projects / pub / USBasp.git / blob
? search:
summary | shortlog | log | commit | commitdiff | tree
blame | history | raw | HEAD
Add new ARCH option to the makefiles to (eventually) specify the target device archit...
[pub/USBasp.git] / LUFA / Drivers / USB / LowLevel / Endpoint.h
1 /*
2 LUFA Library
3 Copyright (C) Dean Camera, 2011.
4
5 dean [at] fourwalledcubicle [dot] com
6 www.lufa-lib.org
7 */
8
9 /*
10 Copyright 2011 Dean Camera (dean [at] fourwalledcubicle [dot] com)
11
12 Permission to use, copy, modify, distribute, and sell this
13 software and its documentation for any purpose is hereby granted
14 without fee, provided that the above copyright notice appear in
15 all copies and that both that the copyright notice and this
16 permission notice and warranty disclaimer appear in supporting
17 documentation, and that the name of the author not be used in
18 advertising or publicity pertaining to distribution of the
19 software without specific, written prior permission.
20
21 The author disclaim all warranties with regard to this
22 software, including all implied warranties of merchantability
23 and fitness. In no event shall the author be liable for any
24 special, indirect or consequential damages or any damages
25 whatsoever resulting from loss of use, data or profits, whether
26 in an action of contract, negligence or other tortious action,
27 arising out of or in connection with the use or performance of
28 this software.
29 */
30
31 /** \file
32 * \brief USB device endpoint management definitions.
33 *
34 * This file contains structures, function prototypes and macros related to the management of the device's
35 * data endpoints when the library is initialized in USB device mode.
36 *
37 * \note This file should not be included directly. It is automatically included as needed by the USB driver
38 * dispatch header located in LUFA/Drivers/USB/USB.h.
39 */
40
41 /** \ingroup Group_EndpointManagement
42 * \defgroup Group_EndpointRW Endpoint Data Reading and Writing
43 *
44 * Functions, macros, variables, enums and types related to data reading and writing from and to endpoints.
45 */
46
47 /** \ingroup Group_EndpointRW
48 * \defgroup Group_EndpointPrimitiveRW Read/Write of Primitive Data Types
49 *
50 * Functions, macros, variables, enums and types related to data reading and writing of primitive data types
51 * from and to endpoints.
52 */
53
54 /** \ingroup Group_EndpointManagement
55 * \defgroup Group_EndpointPacketManagement Endpoint Packet Management
56 *
57 * Functions, macros, variables, enums and types related to packet management of endpoints.
58 */
59
60 /** \ingroup Group_USB
61 * \defgroup Group_EndpointManagement Endpoint Management
62 *
63 * Functions, macros and enums related to endpoint management when in USB Device mode. This
64 * module contains the endpoint management macros, as well as endpoint interrupt and data
65 * send/receive functions for various data types.
66 *
67 * @{
68 */
69
70 #ifndef __ENDPOINT_H__
71 #define __ENDPOINT_H__
72
73 /* Includes: */
74 #include <avr/io.h>
75 #include <stdbool.h>
76
77 #include "../../../Common/Common.h"
78 #include "../HighLevel/USBTask.h"
79 #include "USBInterrupt.h"
80
81 /* Enable C linkage for C++ Compilers: */
82 #if defined(__cplusplus)
83 extern "C" {
84 #endif
85
86 /* Preprocessor Checks: */
87 #if !defined(__INCLUDE_FROM_USB_DRIVER)
88 #error Do not include this file directly. Include LUFA/Drivers/USB/USB.h instead.
89 #endif
90
91 /* Private Interface - For use in library only: */
92 #if !defined(__DOXYGEN__)
93 /* Macros: */
94 #define _ENDPOINT_GET_MAXSIZE(EPIndex) _ENDPOINT_GET_MAXSIZE2(ENDPOINT_DETAILS_EP ## EPIndex)
95 #define _ENDPOINT_GET_MAXSIZE2(EPDetails) _ENDPOINT_GET_MAXSIZE3(EPDetails)
96 #define _ENDPOINT_GET_MAXSIZE3(MaxSize, Banks) (MaxSize)
97
98 #define _ENDPOINT_GET_BANKS(EPIndex) _ENDPOINT_GET_BANKS2(ENDPOINT_DETAILS_EP ## EPIndex)
99 #define _ENDPOINT_GET_BANKS2(EPDetails) _ENDPOINT_GET_BANKS3(EPDetails)
100 #define _ENDPOINT_GET_BANKS3(MaxSize, Banks) (Banks)
101
102 #if defined(USB_SERIES_4_AVR) || defined(USB_SERIES_6_AVR) || defined(USB_SERIES_7_AVR)
103 #define ENDPOINT_DETAILS_MAXEP 7
104
105 #define ENDPOINT_DETAILS_EP0 64, 2
106 #define ENDPOINT_DETAILS_EP1 256, 2
107 #define ENDPOINT_DETAILS_EP2 64, 2
108 #define ENDPOINT_DETAILS_EP3 64, 2
109 #define ENDPOINT_DETAILS_EP4 64, 2
110 #define ENDPOINT_DETAILS_EP5 64, 2
111 #define ENDPOINT_DETAILS_EP6 64, 2
112 #else
113 #define ENDPOINT_DETAILS_MAXEP 5
114
115 #define ENDPOINT_DETAILS_EP0 64, 2
116 #define ENDPOINT_DETAILS_EP1 64, 1
117 #define ENDPOINT_DETAILS_EP2 64, 1
118 #define ENDPOINT_DETAILS_EP3 64, 2
119 #define ENDPOINT_DETAILS_EP4 64, 2
120 #endif
121
122 /* Inline Functions: */
123 static inline uint8_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes) ATTR_WARN_UNUSED_RESULT ATTR_CONST
124 ATTR_ALWAYS_INLINE;
125 static inline uint8_t Endpoint_BytesToEPSizeMask(const uint16_t Bytes)
126 {
127 uint8_t MaskVal = 0;
128 uint16_t CheckBytes = 8;
129
130 while (CheckBytes < Bytes)
131 {
132 MaskVal++;
133 CheckBytes <<= 1;
134 }
135
136 return (MaskVal << EPSIZE0);
137 }
138
139 /* Function Prototypes: */
140 void Endpoint_ClearEndpoints(void);
141 bool Endpoint_ConfigureEndpoint_Prv(const uint8_t Number,
142 const uint8_t UECFG0XData,
143 const uint8_t UECFG1XData);
144
145 #endif
146
147 /* Public Interface - May be used in end-application: */
148 /* Macros: */
149 /** \name Endpoint Direction Masks */
150 //@{
151 /** Endpoint data direction mask for \ref Endpoint_ConfigureEndpoint(). This indicates that the endpoint
152 * should be initialized in the OUT direction - i.e. data flows from host to device.
153 */
154 #define ENDPOINT_DIR_OUT (0 << EPDIR)
155
156 /** Endpoint data direction mask for \ref Endpoint_ConfigureEndpoint(). This indicates that the endpoint
157 * should be initialized in the IN direction - i.e. data flows from device to host.
158 */
159 #define ENDPOINT_DIR_IN (1 << EPDIR)
160 //@}
161
162 /** \name Endpoint Bank Mode Masks */
163 //@{
164 /** Mask for the bank mode selection for the \ref Endpoint_ConfigureEndpoint() macro. This indicates
165 * that the endpoint should have one single bank, which requires less USB FIFO memory but results
166 * in slower transfers as only one USB device (the AVR or the host) can access the endpoint's
167 * bank at the one time.
168 */
169 #define ENDPOINT_BANK_SINGLE (0 << EPBK0)
170
171 /** Mask for the bank mode selection for the \ref Endpoint_ConfigureEndpoint() macro. This indicates
172 * that the endpoint should have two banks, which requires more USB FIFO memory but results
173 * in faster transfers as one USB device (the AVR or the host) can access one bank while the other
174 * accesses the second bank.
175 */
176 #define ENDPOINT_BANK_DOUBLE (1 << EPBK0)
177 //@}
178
179 /** Endpoint address for the default control endpoint, which always resides in address 0. This is
180 * defined for convenience to give more readable code when used with the endpoint macros.
181 */
182 #define ENDPOINT_CONTROLEP 0
183
184 #if (!defined(FIXED_CONTROL_ENDPOINT_SIZE) || defined(__DOXYGEN__))
185 /** Default size of the default control endpoint's bank, until altered by the control endpoint bank size
186 * value in the device descriptor. Not available if the \c FIXED_CONTROL_ENDPOINT_SIZE token is defined.
187 */
188 #define ENDPOINT_CONTROLEP_DEFAULT_SIZE 8
189 #endif
190
191 /** Endpoint number mask, for masking against endpoint addresses to retrieve the endpoint's
192 * numerical address in the device.
193 */
194 #define ENDPOINT_EPNUM_MASK 0x07
195
196 /** Endpoint direction mask, for masking against endpoint addresses to retrieve the endpoint's
197 * direction for comparing with the \c ENDPOINT_DESCRIPTOR_DIR_* masks.
198 */
199 #define ENDPOINT_EPDIR_MASK 0x80
200
201 /** Endpoint bank size mask, for masking against endpoint addresses to retrieve the endpoint's
202 * bank size in the device.
203 */
204 #define ENDPOINT_EPSIZE_MASK 0x7F
205
206 /** Retrives the maximum bank size in bytes of a given endpoint.
207 *
208 * \note This macro will only work correctly on endpoint indexes that are compile-time constants
209 * defined by the preprocessor.
210 *
211 * \param[in] EPIndex Endpoint number, a value between 0 and (\ref ENDPOINT_TOTAL_ENDPOINTS - 1)
212 */
213 #define ENDPOINT_MAX_SIZE(EPIndex) _ENDPOINT_GET_MAXSIZE(EPIndex)
214
215 /** Retrieves the total number of banks supported by the given endpoint.
216 *
217 * \note This macro will only work correctly on endpoint indexes that are compile-time constants
218 * defined by the preprocessor.
219 *
220 * \param[in] EPIndex Endpoint number, a value between 0 and (\ref ENDPOINT_TOTAL_ENDPOINTS - 1)
221 */
222 #define ENDPOINT_BANKS_SUPPORTED(EPIndex) _ENDPOINT_GET_BANKS(EPIndex)
223
224 #if !defined(CONTROL_ONLY_DEVICE) || defined(__DOXYGEN__)
225 /** Total number of endpoints (including the default control endpoint at address 0) which may
226 * be used in the device. Different USB AVR models support different amounts of endpoints,
227 * this value reflects the maximum number of endpoints for the currently selected AVR model.
228 */
229 #define ENDPOINT_TOTAL_ENDPOINTS ENDPOINT_DETAILS_MAXEP
230 #else
231 #define ENDPOINT_TOTAL_ENDPOINTS 1
232 #endif
233
234 /* Enums: */
235 /** Enum for the possible error return codes of the \ref Endpoint_WaitUntilReady() function.
236 *
237 * \ingroup Group_EndpointRW
238 */
239 enum Endpoint_WaitUntilReady_ErrorCodes_t
240 {
241 ENDPOINT_READYWAIT_NoError = 0, /**< Endpoint is ready for next packet, no error. */
242 ENDPOINT_READYWAIT_EndpointStalled = 1, /**< The endpoint was stalled during the stream
243 * transfer by the host or device.
244 */
245 ENDPOINT_READYWAIT_DeviceDisconnected = 2, /**< Device was disconnected from the host while
246 * waiting for the endpoint to become ready.
247 */
248 ENDPOINT_READYWAIT_BusSuspended = 3, /**< The USB bus has been suspended by the host and
249 * no USB endpoint traffic can occur until the bus
250 * has resumed.
251 */
252 ENDPOINT_READYWAIT_Timeout = 4, /**< The host failed to accept or send the next packet
253 * within the software timeout period set by the
254 * \ref USB_STREAM_TIMEOUT_MS macro.
255 */
256 };
257
258 /* Inline Functions: */
259 /** Configures the specified endpoint number with the given endpoint type, direction, bank size
260 * and banking mode. Once configured, the endpoint may be read from or written to, depending
261 * on its direction.
262 *
263 * \param[in] Number Endpoint number to configure. This must be more than 0 and less than
264 * \ref ENDPOINT_TOTAL_ENDPOINTS.
265 *
266 * \param[in] Type Type of endpoint to configure, a \c EP_TYPE_* mask. Not all endpoint types
267 * are available on Low Speed USB devices - refer to the USB 2.0 specification.
268 *
269 * \param[in] Direction Endpoint data direction, either \ref ENDPOINT_DIR_OUT or \ref ENDPOINT_DIR_IN.
270 * All endpoints (except Control type) are unidirectional - data may only be read
271 * from or written to the endpoint bank based on its direction, not both.
272 *
273 * \param[in] Size Size of the endpoint's bank, where packets are stored before they are transmitted
274 * to the USB host, or after they have been received from the USB host (depending on
275 * the endpoint's data direction). The bank size must indicate the maximum packet size
276 * that the endpoint can handle.
277 *
278 * \param[in] Banks Number of banks to use for the endpoint being configured, an \c ENDPOINT_BANK_* mask.
279 * More banks uses more USB DPRAM, but offers better performance. Isochronous type
280 * endpoints <b>must</b> have at least two banks.
281 *
282 * \note When the \c ORDERED_EP_CONFIG compile time option is used, Endpoints <b>must</b> be configured in
283 * ascending order, or bank corruption will occur.
284 * \n\n
285 *
286 * \note Certain models of USB AVR's endpoints may have different maximum packet sizes based on the endpoint's
287 * index - refer to the chosen USB AVR's datasheet to determine the maximum bank size for each endpoint.
288 * \n\n
289 *
290 * \note The default control endpoint should not be manually configured by the user application, as
291 * it is automatically configured by the library internally.
292 * \n\n
293 *
294 * \note This routine will automatically select the specified endpoint upon success. Upon failure, the endpoint
295 * which failed to reconfigure correctly will be selected.
296 *
297 * \return Boolean \c true if the configuration succeeded, \c false otherwise.
298 */
299 static inline bool Endpoint_ConfigureEndpoint(const uint8_t Number,
300 const uint8_t Type,
301 const uint8_t Direction,
302 const uint16_t Size,
303 const uint8_t Banks) ATTR_ALWAYS_INLINE;
304 static inline bool Endpoint_ConfigureEndpoint(const uint8_t Number,
305 const uint8_t Type,
306 const uint8_t Direction,
307 const uint16_t Size,
308 const uint8_t Banks)
309 {
310 return Endpoint_ConfigureEndpoint_Prv(Number, (((Type) << EPTYPE0) | (Direction)),
311 ((1 << ALLOC) | Banks | Endpoint_BytesToEPSizeMask(Size)));
312 }
313
314 /** Indicates the number of bytes currently stored in the current endpoint's selected bank.
315 *
316 * \note The return width of this function may differ, depending on the maximum endpoint bank size
317 * of the selected AVR model.
318 *
319 * \ingroup Group_EndpointRW
320 *
321 * \return Total number of bytes in the currently selected Endpoint's FIFO buffer.
322 */
323 static inline uint16_t Endpoint_BytesInEndpoint(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
324 static inline uint16_t Endpoint_BytesInEndpoint(void)
325 {
326 #if defined(USB_SERIES_6_AVR) || defined(USB_SERIES_7_AVR)
327 return UEBCX;
328 #elif defined(USB_SERIES_4_AVR)
329 return (((uint16_t)UEBCHX << 8) | UEBCLX);
330 #elif defined(USB_SERIES_2_AVR)
331 return UEBCLX;
332 #endif
333 }
334
335 /** Get the endpoint address of the currently selected endpoint. This is typically used to save
336 * the currently selected endpoint number so that it can be restored after another endpoint has
337 * been manipulated.
338 *
339 * \return Index of the currently selected endpoint.
340 */
341 static inline uint8_t Endpoint_GetCurrentEndpoint(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
342 static inline uint8_t Endpoint_GetCurrentEndpoint(void)
343 {
344 #if !defined(CONTROL_ONLY_DEVICE)
345 return (UENUM & ENDPOINT_EPNUM_MASK);
346 #else
347 return ENDPOINT_CONTROLEP;
348 #endif
349 }
350
351 /** Selects the given endpoint number. If the address from the device descriptors is used, the
352 * value should be masked with the \ref ENDPOINT_EPNUM_MASK constant to extract only the endpoint
353 * number (and discarding the endpoint direction bit).
354 *
355 * Any endpoint operations which do not require the endpoint number to be indicated will operate on
356 * the currently selected endpoint.
357 *
358 * \param[in] EndpointNumber Endpoint number to select.
359 */
360 static inline void Endpoint_SelectEndpoint(const uint8_t EndpointNumber) ATTR_ALWAYS_INLINE;
361 static inline void Endpoint_SelectEndpoint(const uint8_t EndpointNumber)
362 {
363 #if !defined(CONTROL_ONLY_DEVICE)
364 UENUM = EndpointNumber;
365 #endif
366 }
367
368 /** Resets the endpoint bank FIFO. This clears all the endpoint banks and resets the USB controller's
369 * data In and Out pointers to the bank's contents.
370 *
371 * \param[in] EndpointNumber Endpoint number whose FIFO buffers are to be reset.
372 */
373 static inline void Endpoint_ResetFIFO(const uint8_t EndpointNumber) ATTR_ALWAYS_INLINE;
374 static inline void Endpoint_ResetFIFO(const uint8_t EndpointNumber)
375 {
376 UERST = (1 << EndpointNumber);
377 UERST = 0;
378 }
379
380 /** Enables the currently selected endpoint so that data can be sent and received through it to
381 * and from a host.
382 *
383 * \note Endpoints must first be configured properly via \ref Endpoint_ConfigureEndpoint().
384 */
385 static inline void Endpoint_EnableEndpoint(void) ATTR_ALWAYS_INLINE;
386 static inline void Endpoint_EnableEndpoint(void)
387 {
388 UECONX |= (1 << EPEN);
389 }
390
391 /** Disables the currently selected endpoint so that data cannot be sent and received through it
392 * to and from a host.
393 */
394 static inline void Endpoint_DisableEndpoint(void) ATTR_ALWAYS_INLINE;
395 static inline void Endpoint_DisableEndpoint(void)
396 {
397 UECONX &= ~(1 << EPEN);
398 }
399
400 /** Determines if the currently selected endpoint is enabled, but not necessarily configured.
401 *
402 * \return Boolean \c true if the currently selected endpoint is enabled, \c false otherwise.
403 */
404 static inline bool Endpoint_IsEnabled(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
405 static inline bool Endpoint_IsEnabled(void)
406 {
407 return ((UECONX & (1 << EPEN)) ? true : false);
408 }
409
410 /** Aborts all pending IN transactions on the currently selected endpoint, once the bank
411 * has been queued for transmission to the host via \ref Endpoint_ClearIN(). This function
412 * will terminate all queued transactions, resetting the endpoint banks ready for a new
413 * packet.
414 *
415 * \ingroup Group_EndpointPacketManagement
416 */
417 static inline void Endpoint_AbortPendingIN(void)
418 {
419 while (UESTA0X & (0x03 << NBUSYBK0))
420 {
421 UEINTX |= (1 << RXOUTI);
422 while (UEINTX & (1 << RXOUTI));
423 }
424 }
425
426 /** Retrieves the number of busy banks in the currently selected endpoint, which have been queued for
427 * transmission via the \ref Endpoint_ClearIN() command, or are awaiting acknowledgement via the
428 * \ref Endpoint_ClearOUT() command.
429 *
430 * \ingroup Group_EndpointPacketManagement
431 *
432 * \return Total number of busy banks in the selected endpoint.
433 */
434 static inline uint8_t Endpoint_GetBusyBanks(void)
435 {
436 return (UESTA0X & (0x03 << NBUSYBK0));
437 }
438
439 /** Determines if the currently selected endpoint may be read from (if data is waiting in the endpoint
440 * bank and the endpoint is an OUT direction, or if the bank is not yet full if the endpoint is an IN
441 * direction). This function will return false if an error has occurred in the endpoint, if the endpoint
442 * is an OUT direction and no packet (or an empty packet) has been received, or if the endpoint is an IN
443 * direction and the endpoint bank is full.
444 *
445 * \ingroup Group_EndpointPacketManagement
446 *
447 * \return Boolean \c true if the currently selected endpoint may be read from or written to, depending
448 * on its direction.
449 */
450 static inline bool Endpoint_IsReadWriteAllowed(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
451 static inline bool Endpoint_IsReadWriteAllowed(void)
452 {
453 return ((UEINTX & (1 << RWAL)) ? true : false);
454 }
455
456 /** Determines if the currently selected endpoint is configured.
457 *
458 * \return Boolean \c true if the currently selected endpoint has been configured, \c false otherwise.
459 */
460 static inline bool Endpoint_IsConfigured(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
461 static inline bool Endpoint_IsConfigured(void)
462 {
463 return ((UESTA0X & (1 << CFGOK)) ? true : false);
464 }
465
466 /** Returns a mask indicating which INTERRUPT type endpoints have interrupted - i.e. their
467 * interrupt duration has elapsed. Which endpoints have interrupted can be determined by
468 * masking the return value against <tt>(1 << <i>{Endpoint Number}</i>)</tt>.
469 *
470 * \return Mask whose bits indicate which endpoints have interrupted.
471 */
472 static inline uint8_t Endpoint_GetEndpointInterrupts(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
473 static inline uint8_t Endpoint_GetEndpointInterrupts(void)
474 {
475 return UEINT;
476 }
477
478 /** Determines if the specified endpoint number has interrupted (valid only for INTERRUPT type
479 * endpoints).
480 *
481 * \param[in] EndpointNumber Index of the endpoint whose interrupt flag should be tested.
482 *
483 * \return Boolean \c true if the specified endpoint has interrupted, \c false otherwise.
484 */
485 static inline bool Endpoint_HasEndpointInterrupted(const uint8_t EndpointNumber) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
486 static inline bool Endpoint_HasEndpointInterrupted(const uint8_t EndpointNumber)
487 {
488 return ((UEINT & (1 << EndpointNumber)) ? true : false);
489 }
490
491 /** Determines if the selected IN endpoint is ready for a new packet to be sent to the host.
492 *
493 * \ingroup Group_EndpointPacketManagement
494 *
495 * \return Boolean \c true if the current endpoint is ready for an IN packet, \c false otherwise.
496 */
497 static inline bool Endpoint_IsINReady(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
498 static inline bool Endpoint_IsINReady(void)
499 {
500 return ((UEINTX & (1 << TXINI)) ? true : false);
501 }
502
503 /** Determines if the selected OUT endpoint has received new packet from the host.
504 *
505 * \ingroup Group_EndpointPacketManagement
506 *
507 * \return Boolean \c true if current endpoint is has received an OUT packet, \c false otherwise.
508 */
509 static inline bool Endpoint_IsOUTReceived(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
510 static inline bool Endpoint_IsOUTReceived(void)
511 {
512 return ((UEINTX & (1 << RXOUTI)) ? true : false);
513 }
514
515 /** Determines if the current CONTROL type endpoint has received a SETUP packet.
516 *
517 * \ingroup Group_EndpointPacketManagement
518 *
519 * \return Boolean \c true if the selected endpoint has received a SETUP packet, \c false otherwise.
520 */
521 static inline bool Endpoint_IsSETUPReceived(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
522 static inline bool Endpoint_IsSETUPReceived(void)
523 {
524 return ((UEINTX & (1 << RXSTPI)) ? true : false);
525 }
526
527 /** Clears a received SETUP packet on the currently selected CONTROL type endpoint, freeing up the
528 * endpoint for the next packet.
529 *
530 * \ingroup Group_EndpointPacketManagement
531 *
532 * \note This is not applicable for non CONTROL type endpoints.
533 */
534 static inline void Endpoint_ClearSETUP(void) ATTR_ALWAYS_INLINE;
535 static inline void Endpoint_ClearSETUP(void)
536 {
537 UEINTX &= ~(1 << RXSTPI);
538 }
539
540 /** Sends an IN packet to the host on the currently selected endpoint, freeing up the endpoint for the
541 * next packet and switching to the alternative endpoint bank if double banked.
542 *
543 * \ingroup Group_EndpointPacketManagement
544 */
545 static inline void Endpoint_ClearIN(void) ATTR_ALWAYS_INLINE;
546 static inline void Endpoint_ClearIN(void)
547 {
548 #if !defined(CONTROL_ONLY_DEVICE)
549 UEINTX &= ~((1 << TXINI) | (1 << FIFOCON));
550 #else
551 UEINTX &= ~(1 << TXINI);
552 #endif
553 }
554
555 /** Acknowledges an OUT packet to the host on the currently selected endpoint, freeing up the endpoint
556 * for the next packet and switching to the alternative endpoint bank if double banked.
557 *
558 * \ingroup Group_EndpointPacketManagement
559 */
560 static inline void Endpoint_ClearOUT(void) ATTR_ALWAYS_INLINE;
561 static inline void Endpoint_ClearOUT(void)
562 {
563 #if !defined(CONTROL_ONLY_DEVICE)
564 UEINTX &= ~((1 << RXOUTI) | (1 << FIFOCON));
565 #else
566 UEINTX &= ~(1 << RXOUTI);
567 #endif
568 }
569
570 /** Stalls the current endpoint, indicating to the host that a logical problem occurred with the
571 * indicated endpoint and that the current transfer sequence should be aborted. This provides a
572 * way for devices to indicate invalid commands to the host so that the current transfer can be
573 * aborted and the host can begin its own recovery sequence.
574 *
575 * The currently selected endpoint remains stalled until either the \ref Endpoint_ClearStall() macro
576 * is called, or the host issues a CLEAR FEATURE request to the device for the currently selected
577 * endpoint.
578 *
579 * \ingroup Group_EndpointPacketManagement
580 */
581 static inline void Endpoint_StallTransaction(void) ATTR_ALWAYS_INLINE;
582 static inline void Endpoint_StallTransaction(void)
583 {
584 UECONX |= (1 << STALLRQ);
585 }
586
587 /** Clears the STALL condition on the currently selected endpoint.
588 *
589 * \ingroup Group_EndpointPacketManagement
590 */
591 static inline void Endpoint_ClearStall(void) ATTR_ALWAYS_INLINE;
592 static inline void Endpoint_ClearStall(void)
593 {
594 UECONX |= (1 << STALLRQC);
595 }
596
597 /** Determines if the currently selected endpoint is stalled, false otherwise.
598 *
599 * \ingroup Group_EndpointPacketManagement
600 *
601 * \return Boolean \c true if the currently selected endpoint is stalled, \c false otherwise.
602 */
603 static inline bool Endpoint_IsStalled(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
604 static inline bool Endpoint_IsStalled(void)
605 {
606 return ((UECONX & (1 << STALLRQ)) ? true : false);
607 }
608
609 /** Resets the data toggle of the currently selected endpoint. */
610 static inline void Endpoint_ResetDataToggle(void) ATTR_ALWAYS_INLINE;
611 static inline void Endpoint_ResetDataToggle(void)
612 {
613 UECONX |= (1 << RSTDT);
614 }
615
616 /** Determines the currently selected endpoint's direction.
617 *
618 * \return The currently selected endpoint's direction, as a \c ENDPOINT_DIR_* mask.
619 */
620 static inline uint8_t Endpoint_GetEndpointDirection(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
621 static inline uint8_t Endpoint_GetEndpointDirection(void)
622 {
623 return (UECFG0X & ENDPOINT_DIR_IN);
624 }
625
626 /** Sets the direction of the currently selected endpoint.
627 *
628 * \param[in] DirectionMask New endpoint direction, as a \c ENDPOINT_DIR_* mask.
629 */
630 static inline void Endpoint_SetEndpointDirection(const uint8_t DirectionMask) ATTR_ALWAYS_INLINE;
631 static inline void Endpoint_SetEndpointDirection(const uint8_t DirectionMask)
632 {
633 UECFG0X = ((UECFG0X & ~ENDPOINT_DIR_IN) | DirectionMask);
634 }
635
636 /** Reads one byte from the currently selected endpoint's bank, for OUT direction endpoints.
637 *
638 * \ingroup Group_EndpointPrimitiveRW
639 *
640 * \return Next byte in the currently selected endpoint's FIFO buffer.
641 */
642 static inline uint8_t Endpoint_Read_Byte(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
643 static inline uint8_t Endpoint_Read_Byte(void)
644 {
645 return UEDATX;
646 }
647
648 /** Writes one byte from the currently selected endpoint's bank, for IN direction endpoints.
649 *
650 * \ingroup Group_EndpointPrimitiveRW
651 *
652 * \param[in] Byte Next byte to write into the the currently selected endpoint's FIFO buffer.
653 */
654 static inline void Endpoint_Write_Byte(const uint8_t Byte) ATTR_ALWAYS_INLINE;
655 static inline void Endpoint_Write_Byte(const uint8_t Byte)
656 {
657 UEDATX = Byte;
658 }
659
660 /** Discards one byte from the currently selected endpoint's bank, for OUT direction endpoints.
661 *
662 * \ingroup Group_EndpointPrimitiveRW
663 */
664 static inline void Endpoint_Discard_Byte(void) ATTR_ALWAYS_INLINE;
665 static inline void Endpoint_Discard_Byte(void)
666 {
667 uint8_t Dummy;
668
669 Dummy = UEDATX;
670 }
671
672 /** Reads two bytes from the currently selected endpoint's bank in little endian format, for OUT
673 * direction endpoints.
674 *
675 * \ingroup Group_EndpointPrimitiveRW
676 *
677 * \return Next word in the currently selected endpoint's FIFO buffer.
678 */
679 static inline uint16_t Endpoint_Read_Word_LE(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
680 static inline uint16_t Endpoint_Read_Word_LE(void)
681 {
682 union
683 {
684 uint16_t Word;
685 uint8_t Bytes[2];
686 } Data;
687
688 Data.Bytes[0] = UEDATX;
689 Data.Bytes[1] = UEDATX;
690
691 return Data.Word;
692 }
693
694 /** Reads two bytes from the currently selected endpoint's bank in big endian format, for OUT
695 * direction endpoints.
696 *
697 * \ingroup Group_EndpointPrimitiveRW
698 *
699 * \return Next word in the currently selected endpoint's FIFO buffer.
700 */
701 static inline uint16_t Endpoint_Read_Word_BE(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
702 static inline uint16_t Endpoint_Read_Word_BE(void)
703 {
704 union
705 {
706 uint16_t Word;
707 uint8_t Bytes[2];
708 } Data;
709
710 Data.Bytes[1] = UEDATX;
711 Data.Bytes[0] = UEDATX;
712
713 return Data.Word;
714 }
715
716 /** Writes two bytes to the currently selected endpoint's bank in little endian format, for IN
717 * direction endpoints.
718 *
719 * \ingroup Group_EndpointPrimitiveRW
720 *
721 * \param[in] Word Next word to write to the currently selected endpoint's FIFO buffer.
722 */
723 static inline void Endpoint_Write_Word_LE(const uint16_t Word) ATTR_ALWAYS_INLINE;
724 static inline void Endpoint_Write_Word_LE(const uint16_t Word)
725 {
726 UEDATX = (Word & 0xFF);
727 UEDATX = (Word >> 8);
728 }
729
730 /** Writes two bytes to the currently selected endpoint's bank in big endian format, for IN
731 * direction endpoints.
732 *
733 * \ingroup Group_EndpointPrimitiveRW
734 *
735 * \param[in] Word Next word to write to the currently selected endpoint's FIFO buffer.
736 */
737 static inline void Endpoint_Write_Word_BE(const uint16_t Word) ATTR_ALWAYS_INLINE;
738 static inline void Endpoint_Write_Word_BE(const uint16_t Word)
739 {
740 UEDATX = (Word >> 8);
741 UEDATX = (Word & 0xFF);
742 }
743
744 /** Discards two bytes from the currently selected endpoint's bank, for OUT direction endpoints.
745 *
746 * \ingroup Group_EndpointPrimitiveRW
747 */
748 static inline void Endpoint_Discard_Word(void) ATTR_ALWAYS_INLINE;
749 static inline void Endpoint_Discard_Word(void)
750 {
751 uint8_t Dummy;
752
753 Dummy = UEDATX;
754 Dummy = UEDATX;
755 }
756
757 /** Reads four bytes from the currently selected endpoint's bank in little endian format, for OUT
758 * direction endpoints.
759 *
760 * \ingroup Group_EndpointPrimitiveRW
761 *
762 * \return Next double word in the currently selected endpoint's FIFO buffer.
763 */
764 static inline uint32_t Endpoint_Read_DWord_LE(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
765 static inline uint32_t Endpoint_Read_DWord_LE(void)
766 {
767 union
768 {
769 uint32_t DWord;
770 uint8_t Bytes[4];
771 } Data;
772
773 Data.Bytes[0] = UEDATX;
774 Data.Bytes[1] = UEDATX;
775 Data.Bytes[2] = UEDATX;
776 Data.Bytes[3] = UEDATX;
777
778 return Data.DWord;
779 }
780
781 /** Reads four bytes from the currently selected endpoint's bank in big endian format, for OUT
782 * direction endpoints.
783 *
784 * \ingroup Group_EndpointPrimitiveRW
785 *
786 * \return Next double word in the currently selected endpoint's FIFO buffer.
787 */
788 static inline uint32_t Endpoint_Read_DWord_BE(void) ATTR_WARN_UNUSED_RESULT ATTR_ALWAYS_INLINE;
789 static inline uint32_t Endpoint_Read_DWord_BE(void)
790 {
791 union
792 {
793 uint32_t DWord;
794 uint8_t Bytes[4];
795 } Data;
796
797 Data.Bytes[3] = UEDATX;
798 Data.Bytes[2] = UEDATX;
799 Data.Bytes[1] = UEDATX;
800 Data.Bytes[0] = UEDATX;
801
802 return Data.DWord;
803 }
804
805 /** Writes four bytes to the currently selected endpoint's bank in little endian format, for IN
806 * direction endpoints.
807 *
808 * \ingroup Group_EndpointPrimitiveRW
809 *
810 * \param[in] DWord Next double word to write to the currently selected endpoint's FIFO buffer.
811 */
812 static inline void Endpoint_Write_DWord_LE(const uint32_t DWord) ATTR_ALWAYS_INLINE;
813 static inline void Endpoint_Write_DWord_LE(const uint32_t DWord)
814 {
815 UEDATX = (DWord & 0xFF);
816 UEDATX = (DWord >> 8);
817 UEDATX = (DWord >> 16);
818 UEDATX = (DWord >> 24);
819 }
820
821 /** Writes four bytes to the currently selected endpoint's bank in big endian format, for IN
822 * direction endpoints.
823 *
824 * \ingroup Group_EndpointPrimitiveRW
825 *
826 * \param[in] DWord Next double word to write to the currently selected endpoint's FIFO buffer.
827 */
828 static inline void Endpoint_Write_DWord_BE(const uint32_t DWord) ATTR_ALWAYS_INLINE;
829 static inline void Endpoint_Write_DWord_BE(const uint32_t DWord)
830 {
831 UEDATX = (DWord >> 24);
832 UEDATX = (DWord >> 16);
833 UEDATX = (DWord >> 8);
834 UEDATX = (DWord & 0xFF);
835 }
836
837 /** Discards four bytes from the currently selected endpoint's bank, for OUT direction endpoints.
838 *
839 * \ingroup Group_EndpointPrimitiveRW
840 */
841 static inline void Endpoint_Discard_DWord(void) ATTR_ALWAYS_INLINE;
842 static inline void Endpoint_Discard_DWord(void)
843 {
844 uint8_t Dummy;
845
846 Dummy = UEDATX;
847 Dummy = UEDATX;
848 Dummy = UEDATX;
849 Dummy = UEDATX;
850 }
851
852 /* External Variables: */
853 /** Global indicating the maximum packet size of the default control endpoint located at address
854 * 0 in the device. This value is set to the value indicated in the device descriptor in the user
855 * project once the USB interface is initialized into device mode.
856 *
857 * If space is an issue, it is possible to fix this to a static value by defining the control
858 * endpoint size in the \c FIXED_CONTROL_ENDPOINT_SIZE token passed to the compiler in the makefile
859 * via the -D switch. When a fixed control endpoint size is used, the size is no longer dynamically
860 * read from the descriptors at runtime and instead fixed to the given value. When used, it is
861 * important that the descriptor control endpoint size value matches the size given as the
862 * \c FIXED_CONTROL_ENDPOINT_SIZE token - it is recommended that the \c FIXED_CONTROL_ENDPOINT_SIZE token
863 * be used in the device descriptors to ensure this.
864 *
865 * \note This variable should be treated as read-only in the user application, and never manually
866 * changed in value.
867 */
868 #if (!defined(FIXED_CONTROL_ENDPOINT_SIZE) || defined(__DOXYGEN__))
869 extern uint8_t USB_ControlEndpointSize;
870 #else
871 #define USB_ControlEndpointSize FIXED_CONTROL_ENDPOINT_SIZE
872 #endif
873
874 /* Function Prototypes: */
875 /** Completes the status stage of a control transfer on a CONTROL type endpoint automatically,
876 * with respect to the data direction. This is a convenience function which can be used to
877 * simplify user control request handling.
878 */
879 void Endpoint_ClearStatusStage(void);
880
881 /** Spin-loops until the currently selected non-control endpoint is ready for the next packet of data
882 * to be read or written to it.
883 *
884 * \note This routine should not be called on CONTROL type endpoints.
885 *
886 * \ingroup Group_EndpointRW
887 *
888 * \return A value from the \ref Endpoint_WaitUntilReady_ErrorCodes_t enum.
889 */
890 uint8_t Endpoint_WaitUntilReady(void);
891
892 /* Disable C linkage for C++ Compilers: */
893 #if defined(__cplusplus)
894 }
895 #endif
896
897 #endif
898
899 /** @} */
900
USB isp AVR programmer