Commit 2731c3a8 authored by Dean Camera's avatar Dean Camera
Browse files

Added new callback to the Audio Class driver to allow for endpoint control...

Added new callback to the Audio Class driver to allow for endpoint control manipulations such as data sample rates.

Modified the Class Driver AudioInput and AudioOutput demos to support multiple sample rates.

Fixed KeyboardHost and KeyboardHostWithParser demos displaying incorrect values when numerical keys were pressed.

Fix broken LowLevel audio demo descriptors.

Minor documentation fixes.
parent c2135f27
......@@ -51,6 +51,9 @@ USB_ClassInfo_Audio_Device_t Microphone_Audio_Interface =
},
};
/** Current audio sampling frequency of the streaming audio endpoint. */
uint32_t CurrentAudioSampleFrequency = 48000;
/** Main program entry point. This routine contains the overall program flow, including initial
* setup of all components and the main program loop.
......@@ -133,7 +136,7 @@ void EVENT_USB_Device_Connect(void)
/* Sample reload timer initialization */
TIMSK0 = (1 << OCIE0A);
OCR0A = ((F_CPU / 8 / AUDIO_SAMPLE_FREQUENCY) - 1);
OCR0A = ((F_CPU / 8 / CurrentAudioSampleFrequency) - 1);
TCCR0A = (1 << WGM01); // CTC mode
TCCR0B = (1 << CS01); // Fcpu/8 speed
}
......@@ -163,3 +166,72 @@ void EVENT_USB_Device_ControlRequest(void)
Audio_Device_ProcessControlRequest(&Microphone_Audio_Interface);
}
/** Audio class driver callback for the setting and retrieval of streaming endpoint properties. This callback must be implemented
* in the user application to handle property manipulations on streaming audio endpoints.
*
* When the DataLength parameter is NULL, this callback should only indicate whether the specified operation is valid for
* the given endpoint index, and should return as fast as possible. When non-NULL, this value may be altered for GET operations
* to indicate the size of the retreived data.
*
* \note The length of the retrieved data stored into the Data buffer on GET operations should not exceed the initial value
* of the \c DataLength parameter.
*
* \param[in,out] AudioInterfaceInfo Pointer to a structure containing an Audio Class configuration and state.
* \param[in] EndpointProperty Property of the endpoint to get or set, a value from Audio_ClassRequests_t.
* \param[in] EndpointIndex Index of the streaming endpoint whose property is being referenced.
* \param[in] EndpointControl Parameter of the endpoint to get or set, a value from Audio_EndpointControls_t.
* \param[in,out] DataLength For SET operations, the length of the parameter data to set. For GET operations, the maximum
* length of the retrieved data. When NULL, the function should return whether the given property
* and parameter is valid for the requested endpoint without reading or modifying the Data buffer.
* \param[in,out] Data Pointer to a location where the parameter data is stored for SET operations, or where
* the retrieved data is to be stored for GET operations.
*
* \return Boolean true if the property get/set was successful, false otherwise
*/
bool CALLBACK_Audio_GetSetEndpointProperty(USB_ClassInfo_Audio_Device_t* const AudioInterfaceInfo,
const uint8_t EndpointProperty,
const uint8_t EndpointIndex,
const uint8_t EndpointControl,
uint16_t* const DataLength,
uint8_t* Data)
{
/* Check the requested endpoint to see if a supported endpoint is being manipulated */
if (EndpointIndex == Microphone_Audio_Interface.Config.DataINEndpointNumber)
{
/* Check the requested control to see if a supported control is being manipulated */
if (EndpointControl == AUDIO_EPCONTROL_SamplingFreq)
{
/* Check the requested property to see if a supported property is being manipulated */
if (EndpointProperty == AUDIO_REQ_SetCurrent)
{
/* Check if we are just testing for a valid property, or actually adjusting it */
if (DataLength != NULL)
{
/* Set the new sampling frequency to the value given by the host */
CurrentAudioSampleFrequency = (((uint32_t)Data[2] << 16) | ((uint32_t)Data[1] << 8) | (uint32_t)Data[0]);
/* Adjust sample reload timer to the new frequency */
OCR0A = ((F_CPU / 8 / CurrentAudioSampleFrequency) - 1);
}
return true;
}
else if (EndpointProperty == AUDIO_REQ_GetCurrent)
{
/* Check if we are just testing for a valid property, or actually reading it */
if (DataLength != NULL)
{
*DataLength = 3;
Data[2] = (CurrentAudioSampleFrequency >> 16);
Data[1] = (CurrentAudioSampleFrequency >> 8);
Data[0] = (CurrentAudioSampleFrequency & 0xFF);
}
return true;
}
}
}
return false;
}
......@@ -54,7 +54,7 @@ const USB_Descriptor_Device_t PROGMEM DeviceDescriptor =
.Endpoint0Size = FIXED_CONTROL_ENDPOINT_SIZE,
.VendorID = 0x03EB,
.ProductID = 0x2047,
.ProductID = 0x206B,
.ReleaseNumber = VERSION_BCD(00.01),
.ManufacturerStrIndex = 0x01,
......@@ -191,7 +191,9 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Audio_AudioFormat =
{
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t), .Type = DTYPE_CSInterface},
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t) +
sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates),
.Type = DTYPE_CSInterface},
.Subtype = AUDIO_DSUBTYPE_CSInterface_FormatType,
.FormatType = 0x01,
......@@ -199,12 +201,17 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.SubFrameSize = 0x02,
.BitResolution = 16,
.TotalDiscreteSampleRates = 1,
.TotalDiscreteSampleRates = (sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates) / sizeof(USB_Audio_SampleFreq_t))
},
.Audio_AudioFormatSampleRates =
{
AUDIO_SAMPLE_FREQ(AUDIO_SAMPLE_FREQUENCY)
AUDIO_SAMPLE_FREQ(8000),
AUDIO_SAMPLE_FREQ(11025),
AUDIO_SAMPLE_FREQ(22050),
AUDIO_SAMPLE_FREQ(44100),
AUDIO_SAMPLE_FREQ(48000),
},
.Audio_StreamEndpoint =
......@@ -228,7 +235,7 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Header = {.Size = sizeof(USB_Audio_Descriptor_StreamEndpoint_Spc_t), .Type = DTYPE_CSEndpoint},
.Subtype = AUDIO_DSUBTYPE_CSEndpoint_General,
.Attributes = AUDIO_EP_ACCEPTS_SMALL_PACKETS,
.Attributes = (AUDIO_EP_ACCEPTS_SMALL_PACKETS | AUDIO_EP_SAMPLE_FREQ_CONTROL),
.LockDelayUnits = 0x00,
.LockDelay = 0x0000
......
......@@ -51,9 +51,6 @@
*/
#define AUDIO_STREAM_EPSIZE ENDPOINT_MAX_SIZE(AUDIO_STREAM_EPNUM)
/** Sample frequency of the data being transmitted through the streaming endpoint. */
#define AUDIO_SAMPLE_FREQUENCY 48000
/* Type Defines: */
/** Type define for the device configuration descriptor structure. This must be defined in the
* application code, as the configuration descriptor contains several sub-descriptors which
......@@ -70,7 +67,7 @@
USB_Descriptor_Interface_t Audio_StreamInterface_Alt1;
USB_Audio_Descriptor_Interface_AS_t Audio_StreamInterface_SPC;
USB_Audio_Descriptor_Format_t Audio_AudioFormat;
USB_Audio_SampleFreq_t Audio_AudioFormatSampleRates[1];
USB_Audio_SampleFreq_t Audio_AudioFormatSampleRates[5];
USB_Audio_Descriptor_StreamEndpoint_Std_t Audio_StreamEndpoint;
USB_Audio_Descriptor_StreamEndpoint_Spc_t Audio_StreamEndpoint_SPC;
} USB_Descriptor_Configuration_t;
......
......@@ -51,6 +51,9 @@ USB_ClassInfo_Audio_Device_t Speaker_Audio_Interface =
},
};
/** Current audio sampling frequency of the streaming audio endpoint. */
uint32_t CurrentAudioSampleFrequency = 48000;
/** Main program entry point. This routine contains the overall program flow, including initial
* setup of all components and the main program loop.
......@@ -135,7 +138,7 @@ void EVENT_USB_Device_Connect(void)
/* Sample reload timer initialization */
TIMSK0 = (1 << OCIE0A);
OCR0A = ((F_CPU / 8 / AUDIO_SAMPLE_FREQUENCY) - 1);
OCR0A = ((F_CPU / 8 / CurrentAudioSampleFrequency) - 1);
TCCR0A = (1 << WGM01); // CTC mode
TCCR0B = (1 << CS01); // Fcpu/8 speed
......@@ -199,3 +202,72 @@ void EVENT_USB_Device_ControlRequest(void)
Audio_Device_ProcessControlRequest(&Speaker_Audio_Interface);
}
/** Audio class driver callback for the setting and retrieval of streaming endpoint properties. This callback must be implemented
* in the user application to handle property manipulations on streaming audio endpoints.
*
* When the DataLength parameter is NULL, this callback should only indicate whether the specified operation is valid for
* the given endpoint index, and should return as fast as possible. When non-NULL, this value may be altered for GET operations
* to indicate the size of the retreived data.
*
* \note The length of the retrieved data stored into the Data buffer on GET operations should not exceed the initial value
* of the \c DataLength parameter.
*
* \param[in,out] AudioInterfaceInfo Pointer to a structure containing an Audio Class configuration and state.
* \param[in] EndpointProperty Property of the endpoint to get or set, a value from Audio_ClassRequests_t.
* \param[in] EndpointIndex Index of the streaming endpoint whose property is being referenced.
* \param[in] EndpointControl Parameter of the endpoint to get or set, a value from Audio_EndpointControls_t.
* \param[in,out] DataLength For SET operations, the length of the parameter data to set. For GET operations, the maximum
* length of the retrieved data. When NULL, the function should return whether the given property
* and parameter is valid for the requested endpoint without reading or modifying the Data buffer.
* \param[in,out] Data Pointer to a location where the parameter data is stored for SET operations, or where
* the retrieved data is to be stored for GET operations.
*
* \return Boolean true if the property get/set was successful, false otherwise
*/
bool CALLBACK_Audio_GetSetEndpointProperty(USB_ClassInfo_Audio_Device_t* const AudioInterfaceInfo,
const uint8_t EndpointProperty,
const uint8_t EndpointIndex,
const uint8_t EndpointControl,
uint16_t* const DataLength,
uint8_t* Data)
{
/* Check the requested endpoint to see if a supported endpoint is being manipulated */
if (EndpointIndex == Speaker_Audio_Interface.Config.DataOUTEndpointNumber)
{
/* Check the requested control to see if a supported control is being manipulated */
if (EndpointControl == AUDIO_EPCONTROL_SamplingFreq)
{
/* Check the requested property to see if a supported property is being manipulated */
if (EndpointProperty == AUDIO_REQ_SetCurrent)
{
/* Check if we are just testing for a valid property, or actually adjusting it */
if (DataLength != NULL)
{
/* Set the new sampling frequency to the value given by the host */
CurrentAudioSampleFrequency = (((uint32_t)Data[2] << 16) | ((uint32_t)Data[1] << 8) | (uint32_t)Data[0]);
/* Adjust sample reload timer to the new frequency */
OCR0A = ((F_CPU / 8 / CurrentAudioSampleFrequency) - 1);
}
return true;
}
else if (EndpointProperty == AUDIO_REQ_GetCurrent)
{
/* Check if we are just testing for a valid property, or actually reading it */
if (DataLength != NULL)
{
*DataLength = 3;
Data[2] = (CurrentAudioSampleFrequency >> 16);
Data[1] = (CurrentAudioSampleFrequency >> 8);
Data[0] = (CurrentAudioSampleFrequency & 0xFF);
}
return true;
}
}
}
return false;
}
......@@ -54,7 +54,7 @@ const USB_Descriptor_Device_t PROGMEM DeviceDescriptor =
.Endpoint0Size = FIXED_CONTROL_ENDPOINT_SIZE,
.VendorID = 0x03EB,
.ProductID = 0x2046,
.ProductID = 0x206C,
.ReleaseNumber = VERSION_BCD(00.01),
.ManufacturerStrIndex = 0x01,
......@@ -191,7 +191,9 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Audio_AudioFormat =
{
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t), .Type = DTYPE_CSInterface},
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t) +
sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates),
.Type = DTYPE_CSInterface},
.Subtype = AUDIO_DSUBTYPE_CSInterface_FormatType,
.FormatType = 0x01,
......@@ -200,12 +202,16 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.SubFrameSize = 0x02,
.BitResolution = 16,
.TotalDiscreteSampleRates = 1,
.TotalDiscreteSampleRates = (sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates) / sizeof(USB_Audio_SampleFreq_t)),
},
.Audio_AudioFormatSampleRates =
{
AUDIO_SAMPLE_FREQ(AUDIO_SAMPLE_FREQUENCY)
AUDIO_SAMPLE_FREQ(8000),
AUDIO_SAMPLE_FREQ(11025),
AUDIO_SAMPLE_FREQ(22050),
AUDIO_SAMPLE_FREQ(44100),
AUDIO_SAMPLE_FREQ(48000),
},
.Audio_StreamEndpoint =
......@@ -229,7 +235,7 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Header = {.Size = sizeof(USB_Audio_Descriptor_StreamEndpoint_Spc_t), .Type = DTYPE_CSEndpoint},
.Subtype = AUDIO_DSUBTYPE_CSEndpoint_General,
.Attributes = AUDIO_EP_ACCEPTS_SMALL_PACKETS,
.Attributes = (AUDIO_EP_ACCEPTS_SMALL_PACKETS | AUDIO_EP_SAMPLE_FREQ_CONTROL),
.LockDelayUnits = 0x00,
.LockDelay = 0x0000
......
......@@ -51,9 +51,6 @@
*/
#define AUDIO_STREAM_EPSIZE ENDPOINT_MAX_SIZE(AUDIO_STREAM_EPNUM)
/** Sample frequency of the data being transmitted through the streaming endpoint. */
#define AUDIO_SAMPLE_FREQUENCY 48000
/* Type Defines: */
/** Type define for the device configuration descriptor structure. This must be defined in the
* application code, as the configuration descriptor contains several sub-descriptors which
......@@ -70,7 +67,7 @@
USB_Descriptor_Interface_t Audio_StreamInterface_Alt1;
USB_Audio_Descriptor_Interface_AS_t Audio_StreamInterface_SPC;
USB_Audio_Descriptor_Format_t Audio_AudioFormat;
USB_Audio_SampleFreq_t Audio_AudioFormatSampleRates[1];
USB_Audio_SampleFreq_t Audio_AudioFormatSampleRates[5];
USB_Audio_Descriptor_StreamEndpoint_Std_t Audio_StreamEndpoint;
USB_Audio_Descriptor_StreamEndpoint_Spc_t Audio_StreamEndpoint_SPC;
} USB_Descriptor_Configuration_t;
......
......@@ -191,7 +191,9 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Audio_AudioFormat =
{
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t), .Type = DTYPE_CSInterface},
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t) +
sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates),
.Type = DTYPE_CSInterface},
.Subtype = AUDIO_DSUBTYPE_CSInterface_FormatType,
.FormatType = 0x01,
......
......@@ -191,7 +191,9 @@ const USB_Descriptor_Configuration_t PROGMEM ConfigurationDescriptor =
.Audio_AudioFormat =
{
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t), .Type = DTYPE_CSInterface},
.Header = {.Size = sizeof(USB_Audio_Descriptor_Format_t) +
sizeof(ConfigurationDescriptor.Audio_AudioFormatSampleRates),
.Type = DTYPE_CSInterface},
.Subtype = AUDIO_DSUBTYPE_CSInterface_FormatType,
.FormatType = 0x01,
......
......@@ -137,9 +137,13 @@ int main(void)
PressedKey = (KeyCode - HID_KEYBOARD_SC_A) + 'A';
}
else if ((KeyCode >= HID_KEYBOARD_SC_1_AND_EXCLAMATION) &
(KeyCode <= HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
(KeyCode < HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
{
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '0';
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '1';
}
else if (KeyCode == HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS)
{
PressedKey = '0';
}
else if (KeyCode == HID_KEYBOARD_SC_SPACE)
{
......
......@@ -157,9 +157,13 @@ int main(void)
PressedKey = (KeyCode - HID_KEYBOARD_SC_A) + 'A';
}
else if ((KeyCode >= HID_KEYBOARD_SC_1_AND_EXCLAMATION) &
(KeyCode <= HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
(KeyCode < HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
{
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '0';
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '1';
}
else if (KeyCode == HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS)
{
PressedKey = '0';
}
else if (KeyCode == HID_KEYBOARD_SC_SPACE)
{
......
......@@ -173,9 +173,13 @@ void ReadNextReport(void)
PressedKey = (KeyCode - HID_KEYBOARD_SC_A) + 'A';
}
else if ((KeyCode >= HID_KEYBOARD_SC_1_AND_EXCLAMATION) &
(KeyCode <= HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
(KeyCode < HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
{
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '0';
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '1';
}
else if (KeyCode == HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS)
{
PressedKey = '0';
}
else if (KeyCode == HID_KEYBOARD_SC_SPACE)
{
......
......@@ -287,9 +287,13 @@ void ProcessKeyboardReport(uint8_t* KeyboardReport)
PressedKey = (KeyCode - HID_KEYBOARD_SC_A) + 'A';
}
else if ((KeyCode >= HID_KEYBOARD_SC_1_AND_EXCLAMATION) &
(KeyCode <= HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
(KeyCode < HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS))
{
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '0';
PressedKey = (KeyCode - HID_KEYBOARD_SC_1_AND_EXCLAMATION) + '1';
}
else if (KeyCode == HID_KEYBOARD_SC_0_AND_CLOSING_PARENTHESIS)
{
PressedKey = '0';
}
else if (KeyCode == HID_KEYBOARD_SC_SPACE)
{
......
......@@ -197,7 +197,7 @@
*
* \param[in] freq Required audio sampling frequency in HZ
*/
#define AUDIO_SAMPLE_FREQ(freq) {.Byte1 = ((uint32_t)freq & 0x0000FF), .Byte2 = (((uint32_t)freq >> 8) & 0xFF), .Byte3 = (((uint32_t)freq >> 16) & 0xFF)}
#define AUDIO_SAMPLE_FREQ(freq) {.Byte1 = ((uint32_t)freq & 0xFF), .Byte2 = (((uint32_t)freq >> 8) & 0xFF), .Byte3 = (((uint32_t)freq >> 16) & 0xFF)}
/** Mask for the attributes parameter of an Audio class-specific Endpoint descriptor, indicating that the endpoint
* accepts only filled endpoint packets of audio samples.
......@@ -208,6 +208,16 @@
* will accept partially filled endpoint packets of audio samples.
*/
#define AUDIO_EP_ACCEPTS_SMALL_PACKETS (0 << 7)
/** Mask for the attributes parameter of an Audio class-specific Endpoint descriptor, indicating that the endpoint
* allows for sampling frequency adjustments to be made via control requests directed at the endpoint.
*/
#define AUDIO_EP_SAMPLE_FREQ_CONTROL (1 << 0)
/** Mask for the attributes parameter of an Audio class-specific Endpoint descriptor, indicating that the endpoint
* allows for pitch adjustments to be made via control requests directed at the endpoint.
*/
#define AUDIO_EP_PITCH_CONTROL (1 << 1)
/* Enums: */
/** Enum for possible Class, Subclass and Protocol values of device and interface descriptors relating to the Audio
......@@ -277,6 +287,15 @@
AUDIO_REQ_GetMemory = 0x85, /**< Audio class-specific request to get the memory value of a parameter within the device. */
AUDIO_REQ_GetStatus = 0xFF, /**< Audio class-specific request to get the device status. */
};
/** Enum for Audio class specific Endpoint control modifiers which can be set and retrieved by a USB host, if the corresponding
* endpoint control is indicated to be supported in the Endpoint's Audio-class specific endpoint descriptor.
*/
enum Audio_EndpointControls_t
{
AUDIO_EPCONTROL_SamplingFreq = 0x01, /**< Sampling frequency adjustment of the endpoint. */
AUDIO_EPCONTROL_Pitch = 0x02, /**< Pitch adjustment of the endpoint. */
};
/* Type Defines: */
/** \brief Audio class-specific Input Terminal Descriptor (LUFA naming conventions).
......@@ -538,18 +557,6 @@
uint16_t wFormatTag; /**< Format of the audio stream, see Audio Device Formats specification. */
} ATTR_PACKED USB_Audio_StdDescriptor_Interface_AS_t;
/** \brief 24-Bit Audio Frequency Structure.
*
* Type define for a 24bit audio sample frequency structure. GCC does not contain a built in 24bit datatype,
* this this structure is used to build up the value instead. Fill this structure with the \ref AUDIO_SAMPLE_FREQ() macro.
*/
typedef struct
{
uint8_t Byte1; /**< Lowest 8 bits of the 24-bit value. */
uint8_t Byte2; /**< Middle 8 bits of the 24-bit value. */
uint8_t Byte3; /**< Upper 8 bits of the 24-bit value. */
} ATTR_PACKED USB_Audio_SampleFreq_t;
/** \brief Audio class-specific Format Descriptor (LUFA naming conventions).
*
* Type define for an Audio class-specific audio format descriptor. This is used to give the host full details
......@@ -581,6 +588,18 @@
*/
} ATTR_PACKED USB_Audio_Descriptor_Format_t;
/** \brief 24-Bit Audio Frequency Structure.
*
* Type define for a 24bit audio sample frequency structure. As GCC does not contain a built in 24-bit datatype,
* this this structure is used to build up the value instead. Fill this structure with the \ref AUDIO_SAMPLE_FREQ() macro.
*/
typedef struct
{
uint8_t Byte1; /**< Lowest 8 bits of the 24-bit value. */
uint8_t Byte2; /**< Middle 8 bits of the 24-bit value. */
uint8_t Byte3; /**< Upper 8 bits of the 24-bit value. */
} ATTR_PACKED USB_Audio_SampleFreq_t;
/** \brief Audio class-specific Format Descriptor (USB-IF naming conventions).
*
* Type define for an Audio class-specific audio format descriptor. This is used to give the host full details
......
......@@ -45,6 +45,22 @@ void Audio_Device_ProcessControlRequest(USB_ClassInfo_Audio_Device_t* const Audi
if (USB_ControlRequest.wIndex != AudioInterfaceInfo->Config.StreamingInterfaceNumber)
return;
if ((USB_ControlRequest.bmRequestType & CONTROL_REQTYPE_RECIPIENT) == REQREC_INTERFACE)
{
if (USB_ControlRequest.wIndex != AudioInterfaceInfo->Config.StreamingInterfaceNumber)
return;
}
else if ((USB_ControlRequest.bmRequestType & CONTROL_REQTYPE_RECIPIENT) == REQREC_ENDPOINT)
{
if (!((AudioInterfaceInfo->Config.DataINEndpointNumber &&
(USB_ControlRequest.wIndex == AudioInterfaceInfo->Config.DataINEndpointNumber)) ||
(AudioInterfaceInfo->Config.DataOUTEndpointNumber &&
(USB_ControlRequest.wIndex == AudioInterfaceInfo->Config.DataOUTEndpointNumber))))
{
return;
}
}
switch (USB_ControlRequest.bRequest)
{
case REQ_SetInterface:
......@@ -64,6 +80,53 @@ void Audio_Device_ProcessControlRequest(USB_ClassInfo_Audio_Device_t* const Audi
Endpoint_ClearSETUP();
Endpoint_ClearStatusStage();
}
break;
case AUDIO_REQ_SetCurrent:
case AUDIO_REQ_SetMinimum:
case AUDIO_REQ_SetMaximum:
case AUDIO_REQ_SetResolution:
if (USB_ControlRequest.bmRequestType == (REQDIR_HOSTTODEVICE | REQTYPE_CLASS | REQREC_ENDPOINT))
{
uint8_t EndpointProperty = USB_ControlRequest.bRequest;
uint8_t EndpointIndex = (uint8_t)USB_ControlRequest.wIndex;
uint8_t EndpointControl = (USB_ControlRequest.wValue >> 8);
if (CALLBACK_Audio_GetSetEndpointProperty(AudioInterfaceInfo, EndpointProperty, EndpointIndex, EndpointControl, NULL, NULL))
{
uint16_t ValueLength = USB_ControlRequest.wLength;
uint8_t Value[ValueLength];
Endpoint_ClearSETUP();
Endpoint_Read_Control_Stream_LE(Value, ValueLength);
Endpoint_ClearIN();
CALLBACK_Audio_GetSetEndpointProperty(AudioInterfaceInfo, EndpointProperty, EndpointIndex, EndpointControl, &ValueLength, Value);
}
}
break;
case AUDIO_REQ_GetCurrent:
case AUDIO_REQ_GetMinimum:
case AUDIO_REQ_GetMaximum:
case AUDIO_REQ_GetResolution:
if (USB_ControlRequest.bmRequestType == (REQDIR_DEVICETOHOST | REQTYPE_CLASS | REQREC_ENDPOINT))
{
uint8_t EndpointProperty = USB_ControlRequest.bRequest;
uint8_t EndpointIndex = (uint8_t)USB_ControlRequest.wIndex;
uint8_t EndpointControl = (USB_ControlRequest.wValue >> 8);
uint16_t ValueLength = USB_ControlRequest.wLength;
uint8_t Value[ValueLength];
if (CALLBACK_Audio_GetSetEndpointProperty(AudioInterfaceInfo, EndpointProperty, EndpointIndex, EndpointControl, &ValueLength, Value))
{
Endpoint_ClearSETUP();
Endpoint_Write_Control_Stream_LE(Value, ValueLength);
Endpoint_ClearOUT();
}
}
break;
}
}
......
......@@ -130,6 +130,35 @@
* \param[in,out] AudioInterfaceInfo Pointer to a structure containing an Audio Class configuration and state.
*/
void Audio_Device_ProcessControlRequest(USB_ClassInfo_Audio_Device_t* const AudioInterfaceInfo) ATTR_NON_NULL_PTR_ARG(1);
/** Audio class driver callback for the setting and retrieval of streaming endpoint properties. This callback must be implemented
* in the user application to handle property manipulations on streaming audio endpoints.
*
* When the DataLength parameter is NULL, this callback should only indicate whether the specified operation is valid for
* the given endpoint index, and should return as fast as possible. When non-NULL, this value may be altered for GET operations
* to indicate the size of the retreived data.
*
* \note The length of the retrieved data stored into the Data buffer on GET operations should not exceed the initial value
* of the \c DataLength parameter.
*
* \param[in,out] AudioInterfaceInfo Pointer to a structure containing an Audio Class configuration and state.
* \param[in] EndpointProperty Property of the endpoint to get or set, a value from \ref Audio_ClassRequests_t.
* \param[in] EndpointIndex Index of the streaming endpoint whose property is being referenced.
* \param[in] EndpointControl Parameter of the endpoint to get or set, a value from \ref Audio_EndpointControls_t.
* \param[in,out] DataLength For SET operations, the length of the parameter data to set. For GET operations, the maximum
* length of the retrieved data. When NULL, the function should return whether the given property
* and parameter is valid for the requested endpoint without reading or modifying the Data buffer.
* \param[in,out] Data Pointer to a location where the parameter data is stored for SET operations, or where
* the retrieved data is to be stored for GET operations.
*
* \return Boolean true if the property get/set was successful, false otherwise
*/
bool CALLBACK_Audio_GetSetEndpointProperty(USB_ClassInfo_Audio_Device_t* const AudioInterfaceInfo,
const uint8_t EndpointProperty,
const uint8_t EndpointIndex,
const uint8_t EndpointControl,
uint16_t* const DataLength,
uint8_t* Data);
/* Inline Functions: */
/** General management task for a given Audio class interface, required for the correct operation of the interface. This should
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