qmk_firmware/lib/lufa/LUFA/DoxygenPages/CompileTimeTokens.txt

/** \file
 *
 *  This file contains special DoxyGen information for the generation of the main page and other special
 *  documentation pages. It is not a project source file.
 */

/** \page Page_TokenSummary Summary of Compile Tokens
 *
 *  The following lists all the possible tokens which can be defined in a project makefile, and passed to the
 *  compiler via the -D switch, to alter the LUFA library code. These tokens may alter the library behaviour,
 *  or remove features unused by a given application in order to save flash space.
 *
 *  \note If the \c USE_LUFA_CONFIG_HEADER token is defined, the library will include a header file named \c LUFAConfig.h located
 *        in the user directory where the below compile time tokens may be defined. This allows for an alternative to makefile
 *        defined tokens for configuring the library.
 *
 *  \section Sec_TokenSummary_NonUSBTokens Non USB Related Tokens
 *  This section describes compile tokens which affect non-USB sections of the LUFA library.
 *
 *  \li <b>DISABLE_TERMINAL_CODES</b> - (\ref Group_Terminal) - <i>All Architectures</i> \n
 *      If an application contains ANSI terminal control codes listed in TerminalCodes.h, it might be desired to remove them
 *      at compile time for use with a terminal which is non-ANSI control code aware, without modifying the source code. If
 *      this token is defined, all ANSI control codes in the application code from the TerminalCodes.h header are removed from
 *      the source code at compile time.
 *
 *
 *  \section Sec_TokenSummary_USBClassTokens USB Class Driver Related Tokens
 *  This section describes compile tokens which affect USB class-specific drivers in the LUFA library.
 *
 *  \li <b>HID_HOST_BOOT_PROTOCOL_ONLY</b> - (\ref Group_USBClassHIDHost) - <i>All Architectures</i> \n
 *      By default, the USB HID Host class driver is designed to work with HID devices using either the Boot or Report HID
 *      communication protocols. On devices where the Report protocol is not used (i.e. in applications where only basic
 *      Mouse or Keyboard operation is desired, using boot compatible devices), the code responsible for the Report protocol
 *      mode can be removed to save space in the compiled application by defining this token. When defined, it is still necessary
 *      to explicitly put the attached device into Boot protocol mode via a call to \ref HID_Host_SetBootProtocol().
 *
 *  \li <b>HID_STATETABLE_STACK_DEPTH</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n
 *      HID reports may contain PUSH and POP elements, to store and retrieve the current HID state table onto a stack. This
 *      allows for reports to save the state table before modifying it slightly for a data item, and then restore the previous
 *      state table in a compact manner. This token may be defined to a non-zero 8-bit value to give the maximum depth of the state
 *      table stack. If not defined, this defaults to the value indicated in the HID.h file documentation.
 *
 *  \li <b>HID_USAGE_STACK_DEPTH</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n
 *      HID reports generally contain many USAGE elements, which are assigned to INPUT, OUTPUT and FEATURE items in succession
 *      when multiple items are defined at once (via REPORT COUNT elements). This allows for several items to be defined with
 *      different usages in a compact manner. This token may be defined to a non-zero 8-bit value to set the maximum depth of the
 *      usage stack, indicating the maximum number of USAGE items which can be stored temporarily until the next INPUT, OUTPUT
 *      and FEATURE item. If not defined, this defaults to the value indicated in the HID.h file documentation.
 *
 *  \li <b>HID_MAX_COLLECTIONS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n
 *      HID reports generally contain several COLLECTION elements, used to group related data items together. Collection information
 *      is stored separately in the processed usage structure (and referred to by the data elements in the structure) to save space.
 *      This token may be defined to a non-zero 8-bit value to set the maximum number of COLLECTION items which can be processed by the
 *      parser into the resultant processed report structure. If not defined, this defaults to the value indicated in the HID.h file
 *      documentation.
 *
 *  \li <b>HID_MAX_REPORTITEMS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n
 *      All HID reports contain one or more INPUT, OUTPUT and/or FEATURE items describing the data which can be sent to and from the HID
 *      device. Each item has associated usages, bit offsets in the item reports and other associated data indicating the manner in which
 *      the report data should be interpreted by the host. This token may be defined to a non-zero 8-bit value to set the maximum number of
 *      data elements which can be stored in the processed HID report structure, including INPUT, OUTPUT and (if enabled) FEATURE items.
 *      If a item has a multiple count (i.e. a REPORT COUNT of more than 1), each item in the report count is placed separately in the
 *      processed HID report table. If not defined, this defaults to the value indicated in the HID.h file documentation.
 *
 *  \li <b>HID_MAX_REPORT_IDS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n
 *      HID reports may contain several report IDs, to logically distinguish grouped device data from one another - for example, a combination
 *      keyboard and mouse might use report IDs to separate the keyboard reports from the mouse reports. In order to determine the size of each
 *      report, and thus know how many bytes must be read or written, the size of each report (IN, OUT and FEATURE) must be calculated and
 *      stored. This token may be defined to a non-zero 8-bit value to set the maximum number of report IDs in a device which can be processed
 *      and their sizes calculated/stored into the resultant processed report structure. If not defined, this defaults to the value indicated in
 *      the HID.h file documentation.
 *
 *  \li <b>NO_CLASS_DRIVER_AUTOFLUSH</b> - (\ref Group_USBClassDrivers) - <i>All Architectures</i> \n
 *      Many of the device and host mode class drivers automatically flush any data waiting to be written to an interface, when the corresponding
 *      USB management task is executed. This is usually desirable to ensure that any queued data is sent as soon as possible once and new data is
 *      constructed in the main program loop. However, if flushing is to be controlled manually by the user application via the *_Flush() commands,
 *      the compile time token may be defined in the application's makefile to disable automatic flushing during calls to the class driver USB
 *      management tasks.
 *
 *
 *  \section Sec_TokenSummary_USBTokens General USB Driver Related Tokens
 *  This section describes compile tokens which affect USB driver stack as a whole in the LUFA library.
 *
 *  \li <b>ORDERED_EP_CONFIG</b> - (\ref Group_EndpointManagement , \ref Group_PipeManagement) - <i>AVR8, UC3</i> \n
 *      The USB AVRs do not allow for Endpoints and Pipes to be configured out of order; they <i>must</i> be configured in an ascending order to
 *      prevent data corruption issues. However, by default LUFA employs a workaround to allow for unordered Endpoint/Pipe initialization. This compile
 *      time token may be used to restrict the initialization order to ascending indexes only in exchange for a smaller compiled binary size. Use
 *      caution when applied to applications using the library USB Class drivers; the user application must ensure that all endpoints and pipes are
 *      allocated sequentially.
 *
 *  \li <b>USE_STATIC_OPTIONS</b>=<i>x</i> - (\ref Group_USBManagement) - <i>All Architectures</i> \n
 *      By default, the USB_Init() function accepts dynamic options at runtime to alter the library behaviour, including whether the USB pad
 *      voltage regulator is enabled, and the device speed when in device mode. By defining this token to a mask comprised of the USB options
 *      mask defines usually passed as the Options parameter to USB_Init(), the resulting compiled binary can be decreased in size by removing
 *      the dynamic options code, and replacing it with the statically set options. When defined, the USB_Init() function no longer accepts an
 *      Options parameter.
 *
 *  \li <b>USB_DEVICE_ONLY</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n
 *      For the USB AVR models supporting both device and host USB modes, the USB_Init() function contains a Mode parameter which specifies the
 *      mode the library should be initialized to. If only device mode is required, the code for USB host mode can be removed from the binary to
 *      save space. When defined, the USB_Init() function no longer accepts a Mode parameter. This define is irrelevant on smaller USB AVRs which
 *      do not support host mode.
 *
 *  \li <b>USB_HOST_ONLY</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n
 *      Same as USB_DEVICE_ONLY, except the library is fixed to USB host mode rather than USB device mode. Not available on some USB AVR models.
 *
 *  \li <b>USB_STREAM_TIMEOUT_MS</b>=<i>x</i> - (\ref Group_USBManagement) - <i>All Architectures</i> \n
 *      When endpoint and/or pipe stream functions are used, by default there is a timeout between each transfer which the connected device or host
 *      must satisfy, or the stream function aborts the remaining data transfer. This token may be defined to a non-zero 16-bit value to set the timeout
 *      period for stream transfers, specified in milliseconds. If not defined, the default value specified in LowLevel.h is used instead.
 *
 *  \li <b>NO_LIMITED_CONTROLLER_CONNECT</b> - (\ref Group_Events) - <i>AVR8 Only</i> \n
 *      On the smaller USB AVRs, the USB controller lacks VBUS events to determine the physical connection state of the USB bus to a host. In lieu of
 *      VBUS events, the library attempts to determine the connection state via the bus suspension and wake up events instead. This however may be
 *      slightly inaccurate due to the possibility of the host suspending the bus while the device is still connected. If accurate connection status is
 *      required, the VBUS line of the USB connector should be routed to an AVR pin to detect its level, so that the \ref USB_DeviceState global
 *      can be accurately set and the \ref EVENT_USB_Device_Connect() and \ref EVENT_USB_Device_Disconnect() events manually raised by the user application.
 *      When defined, this token disables the library's auto-detection of the connection state by the aforementioned suspension and wake up events.
 *
 *  \li <b>NO_SOF_EVENTS</b> - (\ref Group_Events) - <i>All Architectures</i> \n
 *      By default, there exists a LUFA application event for the start of each USB frame while the USB bus is not suspended in either host or device mode.
 *      This event can be selectively enabled or disabled by calling the appropriate device or host mode function. When this compile time token is defined,
 *      the ability to receive USB Start of Frame events via the \ref EVENT_USB_Device_StartOfFrame() or \ref EVENT_USB_Host_StartOfFrame() events is removed,
 *      reducing the compiled program's binary size.
 *
 *
 *  \section Sec_TokenSummary_USBDeviceTokens USB Device Mode Driver Related Tokens
 *  This section describes compile tokens which affect USB driver stack of the LUFA library when used in Device mode.
 *
 *  \li <b>USE_RAM_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n
 *      Define this token to indicate to the USB driver that all device descriptors are stored in RAM, rather than being located in any one
 *      of the AVR's memory spaces. RAM descriptors may be desirable in applications where the descriptors need to be modified at runtime.
 *
 *  \li <b>USE_FLASH_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n
 *      Similar to USE_RAM_DESCRIPTORS, but all descriptors are stored in the AVR's FLASH memory rather than RAM.
 *
 *  \li <b>USE_EEPROM_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n
 *      Similar to USE_RAM_DESCRIPTORS, but all descriptors are stored in the AVR's EEPROM memory rather than RAM.
 *
 *  \li <b>NO_INTERNAL_SERIAL</b> - (\ref Group_StdDescriptors) - <i>All Architectures</i> \n
 *      Some AVR models contain a unique serial number which can be used as the device serial number, while in device mode. This allows
 *      the host to uniquely identify the device regardless of if it is moved between USB ports on the same computer, allowing allocated
 *      resources (such as drivers, COM Port number allocations) to be preserved. This is not needed in many apps, and so the code that
 *      performs this task can be disabled by defining this option and passing it to the compiler via the -D switch.
 *
 *  \li <b>FIXED_CONTROL_ENDPOINT_SIZE</b>=<i>x</i> - (\ref Group_EndpointManagement) - <i>All Architectures</i> \n
 *      By default, the library determines the size of the control endpoint (when in device mode) by reading the device descriptor.
 *      Normally this reduces the amount of configuration required for the library, allows the value to change dynamically (if
 *      descriptors are stored in EEPROM or RAM rather than flash memory) and reduces code maintenance. However, this token can be
 *      defined to a non-zero value instead to give the size in bytes of the control endpoint, to reduce the size of the compiled
 *      binary.
 *
 *  \li <b>DEVICE_STATE_AS_GPIOR</b> - (\ref Group_Device) - <i>AVR8 Only</i> \n
 *      One of the most frequently used global variables in the stack is the USB_DeviceState global, which indicates the current state of
 *      the Device State Machine. To reduce the amount of code and time required to access and modify this global in an application, this token
 *      may be defined to a value between 0 and 2 to fix the state variable into one of the three general purpose IO registers inside the AVR
 *      reserved for application use. When defined, the corresponding GPIOR register should not be used within the user application except
 *      implicitly via the library APIs.
 *
 *  \li <b>FIXED_NUM_CONFIGURATIONS</b>=<i>x</i> - (\ref Group_Device) - <i>All Architectures</i> \n
 *      By default, the library determines the number of configurations a USB device supports by reading the device descriptor. This reduces
 *      the amount of configuration required to set up the library, and allows the value to change dynamically (if descriptors are stored in
 *      EEPROM or RAM rather than flash memory) and reduces code maintenance. However, this value may be fixed via this token in the project
 *      makefile to reduce the compiled size of the binary at the expense of flexibility.
 *
 *  \li <b>CONTROL_ONLY_DEVICE</b> - (\ref Group_Device) - <i>All Architectures</i> \n
 *      In some limited USB device applications, there are no device endpoints other than the control endpoint; i.e. all device communication
 *      is through control endpoint requests. Defining this token will remove several features related to the selection and control of device
 *      endpoints internally, saving space. Generally, this is usually only useful in (some) bootloaders and is best avoided.
 *
 *  \li <b>MAX_ENDPOINT_INDEX</b> - (\ref Group_Device) - <i>XMEGA Only</i> \n
 *      Defining this value to the highest index (not address - this excludes the direction flag) endpoint within the device will restrict the
 *      number of FIFOs created internally for the endpoint buffers, reducing the total RAM usage.
 *
 *  \li <b>INTERRUPT_CONTROL_ENDPOINT</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n
 *      Some applications prefer to not call the USB_USBTask() management task regularly while in device mode, as it can complicate code significantly.
 *      Instead, when device mode is used this token can be passed to the library via the -D switch to allow the library to manage the USB control
 *      endpoint entirely via USB controller interrupts asynchronously to the user application. When defined, USB_USBTask() does not need to be called
 *      when in USB device mode.
 *
 *  \li <b>NO_DEVICE_REMOTE_WAKEUP</b> - (\ref Group_Device) - <i>All Architectures</i> \n
 *      Many devices do not require the use of the Remote Wakeup features of USB, used to wake up the USB host when suspended. On these devices,
 *      the code required to manage device Remote Wakeup can be disabled by defining this token and passing it to the library via the -D switch.
 *
 *  \li <b>NO_DEVICE_SELF_POWER</b> - (\ref Group_Device) - <i>All Architectures</i> \n
 *      USB devices may be bus powered, self powered, or a combination of both. When a device can be both bus powered and self powered, the host may
 *      query the device to determine the current power source, via \ref USB_Device_CurrentlySelfPowered. For solely bus powered devices, this global
 *      and the code required to manage it may be disabled by passing this token to the library via the -D switch.
 *
 *
 *  \section Sec_TokenSummary_USBHostTokens USB Host Mode Driver Related Tokens
 *
 *  This section describes compile tokens which affect USB driver stack of the LUFA library when used in Host mode.
 *
 *  \li <b>HOST_STATE_AS_GPIOR</b> - (\ref Group_Host) - <i>AVR8 Only</i> \n
 *      One of the most frequently used global variables in the stack is the USB_HostState global, which indicates the current state of
 *      the Host State Machine. To reduce the amount of code and time required to access and modify this global in an application, this token
 *      may be defined to a value between 0 and 2 to fix the state variable into one of the three general purpose IO registers inside the AVR
 *      reserved for application use. When defined, the corresponding GPIOR register should not be used within the user application except
 *      implicitly via the library APIs.
 *
 *  \li <b>USB_HOST_TIMEOUT_MS</b>=<i>x</i> - (\ref Group_Host) - <i>All Architectures</i> \n
 *      When a control transfer is initiated in host mode to an attached device, a timeout is used to abort the transfer if the attached
 *      device fails to respond within the timeout period. This token may be defined to a non-zero 16-bit value to set the timeout period for
 *      control transfers, specified in milliseconds. If not defined, the default value specified in Host.h is used instead.
 *
 *  \li <b>HOST_DEVICE_SETTLE_DELAY_MS</b>=<i>x</i> - (\ref Group_Host) - <i>All Architectures</i> \n
 *      Some devices require a delay of up to 5 seconds after they are connected to VBUS before the enumeration process can be started, or
 *      they will fail to enumerate correctly. By placing a delay before the enumeration process, it can be ensured that the bus has settled
 *      back to a known idle state before communications occur with the device. This token may be defined to a 16-bit value to set the device
 *      settle period, specified in milliseconds. If not defined, the default value specified in Host.h is used instead.
 *
 *  \li <b>INVERTED_VBUS_ENABLE_LINE</b> - (\ref Group_Host) - <i>All Architectures</i> \n
 *      If enabled, this will indicate that the USB target VBUS line polarity is inverted; i.e. it should be pulled low to enable VBUS to the
 *      target, and pulled high to stop the target VBUS generation.
 *      \n
 *      \attention On AVR8 architecture devices, this compile time option requires \c NO_AUTO_VBUS_MANAGEMENT to be set.
 *
 *  \li <b>NO_AUTO_VBUS_MANAGEMENT</b> - (\ref Group_Host) - <i>All Architectures</i> \n
 *      Disables the automatic management of VBUS to the target, i.e. automatic shut down in the even of an overcurrent situation. When enabled, VBUS
 *      is enabled while the USB controller is initialized in USB Host mode.
 */
Squashed 'lib/lufa/' content from commit 385d40300 git-subtree-dir: lib/lufa git-subtree-split: 385d4030035dbaf41591309dbde47653bd03841b 2017-07-07 15:55:23 +00:00			`/** \file`
			`*`
			`* This file contains special DoxyGen information for the generation of the main page and other special`
			`* documentation pages. It is not a project source file.`
			`*/`

			`/** \page Page_TokenSummary Summary of Compile Tokens`
			`*`
			`* The following lists all the possible tokens which can be defined in a project makefile, and passed to the`
			`* compiler via the -D switch, to alter the LUFA library code. These tokens may alter the library behaviour,`
			`* or remove features unused by a given application in order to save flash space.`
			`*`
			`* \note If the \c USE_LUFA_CONFIG_HEADER token is defined, the library will include a header file named \c LUFAConfig.h located`
			`* in the user directory where the below compile time tokens may be defined. This allows for an alternative to makefile`
			`* defined tokens for configuring the library.`
			`*`
			`* \section Sec_TokenSummary_NonUSBTokens Non USB Related Tokens`
			`* This section describes compile tokens which affect non-USB sections of the LUFA library.`
			`*`
			`* \li <b>DISABLE_TERMINAL_CODES</b> - (\ref Group_Terminal) - <i>All Architectures</i> \n`
			`* If an application contains ANSI terminal control codes listed in TerminalCodes.h, it might be desired to remove them`
			`* at compile time for use with a terminal which is non-ANSI control code aware, without modifying the source code. If`
			`* this token is defined, all ANSI control codes in the application code from the TerminalCodes.h header are removed from`
			`* the source code at compile time.`
			`*`
			`*`
			`* \section Sec_TokenSummary_USBClassTokens USB Class Driver Related Tokens`
			`* This section describes compile tokens which affect USB class-specific drivers in the LUFA library.`
			`*`
			`* \li <b>HID_HOST_BOOT_PROTOCOL_ONLY</b> - (\ref Group_USBClassHIDHost) - <i>All Architectures</i> \n`
			`* By default, the USB HID Host class driver is designed to work with HID devices using either the Boot or Report HID`
			`* communication protocols. On devices where the Report protocol is not used (i.e. in applications where only basic`
			`* Mouse or Keyboard operation is desired, using boot compatible devices), the code responsible for the Report protocol`
			`* mode can be removed to save space in the compiled application by defining this token. When defined, it is still necessary`
			`* to explicitly put the attached device into Boot protocol mode via a call to \ref HID_Host_SetBootProtocol().`
			`*`
			`* \li <b>HID_STATETABLE_STACK_DEPTH</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n`
			`* HID reports may contain PUSH and POP elements, to store and retrieve the current HID state table onto a stack. This`
			`* allows for reports to save the state table before modifying it slightly for a data item, and then restore the previous`
			`* state table in a compact manner. This token may be defined to a non-zero 8-bit value to give the maximum depth of the state`
			`* table stack. If not defined, this defaults to the value indicated in the HID.h file documentation.`
			`*`
			`* \li <b>HID_USAGE_STACK_DEPTH</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n`
			`* HID reports generally contain many USAGE elements, which are assigned to INPUT, OUTPUT and FEATURE items in succession`
			`* when multiple items are defined at once (via REPORT COUNT elements). This allows for several items to be defined with`
			`* different usages in a compact manner. This token may be defined to a non-zero 8-bit value to set the maximum depth of the`
			`* usage stack, indicating the maximum number of USAGE items which can be stored temporarily until the next INPUT, OUTPUT`
			`* and FEATURE item. If not defined, this defaults to the value indicated in the HID.h file documentation.`
			`*`
			`* \li <b>HID_MAX_COLLECTIONS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n`
			`* HID reports generally contain several COLLECTION elements, used to group related data items together. Collection information`
			`* is stored separately in the processed usage structure (and referred to by the data elements in the structure) to save space.`
			`* This token may be defined to a non-zero 8-bit value to set the maximum number of COLLECTION items which can be processed by the`
			`* parser into the resultant processed report structure. If not defined, this defaults to the value indicated in the HID.h file`
			`* documentation.`
			`*`
			`* \li <b>HID_MAX_REPORTITEMS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n`
			`* All HID reports contain one or more INPUT, OUTPUT and/or FEATURE items describing the data which can be sent to and from the HID`
			`* device. Each item has associated usages, bit offsets in the item reports and other associated data indicating the manner in which`
			`* the report data should be interpreted by the host. This token may be defined to a non-zero 8-bit value to set the maximum number of`
			`* data elements which can be stored in the processed HID report structure, including INPUT, OUTPUT and (if enabled) FEATURE items.`
			`* If a item has a multiple count (i.e. a REPORT COUNT of more than 1), each item in the report count is placed separately in the`
			`* processed HID report table. If not defined, this defaults to the value indicated in the HID.h file documentation.`
			`*`
			`* \li <b>HID_MAX_REPORT_IDS</b>=<i>x</i> - (\ref Group_HIDParser) - <i>All Architectures</i> \n`
			`* HID reports may contain several report IDs, to logically distinguish grouped device data from one another - for example, a combination`
			`* keyboard and mouse might use report IDs to separate the keyboard reports from the mouse reports. In order to determine the size of each`
			`* report, and thus know how many bytes must be read or written, the size of each report (IN, OUT and FEATURE) must be calculated and`
			`* stored. This token may be defined to a non-zero 8-bit value to set the maximum number of report IDs in a device which can be processed`
			`* and their sizes calculated/stored into the resultant processed report structure. If not defined, this defaults to the value indicated in`
			`* the HID.h file documentation.`
			`*`
			`* \li <b>NO_CLASS_DRIVER_AUTOFLUSH</b> - (\ref Group_USBClassDrivers) - <i>All Architectures</i> \n`
			`* Many of the device and host mode class drivers automatically flush any data waiting to be written to an interface, when the corresponding`
			`* USB management task is executed. This is usually desirable to ensure that any queued data is sent as soon as possible once and new data is`
			`* constructed in the main program loop. However, if flushing is to be controlled manually by the user application via the *_Flush() commands,`
			`* the compile time token may be defined in the application's makefile to disable automatic flushing during calls to the class driver USB`
			`* management tasks.`
			`*`
			`*`
			`* \section Sec_TokenSummary_USBTokens General USB Driver Related Tokens`
			`* This section describes compile tokens which affect USB driver stack as a whole in the LUFA library.`
			`*`
			`* \li <b>ORDERED_EP_CONFIG</b> - (\ref Group_EndpointManagement , \ref Group_PipeManagement) - <i>AVR8, UC3</i> \n`
			`* The USB AVRs do not allow for Endpoints and Pipes to be configured out of order; they <i>must</i> be configured in an ascending order to`
			`* prevent data corruption issues. However, by default LUFA employs a workaround to allow for unordered Endpoint/Pipe initialization. This compile`
			`* time token may be used to restrict the initialization order to ascending indexes only in exchange for a smaller compiled binary size. Use`
			`* caution when applied to applications using the library USB Class drivers; the user application must ensure that all endpoints and pipes are`
			`* allocated sequentially.`
			`*`
			`* \li <b>USE_STATIC_OPTIONS</b>=<i>x</i> - (\ref Group_USBManagement) - <i>All Architectures</i> \n`
			`* By default, the USB_Init() function accepts dynamic options at runtime to alter the library behaviour, including whether the USB pad`
			`* voltage regulator is enabled, and the device speed when in device mode. By defining this token to a mask comprised of the USB options`
			`* mask defines usually passed as the Options parameter to USB_Init(), the resulting compiled binary can be decreased in size by removing`
			`* the dynamic options code, and replacing it with the statically set options. When defined, the USB_Init() function no longer accepts an`
			`* Options parameter.`
			`*`
			`* \li <b>USB_DEVICE_ONLY</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n`
			`* For the USB AVR models supporting both device and host USB modes, the USB_Init() function contains a Mode parameter which specifies the`
			`* mode the library should be initialized to. If only device mode is required, the code for USB host mode can be removed from the binary to`
			`* save space. When defined, the USB_Init() function no longer accepts a Mode parameter. This define is irrelevant on smaller USB AVRs which`
			`* do not support host mode.`
			`*`
			`* \li <b>USB_HOST_ONLY</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n`
			`* Same as USB_DEVICE_ONLY, except the library is fixed to USB host mode rather than USB device mode. Not available on some USB AVR models.`
			`*`
			`* \li <b>USB_STREAM_TIMEOUT_MS</b>=<i>x</i> - (\ref Group_USBManagement) - <i>All Architectures</i> \n`
			`* When endpoint and/or pipe stream functions are used, by default there is a timeout between each transfer which the connected device or host`
			`* must satisfy, or the stream function aborts the remaining data transfer. This token may be defined to a non-zero 16-bit value to set the timeout`
			`* period for stream transfers, specified in milliseconds. If not defined, the default value specified in LowLevel.h is used instead.`
			`*`
			`* \li <b>NO_LIMITED_CONTROLLER_CONNECT</b> - (\ref Group_Events) - <i>AVR8 Only</i> \n`
			`* On the smaller USB AVRs, the USB controller lacks VBUS events to determine the physical connection state of the USB bus to a host. In lieu of`
			`* VBUS events, the library attempts to determine the connection state via the bus suspension and wake up events instead. This however may be`
			`* slightly inaccurate due to the possibility of the host suspending the bus while the device is still connected. If accurate connection status is`
			`* required, the VBUS line of the USB connector should be routed to an AVR pin to detect its level, so that the \ref USB_DeviceState global`
			`* can be accurately set and the \ref EVENT_USB_Device_Connect() and \ref EVENT_USB_Device_Disconnect() events manually raised by the user application.`
			`* When defined, this token disables the library's auto-detection of the connection state by the aforementioned suspension and wake up events.`
			`*`
			`* \li <b>NO_SOF_EVENTS</b> - (\ref Group_Events) - <i>All Architectures</i> \n`
			`* By default, there exists a LUFA application event for the start of each USB frame while the USB bus is not suspended in either host or device mode.`
			`* This event can be selectively enabled or disabled by calling the appropriate device or host mode function. When this compile time token is defined,`
			`* the ability to receive USB Start of Frame events via the \ref EVENT_USB_Device_StartOfFrame() or \ref EVENT_USB_Host_StartOfFrame() events is removed,`
			`* reducing the compiled program's binary size.`
			`*`
			`*`
			`* \section Sec_TokenSummary_USBDeviceTokens USB Device Mode Driver Related Tokens`
			`* This section describes compile tokens which affect USB driver stack of the LUFA library when used in Device mode.`
			`*`
			`* \li <b>USE_RAM_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n`
			`* Define this token to indicate to the USB driver that all device descriptors are stored in RAM, rather than being located in any one`
			`* of the AVR's memory spaces. RAM descriptors may be desirable in applications where the descriptors need to be modified at runtime.`
			`*`
			`* \li <b>USE_FLASH_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n`
			`* Similar to USE_RAM_DESCRIPTORS, but all descriptors are stored in the AVR's FLASH memory rather than RAM.`
			`*`
			`* \li <b>USE_EEPROM_DESCRIPTORS</b> - (\ref Group_StdDescriptors) - <i>AVR8 Only</i> \n`
			`* Similar to USE_RAM_DESCRIPTORS, but all descriptors are stored in the AVR's EEPROM memory rather than RAM.`
			`*`
			`* \li <b>NO_INTERNAL_SERIAL</b> - (\ref Group_StdDescriptors) - <i>All Architectures</i> \n`
			`* Some AVR models contain a unique serial number which can be used as the device serial number, while in device mode. This allows`
			`* the host to uniquely identify the device regardless of if it is moved between USB ports on the same computer, allowing allocated`
			`* resources (such as drivers, COM Port number allocations) to be preserved. This is not needed in many apps, and so the code that`
			`* performs this task can be disabled by defining this option and passing it to the compiler via the -D switch.`
			`*`
			`* \li <b>FIXED_CONTROL_ENDPOINT_SIZE</b>=<i>x</i> - (\ref Group_EndpointManagement) - <i>All Architectures</i> \n`
			`* By default, the library determines the size of the control endpoint (when in device mode) by reading the device descriptor.`
			`* Normally this reduces the amount of configuration required for the library, allows the value to change dynamically (if`
			`* descriptors are stored in EEPROM or RAM rather than flash memory) and reduces code maintenance. However, this token can be`
			`* defined to a non-zero value instead to give the size in bytes of the control endpoint, to reduce the size of the compiled`
			`* binary.`
			`*`
			`* \li <b>DEVICE_STATE_AS_GPIOR</b> - (\ref Group_Device) - <i>AVR8 Only</i> \n`
			`* One of the most frequently used global variables in the stack is the USB_DeviceState global, which indicates the current state of`
			`* the Device State Machine. To reduce the amount of code and time required to access and modify this global in an application, this token`
			`* may be defined to a value between 0 and 2 to fix the state variable into one of the three general purpose IO registers inside the AVR`
			`* reserved for application use. When defined, the corresponding GPIOR register should not be used within the user application except`
			`* implicitly via the library APIs.`
			`*`
			`* \li <b>FIXED_NUM_CONFIGURATIONS</b>=<i>x</i> - (\ref Group_Device) - <i>All Architectures</i> \n`
			`* By default, the library determines the number of configurations a USB device supports by reading the device descriptor. This reduces`
			`* the amount of configuration required to set up the library, and allows the value to change dynamically (if descriptors are stored in`
			`* EEPROM or RAM rather than flash memory) and reduces code maintenance. However, this value may be fixed via this token in the project`
			`* makefile to reduce the compiled size of the binary at the expense of flexibility.`
			`*`
			`* \li <b>CONTROL_ONLY_DEVICE</b> - (\ref Group_Device) - <i>All Architectures</i> \n`
			`* In some limited USB device applications, there are no device endpoints other than the control endpoint; i.e. all device communication`
			`* is through control endpoint requests. Defining this token will remove several features related to the selection and control of device`
			`* endpoints internally, saving space. Generally, this is usually only useful in (some) bootloaders and is best avoided.`
			`*`
			`* \li <b>MAX_ENDPOINT_INDEX</b> - (\ref Group_Device) - <i>XMEGA Only</i> \n`
			`* Defining this value to the highest index (not address - this excludes the direction flag) endpoint within the device will restrict the`
			`* number of FIFOs created internally for the endpoint buffers, reducing the total RAM usage.`
			`*`
			`* \li <b>INTERRUPT_CONTROL_ENDPOINT</b> - (\ref Group_USBManagement) - <i>All Architectures</i> \n`
			`* Some applications prefer to not call the USB_USBTask() management task regularly while in device mode, as it can complicate code significantly.`
			`* Instead, when device mode is used this token can be passed to the library via the -D switch to allow the library to manage the USB control`
			`* endpoint entirely via USB controller interrupts asynchronously to the user application. When defined, USB_USBTask() does not need to be called`
			`* when in USB device mode.`
			`*`
			`* \li <b>NO_DEVICE_REMOTE_WAKEUP</b> - (\ref Group_Device) - <i>All Architectures</i> \n`
			`* Many devices do not require the use of the Remote Wakeup features of USB, used to wake up the USB host when suspended. On these devices,`
			`* the code required to manage device Remote Wakeup can be disabled by defining this token and passing it to the library via the -D switch.`
			`*`
			`* \li <b>NO_DEVICE_SELF_POWER</b> - (\ref Group_Device) - <i>All Architectures</i> \n`
			`* USB devices may be bus powered, self powered, or a combination of both. When a device can be both bus powered and self powered, the host may`
			`* query the device to determine the current power source, via \ref USB_Device_CurrentlySelfPowered. For solely bus powered devices, this global`
			`* and the code required to manage it may be disabled by passing this token to the library via the -D switch.`
			`*`
			`*`
			`* \section Sec_TokenSummary_USBHostTokens USB Host Mode Driver Related Tokens`
			`*`
			`* This section describes compile tokens which affect USB driver stack of the LUFA library when used in Host mode.`
			`*`
			`* \li <b>HOST_STATE_AS_GPIOR</b> - (\ref Group_Host) - <i>AVR8 Only</i> \n`
			`* One of the most frequently used global variables in the stack is the USB_HostState global, which indicates the current state of`
			`* the Host State Machine. To reduce the amount of code and time required to access and modify this global in an application, this token`
			`* may be defined to a value between 0 and 2 to fix the state variable into one of the three general purpose IO registers inside the AVR`
			`* reserved for application use. When defined, the corresponding GPIOR register should not be used within the user application except`
			`* implicitly via the library APIs.`
			`*`
			`* \li <b>USB_HOST_TIMEOUT_MS</b>=<i>x</i> - (\ref Group_Host) - <i>All Architectures</i> \n`
			`* When a control transfer is initiated in host mode to an attached device, a timeout is used to abort the transfer if the attached`
			`* device fails to respond within the timeout period. This token may be defined to a non-zero 16-bit value to set the timeout period for`
			`* control transfers, specified in milliseconds. If not defined, the default value specified in Host.h is used instead.`
			`*`
			`* \li <b>HOST_DEVICE_SETTLE_DELAY_MS</b>=<i>x</i> - (\ref Group_Host) - <i>All Architectures</i> \n`
			`* Some devices require a delay of up to 5 seconds after they are connected to VBUS before the enumeration process can be started, or`
			`* they will fail to enumerate correctly. By placing a delay before the enumeration process, it can be ensured that the bus has settled`
			`* back to a known idle state before communications occur with the device. This token may be defined to a 16-bit value to set the device`
			`* settle period, specified in milliseconds. If not defined, the default value specified in Host.h is used instead.`
			`*`
			`* \li <b>INVERTED_VBUS_ENABLE_LINE</b> - (\ref Group_Host) - <i>All Architectures</i> \n`
			`* If enabled, this will indicate that the USB target VBUS line polarity is inverted; i.e. it should be pulled low to enable VBUS to the`
			`* target, and pulled high to stop the target VBUS generation.`
			`* \n`
			`* \attention On AVR8 architecture devices, this compile time option requires \c NO_AUTO_VBUS_MANAGEMENT to be set.`
			`*`
			`* \li <b>NO_AUTO_VBUS_MANAGEMENT</b> - (\ref Group_Host) - <i>All Architectures</i> \n`
			`* Disables the automatic management of VBUS to the target, i.e. automatic shut down in the even of an overcurrent situation. When enabled, VBUS`
			`* is enabled while the USB controller is initialized in USB Host mode.`
			`*/`