VirtualBox

source: vbox/trunk/src/VBox/Devices/Audio/DevHDACommon.cpp@ 76569

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1/* $Id: DevHDACommon.cpp 76553 2019-01-01 01:45:53Z vboxsync $ */
2/** @file
3 * DevHDACommon.cpp - Shared HDA device functions.
4 */
5
6/*
7 * Copyright (C) 2017-2019 Oracle Corporation
8 *
9 * This file is part of VirtualBox Open Source Edition (OSE), as
10 * available from http://www.virtualbox.org. This file is free software;
11 * you can redistribute it and/or modify it under the terms of the GNU
12 * General Public License (GPL) as published by the Free Software
13 * Foundation, in version 2 as it comes in the "COPYING" file of the
14 * VirtualBox OSE distribution. VirtualBox OSE is distributed in the
15 * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
16 */
17
18
19/*********************************************************************************************************************************
20* Header Files *
21*********************************************************************************************************************************/
22#include <iprt/assert.h>
23#include <iprt/errcore.h>
24
25#define LOG_GROUP LOG_GROUP_DEV_HDA
26#include <VBox/log.h>
27
28#include "DrvAudio.h"
29
30#include "DevHDA.h"
31#include "DevHDACommon.h"
32
33#include "HDAStream.h"
34
35
36#ifndef LOG_ENABLED
37/**
38 * Processes (de/asserts) the interrupt according to the HDA's current state.
39 *
40 * @returns IPRT status code.
41 * @param pThis HDA state.
42 */
43int hdaProcessInterrupt(PHDASTATE pThis)
44#else
45/**
46 * Processes (de/asserts) the interrupt according to the HDA's current state.
47 * Debug version.
48 *
49 * @returns IPRT status code.
50 * @param pThis HDA state.
51 * @param pszSource Caller information.
52 */
53int hdaProcessInterrupt(PHDASTATE pThis, const char *pszSource)
54#endif
55{
56 uint32_t uIntSts = hdaGetINTSTS(pThis);
57
58 HDA_REG(pThis, INTSTS) = uIntSts;
59
60 /* NB: It is possible to have GIS set even when CIE/SIEn are all zero; the GIS bit does
61 * not control the interrupt signal. See Figure 4 on page 54 of the HDA 1.0a spec.
62 */
63 /* Global Interrupt Enable (GIE) set? */
64 if ( (HDA_REG(pThis, INTCTL) & HDA_INTCTL_GIE)
65 && (HDA_REG(pThis, INTSTS) & HDA_REG(pThis, INTCTL) & (HDA_INTCTL_CIE | HDA_STRMINT_MASK)))
66 {
67 Log3Func(("Asserted (%s)\n", pszSource));
68
69 PDMDevHlpPCISetIrq(pThis->CTX_SUFF(pDevIns), 0, 1 /* Assert */);
70 pThis->u8IRQL = 1;
71
72#ifdef DEBUG
73 pThis->Dbg.IRQ.tsAssertedNs = RTTimeNanoTS();
74 pThis->Dbg.IRQ.tsProcessedLastNs = pThis->Dbg.IRQ.tsAssertedNs;
75#endif
76 }
77 else
78 {
79 Log3Func(("Deasserted (%s)\n", pszSource));
80
81 PDMDevHlpPCISetIrq(pThis->CTX_SUFF(pDevIns), 0, 0 /* Deassert */);
82 pThis->u8IRQL = 0;
83 }
84
85 return VINF_SUCCESS;
86}
87
88/**
89 * Retrieves the currently set value for the wall clock.
90 *
91 * @return IPRT status code.
92 * @return Currently set wall clock value.
93 * @param pThis HDA state.
94 *
95 * @remark Operation is atomic.
96 */
97uint64_t hdaWalClkGetCurrent(PHDASTATE pThis)
98{
99 return ASMAtomicReadU64(&pThis->u64WalClk);
100}
101
102#ifdef IN_RING3
103
104/**
105 * Sets the actual WALCLK register to the specified wall clock value.
106 * The specified wall clock value only will be set (unless fForce is set to true) if all
107 * handled HDA streams have passed (in time) that value. This guarantees that the WALCLK
108 * register stays in sync with all handled HDA streams.
109 *
110 * @return true if the WALCLK register has been updated, false if not.
111 * @param pThis HDA state.
112 * @param u64WalClk Wall clock value to set WALCLK register to.
113 * @param fForce Whether to force setting the wall clock value or not.
114 */
115bool hdaR3WalClkSet(PHDASTATE pThis, uint64_t u64WalClk, bool fForce)
116{
117 const bool fFrontPassed = hdaR3StreamPeriodHasPassedAbsWalClk (&hdaR3GetStreamFromSink(pThis, &pThis->SinkFront)->State.Period,
118 u64WalClk);
119 const uint64_t u64FrontAbsWalClk = hdaR3StreamPeriodGetAbsElapsedWalClk(&hdaR3GetStreamFromSink(pThis, &pThis->SinkFront)->State.Period);
120# ifdef VBOX_WITH_AUDIO_HDA_51_SURROUND
121# error "Implement me!"
122# endif
123
124 const bool fLineInPassed = hdaR3StreamPeriodHasPassedAbsWalClk (&hdaR3GetStreamFromSink(pThis, &pThis->SinkLineIn)->State.Period, u64WalClk);
125 const uint64_t u64LineInAbsWalClk = hdaR3StreamPeriodGetAbsElapsedWalClk(&hdaR3GetStreamFromSink(pThis, &pThis->SinkLineIn)->State.Period);
126# ifdef VBOX_WITH_HDA_MIC_IN
127 const bool fMicInPassed = hdaR3StreamPeriodHasPassedAbsWalClk (&hdaR3GetStreamFromSink(pThis, &pThis->SinkMicIn)->State.Period, u64WalClk);
128 const uint64_t u64MicInAbsWalClk = hdaR3StreamPeriodGetAbsElapsedWalClk(&hdaR3GetStreamFromSink(pThis, &pThis->SinkMicIn)->State.Period);
129# endif
130
131# ifdef VBOX_STRICT
132 const uint64_t u64WalClkCur = ASMAtomicReadU64(&pThis->u64WalClk);
133# endif
134
135 /* Only drive the WALCLK register forward if all (active) stream periods have passed
136 * the specified point in time given by u64WalClk. */
137 if ( ( fFrontPassed
138# ifdef VBOX_WITH_AUDIO_HDA_51_SURROUND
139# error "Implement me!"
140# endif
141 && fLineInPassed
142# ifdef VBOX_WITH_HDA_MIC_IN
143 && fMicInPassed
144# endif
145 )
146 || fForce)
147 {
148 if (!fForce)
149 {
150 /* Get the maximum value of all periods we need to handle.
151 * Not the most elegant solution, but works for now ... */
152 u64WalClk = RT_MAX(u64WalClk, u64FrontAbsWalClk);
153# ifdef VBOX_WITH_AUDIO_HDA_51_SURROUND
154# error "Implement me!"
155# endif
156 u64WalClk = RT_MAX(u64WalClk, u64LineInAbsWalClk);
157# ifdef VBOX_WITH_HDA_MIC_IN
158 u64WalClk = RT_MAX(u64WalClk, u64MicInAbsWalClk);
159# endif
160
161# ifdef VBOX_STRICT
162 AssertMsg(u64WalClk >= u64WalClkCur,
163 ("Setting WALCLK to a value going backwards does not make any sense (old %RU64 vs. new %RU64)\n",
164 u64WalClkCur, u64WalClk));
165 if (u64WalClk == u64WalClkCur) /* Setting a stale value? */
166 {
167 if (pThis->u8WalClkStaleCnt++ > 3)
168 AssertMsgFailed(("Setting WALCLK to a stale value (%RU64) too often isn't a good idea really. "
169 "Good luck with stuck audio stuff.\n", u64WalClk));
170 }
171 else
172 pThis->u8WalClkStaleCnt = 0;
173# endif
174 }
175
176 /* Set the new WALCLK value. */
177 ASMAtomicWriteU64(&pThis->u64WalClk, u64WalClk);
178 }
179
180 const uint64_t u64WalClkNew = hdaWalClkGetCurrent(pThis);
181
182 Log3Func(("Cur: %RU64, New: %RU64 (force %RTbool) -> %RU64 %s\n",
183 u64WalClkCur, u64WalClk, fForce,
184 u64WalClkNew, u64WalClkNew == u64WalClk ? "[OK]" : "[DELAYED]"));
185
186 return (u64WalClkNew == u64WalClk);
187}
188
189/**
190 * Returns the default (mixer) sink from a given SD#.
191 * Returns NULL if no sink is found.
192 *
193 * @return PHDAMIXERSINK
194 * @param pThis HDA state.
195 * @param uSD SD# to return mixer sink for.
196 * NULL if not found / handled.
197 */
198PHDAMIXERSINK hdaR3GetDefaultSink(PHDASTATE pThis, uint8_t uSD)
199{
200 if (hdaGetDirFromSD(uSD) == PDMAUDIODIR_IN)
201 {
202 const uint8_t uFirstSDI = 0;
203
204 if (uSD == uFirstSDI) /* First SDI. */
205 return &pThis->SinkLineIn;
206# ifdef VBOX_WITH_AUDIO_HDA_MIC_IN
207 if (uSD == uFirstSDI + 1)
208 return &pThis->SinkMicIn;
209# else
210 /* If we don't have a dedicated Mic-In sink, use the always present Line-In sink. */
211 return &pThis->SinkLineIn;
212# endif
213 }
214 else
215 {
216 const uint8_t uFirstSDO = HDA_MAX_SDI;
217
218 if (uSD == uFirstSDO)
219 return &pThis->SinkFront;
220# ifdef VBOX_WITH_AUDIO_HDA_51_SURROUND
221 if (uSD == uFirstSDO + 1)
222 return &pThis->SinkCenterLFE;
223 if (uSD == uFirstSDO + 2)
224 return &pThis->SinkRear;
225# endif
226 }
227
228 return NULL;
229}
230
231#endif /* IN_RING3 */
232
233/**
234 * Returns the audio direction of a specified stream descriptor.
235 *
236 * The register layout specifies that input streams (SDI) come first,
237 * followed by the output streams (SDO). So every stream ID below HDA_MAX_SDI
238 * is an input stream, whereas everything >= HDA_MAX_SDI is an output stream.
239 *
240 * Note: SDnFMT register does not provide that information, so we have to judge
241 * for ourselves.
242 *
243 * @return Audio direction.
244 */
245PDMAUDIODIR hdaGetDirFromSD(uint8_t uSD)
246{
247 AssertReturn(uSD < HDA_MAX_STREAMS, PDMAUDIODIR_UNKNOWN);
248
249 if (uSD < HDA_MAX_SDI)
250 return PDMAUDIODIR_IN;
251
252 return PDMAUDIODIR_OUT;
253}
254
255/**
256 * Returns the HDA stream of specified stream descriptor number.
257 *
258 * @return Pointer to HDA stream, or NULL if none found.
259 */
260PHDASTREAM hdaGetStreamFromSD(PHDASTATE pThis, uint8_t uSD)
261{
262 AssertPtrReturn(pThis, NULL);
263 AssertReturn(uSD < HDA_MAX_STREAMS, NULL);
264
265 if (uSD >= HDA_MAX_STREAMS)
266 {
267 AssertMsgFailed(("Invalid / non-handled SD%RU8\n", uSD));
268 return NULL;
269 }
270
271 return &pThis->aStreams[uSD];
272}
273
274#ifdef IN_RING3
275
276/**
277 * Returns the HDA stream of specified HDA sink.
278 *
279 * @return Pointer to HDA stream, or NULL if none found.
280 */
281PHDASTREAM hdaR3GetStreamFromSink(PHDASTATE pThis, PHDAMIXERSINK pSink)
282{
283 AssertPtrReturn(pThis, NULL);
284 AssertPtrReturn(pSink, NULL);
285
286 /** @todo Do something with the channel mapping here? */
287 return pSink->pStream;
288}
289
290/**
291 * Reads DMA data from a given HDA output stream.
292 *
293 * @return IPRT status code.
294 * @param pThis HDA state.
295 * @param pStream HDA output stream to read DMA data from.
296 * @param pvBuf Where to store the read data.
297 * @param cbBuf How much to read in bytes.
298 * @param pcbRead Returns read bytes from DMA. Optional.
299 */
300int hdaR3DMARead(PHDASTATE pThis, PHDASTREAM pStream, void *pvBuf, uint32_t cbBuf, uint32_t *pcbRead)
301{
302 AssertPtrReturn(pThis, VERR_INVALID_POINTER);
303 AssertPtrReturn(pStream, VERR_INVALID_POINTER);
304 /* pcbRead is optional. */
305
306 PHDABDLE pBDLE = &pStream->State.BDLE;
307
308 int rc = VINF_SUCCESS;
309
310 uint32_t cbReadTotal = 0;
311 uint32_t cbLeft = RT_MIN(cbBuf, pBDLE->Desc.u32BufSize - pBDLE->State.u32BufOff);
312
313# ifdef HDA_DEBUG_SILENCE
314 uint64_t csSilence = 0;
315
316 pStream->Dbg.cSilenceThreshold = 100;
317 pStream->Dbg.cbSilenceReadMin = _1M;
318# endif
319
320 RTGCPHYS addrChunk = pBDLE->Desc.u64BufAddr + pBDLE->State.u32BufOff;
321
322 while (cbLeft)
323 {
324 uint32_t cbChunk = RT_MIN(cbLeft, pStream->u16FIFOS);
325
326 rc = PDMDevHlpPhysRead(pThis->CTX_SUFF(pDevIns), addrChunk, (uint8_t *)pvBuf + cbReadTotal, cbChunk);
327 if (RT_FAILURE(rc))
328 break;
329
330# ifdef HDA_DEBUG_SILENCE
331 uint16_t *pu16Buf = (uint16_t *)pvBuf;
332 for (size_t i = 0; i < cbChunk / sizeof(uint16_t); i++)
333 {
334 if (*pu16Buf == 0)
335 csSilence++;
336 else
337 break;
338 pu16Buf++;
339 }
340# endif
341 if (pStream->Dbg.Runtime.fEnabled)
342 DrvAudioHlpFileWrite(pStream->Dbg.Runtime.pFileDMARaw, (uint8_t *)pvBuf + cbReadTotal, cbChunk, 0 /* fFlags */);
343
344 STAM_COUNTER_ADD(&pThis->StatBytesRead, cbChunk);
345 addrChunk = (addrChunk + cbChunk) % pBDLE->Desc.u32BufSize;
346
347 Assert(cbLeft >= cbChunk);
348 cbLeft -= cbChunk;
349
350 cbReadTotal += cbChunk;
351 }
352
353# ifdef HDA_DEBUG_SILENCE
354 if (csSilence)
355 pStream->Dbg.csSilence += csSilence;
356
357 if ( csSilence == 0
358 && pStream->Dbg.csSilence > pStream->Dbg.cSilenceThreshold
359 && pStream->Dbg.cbReadTotal >= pStream->Dbg.cbSilenceReadMin)
360 {
361 LogFunc(("Silent block detected: %RU64 audio samples\n", pStream->Dbg.csSilence));
362 pStream->Dbg.csSilence = 0;
363 }
364# endif
365
366 if (RT_SUCCESS(rc))
367 {
368 if (pcbRead)
369 *pcbRead = cbReadTotal;
370 }
371
372 return rc;
373}
374
375/**
376 * Writes audio data from an HDA input stream's FIFO to its associated DMA area.
377 *
378 * @return IPRT status code.
379 * @param pThis HDA state.
380 * @param pStream HDA input stream to write audio data to.
381 * @param pvBuf Data to write.
382 * @param cbBuf How much (in bytes) to write.
383 * @param pcbWritten Returns written bytes on success. Optional.
384 */
385int hdaR3DMAWrite(PHDASTATE pThis, PHDASTREAM pStream, const void *pvBuf, uint32_t cbBuf, uint32_t *pcbWritten)
386{
387 AssertPtrReturn(pThis, VERR_INVALID_POINTER);
388 AssertPtrReturn(pStream, VERR_INVALID_POINTER);
389 /* pcbWritten is optional. */
390
391 PHDABDLE pBDLE = &pStream->State.BDLE;
392
393 int rc = VINF_SUCCESS;
394
395 uint32_t cbWrittenTotal = 0;
396 uint32_t cbLeft = RT_MIN(cbBuf, pBDLE->Desc.u32BufSize - pBDLE->State.u32BufOff);
397
398 RTGCPHYS addrChunk = pBDLE->Desc.u64BufAddr + pBDLE->State.u32BufOff;
399
400 while (cbLeft)
401 {
402 uint32_t cbChunk = RT_MIN(cbLeft, pStream->u16FIFOS);
403
404 /* Sanity checks. */
405 Assert(cbChunk <= pBDLE->Desc.u32BufSize - pBDLE->State.u32BufOff);
406
407 if (pStream->Dbg.Runtime.fEnabled)
408 DrvAudioHlpFileWrite(pStream->Dbg.Runtime.pFileDMARaw, (uint8_t *)pvBuf + cbWrittenTotal, cbChunk, 0 /* fFlags */);
409
410 rc = PDMDevHlpPCIPhysWrite(pThis->CTX_SUFF(pDevIns),
411 addrChunk, (uint8_t *)pvBuf + cbWrittenTotal, cbChunk);
412 if (RT_FAILURE(rc))
413 break;
414
415 STAM_COUNTER_ADD(&pThis->StatBytesWritten, cbChunk);
416 addrChunk = (addrChunk + cbChunk) % pBDLE->Desc.u32BufSize;
417
418 Assert(cbLeft >= cbChunk);
419 cbLeft -= (uint32_t)cbChunk;
420
421 cbWrittenTotal += (uint32_t)cbChunk;
422 }
423
424 if (RT_SUCCESS(rc))
425 {
426 if (pcbWritten)
427 *pcbWritten = cbWrittenTotal;
428 }
429 else
430 LogFunc(("Failed with %Rrc\n", rc));
431
432 return rc;
433}
434
435#endif /* IN_RING3 */
436
437/**
438 * Returns a new INTSTS value based on the current device state.
439 *
440 * @returns Determined INTSTS register value.
441 * @param pThis HDA state.
442 *
443 * @remark This function does *not* set INTSTS!
444 */
445uint32_t hdaGetINTSTS(PHDASTATE pThis)
446{
447 uint32_t intSts = 0;
448
449 /* Check controller interrupts (RIRB, STATEST). */
450 if (HDA_REG(pThis, RIRBSTS) & HDA_REG(pThis, RIRBCTL) & (HDA_RIRBCTL_ROIC | HDA_RIRBCTL_RINTCTL))
451 {
452 intSts |= HDA_INTSTS_CIS; /* Set the Controller Interrupt Status (CIS). */
453 }
454
455 /* Check SDIN State Change Status Flags. */
456 if (HDA_REG(pThis, STATESTS) & HDA_REG(pThis, WAKEEN))
457 {
458 intSts |= HDA_INTSTS_CIS; /* Touch Controller Interrupt Status (CIS). */
459 }
460
461 /* For each stream, check if any interrupt status bit is set and enabled. */
462 for (uint8_t iStrm = 0; iStrm < HDA_MAX_STREAMS; ++iStrm)
463 {
464 if (HDA_STREAM_REG(pThis, STS, iStrm) & HDA_STREAM_REG(pThis, CTL, iStrm) & (HDA_SDCTL_DEIE | HDA_SDCTL_FEIE | HDA_SDCTL_IOCE))
465 {
466 Log3Func(("[SD%d] interrupt status set\n", iStrm));
467 intSts |= RT_BIT(iStrm);
468 }
469 }
470
471 if (intSts)
472 intSts |= HDA_INTSTS_GIS; /* Set the Global Interrupt Status (GIS). */
473
474 Log3Func(("-> 0x%x\n", intSts));
475
476 return intSts;
477}
478
479#ifdef IN_RING3
480
481/**
482 * Converts an HDA stream's SDFMT register into a given PCM properties structure.
483 *
484 * @return IPRT status code.
485 * @param u16SDFMT The HDA stream's SDFMT value to convert.
486 * @param pProps PCM properties structure to hold converted result on success.
487 */
488int hdaR3SDFMTToPCMProps(uint16_t u16SDFMT, PPDMAUDIOPCMPROPS pProps)
489{
490 AssertPtrReturn(pProps, VERR_INVALID_POINTER);
491
492# define EXTRACT_VALUE(v, mask, shift) ((v & ((mask) << (shift))) >> (shift))
493
494 int rc = VINF_SUCCESS;
495
496 uint32_t u32Hz = EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_BASE_RATE_MASK, HDA_SDFMT_BASE_RATE_SHIFT)
497 ? 44100 : 48000;
498 uint32_t u32HzMult = 1;
499 uint32_t u32HzDiv = 1;
500
501 switch (EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_MULT_MASK, HDA_SDFMT_MULT_SHIFT))
502 {
503 case 0: u32HzMult = 1; break;
504 case 1: u32HzMult = 2; break;
505 case 2: u32HzMult = 3; break;
506 case 3: u32HzMult = 4; break;
507 default:
508 LogFunc(("Unsupported multiplier %x\n",
509 EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_MULT_MASK, HDA_SDFMT_MULT_SHIFT)));
510 rc = VERR_NOT_SUPPORTED;
511 break;
512 }
513 switch (EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_DIV_MASK, HDA_SDFMT_DIV_SHIFT))
514 {
515 case 0: u32HzDiv = 1; break;
516 case 1: u32HzDiv = 2; break;
517 case 2: u32HzDiv = 3; break;
518 case 3: u32HzDiv = 4; break;
519 case 4: u32HzDiv = 5; break;
520 case 5: u32HzDiv = 6; break;
521 case 6: u32HzDiv = 7; break;
522 case 7: u32HzDiv = 8; break;
523 default:
524 LogFunc(("Unsupported divisor %x\n",
525 EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_DIV_MASK, HDA_SDFMT_DIV_SHIFT)));
526 rc = VERR_NOT_SUPPORTED;
527 break;
528 }
529
530 uint8_t cBytes = 0;
531 switch (EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_BITS_MASK, HDA_SDFMT_BITS_SHIFT))
532 {
533 case 0:
534 cBytes = 1;
535 break;
536 case 1:
537 cBytes = 2;
538 break;
539 case 4:
540 cBytes = 4;
541 break;
542 default:
543 AssertMsgFailed(("Unsupported bits per sample %x\n",
544 EXTRACT_VALUE(u16SDFMT, HDA_SDFMT_BITS_MASK, HDA_SDFMT_BITS_SHIFT)));
545 rc = VERR_NOT_SUPPORTED;
546 break;
547 }
548
549 if (RT_SUCCESS(rc))
550 {
551 RT_BZERO(pProps, sizeof(PDMAUDIOPCMPROPS));
552
553 pProps->cBytes = cBytes;
554 pProps->fSigned = true;
555 pProps->cChannels = (u16SDFMT & 0xf) + 1;
556 pProps->uHz = u32Hz * u32HzMult / u32HzDiv;
557 pProps->cShift = PDMAUDIOPCMPROPS_MAKE_SHIFT_PARMS(pProps->cBytes, pProps->cChannels);
558 }
559
560# undef EXTRACT_VALUE
561 return rc;
562}
563
564# ifdef LOG_ENABLED
565void hdaR3BDLEDumpAll(PHDASTATE pThis, uint64_t u64BDLBase, uint16_t cBDLE)
566{
567 LogFlowFunc(("BDLEs @ 0x%x (%RU16):\n", u64BDLBase, cBDLE));
568 if (!u64BDLBase)
569 return;
570
571 uint32_t cbBDLE = 0;
572 for (uint16_t i = 0; i < cBDLE; i++)
573 {
574 HDABDLEDESC bd;
575 PDMDevHlpPhysRead(pThis->CTX_SUFF(pDevIns), u64BDLBase + i * sizeof(HDABDLEDESC), &bd, sizeof(bd));
576
577 LogFunc(("\t#%03d BDLE(adr:0x%llx, size:%RU32, ioc:%RTbool)\n",
578 i, bd.u64BufAddr, bd.u32BufSize, bd.fFlags & HDA_BDLE_FLAG_IOC));
579
580 cbBDLE += bd.u32BufSize;
581 }
582
583 LogFlowFunc(("Total: %RU32 bytes\n", cbBDLE));
584
585 if (!pThis->u64DPBase) /* No DMA base given? Bail out. */
586 return;
587
588 LogFlowFunc(("DMA counters:\n"));
589
590 for (int i = 0; i < cBDLE; i++)
591 {
592 uint32_t uDMACnt;
593 PDMDevHlpPhysRead(pThis->CTX_SUFF(pDevIns), (pThis->u64DPBase & DPBASE_ADDR_MASK) + (i * 2 * sizeof(uint32_t)),
594 &uDMACnt, sizeof(uDMACnt));
595
596 LogFlowFunc(("\t#%03d DMA @ 0x%x\n", i , uDMACnt));
597 }
598}
599# endif /* LOG_ENABLED */
600
601/**
602 * Fetches a Bundle Descriptor List Entry (BDLE) from the DMA engine.
603 *
604 * @param pThis Pointer to HDA state.
605 * @param pBDLE Where to store the fetched result.
606 * @param u64BaseDMA Address base of DMA engine to use.
607 * @param u16Entry BDLE entry to fetch.
608 */
609int hdaR3BDLEFetch(PHDASTATE pThis, PHDABDLE pBDLE, uint64_t u64BaseDMA, uint16_t u16Entry)
610{
611 AssertPtrReturn(pThis, VERR_INVALID_POINTER);
612 AssertPtrReturn(pBDLE, VERR_INVALID_POINTER);
613 AssertReturn(u64BaseDMA, VERR_INVALID_PARAMETER);
614
615 if (!u64BaseDMA)
616 {
617 LogRel2(("HDA: Unable to fetch BDLE #%RU16 - no base DMA address set (yet)\n", u16Entry));
618 return VERR_NOT_FOUND;
619 }
620 /** @todo Compare u16Entry with LVI. */
621
622 int rc = PDMDevHlpPhysRead(pThis->CTX_SUFF(pDevIns), u64BaseDMA + (u16Entry * sizeof(HDABDLEDESC)),
623 &pBDLE->Desc, sizeof(pBDLE->Desc));
624
625 if (RT_SUCCESS(rc))
626 {
627 /* Reset internal state. */
628 RT_ZERO(pBDLE->State);
629 pBDLE->State.u32BDLIndex = u16Entry;
630 }
631
632 Log3Func(("Entry #%d @ 0x%x: %R[bdle], rc=%Rrc\n", u16Entry, u64BaseDMA + (u16Entry * sizeof(HDABDLEDESC)), pBDLE, rc));
633
634
635 return VINF_SUCCESS;
636}
637
638/**
639 * Tells whether a given BDLE is complete or not.
640 *
641 * @return true if BDLE is complete, false if not.
642 * @param pBDLE BDLE to retrieve status for.
643 */
644bool hdaR3BDLEIsComplete(PHDABDLE pBDLE)
645{
646 bool fIsComplete = false;
647
648 if ( !pBDLE->Desc.u32BufSize /* There can be BDLEs with 0 size. */
649 || (pBDLE->State.u32BufOff >= pBDLE->Desc.u32BufSize))
650 {
651 Assert(pBDLE->State.u32BufOff == pBDLE->Desc.u32BufSize);
652 fIsComplete = true;
653 }
654
655 Log3Func(("%R[bdle] => %s\n", pBDLE, fIsComplete ? "COMPLETE" : "INCOMPLETE"));
656
657 return fIsComplete;
658}
659
660/**
661 * Tells whether a given BDLE needs an interrupt or not.
662 *
663 * @return true if BDLE needs an interrupt, false if not.
664 * @param pBDLE BDLE to retrieve status for.
665 */
666bool hdaR3BDLENeedsInterrupt(PHDABDLE pBDLE)
667{
668 return (pBDLE->Desc.fFlags & HDA_BDLE_FLAG_IOC);
669}
670
671/**
672 * Sets the virtual device timer to a new expiration time.
673 *
674 * @returns Whether the new expiration time was set or not.
675 * @param pThis HDA state.
676 * @param pStream HDA stream to set timer for.
677 * @param tsExpire New (virtual) expiration time to set.
678 * @param fForce Whether to force setting the expiration time or not.
679 *
680 * @remark This function takes all active HDA streams and their
681 * current timing into account. This is needed to make sure
682 * that all streams can match their needed timing.
683 *
684 * To achieve this, the earliest (lowest) timestamp of all
685 * active streams found will be used for the next scheduling slot.
686 *
687 * Forcing a new expiration time will override the above mechanism.
688 */
689bool hdaR3TimerSet(PHDASTATE pThis, PHDASTREAM pStream, uint64_t tsExpire, bool fForce)
690{
691 AssertPtrReturn(pThis, false);
692 AssertPtrReturn(pStream, false);
693
694 uint64_t tsExpireMin = tsExpire;
695
696 if (!fForce)
697 {
698 if (hdaR3StreamTransferIsScheduled(pStream))
699 tsExpireMin = RT_MIN(tsExpireMin, hdaR3StreamTransferGetNext(pStream));
700 }
701
702 AssertPtr(pThis->pTimer[pStream->u8SD]);
703
704 const uint64_t tsNow = TMTimerGet(pThis->pTimer[pStream->u8SD]);
705
706 /*
707 * Make sure to not go backwards in time, as this will assert in TMTimerSet().
708 * This in theory could happen in hdaR3StreamTransferGetNext() from above.
709 */
710 if (tsExpireMin < tsNow)
711 tsExpireMin = tsNow;
712
713 int rc = TMTimerSet(pThis->pTimer[pStream->u8SD], tsExpireMin);
714 AssertRC(rc);
715
716 return RT_SUCCESS(rc);
717}
718
719#endif /* IN_RING3 */
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