// SPDX-License-Identifier: GPL-2.0-only // // Components shared between ASoC and HDA CS35L56 drivers // // Copyright (C) 2023 Cirrus Logic, Inc. and // Cirrus Logic International Semiconductor Ltd. #include #include #include #include #include #include #include #include "cs35l56.h" static const struct reg_sequence cs35l56_patch[] = { /* * Firmware can change these to non-defaults to satisfy SDCA. * Ensure that they are at known defaults. */ { CS35L56_ASP1_ENABLES1, 0x00000000 }, { CS35L56_ASP1_CONTROL1, 0x00000028 }, { CS35L56_ASP1_CONTROL2, 0x18180200 }, { CS35L56_ASP1_CONTROL3, 0x00000002 }, { CS35L56_ASP1_FRAME_CONTROL1, 0x03020100 }, { CS35L56_ASP1_FRAME_CONTROL5, 0x00020100 }, { CS35L56_ASP1_DATA_CONTROL1, 0x00000018 }, { CS35L56_ASP1_DATA_CONTROL5, 0x00000018 }, { CS35L56_ASP1TX1_INPUT, 0x00000000 }, { CS35L56_ASP1TX2_INPUT, 0x00000000 }, { CS35L56_ASP1TX3_INPUT, 0x00000000 }, { CS35L56_ASP1TX4_INPUT, 0x00000000 }, { CS35L56_SWIRE_DP3_CH1_INPUT, 0x00000018 }, { CS35L56_SWIRE_DP3_CH2_INPUT, 0x00000019 }, { CS35L56_SWIRE_DP3_CH3_INPUT, 0x00000029 }, { CS35L56_SWIRE_DP3_CH4_INPUT, 0x00000028 }, /* These are not reset by a soft-reset, so patch to defaults. */ { CS35L56_MAIN_RENDER_USER_MUTE, 0x00000000 }, { CS35L56_MAIN_RENDER_USER_VOLUME, 0x00000000 }, { CS35L56_MAIN_POSTURE_NUMBER, 0x00000000 }, }; int cs35l56_set_patch(struct cs35l56_base *cs35l56_base) { return regmap_register_patch(cs35l56_base->regmap, cs35l56_patch, ARRAY_SIZE(cs35l56_patch)); } EXPORT_SYMBOL_NS_GPL(cs35l56_set_patch, SND_SOC_CS35L56_SHARED); static const struct reg_default cs35l56_reg_defaults[] = { /* no defaults for OTP_MEM - first read populates cache */ { CS35L56_ASP1_ENABLES1, 0x00000000 }, { CS35L56_ASP1_CONTROL1, 0x00000028 }, { CS35L56_ASP1_CONTROL2, 0x18180200 }, { CS35L56_ASP1_CONTROL3, 0x00000002 }, { CS35L56_ASP1_FRAME_CONTROL1, 0x03020100 }, { CS35L56_ASP1_FRAME_CONTROL5, 0x00020100 }, { CS35L56_ASP1_DATA_CONTROL1, 0x00000018 }, { CS35L56_ASP1_DATA_CONTROL5, 0x00000018 }, { CS35L56_ASP1TX1_INPUT, 0x00000000 }, { CS35L56_ASP1TX2_INPUT, 0x00000000 }, { CS35L56_ASP1TX3_INPUT, 0x00000000 }, { CS35L56_ASP1TX4_INPUT, 0x00000000 }, { CS35L56_SWIRE_DP3_CH1_INPUT, 0x00000018 }, { CS35L56_SWIRE_DP3_CH2_INPUT, 0x00000019 }, { CS35L56_SWIRE_DP3_CH3_INPUT, 0x00000029 }, { CS35L56_SWIRE_DP3_CH4_INPUT, 0x00000028 }, { CS35L56_IRQ1_MASK_1, 0x83ffffff }, { CS35L56_IRQ1_MASK_2, 0xffff7fff }, { CS35L56_IRQ1_MASK_4, 0xe0ffffff }, { CS35L56_IRQ1_MASK_8, 0xfc000fff }, { CS35L56_IRQ1_MASK_18, 0x1f7df0ff }, { CS35L56_IRQ1_MASK_20, 0x15c00000 }, { CS35L56_MAIN_RENDER_USER_MUTE, 0x00000000 }, { CS35L56_MAIN_RENDER_USER_VOLUME, 0x00000000 }, { CS35L56_MAIN_POSTURE_NUMBER, 0x00000000 }, }; static bool cs35l56_is_dsp_memory(unsigned int reg) { switch (reg) { case CS35L56_DSP1_XMEM_PACKED_0 ... CS35L56_DSP1_XMEM_PACKED_6143: case CS35L56_DSP1_XMEM_UNPACKED32_0 ... CS35L56_DSP1_XMEM_UNPACKED32_4095: case CS35L56_DSP1_XMEM_UNPACKED24_0 ... CS35L56_DSP1_XMEM_UNPACKED24_8191: case CS35L56_DSP1_YMEM_PACKED_0 ... CS35L56_DSP1_YMEM_PACKED_4604: case CS35L56_DSP1_YMEM_UNPACKED32_0 ... CS35L56_DSP1_YMEM_UNPACKED32_3070: case CS35L56_DSP1_YMEM_UNPACKED24_0 ... CS35L56_DSP1_YMEM_UNPACKED24_6141: case CS35L56_DSP1_PMEM_0 ... CS35L56_DSP1_PMEM_5114: return true; default: return false; } } static bool cs35l56_readable_reg(struct device *dev, unsigned int reg) { switch (reg) { case CS35L56_DEVID: case CS35L56_REVID: case CS35L56_RELID: case CS35L56_OTPID: case CS35L56_SFT_RESET: case CS35L56_GLOBAL_ENABLES: case CS35L56_BLOCK_ENABLES: case CS35L56_BLOCK_ENABLES2: case CS35L56_REFCLK_INPUT: case CS35L56_GLOBAL_SAMPLE_RATE: case CS35L56_OTP_MEM_53: case CS35L56_OTP_MEM_54: case CS35L56_OTP_MEM_55: case CS35L56_ASP1_ENABLES1: case CS35L56_ASP1_CONTROL1: case CS35L56_ASP1_CONTROL2: case CS35L56_ASP1_CONTROL3: case CS35L56_ASP1_FRAME_CONTROL1: case CS35L56_ASP1_FRAME_CONTROL5: case CS35L56_ASP1_DATA_CONTROL1: case CS35L56_ASP1_DATA_CONTROL5: case CS35L56_DACPCM1_INPUT: case CS35L56_DACPCM2_INPUT: case CS35L56_ASP1TX1_INPUT: case CS35L56_ASP1TX2_INPUT: case CS35L56_ASP1TX3_INPUT: case CS35L56_ASP1TX4_INPUT: case CS35L56_DSP1RX1_INPUT: case CS35L56_DSP1RX2_INPUT: case CS35L56_SWIRE_DP3_CH1_INPUT: case CS35L56_SWIRE_DP3_CH2_INPUT: case CS35L56_SWIRE_DP3_CH3_INPUT: case CS35L56_SWIRE_DP3_CH4_INPUT: case CS35L56_IRQ1_CFG: case CS35L56_IRQ1_STATUS: case CS35L56_IRQ1_EINT_1 ... CS35L56_IRQ1_EINT_8: case CS35L56_IRQ1_EINT_18: case CS35L56_IRQ1_EINT_20: case CS35L56_IRQ1_MASK_1: case CS35L56_IRQ1_MASK_2: case CS35L56_IRQ1_MASK_4: case CS35L56_IRQ1_MASK_8: case CS35L56_IRQ1_MASK_18: case CS35L56_IRQ1_MASK_20: case CS35L56_DSP_VIRTUAL1_MBOX_1: case CS35L56_DSP_VIRTUAL1_MBOX_2: case CS35L56_DSP_VIRTUAL1_MBOX_3: case CS35L56_DSP_VIRTUAL1_MBOX_4: case CS35L56_DSP_VIRTUAL1_MBOX_5: case CS35L56_DSP_VIRTUAL1_MBOX_6: case CS35L56_DSP_VIRTUAL1_MBOX_7: case CS35L56_DSP_VIRTUAL1_MBOX_8: case CS35L56_DSP_RESTRICT_STS1: case CS35L56_DSP1_SYS_INFO_ID ... CS35L56_DSP1_SYS_INFO_END: case CS35L56_DSP1_AHBM_WINDOW_DEBUG_0: case CS35L56_DSP1_AHBM_WINDOW_DEBUG_1: case CS35L56_DSP1_SCRATCH1: case CS35L56_DSP1_SCRATCH2: case CS35L56_DSP1_SCRATCH3: case CS35L56_DSP1_SCRATCH4: return true; default: return cs35l56_is_dsp_memory(reg); } } static bool cs35l56_precious_reg(struct device *dev, unsigned int reg) { switch (reg) { case CS35L56_DSP1_XMEM_PACKED_0 ... CS35L56_DSP1_XMEM_PACKED_6143: case CS35L56_DSP1_YMEM_PACKED_0 ... CS35L56_DSP1_YMEM_PACKED_4604: case CS35L56_DSP1_PMEM_0 ... CS35L56_DSP1_PMEM_5114: return true; default: return false; } } static bool cs35l56_volatile_reg(struct device *dev, unsigned int reg) { switch (reg) { case CS35L56_DEVID: case CS35L56_REVID: case CS35L56_RELID: case CS35L56_OTPID: case CS35L56_SFT_RESET: case CS35L56_GLOBAL_ENABLES: /* owned by firmware */ case CS35L56_BLOCK_ENABLES: /* owned by firmware */ case CS35L56_BLOCK_ENABLES2: /* owned by firmware */ case CS35L56_REFCLK_INPUT: /* owned by firmware */ case CS35L56_GLOBAL_SAMPLE_RATE: /* owned by firmware */ case CS35L56_DACPCM1_INPUT: /* owned by firmware */ case CS35L56_DACPCM2_INPUT: /* owned by firmware */ case CS35L56_DSP1RX1_INPUT: /* owned by firmware */ case CS35L56_DSP1RX2_INPUT: /* owned by firmware */ case CS35L56_IRQ1_STATUS: case CS35L56_IRQ1_EINT_1 ... CS35L56_IRQ1_EINT_8: case CS35L56_IRQ1_EINT_18: case CS35L56_IRQ1_EINT_20: case CS35L56_DSP_VIRTUAL1_MBOX_1: case CS35L56_DSP_VIRTUAL1_MBOX_2: case CS35L56_DSP_VIRTUAL1_MBOX_3: case CS35L56_DSP_VIRTUAL1_MBOX_4: case CS35L56_DSP_VIRTUAL1_MBOX_5: case CS35L56_DSP_VIRTUAL1_MBOX_6: case CS35L56_DSP_VIRTUAL1_MBOX_7: case CS35L56_DSP_VIRTUAL1_MBOX_8: case CS35L56_DSP_RESTRICT_STS1: case CS35L56_DSP1_SYS_INFO_ID ... CS35L56_DSP1_SYS_INFO_END: case CS35L56_DSP1_AHBM_WINDOW_DEBUG_0: case CS35L56_DSP1_AHBM_WINDOW_DEBUG_1: case CS35L56_DSP1_SCRATCH1: case CS35L56_DSP1_SCRATCH2: case CS35L56_DSP1_SCRATCH3: case CS35L56_DSP1_SCRATCH4: return true; case CS35L56_MAIN_RENDER_USER_MUTE: case CS35L56_MAIN_RENDER_USER_VOLUME: case CS35L56_MAIN_POSTURE_NUMBER: return false; default: return cs35l56_is_dsp_memory(reg); } } int cs35l56_mbox_send(struct cs35l56_base *cs35l56_base, unsigned int command) { unsigned int val; int ret; regmap_write(cs35l56_base->regmap, CS35L56_DSP_VIRTUAL1_MBOX_1, command); ret = regmap_read_poll_timeout(cs35l56_base->regmap, CS35L56_DSP_VIRTUAL1_MBOX_1, val, (val == 0), CS35L56_MBOX_POLL_US, CS35L56_MBOX_TIMEOUT_US); if (ret) { dev_warn(cs35l56_base->dev, "MBOX command %#x failed: %d\n", command, ret); return ret; } return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_mbox_send, SND_SOC_CS35L56_SHARED); int cs35l56_firmware_shutdown(struct cs35l56_base *cs35l56_base) { int ret; unsigned int val; ret = cs35l56_mbox_send(cs35l56_base, CS35L56_MBOX_CMD_SHUTDOWN); if (ret) return ret; ret = regmap_read_poll_timeout(cs35l56_base->regmap, CS35L56_DSP1_PM_CUR_STATE, val, (val == CS35L56_HALO_STATE_SHUTDOWN), CS35L56_HALO_STATE_POLL_US, CS35L56_HALO_STATE_TIMEOUT_US); if (ret < 0) dev_err(cs35l56_base->dev, "Failed to poll PM_CUR_STATE to 1 is %d (ret %d)\n", val, ret); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_firmware_shutdown, SND_SOC_CS35L56_SHARED); int cs35l56_wait_for_firmware_boot(struct cs35l56_base *cs35l56_base) { unsigned int val = 0; int read_ret, poll_ret; /* * The regmap must remain in cache-only until the chip has * booted, so use a bypassed read of the status register. */ poll_ret = read_poll_timeout(regmap_read_bypassed, read_ret, (val < 0xFFFF) && (val >= CS35L56_HALO_STATE_BOOT_DONE), CS35L56_HALO_STATE_POLL_US, CS35L56_HALO_STATE_TIMEOUT_US, false, cs35l56_base->regmap, CS35L56_DSP1_HALO_STATE, &val); if (poll_ret) { dev_err(cs35l56_base->dev, "Firmware boot timed out(%d): HALO_STATE=%#x\n", read_ret, val); return -EIO; } return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_wait_for_firmware_boot, SND_SOC_CS35L56_SHARED); void cs35l56_wait_control_port_ready(void) { /* Wait for control port to be ready (datasheet tIRS). */ usleep_range(CS35L56_CONTROL_PORT_READY_US, 2 * CS35L56_CONTROL_PORT_READY_US); } EXPORT_SYMBOL_NS_GPL(cs35l56_wait_control_port_ready, SND_SOC_CS35L56_SHARED); void cs35l56_wait_min_reset_pulse(void) { /* Satisfy minimum reset pulse width spec */ usleep_range(CS35L56_RESET_PULSE_MIN_US, 2 * CS35L56_RESET_PULSE_MIN_US); } EXPORT_SYMBOL_NS_GPL(cs35l56_wait_min_reset_pulse, SND_SOC_CS35L56_SHARED); static const struct reg_sequence cs35l56_system_reset_seq[] = { REG_SEQ0(CS35L56_DSP1_HALO_STATE, 0), REG_SEQ0(CS35L56_DSP_VIRTUAL1_MBOX_1, CS35L56_MBOX_CMD_SYSTEM_RESET), }; void cs35l56_system_reset(struct cs35l56_base *cs35l56_base, bool is_soundwire) { /* * Must enter cache-only first so there can't be any more register * accesses other than the controlled system reset sequence below. */ regcache_cache_only(cs35l56_base->regmap, true); regmap_multi_reg_write_bypassed(cs35l56_base->regmap, cs35l56_system_reset_seq, ARRAY_SIZE(cs35l56_system_reset_seq)); /* On SoundWire the registers won't be accessible until it re-enumerates. */ if (is_soundwire) return; cs35l56_wait_control_port_ready(); /* Leave in cache-only. This will be revoked when the chip has rebooted. */ } EXPORT_SYMBOL_NS_GPL(cs35l56_system_reset, SND_SOC_CS35L56_SHARED); int cs35l56_irq_request(struct cs35l56_base *cs35l56_base, int irq) { int ret; if (irq < 1) return 0; ret = devm_request_threaded_irq(cs35l56_base->dev, irq, NULL, cs35l56_irq, IRQF_ONESHOT | IRQF_SHARED | IRQF_TRIGGER_LOW, "cs35l56", cs35l56_base); if (!ret) cs35l56_base->irq = irq; else dev_err(cs35l56_base->dev, "Failed to get IRQ: %d\n", ret); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_irq_request, SND_SOC_CS35L56_SHARED); irqreturn_t cs35l56_irq(int irq, void *data) { struct cs35l56_base *cs35l56_base = data; unsigned int status1 = 0, status8 = 0, status20 = 0; unsigned int mask1, mask8, mask20; unsigned int val; int rv; irqreturn_t ret = IRQ_NONE; if (!cs35l56_base->init_done) return IRQ_NONE; mutex_lock(&cs35l56_base->irq_lock); rv = pm_runtime_resume_and_get(cs35l56_base->dev); if (rv < 0) { dev_err(cs35l56_base->dev, "irq: failed to get pm_runtime: %d\n", rv); goto err_unlock; } regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_STATUS, &val); if ((val & CS35L56_IRQ1_STS_MASK) == 0) { dev_dbg(cs35l56_base->dev, "Spurious IRQ: no pending interrupt\n"); goto err; } /* Ack interrupts */ regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_EINT_1, &status1); regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_MASK_1, &mask1); status1 &= ~mask1; regmap_write(cs35l56_base->regmap, CS35L56_IRQ1_EINT_1, status1); regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_EINT_8, &status8); regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_MASK_8, &mask8); status8 &= ~mask8; regmap_write(cs35l56_base->regmap, CS35L56_IRQ1_EINT_8, status8); regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_EINT_20, &status20); regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_MASK_20, &mask20); status20 &= ~mask20; /* We don't want EINT20 but they default to unmasked: force mask */ regmap_write(cs35l56_base->regmap, CS35L56_IRQ1_MASK_20, 0xffffffff); dev_dbg(cs35l56_base->dev, "%s: %#x %#x\n", __func__, status1, status8); /* Check to see if unmasked bits are active */ if (!status1 && !status8 && !status20) goto err; if (status1 & CS35L56_AMP_SHORT_ERR_EINT1_MASK) dev_crit(cs35l56_base->dev, "Amp short error\n"); if (status8 & CS35L56_TEMP_ERR_EINT1_MASK) dev_crit(cs35l56_base->dev, "Overtemp error\n"); ret = IRQ_HANDLED; err: pm_runtime_put(cs35l56_base->dev); err_unlock: mutex_unlock(&cs35l56_base->irq_lock); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_irq, SND_SOC_CS35L56_SHARED); int cs35l56_is_fw_reload_needed(struct cs35l56_base *cs35l56_base) { unsigned int val; int ret; /* * In secure mode FIRMWARE_MISSING is cleared by the BIOS loader so * can't be used here to test for memory retention. * Assume that tuning must be re-loaded. */ if (cs35l56_base->secured) return true; ret = pm_runtime_resume_and_get(cs35l56_base->dev); if (ret) { dev_err(cs35l56_base->dev, "Failed to runtime_get: %d\n", ret); return ret; } ret = regmap_read(cs35l56_base->regmap, CS35L56_PROTECTION_STATUS, &val); if (ret) dev_err(cs35l56_base->dev, "Failed to read PROTECTION_STATUS: %d\n", ret); else ret = !!(val & CS35L56_FIRMWARE_MISSING); pm_runtime_put_autosuspend(cs35l56_base->dev); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_is_fw_reload_needed, SND_SOC_CS35L56_SHARED); static const struct reg_sequence cs35l56_hibernate_seq[] = { /* This must be the last register access */ REG_SEQ0(CS35L56_DSP_VIRTUAL1_MBOX_1, CS35L56_MBOX_CMD_ALLOW_AUTO_HIBERNATE), }; static const struct reg_sequence cs35l56_hibernate_wake_seq[] = { REG_SEQ0(CS35L56_DSP_VIRTUAL1_MBOX_1, CS35L56_MBOX_CMD_WAKEUP), }; static void cs35l56_issue_wake_event(struct cs35l56_base *cs35l56_base) { /* * Dummy transactions to trigger I2C/SPI auto-wake. Issue two * transactions to meet the minimum required time from the rising edge * to the last falling edge of wake. * * It uses bypassed write because we must wake the chip before * disabling regmap cache-only. * * This can NAK on I2C which will terminate the write sequence so the * single-write sequence is issued twice. */ regmap_multi_reg_write_bypassed(cs35l56_base->regmap, cs35l56_hibernate_wake_seq, ARRAY_SIZE(cs35l56_hibernate_wake_seq)); usleep_range(CS35L56_WAKE_HOLD_TIME_US, 2 * CS35L56_WAKE_HOLD_TIME_US); regmap_multi_reg_write_bypassed(cs35l56_base->regmap, cs35l56_hibernate_wake_seq, ARRAY_SIZE(cs35l56_hibernate_wake_seq)); cs35l56_wait_control_port_ready(); } int cs35l56_runtime_suspend_common(struct cs35l56_base *cs35l56_base) { unsigned int val; int ret; if (!cs35l56_base->init_done) return 0; /* Firmware must have entered a power-save state */ ret = regmap_read_poll_timeout(cs35l56_base->regmap, CS35L56_TRANSDUCER_ACTUAL_PS, val, (val >= CS35L56_PS3), CS35L56_PS3_POLL_US, CS35L56_PS3_TIMEOUT_US); if (ret) dev_warn(cs35l56_base->dev, "PS3 wait failed: %d\n", ret); /* Clear BOOT_DONE so it can be used to detect a reboot */ regmap_write(cs35l56_base->regmap, CS35L56_IRQ1_EINT_4, CS35L56_OTP_BOOT_DONE_MASK); if (!cs35l56_base->can_hibernate) { regcache_cache_only(cs35l56_base->regmap, true); dev_dbg(cs35l56_base->dev, "Suspended: no hibernate"); return 0; } /* * Must enter cache-only first so there can't be any more register * accesses other than the controlled hibernate sequence below. */ regcache_cache_only(cs35l56_base->regmap, true); regmap_multi_reg_write_bypassed(cs35l56_base->regmap, cs35l56_hibernate_seq, ARRAY_SIZE(cs35l56_hibernate_seq)); dev_dbg(cs35l56_base->dev, "Suspended: hibernate"); return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_runtime_suspend_common, SND_SOC_CS35L56_SHARED); int cs35l56_runtime_resume_common(struct cs35l56_base *cs35l56_base, bool is_soundwire) { unsigned int val; int ret; if (!cs35l56_base->init_done) return 0; if (!cs35l56_base->can_hibernate) goto out_sync; /* Must be done before releasing cache-only */ if (!is_soundwire) cs35l56_issue_wake_event(cs35l56_base); out_sync: ret = cs35l56_wait_for_firmware_boot(cs35l56_base); if (ret) { dev_err(cs35l56_base->dev, "Hibernate wake failed: %d\n", ret); goto err; } regcache_cache_only(cs35l56_base->regmap, false); ret = cs35l56_mbox_send(cs35l56_base, CS35L56_MBOX_CMD_PREVENT_AUTO_HIBERNATE); if (ret) goto err; /* BOOT_DONE will be 1 if the amp reset */ regmap_read(cs35l56_base->regmap, CS35L56_IRQ1_EINT_4, &val); if (val & CS35L56_OTP_BOOT_DONE_MASK) { dev_dbg(cs35l56_base->dev, "Registers reset in suspend\n"); regcache_mark_dirty(cs35l56_base->regmap); } regcache_sync(cs35l56_base->regmap); dev_dbg(cs35l56_base->dev, "Resumed"); return 0; err: regcache_cache_only(cs35l56_base->regmap, true); regmap_multi_reg_write_bypassed(cs35l56_base->regmap, cs35l56_hibernate_seq, ARRAY_SIZE(cs35l56_hibernate_seq)); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_runtime_resume_common, SND_SOC_CS35L56_SHARED); static const struct cs_dsp_region cs35l56_dsp1_regions[] = { { .type = WMFW_HALO_PM_PACKED, .base = CS35L56_DSP1_PMEM_0 }, { .type = WMFW_HALO_XM_PACKED, .base = CS35L56_DSP1_XMEM_PACKED_0 }, { .type = WMFW_HALO_YM_PACKED, .base = CS35L56_DSP1_YMEM_PACKED_0 }, { .type = WMFW_ADSP2_XM, .base = CS35L56_DSP1_XMEM_UNPACKED24_0 }, { .type = WMFW_ADSP2_YM, .base = CS35L56_DSP1_YMEM_UNPACKED24_0 }, }; void cs35l56_init_cs_dsp(struct cs35l56_base *cs35l56_base, struct cs_dsp *cs_dsp) { cs_dsp->num = 1; cs_dsp->type = WMFW_HALO; cs_dsp->rev = 0; cs_dsp->dev = cs35l56_base->dev; cs_dsp->regmap = cs35l56_base->regmap; cs_dsp->base = CS35L56_DSP1_CORE_BASE; cs_dsp->base_sysinfo = CS35L56_DSP1_SYS_INFO_ID; cs_dsp->mem = cs35l56_dsp1_regions; cs_dsp->num_mems = ARRAY_SIZE(cs35l56_dsp1_regions); cs_dsp->no_core_startstop = true; } EXPORT_SYMBOL_NS_GPL(cs35l56_init_cs_dsp, SND_SOC_CS35L56_SHARED); struct cs35l56_pte { u8 x; u8 wafer_id; u8 pte[2]; u8 lot[3]; u8 y; u8 unused[3]; u8 dvs; } __packed; static_assert((sizeof(struct cs35l56_pte) % sizeof(u32)) == 0); static int cs35l56_read_silicon_uid(struct cs35l56_base *cs35l56_base, u64 *uid) { struct cs35l56_pte pte; u64 unique_id; int ret; ret = regmap_raw_read(cs35l56_base->regmap, CS35L56_OTP_MEM_53, &pte, sizeof(pte)); if (ret) { dev_err(cs35l56_base->dev, "Failed to read OTP: %d\n", ret); return ret; } unique_id = (u32)pte.lot[2] | ((u32)pte.lot[1] << 8) | ((u32)pte.lot[0] << 16); unique_id <<= 32; unique_id |= (u32)pte.x | ((u32)pte.y << 8) | ((u32)pte.wafer_id << 16) | ((u32)pte.dvs << 24); dev_dbg(cs35l56_base->dev, "UniqueID = %#llx\n", unique_id); *uid = unique_id; return 0; } /* Firmware calibration controls */ const struct cirrus_amp_cal_controls cs35l56_calibration_controls = { .alg_id = 0x9f210, .mem_region = WMFW_ADSP2_YM, .ambient = "CAL_AMBIENT", .calr = "CAL_R", .status = "CAL_STATUS", .checksum = "CAL_CHECKSUM", }; EXPORT_SYMBOL_NS_GPL(cs35l56_calibration_controls, SND_SOC_CS35L56_SHARED); int cs35l56_get_calibration(struct cs35l56_base *cs35l56_base) { u64 silicon_uid = 0; int ret; /* Driver can't apply calibration to a secured part, so skip */ if (cs35l56_base->secured) return 0; ret = cs35l56_read_silicon_uid(cs35l56_base, &silicon_uid); if (ret < 0) return ret; ret = cs_amp_get_efi_calibration_data(cs35l56_base->dev, silicon_uid, cs35l56_base->cal_index, &cs35l56_base->cal_data); /* Only return an error status if probe should be aborted */ if ((ret == -ENOENT) || (ret == -EOVERFLOW)) return 0; if (ret < 0) return ret; cs35l56_base->cal_data_valid = true; return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_get_calibration, SND_SOC_CS35L56_SHARED); int cs35l56_read_prot_status(struct cs35l56_base *cs35l56_base, bool *fw_missing, unsigned int *fw_version) { unsigned int prot_status; int ret; ret = regmap_read(cs35l56_base->regmap, CS35L56_PROTECTION_STATUS, &prot_status); if (ret) { dev_err(cs35l56_base->dev, "Get PROTECTION_STATUS failed: %d\n", ret); return ret; } *fw_missing = !!(prot_status & CS35L56_FIRMWARE_MISSING); ret = regmap_read(cs35l56_base->regmap, CS35L56_DSP1_FW_VER, fw_version); if (ret) { dev_err(cs35l56_base->dev, "Get FW VER failed: %d\n", ret); return ret; } return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_read_prot_status, SND_SOC_CS35L56_SHARED); int cs35l56_hw_init(struct cs35l56_base *cs35l56_base) { int ret; unsigned int devid, revid, otpid, secured, fw_ver; bool fw_missing; /* * When the system is not using a reset_gpio ensure the device is * awake, otherwise the device has just been released from reset and * the driver must wait for the control port to become usable. */ if (!cs35l56_base->reset_gpio) cs35l56_issue_wake_event(cs35l56_base); else cs35l56_wait_control_port_ready(); ret = regmap_read_bypassed(cs35l56_base->regmap, CS35L56_REVID, &revid); if (ret < 0) { dev_err(cs35l56_base->dev, "Get Revision ID failed\n"); return ret; } cs35l56_base->rev = revid & (CS35L56_AREVID_MASK | CS35L56_MTLREVID_MASK); ret = cs35l56_wait_for_firmware_boot(cs35l56_base); if (ret) return ret; ret = regmap_read_bypassed(cs35l56_base->regmap, CS35L56_DEVID, &devid); if (ret < 0) { dev_err(cs35l56_base->dev, "Get Device ID failed\n"); return ret; } devid &= CS35L56_DEVID_MASK; switch (devid) { case 0x35A54: case 0x35A56: case 0x35A57: break; default: dev_err(cs35l56_base->dev, "Unknown device %x\n", devid); return ret; } cs35l56_base->type = devid & 0xFF; /* Silicon is now identified and booted so exit cache-only */ regcache_cache_only(cs35l56_base->regmap, false); ret = regmap_read(cs35l56_base->regmap, CS35L56_DSP_RESTRICT_STS1, &secured); if (ret) { dev_err(cs35l56_base->dev, "Get Secure status failed\n"); return ret; } /* When any bus is restricted treat the device as secured */ if (secured & CS35L56_RESTRICTED_MASK) cs35l56_base->secured = true; ret = regmap_read(cs35l56_base->regmap, CS35L56_OTPID, &otpid); if (ret < 0) { dev_err(cs35l56_base->dev, "Get OTP ID failed\n"); return ret; } ret = cs35l56_read_prot_status(cs35l56_base, &fw_missing, &fw_ver); if (ret) return ret; dev_info(cs35l56_base->dev, "Cirrus Logic CS35L%02X%s Rev %02X OTP%d fw:%d.%d.%d (patched=%u)\n", cs35l56_base->type, cs35l56_base->secured ? "s" : "", cs35l56_base->rev, otpid, fw_ver >> 16, (fw_ver >> 8) & 0xff, fw_ver & 0xff, !fw_missing); /* Wake source and *_BLOCKED interrupts default to unmasked, so mask them */ regmap_write(cs35l56_base->regmap, CS35L56_IRQ1_MASK_20, 0xffffffff); regmap_update_bits(cs35l56_base->regmap, CS35L56_IRQ1_MASK_1, CS35L56_AMP_SHORT_ERR_EINT1_MASK, 0); regmap_update_bits(cs35l56_base->regmap, CS35L56_IRQ1_MASK_8, CS35L56_TEMP_ERR_EINT1_MASK, 0); return 0; } EXPORT_SYMBOL_NS_GPL(cs35l56_hw_init, SND_SOC_CS35L56_SHARED); int cs35l56_get_speaker_id(struct cs35l56_base *cs35l56_base) { struct gpio_descs *descs; u32 speaker_id; int i, ret; /* Attempt to read the speaker type from a device property first */ ret = device_property_read_u32(cs35l56_base->dev, "cirrus,speaker-id", &speaker_id); if (!ret) { dev_dbg(cs35l56_base->dev, "Speaker ID = %d\n", speaker_id); return speaker_id; } /* Read the speaker type qualifier from the motherboard GPIOs */ descs = gpiod_get_array_optional(cs35l56_base->dev, "spk-id", GPIOD_IN); if (!descs) { return -ENOENT; } else if (IS_ERR(descs)) { ret = PTR_ERR(descs); return dev_err_probe(cs35l56_base->dev, ret, "Failed to get spk-id-gpios\n"); } speaker_id = 0; for (i = 0; i < descs->ndescs; i++) { ret = gpiod_get_value_cansleep(descs->desc[i]); if (ret < 0) { dev_err_probe(cs35l56_base->dev, ret, "Failed to read spk-id[%d]\n", i); goto err; } speaker_id |= (ret << i); } dev_dbg(cs35l56_base->dev, "Speaker ID = %d\n", speaker_id); ret = speaker_id; err: gpiod_put_array(descs); return ret; } EXPORT_SYMBOL_NS_GPL(cs35l56_get_speaker_id, SND_SOC_CS35L56_SHARED); static const u32 cs35l56_bclk_valid_for_pll_freq_table[] = { [0x0C] = 128000, [0x0F] = 256000, [0x11] = 384000, [0x12] = 512000, [0x15] = 768000, [0x17] = 1024000, [0x1A] = 1500000, [0x1B] = 1536000, [0x1C] = 2000000, [0x1D] = 2048000, [0x1E] = 2400000, [0x20] = 3000000, [0x21] = 3072000, [0x23] = 4000000, [0x24] = 4096000, [0x25] = 4800000, [0x27] = 6000000, [0x28] = 6144000, [0x29] = 6250000, [0x2A] = 6400000, [0x2E] = 8000000, [0x2F] = 8192000, [0x30] = 9600000, [0x32] = 12000000, [0x33] = 12288000, [0x37] = 13500000, [0x38] = 19200000, [0x39] = 22579200, [0x3B] = 24576000, }; int cs35l56_get_bclk_freq_id(unsigned int freq) { int i; if (freq == 0) return -EINVAL; /* The BCLK frequency must be a valid PLL REFCLK */ for (i = 0; i < ARRAY_SIZE(cs35l56_bclk_valid_for_pll_freq_table); ++i) { if (cs35l56_bclk_valid_for_pll_freq_table[i] == freq) return i; } return -EINVAL; } EXPORT_SYMBOL_NS_GPL(cs35l56_get_bclk_freq_id, SND_SOC_CS35L56_SHARED); static const char * const cs35l56_supplies[/* auto-sized */] = { "VDD_P", "VDD_IO", "VDD_A", }; void cs35l56_fill_supply_names(struct regulator_bulk_data *data) { int i; BUILD_BUG_ON(ARRAY_SIZE(cs35l56_supplies) != CS35L56_NUM_BULK_SUPPLIES); for (i = 0; i < ARRAY_SIZE(cs35l56_supplies); i++) data[i].supply = cs35l56_supplies[i]; } EXPORT_SYMBOL_NS_GPL(cs35l56_fill_supply_names, SND_SOC_CS35L56_SHARED); const char * const cs35l56_tx_input_texts[] = { "None", "ASP1RX1", "ASP1RX2", "VMON", "IMON", "ERRVOL", "CLASSH", "VDDBMON", "VBSTMON", "DSP1TX1", "DSP1TX2", "DSP1TX3", "DSP1TX4", "DSP1TX5", "DSP1TX6", "DSP1TX7", "DSP1TX8", "TEMPMON", "INTERPOLATOR", "SDW1RX1", "SDW1RX2", }; EXPORT_SYMBOL_NS_GPL(cs35l56_tx_input_texts, SND_SOC_CS35L56_SHARED); const unsigned int cs35l56_tx_input_values[] = { CS35L56_INPUT_SRC_NONE, CS35L56_INPUT_SRC_ASP1RX1, CS35L56_INPUT_SRC_ASP1RX2, CS35L56_INPUT_SRC_VMON, CS35L56_INPUT_SRC_IMON, CS35L56_INPUT_SRC_ERR_VOL, CS35L56_INPUT_SRC_CLASSH, CS35L56_INPUT_SRC_VDDBMON, CS35L56_INPUT_SRC_VBSTMON, CS35L56_INPUT_SRC_DSP1TX1, CS35L56_INPUT_SRC_DSP1TX2, CS35L56_INPUT_SRC_DSP1TX3, CS35L56_INPUT_SRC_DSP1TX4, CS35L56_INPUT_SRC_DSP1TX5, CS35L56_INPUT_SRC_DSP1TX6, CS35L56_INPUT_SRC_DSP1TX7, CS35L56_INPUT_SRC_DSP1TX8, CS35L56_INPUT_SRC_TEMPMON, CS35L56_INPUT_SRC_INTERPOLATOR, CS35L56_INPUT_SRC_SWIRE_DP1_CHANNEL1, CS35L56_INPUT_SRC_SWIRE_DP1_CHANNEL2, }; EXPORT_SYMBOL_NS_GPL(cs35l56_tx_input_values, SND_SOC_CS35L56_SHARED); struct regmap_config cs35l56_regmap_i2c = { .reg_bits = 32, .val_bits = 32, .reg_stride = 4, .reg_format_endian = REGMAP_ENDIAN_BIG, .val_format_endian = REGMAP_ENDIAN_BIG, .max_register = CS35L56_DSP1_PMEM_5114, .reg_defaults = cs35l56_reg_defaults, .num_reg_defaults = ARRAY_SIZE(cs35l56_reg_defaults), .volatile_reg = cs35l56_volatile_reg, .readable_reg = cs35l56_readable_reg, .precious_reg = cs35l56_precious_reg, .cache_type = REGCACHE_MAPLE, }; EXPORT_SYMBOL_NS_GPL(cs35l56_regmap_i2c, SND_SOC_CS35L56_SHARED); struct regmap_config cs35l56_regmap_spi = { .reg_bits = 32, .val_bits = 32, .pad_bits = 16, .reg_stride = 4, .reg_format_endian = REGMAP_ENDIAN_BIG, .val_format_endian = REGMAP_ENDIAN_BIG, .max_register = CS35L56_DSP1_PMEM_5114, .reg_defaults = cs35l56_reg_defaults, .num_reg_defaults = ARRAY_SIZE(cs35l56_reg_defaults), .volatile_reg = cs35l56_volatile_reg, .readable_reg = cs35l56_readable_reg, .precious_reg = cs35l56_precious_reg, .cache_type = REGCACHE_MAPLE, }; EXPORT_SYMBOL_NS_GPL(cs35l56_regmap_spi, SND_SOC_CS35L56_SHARED); struct regmap_config cs35l56_regmap_sdw = { .reg_bits = 32, .val_bits = 32, .reg_stride = 4, .reg_format_endian = REGMAP_ENDIAN_LITTLE, .val_format_endian = REGMAP_ENDIAN_BIG, .max_register = CS35L56_DSP1_PMEM_5114, .reg_defaults = cs35l56_reg_defaults, .num_reg_defaults = ARRAY_SIZE(cs35l56_reg_defaults), .volatile_reg = cs35l56_volatile_reg, .readable_reg = cs35l56_readable_reg, .precious_reg = cs35l56_precious_reg, .cache_type = REGCACHE_MAPLE, }; EXPORT_SYMBOL_NS_GPL(cs35l56_regmap_sdw, SND_SOC_CS35L56_SHARED); MODULE_DESCRIPTION("ASoC CS35L56 Shared"); MODULE_AUTHOR("Richard Fitzgerald "); MODULE_AUTHOR("Simon Trimmer "); MODULE_LICENSE("GPL"); MODULE_IMPORT_NS(SND_SOC_CS_AMP_LIB);