nguyen nam
/
BSP_DISCO_F746NG
SPKT
Drivers/BSP/Components/wm8994/wm8994.c
- Committer:
- bcostm
- Date:
- 2016-11-10
- Revision:
- 6:e1d9da7fe856
File content as of revision 6:e1d9da7fe856:
/** ****************************************************************************** * @file wm8994.c * @author MCD Application Team * @version V2.1.0 * @date 22-February-2016 * @brief This file provides the WM8994 Audio Codec driver. ****************************************************************************** * @attention * * <h2><center>© COPYRIGHT(c) 2016 STMicroelectronics</center></h2> * * Redistribution and use in source and binary forms, with or without modification, * are permitted provided that the following conditions are met: * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * 3. Neither the name of STMicroelectronics nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************** */ /* Includes ------------------------------------------------------------------*/ #include "wm8994.h" /** @addtogroup BSP * @{ */ /** @addtogroup Components * @{ */ /** @addtogroup wm8994 * @brief This file provides a set of functions needed to drive the * WM8994 audio codec. * @{ */ /** @defgroup WM8994_Private_Types * @{ */ /** * @} */ /** @defgroup WM8994_Private_Defines * @{ */ /* Uncomment this line to enable verifying data sent to codec after each write operation (for debug purpose) */ #if !defined (VERIFY_WRITTENDATA) /*#define VERIFY_WRITTENDATA*/ #endif /* VERIFY_WRITTENDATA */ /** * @} */ /** @defgroup WM8994_Private_Macros * @{ */ /** * @} */ /** @defgroup WM8994_Private_Variables * @{ */ /* Audio codec driver structure initialization */ AUDIO_DrvTypeDef wm8994_drv = { wm8994_Init, wm8994_DeInit, wm8994_ReadID, wm8994_Play, wm8994_Pause, wm8994_Resume, wm8994_Stop, wm8994_SetFrequency, wm8994_SetVolume, wm8994_SetMute, wm8994_SetOutputMode, wm8994_Reset }; static uint32_t outputEnabled = 0; static uint32_t inputEnabled = 0; /** * @} */ /** @defgroup WM8994_Function_Prototypes * @{ */ static uint8_t CODEC_IO_Write(uint8_t Addr, uint16_t Reg, uint16_t Value); /** * @} */ /** @defgroup WM8994_Private_Functions * @{ */ /** * @brief Initializes the audio codec and the control interface. * @param DeviceAddr: Device address on communication Bus. * @param OutputInputDevice: can be OUTPUT_DEVICE_SPEAKER, OUTPUT_DEVICE_HEADPHONE, * OUTPUT_DEVICE_BOTH, OUTPUT_DEVICE_AUTO, INPUT_DEVICE_DIGITAL_MICROPHONE_1, * INPUT_DEVICE_DIGITAL_MICROPHONE_2, INPUT_DEVICE_DIGITAL_MIC1_MIC2, * INPUT_DEVICE_INPUT_LINE_1 or INPUT_DEVICE_INPUT_LINE_2. * @param Volume: Initial volume level (from 0 (Mute) to 100 (Max)) * @param AudioFreq: Audio Frequency * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Init(uint16_t DeviceAddr, uint16_t OutputInputDevice, uint8_t Volume, uint32_t AudioFreq) { uint32_t counter = 0; uint16_t output_device = OutputInputDevice & 0xFF; uint16_t input_device = OutputInputDevice & 0xFF00; uint16_t power_mgnt_reg_1 = 0; /* Initialize the Control interface of the Audio Codec */ AUDIO_IO_Init(); /* wm8994 Errata Work-Arounds */ counter += CODEC_IO_Write(DeviceAddr, 0x102, 0x0003); counter += CODEC_IO_Write(DeviceAddr, 0x817, 0x0000); counter += CODEC_IO_Write(DeviceAddr, 0x102, 0x0000); /* Enable VMID soft start (fast), Start-up Bias Current Enabled */ counter += CODEC_IO_Write(DeviceAddr, 0x39, 0x006C); /* Enable bias generator, Enable VMID */ if (input_device > 0) { counter += CODEC_IO_Write(DeviceAddr, 0x01, 0x0013); } else { counter += CODEC_IO_Write(DeviceAddr, 0x01, 0x0003); } /* Add Delay */ AUDIO_IO_Delay(50); /* Path Configurations for output */ if (output_device > 0) { outputEnabled = 1; switch (output_device) { case OUTPUT_DEVICE_SPEAKER: /* Enable DAC1 (Left), Enable DAC1 (Right), Disable DAC2 (Left), Disable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0C0C); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0000); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0000); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0002); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0002); break; case OUTPUT_DEVICE_HEADPHONE: /* Disable DAC1 (Left), Disable DAC1 (Right), Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0000); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0000); break; case OUTPUT_DEVICE_BOTH: if (input_device == INPUT_DEVICE_DIGITAL_MIC1_MIC2) { /* Enable DAC1 (Left), Enable DAC1 (Right), also Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303 | 0x0C0C); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path Enable the AIF1 Timeslot 1 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0003); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path Enable the AIF1 Timeslot 1 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0003); /* Enable the AIF1 Timeslot 0 (Left) to DAC 2 (Left) mixer path Enable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0003); /* Enable the AIF1 Timeslot 0 (Right) to DAC 2 (Right) mixer path Enable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0003); } else { /* Enable DAC1 (Left), Enable DAC1 (Right), also Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303 | 0x0C0C); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Enable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0002); /* Enable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0002); } break; case OUTPUT_DEVICE_AUTO : default: /* Disable DAC1 (Left), Disable DAC1 (Right), Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0000); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0000); break; } } else { outputEnabled = 0; } /* Path Configurations for input */ if (input_device > 0) { inputEnabled = 1; switch (input_device) { case INPUT_DEVICE_DIGITAL_MICROPHONE_2 : /* Enable AIF1ADC2 (Left), Enable AIF1ADC2 (Right) * Enable DMICDAT2 (Left), Enable DMICDAT2 (Right) * Enable Left ADC, Enable Right ADC */ counter += CODEC_IO_Write(DeviceAddr, 0x04, 0x0C30); /* Enable AIF1 DRC2 Signal Detect & DRC in AIF1ADC2 Left/Right Timeslot 1 */ counter += CODEC_IO_Write(DeviceAddr, 0x450, 0x00DB); /* Disable IN1L, IN1R, IN2L, IN2R, Enable Thermal sensor & shutdown */ counter += CODEC_IO_Write(DeviceAddr, 0x02, 0x6000); /* Enable the DMIC2(Left) to AIF1 Timeslot 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x608, 0x0002); /* Enable the DMIC2(Right) to AIF1 Timeslot 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x609, 0x0002); /* GPIO1 pin configuration GP1_DIR = output, GP1_FN = AIF1 DRC2 signal detect */ counter += CODEC_IO_Write(DeviceAddr, 0x700, 0x000E); break; case INPUT_DEVICE_INPUT_LINE_1 : /* IN1LN_TO_IN1L, IN1LP_TO_VMID, IN1RN_TO_IN1R, IN1RP_TO_VMID */ counter += CODEC_IO_Write(DeviceAddr, 0x28, 0x0011); /* Disable mute on IN1L_TO_MIXINL and +30dB on IN1L PGA output */ counter += CODEC_IO_Write(DeviceAddr, 0x29, 0x0035); /* Disable mute on IN1R_TO_MIXINL, Gain = +30dB */ counter += CODEC_IO_Write(DeviceAddr, 0x2A, 0x0035); /* Enable AIF1ADC1 (Left), Enable AIF1ADC1 (Right) * Enable Left ADC, Enable Right ADC */ counter += CODEC_IO_Write(DeviceAddr, 0x04, 0x0303); /* Enable AIF1 DRC1 Signal Detect & DRC in AIF1ADC1 Left/Right Timeslot 0 */ counter += CODEC_IO_Write(DeviceAddr, 0x440, 0x00DB); /* Enable IN1L and IN1R, Disable IN2L and IN2R, Enable Thermal sensor & shutdown */ counter += CODEC_IO_Write(DeviceAddr, 0x02, 0x6350); /* Enable the ADCL(Left) to AIF1 Timeslot 0 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x606, 0x0002); /* Enable the ADCR(Right) to AIF1 Timeslot 0 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x607, 0x0002); /* GPIO1 pin configuration GP1_DIR = output, GP1_FN = AIF1 DRC1 signal detect */ counter += CODEC_IO_Write(DeviceAddr, 0x700, 0x000D); break; case INPUT_DEVICE_DIGITAL_MICROPHONE_1 : /* Enable AIF1ADC1 (Left), Enable AIF1ADC1 (Right) * Enable DMICDAT1 (Left), Enable DMICDAT1 (Right) * Enable Left ADC, Enable Right ADC */ counter += CODEC_IO_Write(DeviceAddr, 0x04, 0x030C); /* Enable AIF1 DRC2 Signal Detect & DRC in AIF1ADC1 Left/Right Timeslot 0 */ counter += CODEC_IO_Write(DeviceAddr, 0x440, 0x00DB); /* Disable IN1L, IN1R, IN2L, IN2R, Enable Thermal sensor & shutdown */ counter += CODEC_IO_Write(DeviceAddr, 0x02, 0x6350); /* Enable the DMIC2(Left) to AIF1 Timeslot 0 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x606, 0x0002); /* Enable the DMIC2(Right) to AIF1 Timeslot 0 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x607, 0x0002); /* GPIO1 pin configuration GP1_DIR = output, GP1_FN = AIF1 DRC1 signal detect */ counter += CODEC_IO_Write(DeviceAddr, 0x700, 0x000D); break; case INPUT_DEVICE_DIGITAL_MIC1_MIC2 : /* Enable AIF1ADC1 (Left), Enable AIF1ADC1 (Right) * Enable DMICDAT1 (Left), Enable DMICDAT1 (Right) * Enable Left ADC, Enable Right ADC */ counter += CODEC_IO_Write(DeviceAddr, 0x04, 0x0F3C); /* Enable AIF1 DRC2 Signal Detect & DRC in AIF1ADC2 Left/Right Timeslot 1 */ counter += CODEC_IO_Write(DeviceAddr, 0x450, 0x00DB); /* Enable AIF1 DRC2 Signal Detect & DRC in AIF1ADC1 Left/Right Timeslot 0 */ counter += CODEC_IO_Write(DeviceAddr, 0x440, 0x00DB); /* Disable IN1L, IN1R, Enable IN2L, IN2R, Thermal sensor & shutdown */ counter += CODEC_IO_Write(DeviceAddr, 0x02, 0x63A0); /* Enable the DMIC2(Left) to AIF1 Timeslot 0 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x606, 0x0002); /* Enable the DMIC2(Right) to AIF1 Timeslot 0 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x607, 0x0002); /* Enable the DMIC2(Left) to AIF1 Timeslot 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x608, 0x0002); /* Enable the DMIC2(Right) to AIF1 Timeslot 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x609, 0x0002); /* GPIO1 pin configuration GP1_DIR = output, GP1_FN = AIF1 DRC1 signal detect */ counter += CODEC_IO_Write(DeviceAddr, 0x700, 0x000D); break; case INPUT_DEVICE_INPUT_LINE_2 : default: /* Actually, no other input devices supported */ counter++; break; } } else { inputEnabled = 0; } /* Clock Configurations */ switch (AudioFreq) { case AUDIO_FREQUENCY_8K: /* AIF1 Sample Rate = 8 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0003); break; case AUDIO_FREQUENCY_16K: /* AIF1 Sample Rate = 16 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0033); break; case AUDIO_FREQUENCY_32K: /* AIF1 Sample Rate = 32 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0063); break; case AUDIO_FREQUENCY_48K: /* AIF1 Sample Rate = 48 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0083); break; case AUDIO_FREQUENCY_96K: /* AIF1 Sample Rate = 96 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x00A3); break; case AUDIO_FREQUENCY_11K: /* AIF1 Sample Rate = 11.025 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0013); break; case AUDIO_FREQUENCY_22K: /* AIF1 Sample Rate = 22.050 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0043); break; case AUDIO_FREQUENCY_44K: /* AIF1 Sample Rate = 44.1 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0073); break; default: /* AIF1 Sample Rate = 48 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0083); break; } if(input_device == INPUT_DEVICE_DIGITAL_MIC1_MIC2) { /* AIF1 Word Length = 16-bits, AIF1 Format = DSP mode */ counter += CODEC_IO_Write(DeviceAddr, 0x300, 0x4018); } else { /* AIF1 Word Length = 16-bits, AIF1 Format = I2S (Default Register Value) */ counter += CODEC_IO_Write(DeviceAddr, 0x300, 0x4010); } /* slave mode */ counter += CODEC_IO_Write(DeviceAddr, 0x302, 0x0000); /* Enable the DSP processing clock for AIF1, Enable the core clock */ counter += CODEC_IO_Write(DeviceAddr, 0x208, 0x000A); /* Enable AIF1 Clock, AIF1 Clock Source = MCLK1 pin */ counter += CODEC_IO_Write(DeviceAddr, 0x200, 0x0001); if (output_device > 0) /* Audio output selected */ { /* Analog Output Configuration */ /* Enable SPKRVOL PGA, Enable SPKMIXR, Enable SPKLVOL PGA, Enable SPKMIXL */ counter += CODEC_IO_Write(DeviceAddr, 0x03, 0x0300); /* Left Speaker Mixer Volume = 0dB */ counter += CODEC_IO_Write(DeviceAddr, 0x22, 0x0000); /* Speaker output mode = Class D, Right Speaker Mixer Volume = 0dB ((0x23, 0x0100) = class AB)*/ counter += CODEC_IO_Write(DeviceAddr, 0x23, 0x0000); /* Unmute DAC2 (Left) to Left Speaker Mixer (SPKMIXL) path, Unmute DAC2 (Right) to Right Speaker Mixer (SPKMIXR) path */ counter += CODEC_IO_Write(DeviceAddr, 0x36, 0x0300); /* Enable bias generator, Enable VMID, Enable SPKOUTL, Enable SPKOUTR */ counter += CODEC_IO_Write(DeviceAddr, 0x01, 0x3003); /* Headphone/Speaker Enable */ if (input_device == INPUT_DEVICE_DIGITAL_MIC1_MIC2) { /* Enable Class W, Class W Envelope Tracking = AIF1 Timeslots 0 and 1 */ counter += CODEC_IO_Write(DeviceAddr, 0x51, 0x0205); } else { /* Enable Class W, Class W Envelope Tracking = AIF1 Timeslot 0 */ counter += CODEC_IO_Write(DeviceAddr, 0x51, 0x0005); } /* Enable bias generator, Enable VMID, Enable HPOUT1 (Left) and Enable HPOUT1 (Right) input stages */ /* idem for Speaker */ power_mgnt_reg_1 |= 0x0303 | 0x3003; counter += CODEC_IO_Write(DeviceAddr, 0x01, power_mgnt_reg_1); /* Enable HPOUT1 (Left) and HPOUT1 (Right) intermediate stages */ counter += CODEC_IO_Write(DeviceAddr, 0x60, 0x0022); /* Enable Charge Pump */ counter += CODEC_IO_Write(DeviceAddr, 0x4C, 0x9F25); /* Add Delay */ AUDIO_IO_Delay(15); /* Select DAC1 (Left) to Left Headphone Output PGA (HPOUT1LVOL) path */ counter += CODEC_IO_Write(DeviceAddr, 0x2D, 0x0001); /* Select DAC1 (Right) to Right Headphone Output PGA (HPOUT1RVOL) path */ counter += CODEC_IO_Write(DeviceAddr, 0x2E, 0x0001); /* Enable Left Output Mixer (MIXOUTL), Enable Right Output Mixer (MIXOUTR) */ /* idem for SPKOUTL and SPKOUTR */ counter += CODEC_IO_Write(DeviceAddr, 0x03, 0x0030 | 0x0300); /* Enable DC Servo and trigger start-up mode on left and right channels */ counter += CODEC_IO_Write(DeviceAddr, 0x54, 0x0033); /* Add Delay */ AUDIO_IO_Delay(250); /* Enable HPOUT1 (Left) and HPOUT1 (Right) intermediate and output stages. Remove clamps */ counter += CODEC_IO_Write(DeviceAddr, 0x60, 0x00EE); /* Unmutes */ /* Unmute DAC 1 (Left) */ counter += CODEC_IO_Write(DeviceAddr, 0x610, 0x00C0); /* Unmute DAC 1 (Right) */ counter += CODEC_IO_Write(DeviceAddr, 0x611, 0x00C0); /* Unmute the AIF1 Timeslot 0 DAC path */ counter += CODEC_IO_Write(DeviceAddr, 0x420, 0x0000); /* Unmute DAC 2 (Left) */ counter += CODEC_IO_Write(DeviceAddr, 0x612, 0x00C0); /* Unmute DAC 2 (Right) */ counter += CODEC_IO_Write(DeviceAddr, 0x613, 0x00C0); /* Unmute the AIF1 Timeslot 1 DAC2 path */ counter += CODEC_IO_Write(DeviceAddr, 0x422, 0x0000); /* Volume Control */ wm8994_SetVolume(DeviceAddr, Volume); } if (input_device > 0) /* Audio input selected */ { if ((input_device == INPUT_DEVICE_DIGITAL_MICROPHONE_1) || (input_device == INPUT_DEVICE_DIGITAL_MICROPHONE_2)) { /* Enable Microphone bias 1 generator, Enable VMID */ power_mgnt_reg_1 |= 0x0013; counter += CODEC_IO_Write(DeviceAddr, 0x01, power_mgnt_reg_1); /* ADC oversample enable */ counter += CODEC_IO_Write(DeviceAddr, 0x620, 0x0002); /* AIF ADC2 HPF enable, HPF cut = voice mode 1 fc=127Hz at fs=8kHz */ counter += CODEC_IO_Write(DeviceAddr, 0x411, 0x3800); } else if(input_device == INPUT_DEVICE_DIGITAL_MIC1_MIC2) { /* Enable Microphone bias 1 generator, Enable VMID */ power_mgnt_reg_1 |= 0x0013; counter += CODEC_IO_Write(DeviceAddr, 0x01, power_mgnt_reg_1); /* ADC oversample enable */ counter += CODEC_IO_Write(DeviceAddr, 0x620, 0x0002); /* AIF ADC1 HPF enable, HPF cut = voice mode 1 fc=127Hz at fs=8kHz */ counter += CODEC_IO_Write(DeviceAddr, 0x410, 0x1800); /* AIF ADC2 HPF enable, HPF cut = voice mode 1 fc=127Hz at fs=8kHz */ counter += CODEC_IO_Write(DeviceAddr, 0x411, 0x1800); } else if ((input_device == INPUT_DEVICE_INPUT_LINE_1) || (input_device == INPUT_DEVICE_INPUT_LINE_2)) { /* Disable mute on IN1L, IN1L Volume = +0dB */ counter += CODEC_IO_Write(DeviceAddr, 0x18, 0x000B); /* Disable mute on IN1R, IN1R Volume = +0dB */ counter += CODEC_IO_Write(DeviceAddr, 0x1A, 0x000B); /* AIF ADC1 HPF enable, HPF cut = hifi mode fc=4Hz at fs=48kHz */ counter += CODEC_IO_Write(DeviceAddr, 0x410, 0x1800); } /* Volume Control */ wm8994_SetVolume(DeviceAddr, Volume); } /* Return communication control value */ return counter; } /** * @brief Deinitializes the audio codec. * @param None * @retval None */ void wm8994_DeInit(void) { /* Deinitialize Audio Codec interface */ AUDIO_IO_DeInit(); } /** * @brief Get the WM8994 ID. * @param DeviceAddr: Device address on communication Bus. * @retval The WM8994 ID */ uint32_t wm8994_ReadID(uint16_t DeviceAddr) { /* Initialize the Control interface of the Audio Codec */ AUDIO_IO_Init(); return ((uint32_t)AUDIO_IO_Read(DeviceAddr, WM8994_CHIPID_ADDR)); } /** * @brief Start the audio Codec play feature. * @note For this codec no Play options are required. * @param DeviceAddr: Device address on communication Bus. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Play(uint16_t DeviceAddr, uint16_t* pBuffer, uint16_t Size) { uint32_t counter = 0; /* Resumes the audio file playing */ /* Unmute the output first */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_OFF); return counter; } /** * @brief Pauses playing on the audio codec. * @param DeviceAddr: Device address on communication Bus. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Pause(uint16_t DeviceAddr) { uint32_t counter = 0; /* Pause the audio file playing */ /* Mute the output first */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_ON); /* Put the Codec in Power save mode */ counter += CODEC_IO_Write(DeviceAddr, 0x02, 0x01); return counter; } /** * @brief Resumes playing on the audio codec. * @param DeviceAddr: Device address on communication Bus. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Resume(uint16_t DeviceAddr) { uint32_t counter = 0; /* Resumes the audio file playing */ /* Unmute the output first */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_OFF); return counter; } /** * @brief Stops audio Codec playing. It powers down the codec. * @param DeviceAddr: Device address on communication Bus. * @param CodecPdwnMode: selects the power down mode. * - CODEC_PDWN_SW: only mutes the audio codec. When resuming from this * mode the codec keeps the previous initialization * (no need to re-Initialize the codec registers). * - CODEC_PDWN_HW: Physically power down the codec. When resuming from this * mode, the codec is set to default configuration * (user should re-Initialize the codec in order to * play again the audio stream). * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Stop(uint16_t DeviceAddr, uint32_t CodecPdwnMode) { uint32_t counter = 0; if (outputEnabled != 0) { /* Mute the output first */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_ON); if (CodecPdwnMode == CODEC_PDWN_SW) { /* Only output mute required*/ } else /* CODEC_PDWN_HW */ { /* Mute the AIF1 Timeslot 0 DAC1 path */ counter += CODEC_IO_Write(DeviceAddr, 0x420, 0x0200); /* Mute the AIF1 Timeslot 1 DAC2 path */ counter += CODEC_IO_Write(DeviceAddr, 0x422, 0x0200); /* Disable DAC1L_TO_HPOUT1L */ counter += CODEC_IO_Write(DeviceAddr, 0x2D, 0x0000); /* Disable DAC1R_TO_HPOUT1R */ counter += CODEC_IO_Write(DeviceAddr, 0x2E, 0x0000); /* Disable DAC1 and DAC2 */ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0000); /* Reset Codec by writing in 0x0000 address register */ counter += CODEC_IO_Write(DeviceAddr, 0x0000, 0x0000); outputEnabled = 0; } } return counter; } /** * @brief Sets higher or lower the codec volume level. * @param DeviceAddr: Device address on communication Bus. * @param Volume: a byte value from 0 to 255 (refer to codec registers * description for more details). * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_SetVolume(uint16_t DeviceAddr, uint8_t Volume) { uint32_t counter = 0; uint8_t convertedvol = VOLUME_CONVERT(Volume); /* Output volume */ if (outputEnabled != 0) { if(convertedvol > 0x3E) { /* Unmute audio codec */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_OFF); /* Left Headphone Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x1C, 0x3F | 0x140); /* Right Headphone Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x1D, 0x3F | 0x140); /* Left Speaker Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x26, 0x3F | 0x140); /* Right Speaker Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x27, 0x3F | 0x140); } else if (Volume == 0) { /* Mute audio codec */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_ON); } else { /* Unmute audio codec */ counter += wm8994_SetMute(DeviceAddr, AUDIO_MUTE_OFF); /* Left Headphone Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x1C, convertedvol | 0x140); /* Right Headphone Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x1D, convertedvol | 0x140); /* Left Speaker Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x26, convertedvol | 0x140); /* Right Speaker Volume */ counter += CODEC_IO_Write(DeviceAddr, 0x27, convertedvol | 0x140); } } /* Input volume */ if (inputEnabled != 0) { convertedvol = VOLUME_IN_CONVERT(Volume); /* Left AIF1 ADC1 volume */ counter += CODEC_IO_Write(DeviceAddr, 0x400, convertedvol | 0x100); /* Right AIF1 ADC1 volume */ counter += CODEC_IO_Write(DeviceAddr, 0x401, convertedvol | 0x100); /* Left AIF1 ADC2 volume */ counter += CODEC_IO_Write(DeviceAddr, 0x404, convertedvol | 0x100); /* Right AIF1 ADC2 volume */ counter += CODEC_IO_Write(DeviceAddr, 0x405, convertedvol | 0x100); } return counter; } /** * @brief Enables or disables the mute feature on the audio codec. * @param DeviceAddr: Device address on communication Bus. * @param Cmd: AUDIO_MUTE_ON to enable the mute or AUDIO_MUTE_OFF to disable the * mute mode. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_SetMute(uint16_t DeviceAddr, uint32_t Cmd) { uint32_t counter = 0; if (outputEnabled != 0) { /* Set the Mute mode */ if(Cmd == AUDIO_MUTE_ON) { /* Soft Mute the AIF1 Timeslot 0 DAC1 path L&R */ counter += CODEC_IO_Write(DeviceAddr, 0x420, 0x0200); /* Soft Mute the AIF1 Timeslot 1 DAC2 path L&R */ counter += CODEC_IO_Write(DeviceAddr, 0x422, 0x0200); } else /* AUDIO_MUTE_OFF Disable the Mute */ { /* Unmute the AIF1 Timeslot 0 DAC1 path L&R */ counter += CODEC_IO_Write(DeviceAddr, 0x420, 0x0000); /* Unmute the AIF1 Timeslot 1 DAC2 path L&R */ counter += CODEC_IO_Write(DeviceAddr, 0x422, 0x0000); } } return counter; } /** * @brief Switch dynamically (while audio file is played) the output target * (speaker or headphone). * @param DeviceAddr: Device address on communication Bus. * @param Output: specifies the audio output target: OUTPUT_DEVICE_SPEAKER, * OUTPUT_DEVICE_HEADPHONE, OUTPUT_DEVICE_BOTH or OUTPUT_DEVICE_AUTO * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_SetOutputMode(uint16_t DeviceAddr, uint8_t Output) { uint32_t counter = 0; switch (Output) { case OUTPUT_DEVICE_SPEAKER: /* Enable DAC1 (Left), Enable DAC1 (Right), Disable DAC2 (Left), Disable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0C0C); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0000); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0000); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0002); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0002); break; case OUTPUT_DEVICE_HEADPHONE: /* Disable DAC1 (Left), Disable DAC1 (Right), Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0000); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0000); break; case OUTPUT_DEVICE_BOTH: /* Enable DAC1 (Left), Enable DAC1 (Right), also Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303 | 0x0C0C); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Enable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0002); /* Enable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0002); break; default: /* Disable DAC1 (Left), Disable DAC1 (Right), Enable DAC2 (Left), Enable DAC2 (Right)*/ counter += CODEC_IO_Write(DeviceAddr, 0x05, 0x0303); /* Enable the AIF1 Timeslot 0 (Left) to DAC 1 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x601, 0x0001); /* Enable the AIF1 Timeslot 0 (Right) to DAC 1 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x602, 0x0001); /* Disable the AIF1 Timeslot 1 (Left) to DAC 2 (Left) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x604, 0x0000); /* Disable the AIF1 Timeslot 1 (Right) to DAC 2 (Right) mixer path */ counter += CODEC_IO_Write(DeviceAddr, 0x605, 0x0000); break; } return counter; } /** * @brief Sets new frequency. * @param DeviceAddr: Device address on communication Bus. * @param AudioFreq: Audio frequency used to play the audio stream. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_SetFrequency(uint16_t DeviceAddr, uint32_t AudioFreq) { uint32_t counter = 0; /* Clock Configurations */ switch (AudioFreq) { case AUDIO_FREQUENCY_8K: /* AIF1 Sample Rate = 8 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0003); break; case AUDIO_FREQUENCY_16K: /* AIF1 Sample Rate = 16 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0033); break; case AUDIO_FREQUENCY_48K: /* AIF1 Sample Rate = 48 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0083); break; case AUDIO_FREQUENCY_96K: /* AIF1 Sample Rate = 96 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x00A3); break; case AUDIO_FREQUENCY_11K: /* AIF1 Sample Rate = 11.025 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0013); break; case AUDIO_FREQUENCY_22K: /* AIF1 Sample Rate = 22.050 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0043); break; case AUDIO_FREQUENCY_44K: /* AIF1 Sample Rate = 44.1 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0073); break; default: /* AIF1 Sample Rate = 48 (KHz), ratio=256 */ counter += CODEC_IO_Write(DeviceAddr, 0x210, 0x0083); break; } return counter; } /** * @brief Resets wm8994 registers. * @param DeviceAddr: Device address on communication Bus. * @retval 0 if correct communication, else wrong communication */ uint32_t wm8994_Reset(uint16_t DeviceAddr) { uint32_t counter = 0; /* Reset Codec by writing in 0x0000 address register */ counter = CODEC_IO_Write(DeviceAddr, 0x0000, 0x0000); outputEnabled = 0; inputEnabled=0; return counter; } /** * @brief Writes/Read a single data. * @param Addr: I2C address * @param Reg: Reg address * @param Value: Data to be written * @retval None */ static uint8_t CODEC_IO_Write(uint8_t Addr, uint16_t Reg, uint16_t Value) { uint32_t result = 0; AUDIO_IO_Write(Addr, Reg, Value); #ifdef VERIFY_WRITTENDATA /* Verify that the data has been correctly written */ result = (AUDIO_IO_Read(Addr, Reg) == Value)? 0:1; #endif /* VERIFY_WRITTENDATA */ return result; } /** * @} */ /** * @} */ /** * @} */ /** * @} */ /************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/