Removed Pipe_ClearErrorFlags(), pipe error flags are now automatically cleared when Pipe_ClearError() is called.

More UC3B architecture porting.
pull/1469/head
Dean Camera 14 years ago
parent 66c38cd940
commit cf2411435c

File diff suppressed because one or more lines are too long

@ -410,10 +410,11 @@
return ((UPCONX & (1 << PFREEZE)) ? true : false);
}
/** Clears the master pipe error flag. */
/** Clears the error flags for the currently selected pipe. */
static inline void Pipe_ClearError(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearError(void)
{
UPERRX = 0;
UPINTX &= ~(1 << PERRI);
}
@ -430,15 +431,6 @@
return ((UPINTX & (1 << PERRI)) ? true : false);
}
/** Clears all the currently selected pipe's hardware error flags, but does not clear the master error
* flag for the pipe.
*/
static inline void Pipe_ClearErrorFlags(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearErrorFlags(void)
{
UPERRX = 0;
}
/** Gets a mask of the hardware error flags which have occurred on the currently selected pipe. This
* value can then be masked against the \c PIPE_ERRORFLAG_* masks to determine what error has occurred.
*

@ -50,7 +50,7 @@ uint8_t USB_Host_SendControlRequest(void* const BufferPtr)
goto End_Of_Control_Send;
Pipe_SetPipeToken(PIPE_TOKEN_SETUP);
Pipe_ClearErrorFlags();
Pipe_ClearError();
Pipe_Unfreeze();

@ -55,8 +55,6 @@
#if (ARCH == ARCH_AVR8)
#include "AVR8/OTG_AVR8.h"
#elif (ARCH == ARCH_UC3B)
#include "UC3B/OTG_UC3B.h"
#endif
/* Preprocessor Checks: */

@ -119,9 +119,9 @@
#endif
/* Inline Functions: */
static inline uint8_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes) ATTR_WARN_UNUSED_RESULT ATTR_CONST
static inline uint32_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes) ATTR_WARN_UNUSED_RESULT ATTR_CONST
ATTR_ALWAYS_INLINE;
static inline uint8_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes)
static inline uint32_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes)
{
uint8_t MaskVal = 0;
uint16_t CheckBytes = 8;
@ -151,12 +151,12 @@
/** Endpoint data direction mask for \ref Endpoint_ConfigureEndpoint(). This indicates that the endpoint
* should be initialized in the OUT direction - i.e. data flows from host to device.
*/
#define ENDPOINT_DIR_OUT (0 << AVR32_USBB_UECFG0_EPDIR_OFFSET)
#define ENDPOINT_DIR_OUT AVR32_USBB_UECFG0_EPDIR_OUT
/** Endpoint data direction mask for \ref Endpoint_ConfigureEndpoint(). This indicates that the endpoint
* should be initialized in the IN direction - i.e. data flows from device to host.
*/
#define ENDPOINT_DIR_IN (1 << AVR32_USBB_UECFG0_EPDIR_OFFSET)
#define ENDPOINT_DIR_IN AVR32_USBB_UECFG0_EPDIR_IN
//@}
/** \name Endpoint Bank Mode Masks */
@ -166,21 +166,21 @@
* in slower transfers as only one USB device (the AVR or the host) can access the endpoint's
* bank at the one time.
*/
#define ENDPOINT_BANK_SINGLE (0 << AVR32_USBB_UECFG0_EPBK0_OFFSET)
#define ENDPOINT_BANK_SINGLE AVR32_USBB_UECFG0_EPBK0_SINGLE
/** Mask for the bank mode selection for the \ref Endpoint_ConfigureEndpoint() macro. This indicates
* that the endpoint should have two banks, which requires more USB FIFO memory but results
* in faster transfers as one USB device (the AVR or the host) can access one bank while the other
* accesses the second bank.
*/
#define ENDPOINT_BANK_DOUBLE (1 << AVR32_USBB_UECFG0_EPBK0_OFFSET)
#define ENDPOINT_BANK_DOUBLE AVR32_USBB_UECFG0_EPBK0_DOUBLE
/** Mask for the bank mode selection for the \ref Endpoint_ConfigureEndpoint() macro. This indicates
* that the endpoint should have three banks, which requires more USB FIFO memory but results
* in faster transfers as one USB device (the AVR or the host) can access one bank while the other
* accesses the remaining banks.
*/
#define ENDPOINT_BANK_TRIPLE (2 << AVR32_USBB_UECFG0_EPBK0_OFFSET)
#define ENDPOINT_BANK_TRIPLE AVR32_USBB_UECFG0_TRIPLE
//@}
/** Endpoint address for the default control endpoint, which always resides in address 0. This is
@ -309,9 +309,10 @@
const uint16_t Size,
const uint8_t Banks)
{
return Endpoint_ConfigureEndpoint_Prv(Number, ((Type << AVR32_USBB_EPTYPE_OFFSET) | AVR32_USBB_ALLOC |
(Direction << AVR32_USBB_EPDIR_OFFSET) |
(Banks << AVR32_USBB_EPBK_OFFSET) |
return Endpoint_ConfigureEndpoint_Prv(Number, (AVR32_USBB_ALLOC_MASK |
((uint32_t)Type << AVR32_USBB_EPTYPE_OFFSET) |
((uint32_t)Direction << AVR32_USBB_EPDIR_OFFSET) |
((uint32_t)Banks << AVR32_USBB_EPBK_OFFSET) |
Endpoint_BytesToEPSizeMask(Size)));
}
@ -365,8 +366,8 @@
static inline void Endpoint_ResetFIFO(const uint8_t EndpointNumber) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ResetFIFO(const uint8_t EndpointNumber)
{
AVR32_USBB.uerst |= (AVR32_USBB_EPRST0_OFFSET << EndpointNumber);
AVR32_USBB.uerst &= ~(AVR32_USBB_EPRST0_OFFSET << EndpointNumber);
AVR32_USBB.uerst |= (AVR32_USBB_EPRST0_MASK << EndpointNumber);
AVR32_USBB.uerst &= ~(AVR32_USBB_EPRST0_MASK << EndpointNumber);
}
/** Enables the currently selected endpoint so that data can be sent and received through it to
@ -377,7 +378,7 @@
static inline void Endpoint_EnableEndpoint(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_EnableEndpoint(void)
{
AVR32_USBB.uerst |= (AVR32_USBB_EPEN0 << USB_SelectedEndpoint);
AVR32_USBB.uerst |= (AVR32_USBB_EPEN0_MASK << USB_SelectedEndpoint);
}
/** Disables the currently selected endpoint so that data cannot be sent and received through it
@ -386,7 +387,7 @@
static inline void Endpoint_DisableEndpoint(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_DisableEndpoint(void)
{
AVR32_USBB.uerst &= ~(AVR32_USBB_EPEN0_OFFSET << USB_SelectedEndpoint);
AVR32_USBB.uerst &= ~(AVR32_USBB_EPEN0_MASK << USB_SelectedEndpoint);
}
/** Determines if the currently selected endpoint is enabled, but not necessarily configured.
@ -396,7 +397,7 @@
static inline bool Endpoint_IsEnabled(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Endpoint_IsEnabled(void)
{
return ((AVR32_USBB.uerst & (AVR32_USBB_EPEN0_OFFSET << USB_SelectedEndpoint)) ? true : false);
return ((AVR32_USBB.uerst & (AVR32_USBB_EPEN0_MASK << USB_SelectedEndpoint)) ? true : false);
}
/** Retrieves the number of busy banks in the currently selected endpoint, which have been queued for
@ -464,10 +465,10 @@
static inline uint8_t Endpoint_GetEndpointInterrupts(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint8_t Endpoint_GetEndpointInterrupts(void)
{
return ((AVR32_USBB.udint & (AVR32_USBB_EP6INTES_MASK | AVR32_USBB_EP5INTES_MASK |
AVR32_USBB_EP4INTES_MASK | AVR32_USBB_EP3INTES_MASK |
AVR32_USBB_EP2INTES_MASK | AVR32_USBB_EP1INTES_MASK |
AVR32_USBB_EP0INTES_MASK)) >> AVR32_USBB_EP0INT_OFFSET);
return ((AVR32_USBB.udint & (AVR32_USBB_EP6INT_MASK | AVR32_USBB_EP5INT_MASK |
AVR32_USBB_EP4INT_MASK | AVR32_USBB_EP3INT_MASK |
AVR32_USBB_EP2INT_MASK | AVR32_USBB_EP1INT_MASK |
AVR32_USBB_EP0INT_MASK)) >> AVR32_USBB_EP0INT_OFFSET);
}
/** Determines if the specified endpoint number has interrupted (valid only for INTERRUPT type
@ -480,7 +481,7 @@
static inline bool Endpoint_HasEndpointInterrupted(const uint8_t EndpointNumber) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Endpoint_HasEndpointInterrupted(const uint8_t EndpointNumber)
{
return ((Endpoint_GetEndpointInterrupts() & (1 << EndpointNumber)) ? true : false);
return ((Endpoint_GetEndpointInterrupts() & (AVR32_USBB_EP0INT_MASK << EndpointNumber)) ? true : false);
}
/** Determines if the selected IN endpoint is ready for a new packet to be sent to the host.
@ -529,7 +530,7 @@
static inline void Endpoint_ClearSETUP(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ClearSETUP(void)
{
((avr32_usbb_uesta0_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].rxstpi = true;
((avr32_usbb_uesta0clr_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].rxstpic = true;
}
/** Sends an IN packet to the host on the currently selected endpoint, freeing up the endpoint for the
@ -540,8 +541,8 @@
static inline void Endpoint_ClearIN(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ClearIN(void)
{
((avr32_usbb_uesta0_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].txini = true;
((avr32_usbb_uecon0_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].fifocon = true;
((avr32_usbb_uesta0clr_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].txinic = true;
((avr32_usbb_uecon0clr_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].fifoconc = true;
}
/** Acknowledges an OUT packet to the host on the currently selected endpoint, freeing up the endpoint
@ -552,8 +553,8 @@
static inline void Endpoint_ClearOUT(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ClearOUT(void)
{
((avr32_usbb_uesta0_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].rxouti = true;
((avr32_usbb_uecon0_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].fifocon = true;
((avr32_usbb_uesta0clr_t*)AVR32_USBB_UESTA0CLR)[USB_SelectedEndpoint].rxoutic = true;
((avr32_usbb_uecon0clr_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].fifoconc = true;
}
/** Stalls the current endpoint, indicating to the host that a logical problem occurred with the
@ -570,7 +571,7 @@
static inline void Endpoint_StallTransaction(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_StallTransaction(void)
{
((avr32_usbb_uecon0_t*)AVR32_USBB_UECON0SET)[USB_SelectedEndpoint].stallrq = true;
((avr32_usbb_uecon0set_t*)AVR32_USBB_UECON0SET)[USB_SelectedEndpoint].stallrqs = true;
}
/** Clears the STALL condition on the currently selected endpoint.
@ -580,7 +581,7 @@
static inline void Endpoint_ClearStall(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ClearStall(void)
{
((avr32_usbb_uecon0_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].stallrq = true;
((avr32_usbb_uecon0clr_t*)AVR32_USBB_UECON0CLR)[USB_SelectedEndpoint].stallrqc = true;
}
/** Determines if the currently selected endpoint is stalled, false otherwise.
@ -599,7 +600,7 @@
static inline void Endpoint_ResetDataToggle(void) ATTR_ALWAYS_INLINE;
static inline void Endpoint_ResetDataToggle(void)
{
((avr32_usbb_uecon0_t*)AVR32_USBB_UECON0SET)[USB_SelectedEndpoint].rstdt = true;
((avr32_usbb_uecon0set_t*)AVR32_USBB_UECON0SET)[USB_SelectedEndpoint].rstdts = true;
}
/** Determines the currently selected endpoint's direction.

@ -245,7 +245,7 @@
*/
static inline uint16_t USB_Host_GetFrameNumber(void)
{
return UHFNUM;
return AVR32_USBB_UHFNUM;
}
#if !defined(NO_SOF_EVENTS)
@ -282,7 +282,7 @@
static inline void USB_Host_ResetBus(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_ResetBus(void)
{
UHCON |= (1 << RESET);
AVR32_USBB_UHCON.reset = true;
}
/** Determines if a previously issued bus reset (via the \ref USB_Host_ResetBus() macro) has
@ -293,7 +293,7 @@
static inline bool USB_Host_IsBusResetComplete(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_Host_IsBusResetComplete(void)
{
return ((UHCON & (1 << RESET)) ? false : true);
return AVR32_USBB_UHCON.reset;
}
/** Resumes USB communications with an attached and enumerated device, by resuming the transmission
@ -303,7 +303,7 @@
static inline void USB_Host_ResumeBus(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_ResumeBus(void)
{
UHCON |= (1 << SOFEN);
AVR32_USBB_UHCON.sofe = true;
}
/** Suspends the USB bus, preventing any communications from occurring between the host and attached
@ -313,7 +313,7 @@
static inline void USB_Host_SuspendBus(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_SuspendBus(void)
{
UHCON &= ~(1 << SOFEN);
AVR32_USBB_UHCON.sofe = false;
}
/** Determines if the USB bus has been suspended via the use of the \ref USB_Host_SuspendBus() macro,
@ -325,7 +325,7 @@
static inline bool USB_Host_IsBusSuspended(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_Host_IsBusSuspended(void)
{
return ((UHCON & (1 << SOFEN)) ? false : true);
return AVR32_USBB_UHCON.sofe;
}
/** Determines if the attached device is currently enumerated in Full Speed mode (12Mb/s), or
@ -336,7 +336,7 @@
static inline bool USB_Host_IsDeviceFullSpeed(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_Host_IsDeviceFullSpeed(void)
{
return ((USBSTA & (1 << SPEED)) ? true : false);
return (AVR32_USBB_USBSTA.speed == AVR32_USBB_SPEED_FULL);
}
/** Determines if the attached device is currently issuing a Remote Wakeup request, requesting
@ -347,14 +347,14 @@
static inline bool USB_Host_IsRemoteWakeupSent(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_Host_IsRemoteWakeupSent(void)
{
return ((UHINT & (1 << RXRSMI)) ? true : false);
return AVR32_USBB_UHINT.rxrsmi;
}
/** Clears the flag indicating that a Remote Wakeup request has been issued by an attached device. */
static inline void USB_Host_ClearRemoteWakeupSent(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_ClearRemoteWakeupSent(void)
{
UHINT &= ~(1 << RXRSMI);
AVR32_USBB_UHINTCLR.rxrsmic = true;
}
/** Accepts a Remote Wakeup request from an attached device. This must be issued in response to
@ -364,7 +364,7 @@
static inline void USB_Host_ResumeFromWakeupRequest(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_ResumeFromWakeupRequest(void)
{
UHCON |= (1 << RESUME);
AVR32_USBB_UHCON.resume = true;
}
/** Determines if a resume from Remote Wakeup request is currently being sent to an attached
@ -375,7 +375,7 @@
static inline bool USB_Host_IsResumeFromWakeupRequestSent(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_Host_IsResumeFromWakeupRequestSent(void)
{
return ((UHCON & (1 << RESUME)) ? false : true);
return AVR32_USBB_UHCON.resume;
}
/* Function Prototypes: */
@ -438,59 +438,63 @@
static inline void USB_Host_HostMode_On(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_HostMode_On(void)
{
USBCON |= (1 << HOST);
// Not required for UC3B
}
static inline void USB_Host_HostMode_Off(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_HostMode_Off(void)
{
USBCON &= ~(1 << HOST);
// Not required for UC3B
}
static inline void USB_Host_VBUS_Auto_Enable(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Auto_Enable(void)
{
OTGCON &= ~(1 << VBUSHWC);
UHWCON |= (1 << UVCONE);
AVR32_USBB_USBCON.vbushwc = false;
}
static inline void USB_Host_VBUS_Manual_Enable(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Manual_Enable(void)
{
OTGCON |= (1 << VBUSHWC);
UHWCON &= ~(1 << UVCONE);
AVR32_USBB_USBCON.vbushwc = true;
DDRE |= (1 << 7);
// TODO: Manual VBUS pin output setup
}
static inline void USB_Host_VBUS_Auto_On(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Auto_On(void)
{
OTGCON |= (1 << VBUSREQ);
AVR32_USBB_USBSTASET.vbusreqs = true;
}
static inline void USB_Host_VBUS_Manual_On(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Manual_On(void)
{
PORTE |= (1 << 7);
// TODO: Manual VBUS pin output on
}
static inline void USB_Host_VBUS_Auto_Off(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Auto_Off(void)
{
OTGCON |= (1 << VBUSRQC);
AVR32_USBB_USBSTACLR.vbusreqc = true;
}
static inline void USB_Host_VBUS_Manual_Off(void) ATTR_ALWAYS_INLINE;
static inline void USB_Host_VBUS_Manual_Off(void)
{
PORTE &= ~(1 << 7);
// TODO: Manual VBUS pin output off
}
static inline void USB_Host_SetDeviceAddress(const uint8_t Address) ATTR_ALWAYS_INLINE;
static inline void USB_Host_SetDeviceAddress(const uint8_t Address)
{
UHADDR = (Address & 0x7F);
AVR32_USBB_UHADDR1.uhaddrp0 = Address;
AVR32_USBB_UHADDR1.uhaddrp1 = Address;
AVR32_USBB_UHADDR1.uhaddrp2 = Address;
AVR32_USBB_UHADDR1.uhaddrp3 = Address;
AVR32_USBB_UHADDR2.uhaddrp4 = Address;
AVR32_USBB_UHADDR2.uhaddrp5 = Address;
AVR32_USBB_UHADDR2.uhaddrp6 = Address;
}
/* Enums: */

@ -1,149 +0,0 @@
/*
LUFA Library
Copyright (C) Dean Camera, 2011.
dean [at] fourwalledcubicle [dot] com
www.lufa-lib.org
*/
/*
Copyright 2011 Dean Camera (dean [at] fourwalledcubicle [dot] com)
Permission to use, copy, modify, distribute, and sell this
software and its documentation for any purpose is hereby granted
without fee, provided that the above copyright notice appear in
all copies and that both that the copyright notice and this
permission notice and warranty disclaimer appear in supporting
documentation, and that the name of the author not be used in
advertising or publicity pertaining to distribution of the
software without specific, written prior permission.
The author disclaim all warranties with regard to this
software, including all implied warranties of merchantability
and fitness. In no event shall the author be liable for any
special, indirect or consequential damages or any damages
whatsoever resulting from loss of use, data or profits, whether
in an action of contract, negligence or other tortious action,
arising out of or in connection with the use or performance of
this software.
*/
/** \file
* \brief USB OTG definitions for the AVR32 UC3B microcontrollers.
* \copydetails Group_OTG_UC3B
*
* \note This file should not be included directly. It is automatically included as needed by the USB driver
* dispatch header located in LUFA/Drivers/USB/USB.h.
*/
/** \ingroup Group_OTG
* \defgroup Group_OTG_UC3B USB On The Go (OTG) Management (UC3B)
* \brief USB OTG definitions for the AVR32 UC3B microcontrollers.
*
* Architecture specific USB OTG definitions for the Atmel 32-bit AVR UC3B microcontrollers.
*
* @{
*/
#ifndef __USBOTG_UC3B_H__
#define __USBOTG_UC3B_H__
/* Includes: */
#include "../../../../Common/Common.h"
/* Preprocessor Checks: */
#if !defined(__INCLUDE_FROM_USB_DRIVER)
#error Do not include this file directly. Include LUFA/Drivers/USB/USB.h instead.
#endif
/* Public Interface - May be used in end-application: */
/* Macros: */
/** Mask for the VBUS pulsing method of SRP, supported by some OTG devices.
*
* \see \ref USB_OTG_Device_InitiateSRP().
*/
#define USB_OTG_SRP_VBUS (1 << SRPSEL)
/** Mask for the Data + pulsing method of SRP, supported by some OTG devices.
*
* \see \ref USB_OTG_Device_InitiateSRP().
*/
#define USB_OTG_STP_DATA 0
/* Inline Functions: */
/** Initiate a Host Negotiation Protocol request. This indicates to the other connected device
* that the device wishes to change device/host roles.
*/
static inline void USB_OTG_Device_RequestHNP(void) ATTR_ALWAYS_INLINE;
static inline void USB_OTG_Device_RequestHNP(void)
{
OTGCON |= (1 << HNPREQ);
}
/** Cancel a Host Negotiation Protocol request. This stops a pending HNP request to the other
* connected device.
*/
static inline void USB_OTG_Device_CancelHNPRequest(void) ATTR_ALWAYS_INLINE;
static inline void USB_OTG_Device_CancelHNPRequest(void)
{
OTGCON &= ~(1 << HNPREQ);
}
/** Determines if the device is currently sending a HNP to an attached host.
*
* \return Boolean \c true if currently sending a HNP to the other connected device, \c false otherwise
*/
static inline bool USB_OTG_Device_IsSendingHNP(void) ATTR_ALWAYS_INLINE;
static inline bool USB_OTG_Device_IsSendingHNP(void)
{
return ((OTGCON & (1 << HNPREQ)) ? true : false);
}
/** Initiates a Session Request Protocol request. Most OTG devices turn off VBUS when the USB
* interface is not in use, to conserve power. Sending a SRP to a USB OTG device running in
* host mode indicates that VBUS should be applied and a session started.
*
* There are two different methods of sending a SRP - either pulses on the VBUS line, or by
* pulsing the Data + line via the internal pull-up resistor.
*
* \param[in] SRPTypeMask Mask indicating the type of SRP to use, either \ref USB_OTG_SRP_VBUS or
* \ref USB_OTG_STP_DATA.
*/
static inline void USB_OTG_Device_InitiateSRP(const uint8_t SRPTypeMask) ATTR_ALWAYS_INLINE;
static inline void USB_OTG_Device_InitiateSRP(const uint8_t SRPTypeMask)
{
OTGCON = ((OTGCON & ~(1 << SRPSEL)) | (SRPTypeMask | (1 << SRPREQ)));
}
/** Accepts a HNP from a connected device, indicating that both devices should exchange
* device/host roles.
*/
static inline void USB_OTG_Host_AcceptHNP(void) ATTR_ALWAYS_INLINE;
static inline void USB_OTG_Host_AcceptHNP(void)
{
OTGCON |= (1 << HNPREQ);
}
/** Rejects a HNP from a connected device, indicating that both devices should remain in their
* current device/host roles.
*/
static inline void USB_OTG_Host_RejectHNP(void) ATTR_ALWAYS_INLINE;
static inline void USB_OTG_Host_RejectHNP(void)
{
OTGCON &= ~(1 << HNPREQ);
}
/** Indicates if the connected device is not currently sending a HNP request.
*
* \return Boolean \c true if a HNP is currently being issued by the connected device, \c false otherwise.
*/
static inline bool USB_OTG_Host_IsHNPReceived(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool USB_OTG_Host_IsHNPReceived(void)
{
return ((OTGCON & (1 << HNPREQ)) ? true : false);
}
#endif
/** @} */

@ -36,6 +36,7 @@
#include "../Pipe.h"
uint8_t USB_ControlPipeSize = PIPE_CONTROLPIPE_DEFAULT_SIZE;
uint8_t USB_SelectedPipe = PIPE_CONTROLPIPE;
bool Pipe_ConfigurePipe(const uint8_t Number,
const uint8_t Type,
@ -44,70 +45,19 @@ bool Pipe_ConfigurePipe(const uint8_t Number,
const uint16_t Size,
const uint8_t Banks)
{
#if defined(ORDERED_EP_CONFIG)
Pipe_SelectPipe(Number);
Pipe_EnablePipe();
UPCFG1X = 0;
UPCFG0X = ((Type << EPTYPE0) | Token | ((EndpointNumber & PIPE_EPNUM_MASK) << PEPNUM0));
UPCFG1X = ((1 << ALLOC) | Banks | Pipe_BytesToEPSizeMask(Size));
*((uint32_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe] = 0;
*((uint32_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe] = (AVR32_USBB_ALLOC_MASK |
((uint32_t)Type << AVR32_USBB_PTYPE_OFFSET) |
((uint32_t)Token << AVR32_USBB_PTOKEN_OFFSET) |
((uint32_t)Banks << AVR32_USBB_PBK_OFFSET) |
((EndpointNumber & PIPE_EPNUM_MASK) << AVR32_USBB_PEPNUM_OFFSET));
Pipe_SetInfiniteINRequests();
return Pipe_IsConfigured();
#else
for (uint8_t PNum = Number; PNum < PIPE_TOTAL_PIPES; PNum++)
{
uint8_t UPCFG0XTemp;
uint8_t UPCFG1XTemp;
uint8_t UPCFG2XTemp;
uint8_t UPCONXTemp;
uint8_t UPINRQXTemp;
uint8_t UPIENXTemp;
Pipe_SelectPipe(PNum);
if (PNum == Number)
{
UPCFG0XTemp = ((Type << EPTYPE0) | Token | ((EndpointNumber & PIPE_EPNUM_MASK) << PEPNUM0));
UPCFG1XTemp = ((1 << ALLOC) | Banks | Pipe_BytesToEPSizeMask(Size));
UPCFG2XTemp = 0;
UPCONXTemp = ((1 << PEN) | (1 << INMODE));
UPINRQXTemp = 0;
UPIENXTemp = 0;
}
else
{
UPCFG0XTemp = UPCFG0X;
UPCFG1XTemp = UPCFG1X;
UPCFG2XTemp = UPCFG2X;
UPCONXTemp = UPCONX;
UPINRQXTemp = UPINRQX;
UPIENXTemp = UPIENX;
}
if (!(UPCFG1XTemp & (1 << ALLOC)))
continue;
Pipe_DisablePipe();
UPCFG1X &= (1 << ALLOC);
Pipe_EnablePipe();
UPCFG0X = UPCFG0XTemp;
UPCFG1X = UPCFG1XTemp;
UPCFG2X = UPCFG2XTemp;
UPCONX = UPCONXTemp;
UPINRQX = UPINRQXTemp;
UPIENX = UPIENXTemp;
if (!(Pipe_IsConfigured()))
return false;
}
Pipe_SelectPipe(Number);
return true;
#endif
}
void Pipe_ClearPipes(void)
@ -117,9 +67,7 @@ void Pipe_ClearPipes(void)
for (uint8_t PNum = 0; PNum < PIPE_TOTAL_PIPES; PNum++)
{
Pipe_SelectPipe(PNum);
UPIENX = 0;
UPINTX = 0;
UPCFG1X = 0;
*((uint32_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe] = 0;
Pipe_DisablePipe();
}
}

@ -101,25 +101,25 @@
/** \name Pipe Error Flag Masks */
//@{
/** Mask for \ref Pipe_GetErrorFlags(), indicating that an overflow error occurred in the pipe on the received data. */
#define PIPE_ERRORFLAG_OVERFLOW (1 << 6)
#define PIPE_ERRORFLAG_OVERFLOW ((1 << AVR32_USBB_UPSTA0_OVERFI_OFFSET) << 8)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that an underflow error occurred in the pipe on the received data. */
#define PIPE_ERRORFLAG_UNDERFLOW (1 << 5)
#define PIPE_ERRORFLAG_UNDERFLOW ((1 << AVR32_USBB_UPSTA0_UNDERFI_OFFSET) << 8)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that a CRC error occurred in the pipe on the received data. */
#define PIPE_ERRORFLAG_CRC16 (1 << 4)
#define PIPE_ERRORFLAG_CRC16 (1 << AVR32_USBB_UPERR0_CRC16_OFFSET)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that a hardware timeout error occurred in the pipe. */
#define PIPE_ERRORFLAG_TIMEOUT (1 << 3)
#define PIPE_ERRORFLAG_TIMEOUT (1 << AVR32_USBB_UPERR0_TIMEOUT_OFFSET)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that a hardware PID error occurred in the pipe. */
#define PIPE_ERRORFLAG_PID (1 << 2)
#define PIPE_ERRORFLAG_PID (1 << AVR32_USBB_UPERR0_PID_OFFSET)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that a hardware data PID error occurred in the pipe. */
#define PIPE_ERRORFLAG_DATAPID (1 << 1)
#define PIPE_ERRORFLAG_DATAPID (1 << AVR32_USBB_UPERR0_DATAPID_OFFSET)
/** Mask for \ref Pipe_GetErrorFlags(), indicating that a hardware data toggle error occurred in the pipe. */
#define PIPE_ERRORFLAG_DATATGL (1 << 0)
#define PIPE_ERRORFLAG_DATATGL (1 << AVR32_USBB_UPERR0_DATATGL_OFFSET)
//@}
/** \name Pipe Token Masks */
@ -127,17 +127,17 @@
/** Token mask for \ref Pipe_ConfigurePipe(). This sets the pipe as a SETUP token (for CONTROL type pipes),
* which will trigger a control request on the attached device when data is written to the pipe.
*/
#define PIPE_TOKEN_SETUP (0 << PTOKEN0)
#define PIPE_TOKEN_SETUP AVR32_USBB_UPCFG0_PTOKEN_SETUP
/** Token mask for \ref Pipe_ConfigurePipe(). This sets the pipe as a IN token (for non-CONTROL type pipes),
* indicating that the pipe data will flow from device to host.
*/
#define PIPE_TOKEN_IN (1 << PTOKEN0)
#define PIPE_TOKEN_IN AVR32_USBB_UPCFG0_PTOKEN_IN
/** Token mask for \ref Pipe_ConfigurePipe(). This sets the pipe as a OUT token (for non-CONTROL type pipes),
* indicating that the pipe data will flow from host to device.
*/
#define PIPE_TOKEN_OUT (2 << PTOKEN0)
#define PIPE_TOKEN_OUT AVR32_USBB_UPCFG0_PTOKEN_OUT
//@}
/** \name Pipe Bank Mode Masks */
@ -146,14 +146,21 @@
* should have one single bank, which requires less USB FIFO memory but results in slower transfers as
* only one USB device (the AVR or the attached device) can access the pipe's bank at the one time.
*/
#define PIPE_BANK_SINGLE (0 << EPBK0)
#define PIPE_BANK_SINGLE AVR32_USBB_UPCFG0_PBK_SINGLE
/** Mask for the bank mode selection for the \ref Pipe_ConfigurePipe() macro. This indicates that the pipe
* should have two banks, which requires more USB FIFO memory but results in faster transfers as one
* USB device (the AVR or the attached device) can access one bank while the other accesses the second
* bank.
*/
#define PIPE_BANK_DOUBLE (1 << EPBK0)
#define PIPE_BANK_DOUBLE AVR32_USBB_UPCFG0_PBK_DOUBLE
/** Mask for the bank mode selection for the \ref Pipe_ConfigurePipe() macro. This indicates that the pipe
* should have three banks, which requires more USB FIFO memory but results in faster transfers as one
* USB device (the AVR or the attached device) can access one bank while the other accesses the remaining
* banks.
*/
#define PIPE_BANK_TRIPLE AVR32_USBB_UPCFG0_PBK_TRIPLE
//@}
/** Pipe address for the default control pipe, which always resides in address 0. This is
@ -223,7 +230,7 @@
static inline uint16_t Pipe_BytesInPipe(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint16_t Pipe_BytesInPipe(void)
{
return UPBCX;
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].pbyct;
}
/** Returns the pipe address of the currently selected pipe. This is typically used to save the
@ -234,7 +241,7 @@
static inline uint8_t Pipe_GetCurrentPipe(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint8_t Pipe_GetCurrentPipe(void)
{
return (UPNUM & PIPE_PIPENUM_MASK);
return USB_SelectedPipe;
}
/** Selects the given pipe number. Any pipe operations which do not require the pipe number to be
@ -245,7 +252,7 @@
static inline void Pipe_SelectPipe(const uint8_t PipeNumber) ATTR_ALWAYS_INLINE;
static inline void Pipe_SelectPipe(const uint8_t PipeNumber)
{
UPNUM = PipeNumber;
USB_SelectedPipe = PipeNumber;
}
/** Resets the desired pipe, including the pipe banks and flags.
@ -255,8 +262,8 @@
static inline void Pipe_ResetPipe(const uint8_t PipeNumber) ATTR_ALWAYS_INLINE;
static inline void Pipe_ResetPipe(const uint8_t PipeNumber)
{
UPRST = (1 << PipeNumber);
UPRST = 0;
AVR32_USBB.uprst |= (AVR32_USBB_PRST0_MASK << PipeNumber);
AVR32_USBB.uprst &= ~(AVR32_USBB_PRST0_MASK << PipeNumber);
}
/** Enables the currently selected pipe so that data can be sent and received through it to and from
@ -267,7 +274,7 @@
static inline void Pipe_EnablePipe(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_EnablePipe(void)
{
UPCONX |= (1 << PEN);
AVR32_USBB.uprst |= (AVR32_USBB_PEN0_MASK << PipeNumber);
}
/** Disables the currently selected pipe so that data cannot be sent and received through it to and
@ -276,7 +283,7 @@
static inline void Pipe_DisablePipe(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_DisablePipe(void)
{
UPCONX &= ~(1 << PEN);
AVR32_USBB.uprst &= ~(AVR32_USBB_PEN0_MASK << PipeNumber);
}
/** Determines if the currently selected pipe is enabled, but not necessarily configured.
@ -286,7 +293,7 @@
static inline bool Pipe_IsEnabled(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsEnabled(void)
{
return ((UPCONX & (1 << PEN)) ? true : false);
return ((AVR32_USBB.uprst & (AVR32_USBB_PEN0_MASK << PipeNumber)) ? true : false);
}
/** Gets the current pipe token, indicating the pipe's data direction and type.
@ -296,7 +303,7 @@
static inline uint8_t Pipe_GetPipeToken(void) ATTR_ALWAYS_INLINE;
static inline uint8_t Pipe_GetPipeToken(void)
{
return (UPCFG0X & (0x03 << PTOKEN0));
return ((avr32_usbb_upcfg0_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe].ptoken;
}
/** Sets the token for the currently selected pipe to one of the tokens specified by the \c PIPE_TOKEN_*
@ -309,14 +316,14 @@
static inline void Pipe_SetPipeToken(const uint8_t Token) ATTR_ALWAYS_INLINE;
static inline void Pipe_SetPipeToken(const uint8_t Token)
{
UPCFG0X = ((UPCFG0X & ~(0x03 << PTOKEN0)) | Token);
((avr32_usbb_upcfg0_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe].ptoken = Token;
}
/** Configures the currently selected pipe to allow for an unlimited number of IN requests. */
static inline void Pipe_SetInfiniteINRequests(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_SetInfiniteINRequests(void)
{
UPCONX |= (1 << INMODE);
((avr32_usbb_upinrq0_t*)AVR32_USBB_UPINRQ0)[USB_SelectedPipe].inmode = true;
}
/** Configures the currently selected pipe to only allow the specified number of IN requests to be
@ -327,8 +334,8 @@
static inline void Pipe_SetFiniteINRequests(const uint8_t TotalINRequests) ATTR_ALWAYS_INLINE;
static inline void Pipe_SetFiniteINRequests(const uint8_t TotalINRequests)
{
UPCONX &= ~(1 << INMODE);
UPINRQX = TotalINRequests;
((avr32_usbb_upinrq0_t*)AVR32_USBB_UPINRQ0)[USB_SelectedPipe].inmode = false;
((avr32_usbb_upinrq0_t*)AVR32_USBB_UPINRQ0)[USB_SelectedPipe].inrq = TotalINRequests;
}
/** Determines if the currently selected pipe is configured.
@ -338,7 +345,7 @@
static inline bool Pipe_IsConfigured(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsConfigured(void)
{
return ((UPSTAX & (1 << CFGOK)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].cfgok;
}
/** Retrieves the endpoint number of the endpoint within the attached device that the currently selected
@ -349,7 +356,7 @@
static inline uint8_t Pipe_BoundEndpointNumber(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint8_t Pipe_BoundEndpointNumber(void)
{
return ((UPCFG0X >> PEPNUM0) & PIPE_EPNUM_MASK);
return ((avr32_usbb_upcfg0_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe].pepnum;
}
/** Sets the period between interrupts for an INTERRUPT type pipe to a specified number of milliseconds.
@ -359,7 +366,7 @@
static inline void Pipe_SetInterruptPeriod(const uint8_t Milliseconds) ATTR_ALWAYS_INLINE;
static inline void Pipe_SetInterruptPeriod(const uint8_t Milliseconds)
{
UPCFG2X = Milliseconds;
((avr32_usbb_upcfg0_t*)AVR32_USBB_UPCFG0)[USB_SelectedPipe].intfrq = Milliseconds;
}
/** Returns a mask indicating which pipe's interrupt periods have elapsed, indicating that the pipe should
@ -370,7 +377,10 @@
static inline uint8_t Pipe_GetPipeInterrupts(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint8_t Pipe_GetPipeInterrupts(void)
{
return UPINT;
return ((AVR32_USBB.uhint & (AVR32_USBB_P6INT_MASK | AVR32_USBB_P5INT_MASK |
AVR32_USBB_P4INT_MASK | AVR32_USBB_P3INT_MASK |
AVR32_USBB_P2INT_MASK | AVR32_USBB_P1INT_MASK |
AVR32_USBB_P0INT_MASK)) >> AVR32_USBB_P0INT_OFFSET);
}
/** Determines if the specified pipe number has interrupted (valid only for INTERRUPT type
@ -383,21 +393,21 @@
static inline bool Pipe_HasPipeInterrupted(const uint8_t PipeNumber) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_HasPipeInterrupted(const uint8_t PipeNumber)
{
return ((UPINT & (1 << PipeNumber)) ? true : false);
return ((AVR32_USBB.uhint & (AVR32_USBB_P0INTES_MASK << USB_SelectedPipe)) ? true : false);
}
/** Unfreezes the selected pipe, allowing it to communicate with an attached device. */
static inline void Pipe_Unfreeze(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_Unfreeze(void)
{
UPCONX &= ~(1 << PFREEZE);
((avr32_usbb_upcon0clr_t*)AVR32_USBB_UPCON0CLR)[USB_SelectedPipe].pfreezec = true;
}
/** Freezes the selected pipe, preventing it from communicating with an attached device. */
static inline void Pipe_Freeze(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_Freeze(void)
{
UPCONX |= (1 << PFREEZE);
((avr32_usbb_upcon0set_t*)AVR32_USBB_UPCON0SET)[USB_SelectedPipe].pfreezes = true;
}
/** Determines if the currently selected pipe is frozen, and not able to accept data.
@ -407,14 +417,14 @@
static inline bool Pipe_IsFrozen(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsFrozen(void)
{
return ((UPCONX & (1 << PFREEZE)) ? true : false);
return ((((avr32_usbb_upcon0_t*)AVR32_USBB_UPCON0)[USB_SelectedPipe].pfreeze) ? true : false);
}
/** Clears the master pipe error flag. */
/** Clears the error flags for the currently selected pipe. */
static inline void Pipe_ClearError(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearError(void)
{
UPINTX &= ~(1 << PERRI);
((uint32_t*)AVR32_USBB_UPERR0)[USB_SelectedPipe] = 0;
}
/** Determines if the master pipe error flag is set for the currently selected pipe, indicating that
@ -427,16 +437,7 @@
static inline bool Pipe_IsError(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsError(void)
{
return ((UPINTX & (1 << PERRI)) ? true : false);
}
/** Clears all the currently selected pipe's hardware error flags, but does not clear the master error
* flag for the pipe.
*/
static inline void Pipe_ClearErrorFlags(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearErrorFlags(void)
{
UPERRX = 0;
return ((((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].perri) ? true : false);
}
/** Gets a mask of the hardware error flags which have occurred on the currently selected pipe. This
@ -463,7 +464,7 @@
*/
static inline uint8_t Pipe_GetBusyBanks(void)
{
return (UPSTAX & (0x03 << NBUSYBK0));
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].nbusybk;
}
/** Determines if the currently selected pipe may be read from (if data is waiting in the pipe
@ -482,7 +483,7 @@
static inline bool Pipe_IsReadWriteAllowed(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsReadWriteAllowed(void)
{
return ((UPINTX & (1 << RWAL)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].rwall;
}
/** Determines if a packet has been received on the currently selected IN pipe from the attached device.
@ -494,7 +495,7 @@
static inline bool Pipe_IsINReceived(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsINReceived(void)
{
return ((UPINTX & (1 << RXINI)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].rxini;
}
/** Determines if the currently selected OUT pipe is ready to send an OUT packet to the attached device.
@ -506,7 +507,7 @@
static inline bool Pipe_IsOUTReady(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsOUTReady(void)
{
return ((UPINTX & (1 << TXOUTI)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].rxouti;
}
/** Determines if no SETUP request is currently being sent to the attached device on the selected
@ -519,7 +520,7 @@
static inline bool Pipe_IsSETUPSent(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsSETUPSent(void)
{
return ((UPINTX & (1 << TXSTPI)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].txstpi;
}
/** Sends the currently selected CONTROL type pipe's contents to the device as a SETUP packet.
@ -529,7 +530,7 @@
static inline void Pipe_ClearSETUP(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearSETUP(void)
{
UPINTX &= ~((1 << TXSTPI) | (1 << FIFOCON));
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].txstpic = true;
}
/** Acknowledges the reception of a setup IN request from the attached device on the currently selected
@ -540,7 +541,8 @@
static inline void Pipe_ClearIN(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearIN(void)
{
UPINTX &= ~((1 << RXINI) | (1 << FIFOCON));
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].rxinic = true;
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].fifoconc = true;
}
/** Sends the currently selected pipe's contents to the device as an OUT packet on the selected pipe, freeing
@ -551,7 +553,8 @@
static inline void Pipe_ClearOUT(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearOUT(void)
{
UPINTX &= ~((1 << TXOUTI) | (1 << FIFOCON));
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].txoutic = true;
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].fifoconc = true;
}
/** Determines if the device sent a NAK (Negative Acknowledge) in response to the last sent packet on
@ -567,7 +570,7 @@
static inline bool Pipe_IsNAKReceived(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsNAKReceived(void)
{
return ((UPINTX & (1 << NAKEDI)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].nakedi;
}
/** Clears the NAK condition on the currently selected pipe.
@ -579,7 +582,7 @@
static inline void Pipe_ClearNAKReceived(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearNAKReceived(void)
{
UPINTX &= ~(1 << NAKEDI);
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].nakedic = true;
}
/** Determines if the currently selected pipe has had the STALL condition set by the attached device.
@ -591,7 +594,7 @@
static inline bool Pipe_IsStalled(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline bool Pipe_IsStalled(void)
{
return ((UPINTX & (1 << RXSTALLI)) ? true : false);
return ((avr32_usbb_upsta0_t*)AVR32_USBB_UPSTA0)[USB_SelectedPipe].rxstalledi;
}
/** Clears the STALL condition detection flag on the currently selected pipe, but does not clear the
@ -602,7 +605,7 @@
static inline void Pipe_ClearStall(void) ATTR_ALWAYS_INLINE;
static inline void Pipe_ClearStall(void)
{
UPINTX &= ~(1 << RXSTALLI);
((avr32_usbb_upsta0clr_t*)AVR32_USBB_UPSTA0CLR)[USB_SelectedPipe].rxstalledic = true;
}
/** Reads one byte from the currently selected pipe's bank, for OUT direction pipes.
@ -614,7 +617,7 @@
static inline uint8_t Pipe_Read_Byte(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
static inline uint8_t Pipe_Read_Byte(void)
{
return UPDATX;
return *((uint8_t*)AVR32_USBB_EP_DATA);
}
/** Writes one byte from the currently selected pipe's bank, for IN direction pipes.
@ -626,7 +629,7 @@
static inline void Pipe_Write_Byte(const uint8_t Byte) ATTR_ALWAYS_INLINE;
static inline void Pipe_Write_Byte(const uint8_t Byte)
{
UPDATX = Byte;
*((uint8_t*)AVR32_USBB_EP_DATA) = Byte;
}
/** Discards one byte from the currently selected pipe's bank, for OUT direction pipes.
@ -638,7 +641,7 @@
{
uint8_t Dummy;
Dummy = UPDATX;
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
}
/** Reads two bytes from the currently selected pipe's bank in little endian format, for OUT
@ -657,8 +660,8 @@
uint8_t Bytes[2];
} Data;
Data.Bytes[0] = UPDATX;
Data.Bytes[1] = UPDATX;
Data.Bytes[0] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[1] = *((uint8_t*)AVR32_USBB_EP_DATA);
return Data.Word;
}
@ -679,8 +682,8 @@
uint8_t Bytes[2];
} Data;
Data.Bytes[1] = UPDATX;
Data.Bytes[0] = UPDATX;
Data.Bytes[1] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[0] = *((uint8_t*)AVR32_USBB_EP_DATA);
return Data.Word;
}
@ -695,8 +698,8 @@
static inline void Pipe_Write_Word_LE(const uint16_t Word) ATTR_ALWAYS_INLINE;
static inline void Pipe_Write_Word_LE(const uint16_t Word)
{
UPDATX = (Word & 0xFF);
UPDATX = (Word >> 8);
*((uint8_t*)AVR32_USBB_EP_DATA) = (Word & 0xFF);
*((uint8_t*)AVR32_USBB_EP_DATA) = (Word >> 8);
}
/** Writes two bytes to the currently selected pipe's bank in big endian format, for IN
@ -709,8 +712,8 @@
static inline void Pipe_Write_Word_BE(const uint16_t Word) ATTR_ALWAYS_INLINE;
static inline void Pipe_Write_Word_BE(const uint16_t Word)
{
UPDATX = (Word >> 8);
UPDATX = (Word & 0xFF);
*((uint8_t*)AVR32_USBB_EP_DATA) = (Word >> 8);
*((uint8_t*)AVR32_USBB_EP_DATA) = (Word & 0xFF);
}
/** Discards two bytes from the currently selected pipe's bank, for OUT direction pipes.
@ -722,8 +725,8 @@
{
uint8_t Dummy;
Dummy = UPDATX;
Dummy = UPDATX;
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
}
/** Reads four bytes from the currently selected pipe's bank in little endian format, for OUT
@ -742,10 +745,10 @@
uint8_t Bytes[4];
} Data;
Data.Bytes[0] = UPDATX;
Data.Bytes[1] = UPDATX;
Data.Bytes[2] = UPDATX;
Data.Bytes[3] = UPDATX;
Data.Bytes[0] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[1] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[2] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[3] = *((uint8_t*)AVR32_USBB_EP_DATA);
return Data.DWord;
}
@ -766,10 +769,10 @@
uint8_t Bytes[4];
} Data;
Data.Bytes[3] = UPDATX;
Data.Bytes[2] = UPDATX;
Data.Bytes[1] = UPDATX;
Data.Bytes[0] = UPDATX;
Data.Bytes[3] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[2] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[1] = *((uint8_t*)AVR32_USBB_EP_DATA);
Data.Bytes[0] = *((uint8_t*)AVR32_USBB_EP_DATA);
return Data.DWord;
}
@ -784,10 +787,10 @@
static inline void Pipe_Write_DWord_LE(const uint32_t DWord) ATTR_ALWAYS_INLINE;
static inline void Pipe_Write_DWord_LE(const uint32_t DWord)
{
UPDATX = (DWord & 0xFF);
UPDATX = (DWord >> 8);
UPDATX = (DWord >> 16);
UPDATX = (DWord >> 24);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord & 0xFF);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 8);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 16);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 24);
}
/** Writes four bytes to the currently selected pipe's bank in big endian format, for IN
@ -800,10 +803,10 @@
static inline void Pipe_Write_DWord_BE(const uint32_t DWord) ATTR_ALWAYS_INLINE;
static inline void Pipe_Write_DWord_BE(const uint32_t DWord)
{
UPDATX = (DWord >> 24);
UPDATX = (DWord >> 16);
UPDATX = (DWord >> 8);
UPDATX = (DWord & 0xFF);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 24);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 16);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord >> 8);
*((uint8_t*)AVR32_USBB_EP_DATA) = (DWord & 0xFF);
}
/** Discards four bytes from the currently selected pipe's bank, for OUT direction pipes.
@ -815,10 +818,10 @@
{
uint8_t Dummy;
Dummy = UPDATX;
Dummy = UPDATX;
Dummy = UPDATX;
Dummy = UPDATX;
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
Dummy = *((uint8_t*)AVR32_USBB_EP_DATA);
}
/* External Variables: */
@ -925,11 +928,14 @@
CheckBytes <<= 1;
}
return (MaskVal << EPSIZE0);
return (MaskVal << AVR32_USBB_PSIZE_OFFSET);
}
/* Function Prototypes: */
void Pipe_ClearPipes(void);
/* External Variables: */
extern uint8_t USB_SelectedPipe;
#endif
/* Disable C linkage for C++ Compilers: */

@ -55,6 +55,7 @@
* added new versions of the *_SendString() routines that expect a null terminated string instead
* - Renamed all driver termination *_ShutDown() functions to the more logical name *_Disable()
* - Reduced latency for executing the Start-Of-Frame events (if enabled in the user application)
* - Removed Pipe_ClearErrorFlags(), pipe error flags are now automatically cleared when Pipe_ClearError() is called
* - Library Applications:
* - Changed the XPLAINBridge software UART to use the regular timer CTC mode instead of the alternative CTC mode
* via the Input Capture register, to reduce user confusion

@ -51,9 +51,6 @@ volatile struct
uint8_t PingPongLEDPulse; /**< Milliseconds remaining for enumeration Tx/Rx ping-pong LED pulse */
} PulseMSRemaining;
/** Previous state of the virtual DTR control line from the host */
bool PreviousDTRState = false;
/** Milliseconds remaining until the receive buffer is flushed to the USB host */
uint8_t FlushPeriodRemaining = RECEIVE_BUFFER_FLUSH_MS;
@ -286,6 +283,7 @@ ISR(USART1_RX_vect, ISR_BLOCK)
*/
void EVENT_CDC_Device_ControLineStateChanged(USB_ClassInfo_CDC_Device_t* const CDCInterfaceInfo)
{
static bool PreviousDTRState = false;
bool CurrentDTRState = (CDCInterfaceInfo->State.ControlLineStates.HostToDevice & CDC_CONTROL_LINE_OUT_DTR);
/* Check if the DTR line has been asserted - if so, start the target AVR's reset pulse */

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