_multi_reg_write(regmap, tas675x_page1_init, ARRAY_SIZE(tas675x_page1_init)); regcache_cache_bypass(regmap, false); if (ret) goto err_setup; /* Resync regmap's cached page selector */ regmap_write(regmap, TAS675X_PAGE_CTRL_REG, 0x00); /* Exit setup mode */ regmap_write(regmap, TAS675X_SETUP_REG1, TAS675X_SETUP_EXIT_VAL); regmap_write(regmap, TAS675X_SETUP_REG2, TAS675X_SETUP_EXIT_VAL); /* Write DSP parameters if cached */ for (i = 0; i < ARRAY_SIZE(tas->dsp_params); i++) { if (tas->dsp_params[i].val) tas675x_dsp_mem_write(tas, tas->dsp_params[i].page, tas->dsp_params[i].reg, tas->dsp_params[i].val); } /* * Configure fault and warning event routing: * * ROUTING_1: CP fault/UVLO latch, OUTM soft short latch * ROUTING_2: CBC latch, OTSD latch, OTSD, power fault * ROUTING_3: CBC latch, OTSD latch, power latch, DC LDG, * OTSD, power warnings * ROUTING_4: OC latch, DC latch, protection shutdown * OTW latch, OTW, clip latch * ROUTING_5: clock latch+non-latch, RTLDG latch * CBC warning, clip warning */ regmap_write(regmap, TAS675X_REPORT_ROUTING_1_REG, 0x70); regmap_write(regmap, TAS675X_REPORT_ROUTING_2_REG, 0xA3); regmap_write(regmap, TAS675X_REPORT_ROUTING_3_REG, 0xBB); regmap_write(regmap, TAS675X_REPORT_ROUTING_4_REG, 0x7E); regmap_write(regmap, TAS675X_REPORT_ROUTING_5_REG, 0xF3); /* Configure GPIO pins if specified in DT */ if (tas->gpio1_func >= 0 || tas->gpio2_func >= 0) { unsigned int gpio_ctrl = TAS675X_GPIO_CTRL_RSTVAL; tas675x_config_gpio_pin(regmap, tas->gpio1_func, TAS675X_GPIO1_OUTPUT_SEL_REG, 0, &gpio_ctrl); tas675x_config_gpio_pin(regmap, tas->gpio2_func, TAS675X_GPIO2_OUTPUT_SEL_REG, 1, &gpio_ctrl); regmap_write(regmap, TAS675X_GPIO_CTRL_REG, gpio_ctrl); } /* Clear fast boot bits */ if (tas->fast_boot) regmap_update_bits(regmap, TAS675X_DC_LDG_CTRL_REG, TAS675X_LDG_ABORT_BIT | TAS675X_LDG_BYPASS_BIT, 0); /* Clear any stale faults from the boot sequence */ regmap_read(regmap, TAS675X_POWER_FAULT_STATUS_1_REG, &val); regmap_read(regmap, TAS675X_POWER_FAULT_LATCHED_REG, &val); regmap_read(regmap, TAS675X_CLK_FAULT_LATCHED_REG, &val); regmap_write(regmap, TAS675X_RESET_REG, TAS675X_FAULT_CLEAR); return 0; err_setup: regmap_write(regmap, TAS675X_SETUP_REG1, TAS675X_SETUP_EXIT_VAL); regmap_write(regmap, TAS675X_SETUP_REG2, TAS675X_SETUP_EXIT_VAL); err: dev_err(tas->dev, "Init device failed: %d\n", ret); return ret; } static void tas675x_power_off(struct tas675x_priv *tas) { regcache_cache_only(tas->regmap, true); regcache_mark_dirty(tas->regmap); tas675x_hw_disable(tas); } static int tas675x_power_on(struct tas675x_priv *tas) { int ret; ret = tas675x_hw_enable(tas); if (ret) return ret; regcache_cache_only(tas->regmap, false); regcache_mark_dirty(tas->regmap); ret = tas675x_init_device(tas); if (ret) goto err_disable; ret = regcache_sync(tas->regmap); if (ret) { dev_err(tas->dev, "Failed to sync regcache: %d\n", ret); goto err_disable; } /* Reset fault tracking */ memset(tas->last_status, 0, sizeof(tas->last_status)); return 0; err_disable: tas675x_power_off(tas); return ret; } static int tas675x_runtime_suspend(struct device *dev) { struct tas675x_priv *tas = dev_get_drvdata(dev); disable_delayed_work_sync(&tas->fault_check_work); tas675x_set_state_all(tas, TAS675X_STATE_SLEEP_BOTH); return 0; } static int tas675x_runtime_resume(struct device *dev) { struct tas675x_priv *tas = dev_get_drvdata(dev); tas675x_set_state_all(tas, TAS675X_STATE_SLEEP_BOTH); if (!to_i2c_client(dev)->irq) { enable_delayed_work(&tas->fault_check_work); schedule_delayed_work(&tas->fault_check_work, msecs_to_jiffies(TAS675X_FAULT_CHECK_INTERVAL_MS)); } return 0; } static int tas675x_system_suspend(struct device *dev) { struct tas675x_priv *tas = dev_get_drvdata(dev); int ret; ret = tas675x_runtime_suspend(dev); if (ret) return ret; if (to_i2c_client(dev)->irq) disable_irq(to_i2c_client(dev)->irq); tas675x_power_off(tas); return 0; } static int tas675x_system_resume(struct device *dev) { struct tas675x_priv *tas = dev_get_drvdata(dev); int ret; ret = tas675x_power_on(tas); if (ret) return ret; if (to_i2c_client(dev)->irq) enable_irq(to_i2c_client(dev)->irq); return tas675x_runtime_resume(dev); } static const struct snd_soc_component_driver soc_codec_dev_tas675x = { .controls = tas675x_snd_controls, .num_controls = ARRAY_SIZE(tas675x_snd_controls), .dapm_widgets = tas675x_dapm_widgets, .num_dapm_widgets = ARRAY_SIZE(tas675x_dapm_widgets), .dapm_routes = tas675x_dapm_routes, .num_dapm_routes = ARRAY_SIZE(tas675x_dapm_routes), .endianness = 1, }; /* Fault register flags */ #define TAS675X_FAULT_CRITICAL BIT(0) /* causes FAULT state, FAULT_CLEAR required */ #define TAS675X_FAULT_TRACK BIT(1) /* track last value, only log on change */ #define TAS675X_FAULT_ACTIVE BIT(2) /* skip when no stream is active */ struct tas675x_fault_reg { unsigned int reg; unsigned int flags; const char *name; }; static const struct tas675x_fault_reg tas675x_fault_table[] = { /* Critical */ { TAS675X_OTSD_LATCHED_REG, TAS675X_FAULT_CRITICAL | TAS675X_FAULT_TRACK, "Overtemperature Shutdown" }, { TAS675X_OC_DC_FAULT_LATCHED_REG, TAS675X_FAULT_CRITICAL | TAS675X_FAULT_TRACK, "Overcurrent / DC Fault" }, { TAS675X_RTLDG_OL_SL_FAULT_LATCHED_REG, TAS675X_FAULT_CRITICAL | TAS675X_FAULT_TRACK, "Real-Time Load Diagnostic Fault" }, { TAS675X_CBC_FAULT_WARN_LATCHED_REG, TAS675X_FAULT_CRITICAL | TAS675X_FAULT_TRACK, "CBC Fault/Warning" }, /* Warning */ { TAS675X_POWER_FAULT_STATUS_1_REG, TAS675X_FAULT_TRACK, "CP / OUTM Fault" }, { TAS675X_POWER_FAULT_LATCHED_REG, TAS675X_FAULT_TRACK, "Power Fault" }, { TAS675X_CLK_FAULT_LATCHED_REG, TAS675X_FAULT_TRACK | TAS675X_FAULT_ACTIVE, "Clock Fault" }, { TAS675X_OTW_LATCHED_REG, TAS675X_FAULT_TRACK, "Overtemperature Warning" }, { TAS675X_CLIP_WARN_LATCHED_REG, TAS675X_FAULT_ACTIVE, "Clip Warning" }, }; static_assert(ARRAY_SIZE(tas675x_fault_table) == TAS675X_FAULT_REGS_NUM); /* * Read and log all latched fault registers. * Shared by both the polled fault_check_work and IRQ handler paths * (which are mutually exclusive, only one is active per device). * Returns true if any fault register needs to be cleared. * * For deciphering fault messages, see "Fault Monitoring" in * Documentation/sound/codecs/tas675x.rst */ static bool tas675x_check_faults(struct tas675x_priv *tas) { struct device *dev = tas->dev; bool needs_clear = false; unsigned int reg; int i, ret; for (i = 0; i < ARRAY_SIZE(tas675x_fault_table); i++) { const struct tas675x_fault_reg *f = &tas675x_fault_table[i]; ret = regmap_read(tas->regmap, f->reg, ®); if (ret) { if (f->flags & TAS675X_FAULT_CRITICAL) { dev_err(dev, "failed to read %s: %d\n", f->name, ret); return needs_clear; } continue; } if (reg) needs_clear = true; /* Skip logging stream-dependent events when no stream is active */ if ((f->flags & TAS675X_FAULT_ACTIVE) && !READ_ONCE(tas->active_playback_dais) && !READ_ONCE(tas->active_capture_dais)) continue; /* Log on change or on every non-zero read */ if (reg && (!(f->flags & TAS675X_FAULT_TRACK) || reg != tas->last_status[i])) { if (f->flags & TAS675X_FAULT_CRITICAL) dev_crit(dev, "%s Latched: 0x%02x\n", f->name, reg); else dev_warn(dev, "%s Latched: 0x%02x\n", f->name, reg); } if (f->flags & TAS675X_FAULT_TRACK) tas->last_status[i] = reg; } return needs_clear; } static void tas675x_fault_check_work(struct work_struct *work) { struct tas675x_priv *tas = container_of(work, struct tas675x_priv, fault_check_work.work); if (tas675x_check_faults(tas)) regmap_write(tas->regmap, TAS675X_RESET_REG, TAS675X_FAULT_CLEAR); schedule_delayed_work(&tas->fault_check_work, msecs_to_jiffies(TAS675X_FAULT_CHECK_INTERVAL_MS)); } static irqreturn_t tas675x_irq_handler(int irq, void *data) { struct tas675x_priv *tas = data; irqreturn_t ret = IRQ_NONE; if (pm_runtime_resume_and_get(tas->dev) < 0) return IRQ_NONE; if (tas675x_check_faults(tas)) { regmap_write(tas->regmap, TAS675X_RESET_REG, TAS675X_FAULT_CLEAR); ret = IRQ_HANDLED; } pm_runtime_mark_last_busy(tas->dev); pm_runtime_put_autosuspend(tas->dev); return ret; } static const struct reg_default tas675x_reg_defaults[] = { { TAS675X_PAGE_CTRL_REG, 0x00 }, { TAS675X_OUTPUT_CTRL_REG, 0x00 }, { TAS675X_STATE_CTRL_CH1_CH2_REG, TAS675X_STATE_SLEEP_BOTH }, { TAS675X_STATE_CTRL_CH3_CH4_REG, TAS675X_STATE_SLEEP_BOTH }, { TAS675X_ISENSE_CTRL_REG, 0x0F }, { TAS675X_DC_DETECT_CTRL_REG, 0x00 }, { TAS675X_SCLK_INV_CTRL_REG, 0x00 }, { TAS675X_AUDIO_IF_CTRL_REG, 0x00 }, { TAS675X_SDIN_CTRL_REG, 0x0A }, { TAS675X_SDOUT_CTRL_REG, 0x1A }, { TAS675X_SDIN_OFFSET_MSB_REG, 0x00 }, { TAS675X_SDIN_AUDIO_OFFSET_REG, 0x00 }, { TAS675X_SDIN_LL_OFFSET_REG, 0x60 }, { TAS675X_SDIN_CH_SWAP_REG, 0x00 }, { TAS675X_SDOUT_OFFSET_MSB_REG, 0xCF }, { TAS675X_VPREDICT_OFFSET_REG, 0xFF }, { TAS675X_ISENSE_OFFSET_REG, 0x00 }, { TAS675X_SDOUT_EN_REG, 0x00 }, { TAS675X_LL_EN_REG, 0x00 }, { TAS675X_RTLDG_EN_REG, 0x10 }, { TAS675X_DC_BLOCK_BYP_REG, 0x00 }, { TAS675X_DSP_CTRL_REG, 0x00 }, { TAS675X_PAGE_AUTO_INC_REG, 0x00 }, { TAS675X_DIG_VOL_CH1_REG, 0x30 }, { TAS675X_DIG_VOL_CH2_REG, 0x30 }, { TAS675X_DIG_VOL_CH3_REG, 0x30 }, { TAS675X_DIG_VOL_CH4_REG, 0x30 }, { TAS675X_DIG_VOL_RAMP_CTRL_REG, 0x77 }, { TAS675X_DIG_VOL_COMBINE_CTRL_REG, 0x00 }, { TAS675X_AUTO_MUTE_EN_REG, 0x00 }, { TAS675X_AUTO_MUTE_TIMING_CH1_CH2_REG, 0x00 }, { TAS675X_AUTO_MUTE_TIMING_CH3_CH4_REG, 0x00 }, { TAS675X_ANALOG_GAIN_CH1_CH2_REG, 0x00 }, { TAS675X_ANALOG_GAIN_CH3_CH4_REG, 0x00 }, { TAS675X_ANALOG_GAIN_RAMP_CTRL_REG, 0x00 }, { TAS675X_PULSE_INJECTION_EN_REG, 0x03 }, { TAS675X_CBC_CTRL_REG, 0x07 }, { TAS675X_CURRENT_LIMIT_CTRL_REG, 0x00 }, { TAS675X_ISENSE_CAL_REG, 0x00 }, { TAS675X_PWM_PHASE_CTRL_REG, 0x00 }, { TAS675X_SS_CTRL_REG, 0x00 }, { TAS675X_SS_RANGE_CTRL_REG, 0x00 }, { TAS675X_SS_DWELL_CTRL_REG, 0x00 }, { TAS675X_RAMP_PHASE_CTRL_GPO_REG, 0x00 }, { TAS675X_PWM_PHASE_M_CTRL_CH1_REG, 0x00 }, { TAS675X_PWM_PHASE_M_CTRL_CH2_REG, 0x00 }, { TAS675X_PWM_PHASE_M_CTRL_CH3_REG, 0x00 }, { TAS675X_PWM_PHASE_M_CTRL_CH4_REG, 0x00 }, { TAS675X_DC_LDG_CTRL_REG, 0x00 }, { TAS675X_DC_LDG_LO_CTRL_REG, 0x00 }, { TAS675X_DC_LDG_TIME_CTRL_REG, 0x00 }, { TAS675X_DC_LDG_SL_CH1_CH2_CTRL_REG, 0x11 }, { TAS675X_DC_LDG_SL_CH3_CH4_CTRL_REG, 0x11 }, { TAS675X_AC_LDG_CTRL_REG, 0x10 }, { TAS675X_TWEETER_DETECT_CTRL_REG, 0x08 }, { TAS675X_TWEETER_DETECT_THRESH_REG, 0x00 }, { TAS675X_AC_LDG_FREQ_CTRL_REG, 0xC8 }, { TAS675X_REPORT_ROUTING_1_REG, 0x00 }, { TAS675X_OTSD_RECOVERY_EN_REG, 0x00 }, { TAS675X_REPORT_ROUTING_2_REG, 0xA2 }, { TAS675X_REPORT_ROUTING_3_REG, 0x00 }, { TAS675X_REPORT_ROUTING_4_REG, 0x06 }, { TAS675X_CLIP_DETECT_CTRL_REG, 0x00 }, { TAS675X_REPORT_ROUTING_5_REG, 0x00 }, { TAS675X_GPIO1_OUTPUT_SEL_REG, 0x00 }, { TAS675X_GPIO2_OUTPUT_SEL_REG, 0x00 }, { TAS675X_GPIO_CTRL_REG, TAS675X_GPIO_CTRL_RSTVAL }, { TAS675X_OTW_CTRL_CH1_CH2_REG, 0x11 }, { TAS675X_OTW_CTRL_CH3_CH4_REG, 0x11 }, }; static bool tas675x_is_readable_register(struct device *dev, unsigned int reg) { switch (reg) { case TAS675X_RESET_REG: return false; default: return true; } } static bool tas675x_is_volatile_register(struct device *dev, unsigned int reg) { switch (reg) { case TAS675X_RESET_REG: case TAS675X_BOOK_CTRL_REG: case TAS675X_AUTO_MUTE_STATUS_REG: case TAS675X_STATE_REPORT_CH1_CH2_REG: case TAS675X_STATE_REPORT_CH3_CH4_REG: case TAS675X_PVDD_SENSE_REG: case TAS675X_TEMP_GLOBAL_REG: case TAS675X_TEMP_CH1_CH2_REG: case TAS675X_TEMP_CH3_CH4_REG: case TAS675X_FS_MON_REG: case TAS675X_SCLK_MON_REG: case TAS675X_POWER_FAULT_STATUS_1_REG: case TAS675X_POWER_FAULT_STATUS_2_REG: case TAS675X_OT_FAULT_REG: case TAS675X_OTW_STATUS_REG: case TAS675X_CLIP_WARN_STATUS_REG: case TAS675X_CBC_WARNING_STATUS_REG: case TAS675X_POWER_FAULT_LATCHED_REG: case TAS675X_OTSD_LATCHED_REG: case TAS675X_OTW_LATCHED_REG: case TAS675X_CLIP_WARN_LATCHED_REG: case TAS675X_CLK_FAULT_LATCHED_REG: case TAS675X_RTLDG_OL_SL_FAULT_LATCHED_REG: case TAS675X_CBC_FAULT_WARN_LATCHED_REG: case TAS675X_OC_DC_FAULT_LATCHED_REG: case TAS675X_WARN_OT_MAX_FLAG_REG: case TAS675X_DC_LDG_REPORT_CH1_CH2_REG ... TAS675X_TWEETER_REPORT_REG: case TAS675X_CH1_RTLDG_IMP_MSB_REG ... TAS675X_CH4_DC_LDG_DCR_LSB_REG: return true; default: return false; } } static const struct regmap_range_cfg tas675x_ranges[] = { { .name = "Pages", .range_min = 0, .range_max = TAS675X_PAGE_SIZE * TAS675X_PAGE_SIZE - 1, .selector_reg = TAS675X_PAGE_CTRL_REG, .selector_mask = 0xff, .selector_shift = 0, .window_start = 0, .window_len = TAS675X_PAGE_SIZE, }, }; static void tas675x_regmap_lock(void *lock_arg) { struct tas675x_priv *tas = lock_arg; mutex_lock(&tas->io_lock); } static void tas675x_regmap_unlock(void *lock_arg) { struct tas675x_priv *tas = lock_arg; mutex_unlock(&tas->io_lock); } static const struct regmap_config tas675x_regmap_config = { .reg_bits = 8, .val_bits = 8, .max_register = TAS675X_PAGE_SIZE * TAS675X_PAGE_SIZE - 1, .ranges = tas675x_ranges, .num_ranges = ARRAY_SIZE(tas675x_ranges), .cache_type = REGCACHE_MAPLE, .reg_defaults = tas675x_reg_defaults, .num_reg_defaults = ARRAY_SIZE(tas675x_reg_defaults), .readable_reg = tas675x_is_readable_register, .volatile_reg = tas675x_is_volatile_register, }; static int tas675x_i2c_probe(struct i2c_client *client) { struct regmap_config cfg = tas675x_regmap_config; struct tas675x_priv *tas; u32 val; int i, ret; tas = devm_kzalloc(&client->dev, sizeof(*tas), GFP_KERNEL); if (!tas) return -ENOMEM; tas->dev = &client->dev; i2c_set_clientdata(client, tas); mutex_init(&tas->io_lock); cfg.lock = tas675x_regmap_lock; cfg.unlock = tas675x_regmap_unlock; cfg.lock_arg = tas; memcpy(tas->dsp_params, tas675x_dsp_defaults, sizeof(tas->dsp_params)); INIT_DELAYED_WORK(&tas->fault_check_work, tas675x_fault_check_work); tas->regmap = devm_regmap_init_i2c(client, &cfg); if (IS_ERR(tas->regmap)) return PTR_ERR(tas->regmap); /* Keep regmap cache-only until hardware is powered on */ regcache_cache_only(tas->regmap, true); tas->dev_type = (enum tas675x_type)(unsigned long)device_get_match_data(tas->dev); tas->fast_boot = device_property_read_bool(tas->dev, "ti,fast-boot"); tas->audio_slot = -1; tas->llp_slot = -1; tas->vpredict_slot = -1; tas->isense_slot = -1; if (!device_property_read_u32(tas->dev, "ti,audio-slot-no", &val)) tas->audio_slot = val; if (!device_property_read_u32(tas->dev, "ti,llp-slot-no", &val)) tas->llp_slot = val; if (!device_property_read_u32(tas->dev, "ti,vpredict-slot-no", &val)) tas->vpredict_slot = val; if (!device_property_read_u32(tas->dev, "ti,isense-slot-no", &val)) tas->isense_slot = val; tas->gpio1_func = tas675x_gpio_func_parse(tas->dev, "ti,gpio1-function"); tas->gpio2_func = tas675x_gpio_func_parse(tas->dev, "ti,gpio2-function"); for (i = 0; i < ARRAY_SIZE(tas675x_supply_names); i++) tas->supplies[i].supply = tas675x_supply_names[i]; ret = devm_regulator_bulk_get(tas->dev, ARRAY_SIZE(tas->supplies), tas->supplies); if (ret) return dev_err_probe(tas->dev, ret, "Failed to request supplies\n"); tas->vbat = devm_regulator_get_optional(tas->dev, "vbat"); if (IS_ERR(tas->vbat) && PTR_ERR(tas->vbat) != -ENODEV) return dev_err_probe(tas->dev, PTR_ERR(tas->vbat), "Failed to get vbat supply\n"); tas->pd_gpio = devm_gpiod_get_optional(tas->dev, "powerdown", GPIOD_OUT_HIGH); if (IS_ERR(tas->pd_gpio)) return dev_err_probe(tas->dev, PTR_ERR(tas->pd_gpio), "Failed powerdown-gpios\n"); tas->stby_gpio = devm_gpiod_get_optional(tas->dev, "standby", GPIOD_OUT_HIGH); if (IS_ERR(tas->stby_gpio)) return dev_err_probe(tas->dev, PTR_ERR(tas->stby_gpio), "Failed standby-gpios\n"); if (!tas->pd_gpio && !tas->stby_gpio) return dev_err_probe(tas->dev, -EINVAL, "At least one of powerdown-gpios or standby-gpios is required\n"); ret = tas675x_power_on(tas); if (ret) return ret; if (client->irq) { ret = devm_request_threaded_irq(tas->dev, client->irq, NULL, tas675x_irq_handler, IRQF_ONESHOT | IRQF_TRIGGER_FALLING, "tas675x-fault", tas); if (ret) { tas675x_power_off(tas); return dev_err_probe(tas->dev, ret, "Failed to request IRQ\n"); } } else { /* Schedule delayed work for fault checking at probe and runtime resume */ schedule_delayed_work(&tas->fault_check_work, msecs_to_jiffies(TAS675X_FAULT_CHECK_INTERVAL_MS)); } /* Enable runtime PM with 2s autosuspend */ pm_runtime_set_autosuspend_delay(tas->dev, 2000); pm_runtime_use_autosuspend(tas->dev); pm_runtime_set_active(tas->dev); pm_runtime_mark_last_busy(tas->dev); pm_runtime_enable(tas->dev); ret = devm_snd_soc_register_component(tas->dev, &soc_codec_dev_tas675x, tas675x_dais, ARRAY_SIZE(tas675x_dais)); if (ret) goto err_pm_disable; return 0; err_pm_disable: pm_runtime_force_suspend(tas->dev); pm_runtime_disable(tas->dev); tas675x_power_off(tas); return ret; } static void tas675x_i2c_remove(struct i2c_client *client) { struct tas675x_priv *tas = dev_get_drvdata(&client->dev); disable_delayed_work_sync(&tas->fault_check_work); if (client->irq) disable_irq(client->irq); pm_runtime_force_suspend(&client->dev); pm_runtime_disable(&client->dev); tas675x_power_off(tas); } static const struct dev_pm_ops tas675x_pm_ops = { SYSTEM_SLEEP_PM_OPS(tas675x_system_suspend, tas675x_system_resume) RUNTIME_PM_OPS(tas675x_runtime_suspend, tas675x_runtime_resume, NULL) }; static const struct of_device_id tas675x_of_match[] = { { .compatible = "ti,tas67524", .data = (void *)TAS67524 }, { } }; MODULE_DEVICE_TABLE(of, tas675x_of_match); static const struct i2c_device_id tas675x_i2c_id[] = { { "tas67524", TAS67524 }, { } }; MODULE_DEVICE_TABLE(i2c, tas675x_i2c_id); static struct i2c_driver tas675x_i2c_driver = { .driver = { .name = "tas675x", .of_match_table = tas675x_of_match, .pm = pm_ptr(&tas675x_pm_ops), }, .probe = tas675x_i2c_probe, .remove = tas675x_i2c_remove, .id_table = tas675x_i2c_id, }; module_i2c_driver(tas675x_i2c_driver); MODULE_AUTHOR("Sen Wang "); MODULE_DESCRIPTION("ASoC TAS675x Audio Amplifier Driver"); MODULE_LICENSE("GPL");